(420 mm 190
191
).
A lotal =2x471=942mm 2
The factored weight of the vertical and horizontal beam equals to:
p" =0.35 feu Ae +0.67xfyXAs
ow. =1.4 x 25x (0.25xO.6 + 0.20xO.5) = 8.75 kN 1m'
Pu = (0.35 x25xI40x1000+0.67x360x942)/l000 = 1452 kN
The total factored load on the beam equals to:
Since the applied compression force is less than the section capacity, the section is considered adequate.
W
u
=R max +ow =55.68+8.75=64.43kN 1m'
,
w u =64.43 kNlm /
Step 3.2.3: Design for shear
l'
The applied shear at this section (Q') equals to zero.
Step 4: Design the vertical beam (250 mm x 600 mm)
.
.
, ill
I
I
The vertical beam is analyzed as continuous beam supported on columns
Step 4.1: Calculate the straining actions
-24
S=5.0
~
I
I I
S=).O
I ill
'I
-10 __________ __________-12 _____ k
JS,.
~
+12
:A
~
+16
4
161
Vertical beam
J
67.1
:A 134.2
~
~Bending . moment 100.7
134.2 tie
Critical sections
Step 4.2: Flexural design Sec. 1
=_w_S_2 = 64.43 X 52 = 134.23 kN.m
~
12
=
R
750
1
192
Mu feu b d 2
12
=
6
134.23 X 10 = 0.071 25x250 x550 2
193
(J)
=0.089
As =m
feu b xd =0.089 25 x250x550=850mm 2 fy 360
0.98 2
qsu =1.22---=0.73 N Imm
Choose 5 16 (As = 1005 mm2)
8 2 64.43 x 52 =-1-0- = 10 = 161.07 kN.m
The spacing of the reinforcement area is given by
W
I
Mu feu b d
As =m
2
=
6
161.'07 X10 25x250 x550 2
=0.085
~
ill
=0.11
feu b xd =0.11 25 x250x550 =1050 mm 2 fy 360
Choose 4 20 (As
=1256 mm
0.60 0.50
A
0.5 0.50
?Sf
:k7
I
.
s ,mm
Use spacing of 125 mm
= 0.4 b xs = 0.4 x250xl25 = 44.6 mm 2
The horizontal beam is analyzed as a continuous beam supported on the ties. It carries a uniformly distributed load equals to the horizontal thrust. This uniform load equals the horizontal reaction of 1.0 m strip of the arched slab.
Step 5.1: Flexural design Sec. 1 M
=w 8 12
2
2 92.8x5 = 193.3 kN.m 12 6
_ Qu _ 167.52x1000 2 qu - b xd - 250x550 = 1.22 N I mm
eu = 0.24
A
193.3 X10 = 0.079 25 x 200 x 700 2
Qu = 0.6X64.43X5.0-64.43X( 0~5 + 0;5) = 167.52 kN
1.5
~
Use ¢8 @ 125mm or 8
u
Qu =k q w u L-w u (~+~) 2 2
!I
s = 133 m
~
Step 5: Design the horizontal beam (200 mm x 750 mm)
The critical section for shear is at d/2 from the face of the middle support. The width of the column is 250 mm. The critical section is at section (I) as shown in figure with code coefficient of kq =0.6.
0.45
100 =0.73x250xs 280/1.15
2 )
Step 4.3: Design for Shear
qeu = 0.24
fy I Ys
sl
Using
Sec. 2
R =
= qsu xbxs
A
The secondary reinforcement is chosen as 0.1-0.2 As. Choose 2 12.
2
{25 = 0.98 N I mm Vl.5
OJ=
0.101
As =m feu bxd =0.101 25 x200x700=978mm 2 fy 360
Choose 4 18 (As = 1017 mm2) 2
The secondary reinforcement is chosen as at least 0.1- 0.2 As. Choose 2 12.
Since qu> qcu, shear reinforcement is needed.
194
~
195
step 5.3: Design for Shear Bending moment
Factor k
Loads
The critical section for shear is at the face of the column because the tie is in tension. The width. of the column is 250 mm. The critical section is at section (1) as shown in figure with code coefficient of kq :::0.6.
Critical sections
Qu =k q Wu L-w u
....
C'l
...
.
I
,
(%) 0.250)
Qu =0.6x92.8x5.0-92.8x ( -2- ::: 266.8 kN Shear
I
....+
\0
\II
tie
0 C'l
T
o ....
«)
\II
C'l
0
c
I
tri II
t-:l C'l ....
>n
1
+
c3
"':
00
\0
r-
0
~I
C'l
c
tri II
t-:l
Sec. 2
1
92.8x52 ::: -1-0- ::: 10 ::: 232 kN.m
>n
"': 0
.~
.....
R = 1
A s --
6
Mu = 232xI0 feu b d 2 25 X 200 X 7002 = 0.0946 (j)
---7
(0=0.124
Qu qu ::: b xd
25 X 200 X 700 = 1203 mm 2 ffeuy b X d = 0 .124 360 qeu = 0.24
Choose 4.<1> 20 (As = 1256 mm2)
196
266.8 X 1000 ::: 1.9 N I mm 2 200 x 700
E
-E!!..:::
1.5
~=
0.24 1.5
0.98 N I mm 2
197
1 .,
":\1 ":.
qumax =0.70Jlcu =0.70
,
1.5
{25 =2.85N Imm 2 VLS
. '.",.
~
loads
Reactions
Since qu < qumax, then section dimensions are adequate. However, since qu> qcu, shear reinforcement is needed. 0.98
qsu = 1.9 --2- = 1.4 N I mm ASI
tI)
2
In
-'"
~ ~ ,.....
0
qsu xbxs =..;;;.::;;=----Iylys
In
T
II
0
E-<
<:::>
Assuming a spacing of 125 mm, the shear reinforcement area is given by:
~
ori
:;:I
"'J
;J
II
A =1.4X200XI25=145mm2
~
tI)
280/1.15
.vI
In
~'"
0
. branch =_J1 A. = _145 = 72 mm 2 Thus, the area of one
2
...-: ,.....
\0
~
0
2
.9 ~
u
'"' 0
"'"
<:::>
ori II
Use ¢10@ 125mm -7 8¢101 m'
tI)
1
0.4 0 = 2 8mm 2
In
""= 0
..
'"
~ In
..q-
0
II
E-<
Step 6: Design of the tension tie (200 mm x 200 mm)
Step 7: Design of the hanger (200 mm x 200 mm)
The tie is the main supporting element for the horizontal beam. The reaction is transferred to the tie. For continuous beams with equal loads and equal spans, the ECP 203 gives the reaction at intermediate supports as (1.1 WU S), as shown in the figure below.
The weight of the hanger equals to: ow H = 25xO.2xO.2x2.4= 2.4 kN
The weight of the tie equals to: T =1.1xH max xS =1.1X92.8x5=51O.4kN
A = S
Iy
T = 501.4 x 1000 = 1630 mm 2 ILlS 360/1.15
Choose (6 18+2 16) (As= 1929 mm 2)
oW T
Hanger
= 25xO.2xO.2x2,667 = 2.667 kN
The total factored weight (tension T H)
tie '
T H = 1.4 x (2.4+ 2.667) = 7.1 kN _ T = 7.1xlOOO = 22.6 mm2 As - Iy IUS 360/1.15 .
2
Choose 4 101m' (As =314 rom )
198
199
Step 8: Design of the column (250 mm x 600 mm) Step 8.2: Calculation of the reinforcement
Step 8.1: Calculate applied loads The ~olumn is subjected to an axial load in addition to bending moments resultmg from the slenderness effect. Since wind load is neglected the fOllowing load case is considered . U
Item
=1.4xD + 1.6xL = 1.4x25xO.25xO.6x6.0 = 31.5 kN
2. weight of the wall beam +semelle (250x500)
W
wall beam
-t
vertical beam
)
Assuming Yw=18 kN/m3
4. Arched slab load = Reaction from the vertical beam = 1.1 xw u (vertical beam)xS
= 1.1x64.43x5 = 354.4 kN
1
I
I
R=O.45 WU L
I-
5.0
J
II
R=l.Owu L
5.0
• f.
568.3
568.3
Short column if
11,<10
11,<15
Ho (m)
6.0
2.5
(m)
0.6
0.25
bracing condition at top
case 3
case 1
bracing condition at bottom
case 1
case 1
1.6 (Code table 6-10)
0.75 (Code table 6-9)
He
9.6
1.875
A=kxHolt
16
7.5
10ng(A>10)
short (A> 15)
0.0768
0
43.6
0
43.6
0
Madd
I
R=l.l Wu L =354.4
Ultimate load P u(kN)
J = if Xt 12000
wu=64.43 kNlm'
J J J
braced
Status
p" = 31.5 + 43.75 + 138.6 + 354.4 = 568.3kN
I I I I I I II' I I
unbraced
k (bracing factor)
= 1.4x18xO.25x5.0X(6.0-2X0.5_0.60) =138.6 kN
Rarch
Y-direction
t
= 2x1.4xyc xb xt xspacing = 2X1.4x25xO.25xO.5X5.0 = 43.75 kN
3. Wallload=1.4xy, XbxSX(h-2xt
X-direction
bracing condition
The vertical load on the column is the summation of the following loads: 1. Self-weight = 1.4xyc xb xt xh
The unsupported length in X- direction is 6.0 ms and the unsupported length in y- direction is 3.4 ms. The calculation of the additional moment can be summarized in the following table.
-I
Loads and the reactions of the vertical beam
J J
lj
= Pu·J
Mtot = Mu+ Madd
It is clear from the previous table that the column is subjected to a uniaxial bending moment as shown in the figure.
~43.6kN.m y
1
0.25
I
I
I
-I-·_·_·_j·_·_·-l-·_·_·_·_·_?C
T I"
0.60
-I
200 201
vertical o-r-
7-
Team
\0
ci- I -
0
~- I--
-
I
~
'
N
0
column
0
~ ~ ~~S
~
tn
~r:Q
I--
I.C5
Il
~
i
(')
o
tn
N II
..c>< ~
I
I
co
o
......
semelle
i
C\I
B
j
B
i
(')
Calculation of buckling lengths (refer to the table)
i
(')
Using interaction diagram withfy==360N/mm2, a=1.0, ~=0.8, calculate
R = b
P" feu xb xt
= 568.3x1000 = 0.152 25x250x600 6
Mu 2 = 43.6x10 =0.019 feu xb Xt 25x250x600 2 The intersection point is below the chart -7 use !lmin Since the column is long, the minimum reinforcement ratio Ilmin is given by: fJmin = 0.25+0.052,.1. = 0.25 + 0.052x16.0 = 1.1082%
FI
1.1082 2 As min = PlIlI'n xb Xt = - x 250x600 = 1623 mm . 100 Choose (8 $18, 2035 mm 2).
202
203
T"" I T""
o Q)
C/)
DEEP BEAMS AND CORBELS I ooc! I
009
0017.
C\I
'.
J
J:
~·f
iC\I
t
I
-G. co
8<0
~ on c: E
0 0
~ 0
C\I
C\I
::J
(5
0 I
@
1
2
~
-
..,.
I
w i=
c =
~ Q:I
t
2
!';r;l
f-
2
I
1 1
I-
S
Q:I ~
-
I:Q Q:I
U ~ J,., ~
Photo 2.1 Corbels supporting beams in a stadium
;;... 1
~
-
I
-f-
0 0 0 <0
~
C\I
~ C\I
1
f-
0 0 0 <0
C\I ~
co
~ ..,.
I
·r ~H
~:.....J
I
204
I
1
~
J~
2.1 Introduction This chapter will discuss the behavior of reinforced concrete deep beams and corbels (short cantilevers). The behavior of these members is different· from shallow (slender beams). In deep beams and in corbels, plane sections before bending do not remain plain after bending. In order to fully understand the behavior of these members, the subject of shear friction will be presented. Another approach for designing these members is the Strut and Tie Model that will be presented in Chapter Six of this volume.
205
2.2 Deep beams 2.2.1 General Deep beams are beams of relative) hi h d . deep beams OCcur as transfer girde!s Agtran:~th-t~~pan ratIO. Most typically, e~ glr er supports the load from one or more columns transferring it ~o oth er co umn~ (Fig. 2.la). Deep beams also occur in tanks and walls supported . on co lumns (Flg.2.lb).
Transfer girder
Deep beams may be loaded at their top surface as in the case of a transfer girder supporting the load from one or more columns (Fig. 2.2a). The loading may take place at the bottom surface as in water tank wall loaded by the action of the suspended tank's floor (Fig. 2.2b). Loads may also act along the height of the wall as shown in Fig. (2.2c). The wall in this figure approximates the case of wall supporting successive floor slabs and transferring the loads to columns at ground floor level.
(a)
(b)
Fig. 2.2 Types of loading of deep beams
(a) Transfer girder
(b) Elevated water tank Fig. 2.1 Typical examples of deep beams Photo 2.2 Deep beam supporting columns (Brunswick Building, Chicago) 206
207
Elastic analysis of deep beams indicates that the usual assumption that plane sections before bending remain plane after bending is not valid for such members. Thus, flexural stresses are not linearly distributed even in the elastic range. Typical stress distribution is shown in Fig. (2.3a). The cracking load of a deep beam is about 1/3 to 1/2 of the ultimate load. Traditional principles of analysis and design of ordinary reinforced concrete beams are neither suitable nor adequate to determine the strength of reinforced concrete deep beams. The cracking pattern of a uniformly loaded deep beam is shown in Fig. (2.3b). After cracking a major tedistribution occurs and the elastic analysis is no longer valid. Deep beams loaded at the top behave mainly as a tied arch as shown in Fig. (2.3c).
..
Tension
..
Figure 2.4a shows a deep beam that is supporting uniformly distributed load acting at the lower face of the beam. Vertical stirrups must be provided as hangers to prevent local failure and to transfer the effective acting load to a higher level. If such a beam is provided with stirrups that are able to deliver the bottom load to the upper part of the beam, the beam will be behave nearly like a top loaded beam. The crack pattern in Fig. 2.4b clearly shows that the l~ad is transferred upward by reinforcement until it acts on the compression arch, which then transfers the loads down to the support as shown in Fig. 2.4c.
a) Loading pattern
b) Cracking pattern
c) Arch mechanism
(e)
Fig. 2.4 A bottom loaded deep beam a) Normal stress
b) Cracking pattern
c) Arch mechanism
Fig. 2.3 Top loaded deep beams The tied-arch mechanism, shown in Fig. (2.3c), brings designer attention to the fact that longitudinal tension reinforcement acting as a tie that is fully stressed over neady the whole span. Therefore, sufficient anchorage at the supports and continuity of reinforcement bars without curtailment are essential requirements for top loaded deep beams.
208
209
2.2.2 Egyptian Code's Provisions for Deep Beams
A: Design for Flexure
The Egyptian Code's provisions for deep beams are applied to deep beams loaded at the top or at the compression faces. If loads are applied at the bottom of a deep beam, the Egyptian Code requires using vertical reinforcement that is able to transfer the load to a height equals at least half the span. This. vertical reinforcement should be added to that resulting from the design of the beam as if it is a top loaded deep beam.
The longitudinal reinforcement should be provided to resist the tension force that resulting from the applied bending moment. The tension force at any section is gi ven by:
In deep beams plain sections do not remain plain after bending and the design methods developed for shallow beams can not be applied. The Egyptian Code presents two methods for designing deep beams. These methods are:
Where Mu is the applied ultimate moment, Tu is the developed tension force at the critical section, and Yet is the lever arm and is given by:
• •
The Empirical design method The Strut and Tie method
The empirical design method applies to beams having the following ratios of the span (L) to the effective depth (d): Simply supported beams: (L / d)<1.25 .................. (2.la) Continuous beams: (L / d) < 2.50 ........................... (2.1 b) where L is defined with reference to Fig. (2.5) as the smaller value of the following:
= 1.05 Ln ............................................ (2.2a) L .
=L
0
................................................ (2.2b) I
d
= M u ...................: ........................... (2.3) Yel
Yct =0.86 L::::;0.87d
For simply supported beams.
YC1 =0.43 L::::;0.87d
For continuous beams at mid-span.
Y el
2.2.2.1 The Empirical Design Method
L
Tu
= 0.37 L::::; 0.87 d
For continuous beams at interior support.
The reinforcement can be obtained by dividing the developed tension force by the steel yield stress as follows: A = S
Tu ........................................... (2.4) fy /1.15
The distribution of this reinforcement differs from that of the slender beams. The flexural reinforcement is placed near the tension edges. Because of the greater depth of the tension zone, it is required to distribute such steel over a certain height of the cross-section (See Figs. 2.7 and 2.8). The tied-arch mechanism of deep beams dictates that longitudinal tension reinforcement acting as a tie is fully stressed over nearly the whole span of simply supported deep beams. Therefore, sufficient anchorage at the supports and continuity of reinforcement bars without curtailment are essential requirements. Recommendations for the detailing of deep beams are given in Figs. 2.7 to 2.10. The Egyptian code requires that the actual area of steel be greater than Asmin given by:
L
I. 1--1.----:-L~:----1,1.
1
Fig. 2.5 Definition of a deep beam 210
211
As
in any section should
0.225
A Sflltn. = smaller 01· {
but not less than
JJ: ~.!J.b d
f y.
fy
Nominal Ultimate Shear Stress
........................,(2.5)
The applied shear stress is given by:
1.3 As
qu = b:Ug
'{0.25 b d (mild steel) } 100
Where b is width of the beam, and g
qumax =bd xO.70
B: Design for Shear The design for shear in deep beams is of special importance. The amount and spacing of both the vertical and horizontal web reinforcement differ than those used in shallow beams, as well as the expressions that to be used in design. The critical section for shallow beams is taken at a distance d/2 from the face of the support, and the shear plane is inclined more and closer to the support. However, in deep beams, the critical section for shear is to be taken as: Uniformly distributed ~ x = 0.15 Ln ................ (2.6a) Concentrated load
~
x = 0.5 a ..................... (2.6b)
In either case, the distance x should not exceed the distance d/2 as shown in Fig 2.6 .. If both uniform and concentrated load exist on the beam, design the most critical one.
!
!
V~ I
I
I
i
I
.
i i
i
i i i
Critical sections
i
i -
I
i i
I
i ~I
i
i
l
i
~ I i I
i i
.i a) Unifonn Load x < dl2
Ln b) Concentrated Load x < dl2
(2.8)
It interesting to note the Od is less than or equal to one. This could wrongly imply that the maximum shear strength is less than shallow beams. However, this requirement is intended to prevent bearing failure in deep beam rather than controlling shear failure.
Shear Strength provided by Concrete The nominal ultimate shear provided by concrete is given as follows: No axial load
q cu =bdc XO.24!iU Yc
~0.46~CU
............................ (2.10a)
Yc
Where
bdc = 3.5 - 2.5 M u Qu d
~ 1.0 ~
2.5 Mu : is the ultimate moment at the critical section. QII: is the ultimate shear at the critical section. The factor b dc is a multiplier for qcu in shallow beams to account for the higher resisting capacity of deep beams due to arching action.
Fig. 2.6 Critical sections for shear design 212
••••••••••••••••••
If q u ~ q u max' the dimensions of the section should be increased
!
V~
fY:
2
bd =1/3 (2+0.4(Ln Id))~1 ................................ (2.9)
i
!
fl: ~(bd 4.0)N Imm
in which
•
Critical sections
the smaller of d or Ln
The value of the nominal shear stress qu should be less than qwnax given by
0.15 b d (high grade) 100
i
=
~qumax .......................................... (2.7)
213
•
Axial compression (Pu )
qcu =Odc xOc
0.24~cUY
H
............................. (2.10b)
c
where
ILJJIIIIIlllllllllllllJIIIllll
P
0;, = (1 + 0.07 AU ):::; 1.5 c
•
~t
Axial tension (Tu)
qou = ode where
X
q
0.24
~cu Yo
............................. (2.lO c)
3 ® --..... H
0, = (1- 0.3 Tu )
®
4
Ac A limiting value is placed by the code on qcu by the equation:
qcu :::;
0.46.J~:u .................................... (2.10d) ~ve)
To design the beam for shear, two cases should be considered
If the value of qu does not exceedqcu, minimum shear reinforcement in the form of vertical and horizontal web reinforcement as shown in Fig. (2.7) should be provided. The minimum values are given with reference to Fig. (2.7) as follows:
Av
= (0.20/l00)b Sv
............................ for mild steel
®
(2.11a)
Av =(0.l5/100)bsv ..................... forhighgradesteel (2. 11 b) Fig. 2.7 Reinforcement detailing of a top-loaded simply supported deep beam
A"
= (0.30/100)bs"
A"
= (O.251l00)bs" .................... forhighgradesteel
svor Sh should be less than 200
............................. formildsteel (2.1le) (2. 11 d)
mm
The purpose of providing ininimum web reinforcement is to limit erack width along the surface area of the beam.'
214
215
2.2.2.2 Design Using the strut and Tie Method If, on the other hand, the value of q u exceeds q cu' web reinforcement should be provided to resist the ultimate shear stress q su • For deep beams in the ranges of the Lid ratios considered, diagonal cracks will be at a slope steeper than 45°. Consequently, both horizontal and vertical web reinforcements are required. In fact, for such Lid ratios, horizontal reinforcement could be more effective than vertical reinforcement. The horizontal bars are effective because they act more nearly in the direction perpendicular to the diagonal crack. The ECP-203 gives the following equations for calculating the web reinforcement for deep beams:
qsu =qu - q;u .......................................... (2.l2a) qsu =b;, xqsllv +0" xqsuh ........................ (2.12b)
The Egyptian Code permits the use of the Strut and Tie Model (explained in detail in Chapter 6) to design the beams in which the ratio of the effective span to depth satisfies the following conditions:
A., Simply supported beams 1.2S::;'Lld ::;'4.0
B- Continuous beams 2.S ::;, Lid ::;, 4.0 The model consists of compression struts in the concrete and tension ties in the steel reinforcement and truss nodes as shown in Fig. 2.8. The detail of the application of the method for the case of deep beams is explained in Chapter 6, together with illustrative examples.
in which
0" =
ll-(Lllld) 12 .................................... (2.13a)
°v -_l+(Lllld) 12 qsuv = q,u" =
xb
A" x(fy Irs> Sh
xb
Truss node
. ..................................... (2.13b)
Av x(fy IrS> Sv
p
................... : ............. (2.13c)
.
Compression
Compression
strut
strut
................................ (2. 13d)
It can be concluded from Eq. 2.12 and Eq. 2.13 (as stated above) that horizontal reinforcement is more effective than the vertical web reinforcement. Equation 2.12b has four parameters (Av. Sv. All. SII). It is customary to assume the value of these parameters and calculate the value of the shear carried by the reinforcement qsu. The value of qsu in Eq. 2.12b should be greater than required shear stress qsu given by Eq. 2.12a. Thus, assume three of these parameters to obtain the fourth unknown. Figure (2.7) shows the recommended reinforcement detailing of a simply supported top-loaded deep beam.
216
Tie force, T
Fig. 2.8 Strut and tie model for a deep beam
217
2.2.3 Detailing of Other Types of Deep Beams 2.2.3.1 Bottom Loaded Deep Beam Figure 2.9 shows the reinforcement detailing of a bottom loaded deep beam. As mentioned before, a bottom loaded deep beam could behave nearly like a top loaded one if provided with vertical stirrups that are able to deliver the bottom load to the upper part of the beam. It should be mentioned that these vertical stirrups should be added to those required as shear reinforcement. The Egyptian Code does not give special recommendations for the design of the bottom loaded deep beam. However, it implicitly recommends designing them as shallow beams.
O. 15L t
O.15L t
O.70Lt
® @
®'
~
:r
~ @ c
~ 1111111111 111111 ~1I1111 ! \. I•
,I L
.\
,
!
Photo 2.3 Multistory reinforced concrete buildings
Lt.1
2.2.3.2· Continuous Deep Beams
®
Continuous deep beams can be designed in the same fashion as simply supported deep beams, except that additional reinforcement is provided at the location of the middle support. Figures 2.lOa and 2.lOb show the recommend detailing of the reinforcement of continuous deep beams loaded at the top and at the bottom, respectively.
Fig. 2.9 Reinforcement detailing of a bottom-loaded simply supported deep beam 218
219
IA
- --, - -,.-
.
"
_._-
_. - -
v.uv
I I\i IfI I I I I I I I I I I I I I tl I I
,
v.vv
L..
I I I
L.
~
I I I, I I III I I I I I
@ 0.80 I «0.8 .)
- , JfL I As
+vel
CD
Ll I
tv tv
I
rE-
o
J:
,
0.40 H «0.4 L)
As(-vel/2
L?
IS!
As(-ve)/2
L!,\
___CD
~
@
rI-h
1- The main bottom steel should cover the whole span.
@
@
2- One-half of the main top steel should be located at a height (0.8H< 0.8l) and should cover the total length of the beam. 3- Span variations and variations in loads should not be more than 20%. 4- In case of span variations, (l) is the bigger span.
@
@
Sec. A-A
Sec. 8-8
Fig. 2.10a Reinforcement of a top-loaded continuous deep beam
w
IB -
--,
-1'-
U.
I
\
As (top)
U.
U.VU L.
U.
I
I
,
@ 0.80 I «0.8 .)
J:
DAD H «0.4 L)
,-1
J IIU(.l)I~L: I I f I IIIJ(_l)J IL,I I II~ fl I 'LU)"I !, I Ipi I rrr IA
tv
tv ,.....
rE
-+,
ill @
CD 1- The main bottom steel should cover the whole span. 2- One-half of the main top steel should be located at a height (0.8H< 0.8l) and should cover the total length of the beam. @ 3- The vertical steel should be designed to deliver the bottom load to the upper part of the beam. 4- Span variations and variations in loads should not be more than 20%. Sec. A-A 5- In case of span variations, (l) is the bigger span.
@
@
Fig. 2.10b Reinforcement of a bottom-loaded continuous deep beam
@
Sec. 8-8
LJW
2.2.3.3 Deep Beam Supporting another Deep Beam
2.3 Shear- Friction Concept
Special provisions are needed when loads or reactions are introduced along the full depth of a beam for example, when deep beams support each other, as illustrated in Fig. (2.11).
There are many situations in reinforced concrete stru..:tures where it is necessary to transfer shear across planes of weakness such as interface between concrete cast at different times. Shear-friction concept provides a simple but poweiful model to investigate situations such as those shown in Fig. (2.12).
®
-
-~
A
"-
/
v
@
" ®
,
Cast-in-situ
" "" "
7' 7'
"
7'
~
7'
I"
7'
:r
®
~+ve) I
'
. . . . . .4
••••••
I.
:
(a) Precast beam supporting cast-in-situ slabs
(b) Corbels
Fig. 2.11 Deep beam supporting another deep beam Fig. 2.12 Applications of shear friction concept
222
223
Typical examples are reinforced concrete bridges in which the deck is cast-insitu concrete slab supported on precast girders as shown in Fig. 2.12a. Another example is corbels supporting crane girders.
Shear displacement ':"
~
UIllllllJ
--
Q
L-
--
Q
I-I -,,-,.-, -,I Shearstress=JlT T =tension in I Compression in concrete =C reinforcement t a) Shear displacement causing crack opening
b) Free-body fiagram
c) Aggregate interlock at crack interface
Fig. 2.13 Mechanism of shear friction
Photo 2.4 Short cantilever supporting prestressed beams The basis of this model is explained in Fig. (2.13). When shear is applied to an initially cracked surface, or a surface formed by placing one layer of concrete on top of an existing layer of hardened concrete, relative slip of the layers causes a separation of the surfaces as shown in Fig. (2.13a). If there is reinforcement across the crack, it is elongated by the separation of the surfaces. The elongation of the reinforcement means that it is stressed in tension. For equilibrium of the free body diagram at the interface, a compressive stress is needed as shown in Fig. (2. 13b). Figure 2.13c shows aggregate interlock at crack interface. Photo 2.5 Aggregate distribution in concrete section 224
225
Shear IS transmitted across the crack by:
Table 2.1: Values of J.1 according to surface condition Crack Interface Condition JI. 1 Concrete cast monolithically 1.20 0.80 2 Concrete cast against hardened concrete with surface intentionally roughened 3 Concrete cast against hardened concrete not 'intentionally 0.50 roughened or concrete anchored to structural steel by headed studs or bars.
1. Friction resuJting from the compressive stress. 2. Interlocking of aggregate protrusions on the cracked surfaces combined with dowel action of the reinforcement crossing the surface. . .
.
The shear stresses on the concrete face are assumed to be related to the compressive stresses by a coefficient of friction !-t. The maximum capacity is assumed to be reached when the reinforcement crossing the crack yields leading to a shear resistance of:
Q = As!ly Iys JI. ................................................. (2.14)
-------.- ......
where As! is the area of reinforcement crossing the surface and fY its yield strength. Equation (2.14) states that the resistance to slip is equal to the nonnal force times the coefficient of friction J.1.
~
Tests have shown that shear-friction capacity is also a function of the concrete strength and the area of contact. As the concrete strength and the area of contact increase, the aggregate interlock mechanism becomes more efficient aI?-d the shear friction increases. Hence, there is an upper limit qn the shear resistance due to friction:
Q= constant (feu Ae ) ................................... (2.15) where
A is the area of contact. The area of reinforcement that crosses the crack
.
Crack
As!(Fig. 2.14) is given by the Egyptian Code as: AS!
=
Qu
JI.
Iy I Ys
......................................... (2.16)
If the section is subjected to a tension force in addition to the shear force, additional steel should be provided as given by the following equation: Aif
=
Qu
+~ .................................... (2.17)
Fig. 2.14 Shear friction reinforcement
The values given by the Egyptian Code for the coefficient of friction (JI.) are
The steel must be placed approximately uniform across the shear plane so that all parts of the crack are clamped together. Each bar must be anchored on both sides of the crack to develop the yield strength. .
given in Table 2.1.
The ultimate shear (Qu I A) shall not exceed the following limits:
s
JI.
Iy I Ys
Iy I Ys
qu
=Qu I Ac
~
0.151cu ................................... (2.18a)
qu =Qu I Ac ~ 4.0 N I mm 2
226
227
••••••••••••••••••••••••
(2.18b)
2.4 Short Cantilevers (Brackets or Corbels) Corbels or brackets are short cantilever members that project from a column or a beam to support another beam or heavy concentrated load. The importance of these members is clear in precast buildings where corbels support beams and girders. Therefore, the total safety of these types of structures depends on the ability of the corbels and brackets to transfer the load safely to the columns. Steel bearing plates or angles are commonly used in the top surface of the brackets to provide a uniform contact surface and to distribute the reaction. Short cantilevers are defined by the Egyptian Code as cantilevers whose shear span-to depth ratio (aid) is 1.0 or less (See Fig. (2.15». This small ratio changes the pattern and distribution of stresses similar to the case of deep members. In corbels, a large horizontal force develops due to shrinkage and creep of the supported elements such as beams that are connected to the corbels.
The structural action of a short cantilever can be idealized as a truss made up of a compression strut and a tension tie as shown in Fig. (2. 16a). The inclination of the strut determines the tension in the tie by a simple force polygon. Since the tension tie supports a constant tension force, sufficient anchorage of bars should be provided beyond the corbel interface with the column. Failure of the strutand tie model could occur as a result of yielding of the tension tie; failure of the compression strut, or failure of the end anchorage of the tension tie. A direct shear failure could also be a possible mode of failure along the face of the column as shown in Fig.(2.16b). Local failure under the bearing plate could occur. Finally, if the corbel is too shallow at the outside end, there is a danger that cracking may extend through the corbel as shown in Fig. (2.16c). For this reason, ECP 203 requires the depth of th~ corbel to be O.Sd at the outside edge of the bearing plate.
The code provisions apply to short cantilevers in which the depth at the outside edge of the bearing area is not less that (O.Sd) where d is the depth m~asured at column face. Short cantilevers are designed to support beams transferring vertical reactions Qu ' Horizontal force (N u) caused by restrained shrinkage,
,--_-=,,--Nu
Shear friction reinforcement
)---<=l-,--
creep in prestressed beams and expansion or contraction effects. Therefore, it is advisable to consider a minimum horizontal force, Nu = 0.2Qu'
a (b)
(a)
~
t
d/2
d
(c)
Fig. 2.15 Definition of a Corbel according to the Egyptian Code
228
Fig. 2.16 Failure modes of corbels 229
Nu
The Egyptian Code requires that reinforcement be arranged as shown in P(2.17). The main tension reinforcement is calculated to resist a moment (M u )lg. at column face and a normal force (N u) .
Mu =Qu a+Nu (t+ll-d) ............................ (2.20)
The area of steel required to resist the tensile force (N ;::: 0.2Q ) is given by.. U
A I!
3
As
p
Ah
,/
.
The shear-friction reinforcement (A.j) calculated using the shear-friction concept is given by: . Ai!
=
s
Qu
Jl (/y 1YS)
+~ .................................. (2.21)
Iy I Y.
Corbel reinforcement consists of three types: 1. Main reinforcement. 2. Horizontal stirrups. 3; Vertical stirrups.
1. Main Reinforcement Vertic
7
r
CI ased st.
1/
Main steel,
, 7
2d
Il
Nu . -I I ....................................................... (2.20) y Ys
-- --------
The bending moment is calculated as follows (refer to Fig. 2.15). The flexural reinforcement Afis calculated using regular sectional analysis.
,,"~
I
------ -
The total main top steel As is the greater of the following:
= AI! + Af ................................................ (2.22a)
1.
As
2.
As =An +2/3Asf ...................................... (2.22b)
3.
A. min
=
O.03j: bd .............................·.· . · (2.23)
where b is the width of the corbel.
Fig. 2.17 Reinforcement of corbels 2. Horizontal Stirrups The horizontal shear reinforcement, All, consists of horizontal closed stirrups uniformly distributed in the top 2/3 of the cross section. This area is given by: Ah =0.5 (As -An) .................................... (2.24)
3. Vertical Stirrups Corbels should also be provided with vertical stirrups that satisfies the minimum requirements of the ECP-203.
A" = 0.4 b Iy
s ........................................... (2.25)
where s is the spacing ofthe vertical stirrups.
Photo 2.6 reinforced concrete buildings 230
231
Example 2.1
Solution
A transfer girder is to support two columns, each having a factored load of 7500 kN as shown in the figure. Its clear span is 7.0 m. The girder has to carry also a factored uniform load, including its weight, having a value of 206.5 kN/m'. The material properties are feu = 25 N I mm 2 and fy = 360 N I mm 2 •
Step 1: Check the applicability of the empirical method Lett
= smaller of
1.05 x clear span = 1.05 x 7.00 = 7.35m {
CL.to CL. = 7.8 m
Design the beam using the empirical design method presented in the Eep 203 :. Lejf =
7500 kN
7.35m
Assume the distance from the bottom fibers to the center of the tension ~ d = 6000 -100 = 5900 mm reinforcement = 100 mm
7500 kN
~ = 7.35 = 1.245 < 1.25 d
5.90
Since the (d / Lett) < 1.25 (simple beam condition), the empirical method can be applied.
Step 2: Flexural design Y ct = smaller of {
E E o o o
:. Yet
0.86 Lett = 0.86x7.35 = 6.32 m 0.87 d = 0.87x5.9 = 5.133 m
= 5.13m
CD
I
F=2.275
2.8
·1
--t.lq.891
7.00 m - - -_ _
Bending moment diagram
232
233
.
Mmax(atIDld-span)=
w
X
u
L2
8
I
+PuxL =
206.5 X 7.35 2 8 +7500x2.275
7500
7500 w u =206.5 kNlm'
= 18457 kN:m
1~457x106. = 11493mm 2 5130x 360'/1.15
0.
225
A.min =smaller of
fy
.JJ::
{
.\
0.22555 x650x5900=11984 mm2 360 .
l.3A. =1.3x11493=14941mm 2 8258.8 r--,-,....;.,'"---_
R
Q=8006kN
But notless than 0.15 b d = 0.15 x 650x5900 = 5752 mm 2 100 100 . (-)
Use 20 28 mm(=12315 mm2), arranged in three layers.
8258.8
Shear diagram
Assume that the top steel equals 15% ofthe bottom steel Use (As) 4 25
Step 3.2: Check the adequacy of the concrete dimensions
mID.
Step 3: Shear design
Average shear stress at the critical section is given by:
Step 3.1: Straining actions at the critical sections The Cntical section for shear is at O.5a from the face of the support but not more than d/2 from the face of support.
•
o
(CL distance)
.
735 R = 206.5 x -'- + 7500 = 8258.88 kN 2
Q = R -w u x = 8258.88 - 206.5 x 1.225 = 8006 kN X 2
12 = 8258.88 x 1.225 - 206.5 x 1.225 2 /2 = 9962 kN .m
234
=2.09N /mm 2
650x 5900
Maximum allowable shear stresses, q umax =
At the critical section for shear, the straining actions are:
M u = R x -w u
3
qu
o
•
(g is the smaller of d (5900 mm) or L eff(7350 mm))
= 8006 x 10
a /2 = 0.5(2500-400) = 1050mm
d /2 = 5900 = 2950mm 2 x = 7.35 - 2.8 - 2x 1.05 = 1.225m 2
Qu qu = b xg
ad
.
ad
x 0.7 .Jlcu
/ Yc ::;; ad x 4
1 L =3(2+0.4--:-)
ad = !(2 + 0.4 7.0) = 0.825 3
q umax
5.9
= 0.825 x 0.7.J25/1.5 = 2.35N / mm 2 < 0.825x 4 ..... -+o.k .
Since the average shear stress at the critical section is less than the maximum allowable shear stress, the concrete dimensions are adequate.
235
Step 3.3: Calculation of shear carried by concrete qsu =1.13= b~(' =3.5-2.5(M u IQu d )
> 1.0 < 2.5
~/e = 3.5 - 2.5 x (
Take
9962 ) = 2.97 > 2.5 ~ 8006 x 5.90
ode
= 2.5
The concrete shear strength qcu is chosen as the smaller of: 1. qcu =~/e
X
0.24 Jfcl/ 11.5 =2.5xO.24·h511.5 =2.45N Imm 2
2. qcu = 0.46 Jfcl/ 11.5 = 0.46 .J25/1.5 = 1.88N 1mm 2
Sh
~
360 [0.182(226)+0.818(400)] 650x1.15 200 s"
S"
=
152.8 mm
= 150 mm (satisfies code requirements)
Note: q su (provided) = 1.15 N 1mm 2 > q su (required) = 1.13 .
~
O.K.
Check the s(ltisfaction of the minimum web reinforcement A",min
= 0.0015 b s" = 0.0015x 650x 200 = 195 mm 2
A",min
= 0.0025 b Sh = 0.0025x 650x 150:= 244mm 2
qcu =1.88 N Imm 2 The average shear stress at the critical section is more than the shear can'ied by concrete. Web reinforcement (vertical and horizontal) needs to be designed.
4 ~ 25
Step 3.4: Design of web reinforcement _1~2@200mm
qsu =qu -0.5qcu =2.09_1.88 =1.15N Imm 2 2
Oh =
(11 - Lid) Il
12
°_+ v-
( 1 LII / d) _
12
(Vertical)
7.0) (1 I - -5 9 = . =0.818 12
~16@150mm
(1 + L~)
-
(Horizontal)
5.9 =0.182 12
JO~2B
or 0,. =1-0" =1-0.818=0.182
6~28
qsu
_ If' [0,,(A,,) +u,,(-) s: A" ] -b rs s" s"
®
~
Try vertical bars of diameter 12.0 mm (2 branches) and horizontal bars of diameter 16.0 mm (2 branches). and Assul'Il:e s v = 200 mm
A"
::=:
400mm 2
14~28
CD CD--=:jJ ®
(satisfies code requirement) Reinforcement details 236
237
I Example 2.2
Step 3: Area of main reinforcement: The bending moment acting on the bracket equals to:
Determine the required reinforcement for the bracket shown in figure according to the following data: Bracket dimensions (b x t)
=300 mm x 800 mm and d =750 mm,
2
feu = 25 N I mm and fy = 240 N lmm
2
Mu
= Qu·a + Nu(t+ /::i-d)
M u = 500 x 0.4 + 100(0.8 + 0.05 - 0.75) = 210kN .m, Mu =0.67/cu h.ar(d -af 12) Yc 25 M =210x10 6 =0.67x-x300xal x(750-af 12) u 1.5
Factored vertical load Qu =500 kN Factored horizontal load Nu= 100 kN
af --88
--.,-------
>0.1d 6
______ 2_10_x_1_0__ _ _ _ _ =1425mm 2 (750-88/2)x 240/1.15 b 3 I' . I 100xl0 =479 mm 2 240/1.15
400 1 Qu= 500 kN
.-- o.o5-i-l-I
Nu = 100 kN
n
o
Iy 1Ys
o
E E
LO
~~/ 500
Aif=
s
Step 1: Check the bracket dimensions: To be classified as a corbel, the distance a should not exceed the effective depth. d =750 mm > a (400 mm) -+-+ok.
Step 2: Check the ultimate shear friction value: but not more than 4 N/mm2
Qu f.lly1ys
- 500xlO A if-
3
1.2x 240 1.15
238
AI xf).
Y.,
Iylys
+ 100x1
03
240/1.15
-2476
-
c
=1.2 mm
2
O.67 x fcu 1.5
The area of the main reinforcement is the largest area obtained by evaluating three equations:
The first equation As =An +AJ Then As =479+1425 = 1904mm
2
The second equation 2
500x103 = 2.22::;;0.15x25 =3.75 N Imm 2 O.K. 300x750
---
+~
For monolithically cast concrete f.l
s
;~ ::;;O. 15f eu
.....
=~=
A
-As = An +'3 AsJ . 2 2 then As =479+-x2476=2130mm 3
239
The third equation 5$25
A = 0.03 feu bd =0.03x 25 x300x750=703mm2 S fy 240 Hence, the area main reinforcement is obtained from the second equation. A. = 2130 mm 2 "
Use 5
Step 4: Find the area of the horizontal stirrups Ah = 0.50(A" -An) = 0.50(2130 -479) = 826 mm 2 This area has to be distributed over 2/3 of the effective depth, i.e. over a distance equals to (2/3x750) = 500 mm.
1/
7 Close_d_s_t.-t-il-'
'---~
6$12/m
Choose closed stirrups (two branches) having a bar diameter spaced at 166 mm.
= 12
mm and
The available area of horizontal stirrups = 113x2 x(5001166 +1) = 906.7 mm2 > 826mm2 O.K. Reinforcement Details
Step 5: Find the area of the vertical stirrups Assume that the spacing of the vertical stirrups is 200 mm. 0.4 b 0.4 2 As, =p.rrun b s =-x xs =-x300x200=1OOmm fy 240 '
Choose vertical stirrups (two branches) having a bar diameter =8 mm and spaced at 200 mm. The available area =50 x 2 = 100 mm2
240
O.K.
241
CONTROL OF DEFLECTIPNS
Photo 3.1 A cable-stayed bridge during construction
3.1 Introduction The Egyptian Code is based on the limit states design method. The limit states (states at which the stru'.":ture becomes unfit for its intended function) are divided into two main groups: those related to collapse and those that disrupt the use of the structures but do not cause collapse. These are referred to as ultimate limit states and serviceability 'limit states, respectively. The major 242
serviceability limit states are excessive deflections, undesirable vibrations and excessive cracking. Deflection control will be thoroughly presented in this chapter. Control of cracking will be discussed in chapter four. The adoption of the limit states design method in recent years, accompanied by the use of higher strength concrete and high-grade steel, has permitted the use of relatively shallower members. As a result, deflection calculations gained more importance than they were few decades ago. Excessive deflections of beams and slabs may cause excessive vibrations, damage to the appearance of the structure, poor roof drainage, and uncomfortable feelings for the occupants. Also, such deflections may damage partitions and cause poor fitting of doors and windows. Therefore, it is very important to maintain control of deflections. The Egyptian code presents the following two approaches for controlling deflection: •
Control of deflection by limiting the span/thickness ratio of the member.
•
Control of deflection by calculating the deflection and set limitations to its value.
yielding of reinforcement
-g
D
to the ultimate load service load
.3 cracking Load - - - - uncracked stage
I
Cracking stage
o
Midspan Deflection 11
The first approach indirectly controls the deflection by setting an upper limit for span-to-thickness ratio. It is simple to follow without the need for deflection calculations. However, if smaller members are required, the second approach should be followed by calculating the deflections and comparing the computed values with specific limitations imposed by the code.
3.2 Load-Deflection Behavior of RC Beams Figure 3.1 shows the load deflection response of a reinforced concrete beam. Initially, the beam is un cracked and is stiff. With further loads, cracking occur at mid-span when the applied moment exceeds the cracking moment of the beam. When a section cracks its moment of inertia decreases leading to a significant reduction in the stiffness of the beam. This is the start of the cracking stage. At this stage, the beam continues to carry load but with relatively large deflection. Eventually the reinforcement yields at mid-span leading to a large increase in deflections with little change in load (points C and D). .
Fig. 3.1 Load-deflection response
3.3 Moment of Inertia of RC sections
Since the service load of any member is about 65% of its ultimate load, the service load level of the beam in Fig. 3.1 can be represented by point B. Longterm application of service load (sustained load) results in increasing the deflection from point B to B', due to creep of concrete. The short-term, or immediate, deflection under service load (point B) and the long-term service load deflection (point B') are both of interest in design and will be discussed later. 243
3.3.1 Gross moment of inertia As mentioned in the previous section, if the applied moment is less than the cracking moment, the section is considered uncracked. In this case, the moment of inertia of the section equals to Ig (uncracked stage) as shown in Fig. 3.2.
244
Maximum tension
cracking Loa cracking stage
19>1. >ler
'
tension
uncracked stage
a- Negative bending moment
Ie=Ig Midspan Deflection 11
b-Positive bending moment
Fig. 3.3 Determination of the distance Yt in simple and cantilever T -beams 1\
Fig. 3.2 Moment of inertia in concrete beams
3.3.2 Cracked Transformed Moment of Inertia For design purposes, the calculation of the gross uncracked moment of inertia, , I g, can be carried out by neglecting the cross-sectional area of steel reinforcement (e.g. Ig for rectangular sections = b e/12). For normal reinforcement ratios, the error in calculating Ig does not exceed 10%. The ECP 203 gives the following formula for calculating the cracking moment: fetr· I g
Mer = - - ................................................ (3.1)
Yt where !clr is the concrete tensile strength (N/mm2), Ig is the gross moment of inertia neglecting the effect of reinforcement (mm4), and Yt is the distance from the neutral axis to the extreme fiber in tension for the uncracked section (mm). "In the ECP 203, the concrete tensile strength!c,r is given by: fetr
=0.6.,JJ:: ...........................................:... (3.2)
For rectangular sections, YI equals to half the section thickness. For T -sections the reader should pay attention to the direction of the bending moment. Thus, for T -section in cantilever beams the distance YI is measured from the top fibers Fig.3.3.a and for T-sections in simple beams it is measured from the bottom fibers as shown in Fig.3.3.b.
245
When the applied moment exceeds Mer. the developed tensile stress exceeds the tensile strength of concrete producing cracks as shown in Fig. 3.4. The developed cracks will cause the moment of inertia to drop to a value less than the gross moment of inertia I g• Since concrete is weak in tension, it will crack below the neutral axis and its contribution to the rigidity and strength will be neglected. On the other hand, the concrete in the compression zone acts effectively and contribute to the section rigidity. The actual cracked section is non-homogeneous and consists of the compressed concrete above the neutral axis and the reinforcing steel bars below the neutral axis. The nonhomogeneous section can be replaced by an imaginary homogenous section called the transformed section. To obtain the transformed section of a reinforced concrete beam, the area of the reinforcing steel bars As is replaced by an equivalent area of concrete equals nAs, in which n= E/Ee is the modular ratio (the modulus of elasticity of steel I modulus of elasticity of concrete). The moment of inertia of this transformed section is called the cracked transformed moment of inertia Ier.
246
bx Z2 /2-n A., (d - z)
=0
.............................. (3.3)
Subsisting with z=kd and fi =Alb d gives:
n As (d - kd) = O.................................. (3.4) 2 Dividing by bd2, substituting with JAn= (n ~), and solving for k gives k
and,
= ~2fin + fin 2
-
fin ......................................... (3.5)
z=kd
Having determined the neutral axis distance z, the cracked moment of inertia Ier can be computed as
cracked zone
• • • As
Fig. 3.4 Cracking of concrete section under applied loads The neutral axis is located at distance z from the compression face. The location of the neutral axis can be easily determined by taking the first moment of area about the center of gravity of the section (c.g.). It should be noted that the center of gravity coincides with neutral axis (no normal force).
b
1•
-I
b
bxz =-3-+ n As (d -
z)
2
............................. (3.6)
Using the previous set of equations, design chart was prepared to facilitate the determination of the Ier for singly reinforced section (refer to the Appendix).
Cracked section
Uncracked section
3
Ier
-I
For doubly reinforced section, the compression steel displaces the stressed concrete and has a transformed area of (n-1)As Referring to Fig. 3.5 and taking the first moment of area about the top fibers gives:
bxz 2 /2+(n-1) A; (z-d')-n As (d _Z)2 =0 ............. (3.7) The previous equation is a quadratic equation in z and can be solved directly. Te value of z can be directly obtained from Eq. 3.8.
(n-l)A's
.'Jz
4 -bJ+.J z = . bf- aJcJ ................................... (3.8) 2 aJ
wh<1re
I
I
al bl
I I
._.~~"\~
•••• As Cracked section
•
nAs
I
1._._._._ . .:
linear stress distribution
Cl
=bl2 =n As + (n-1) A's =-[(n-1) As d' + n As d]
Transformed section
The cracked moment of inertia equals
'.
3'
bxz·· 2 " 2 . Icr=-3-+nAs (d-z) +(n-1)As (z-d) ...................... (3.9)
Fig. 3.5 Determination of the neutral axis and cracked transformed moment of inertia calculations
Design aids for calculating the cracked moment of inertia for rectangular sections with tension steel only are given in Appendix.
247
248
ill T-sections, the neutral axis could be located inside or outside the flange as shown in Fig. 3.6. Therefore, hand calculations should be carried out as explained in the illustrative examples. B
..... J7-'-'neutral
n As --- •••
axis
Neutral axis outside the flange z>ts
Neutral axis inside the flange z
3.3.3 The Effective moment of inertia Ie Sections located at tension cracks have their moment of inertia approximately equal to the transformed cracked moment of inertia Ier. However, between cracks the moment of inertia could be approximately taken equals to I g • Referring to Fig. 3.4, it is clear that a cracked reinforced concrete beam behaves as a beam with variable moment of inertia. To simplify deflection calculations, the cracked RC beam is assumed to have a constant moment of inertia (called the effective moment of inertia Ie). The effective moment of inertia has a value less than Ig but is greater than Icr• The most widely accepted formula for estimating the effective moment of inertia was developed by Branson and IS adopted in the Egyptian code. This empirical equation, presented graphically in Fig. 3.7, was based on statistical analysis of deflections measured from test data, and is given by:
Fig. 3.6 Location of the neutral axis in cracked T -sections 1,
=(~:)' 1, +-(~:) 'll~ Sl, ................ (3.10)
The previous equation can be simplified as:
Ie =Icr+(Ig _Icr)(~:)3 ............................................. (3.11) where Ier cracked transformed moment of inertia. Ma maximum service (unfactored) moment in the member. Mer cracking moment calculated using Eq. 3.1. The variability of deflection calculated using this expression, which is based on laboratory tests, is relatively high. However, considering the variety of factors that influence deflection of reinforced concrete beams, greater accuracy can be hardly expected from using such a simple equation. '
Ie
Figure 3.6 shows variation of the effective moment of inertia With the applied moment Ma. In this figure, the horizontal axis refers to the applied bending moment and the vertical axis refers to the moment of inertia that should be used in deflection calculations. It is clear that if the applied moment is less than cracking moment of the beam; deflection is calculated using the gross moment Photo 3.2 Reinforced concrete building 249
250
of inertia Ig. On the other hand, if the applied moment is greater than the cracking moment, deflection is calculated using the effective moment of inerr Ie. It is interesting to note that the value of the effective moment of inert:: approaches the cracked moment of inertia as the applied moment increases.
II I
~
3.4 Code Provisions for Control of Deflections The Egyptian code presents two approaches for controlling deflection. The first is indirect by setting an upper limit for span-to-thickness ratio. In the second approach, the computed member deflections are compared with specific limitations imposed by the code.
I
I
I
Igl-----.
,,
, ,,
Effective moment of inertia
,, ,,, Ma::=;Mcr ,:
Ie=Ig :,' ___ _ Ier __________
,,
-----------------------------------------_.
, ,,
~r
Ma
3.4.1 Control of Deflection by Span-to-Thickness Ratio 3.4.1.1 Beams and One-Way·slabs The Egyptian code imposes restrictions on the member thickness relative to the clear span Ln, to ensure that the member will be rigid enough so that deflections are unlikely to cause problems as given by Eq. 3.13 and Table 3.1. Table 3.1 .can not be used for beams or slabs supporting elements that are likely to be damaged due to deflection. It can not also be used in case of abnormal buildings and in case of heavy or uneven loads The code recognizes the effect of support conditions on deflection by assigning different span/thickness ratios according to the continuity conditions at both ends of the member.
~:::; Values listed in Table 3.1 ........................... (3.13)
Fig. 3.7 Variation of the effective moment of inertia Ie with the applied momentMa
t
Table 3.1 L./t ratios for members spanning less than 10 meters or cantilevers spanning less than 2m. (Deflection calculations are waived) In summery the effective moment of inertia equals Element
f
Solid slabs
Ie
=
.................. (3.12)
Icr+'{I -IJ(::r g
if Ma,>M
cr
Hidden Beams and hollow blocks Beams
end
Two
Cantilever
Simply
One end
supported
continuous
25
30
36
10
20
25
28
8
16
18
21
5
continuous
The values listed in Table (3.1) are valid when using high grade steel 400(600. In the case of using other types of reinforcing steel, the values mentioned in Table 3.1 should be divided by factor~, given by: f=0.40+
iy .................................... (3.14)
650
Where h is the yield strength 'of reinforcing steel in N/mm2• 251
252
T-sections
The limiting values listed in Table 3.1 are also valid for T-sections by multiplying the values by the reduction factor 0 determined from the either Eq. 3.15 or Fig 3.8.
8 = 0.71 +0.29 (:);::: 0.8 ..................................... (3.15) 1.00
c.o 0.95 ~ 0
....
0.90
:=
0.85
~
.s .~ ~
:=
't:I
~
, .., V
.-.~
..,,-100""
0.80
/
V ~--
B
Also the slab thickness should be greater than troin a 35
0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
(bIB) ratio
Fig. 3.8 Modification of LIt ratio for T -sections
3.4.1.2 Two-way slabs Resting on Rigid Beams For two-way slabs resting on rigid beams, having spans of less than 10 meters, subjected to uniform loads that are not heavy and attached to non-structural elements not likely to be damaged by large deflections, the deflection calculations can be waived if the slab thickness is grater than t calculated using the following equation:
•
Values of span-to-thickness ratios given in Table 3-1 are not satisfied.
•
Span of the beam is more than 10 ms or length of the cantilever is greater than 2 ms.
•
The member is subjected to heavy or uneven loads or located in abnormal type of building.
3.4.2.1 Calculation of Immediate Deflection Deflection of reinforced concrete members can be calculated using the simple structural analysis expressions. Examples of these expressions are given in Eq. 3.18, the rest is given in appendix A. It interesting to note that the deflection of a uniformly loaded simple beam is five times the deflection of a uniformly loaded beam with fixed ends.
w L4 384EJe 5w L4
. a(0.85+~) . 1600
t
=
=
Calculations of deflections are carried out in the following cases:
0.70 0.1
a
for slab continuous frorp. one side ............... (3.17) 40 a for slab continuous from two sides 45 where a is the short direction. tmin
3.4.2 Control of Deflection by Limiting its Value
0.75
o
for simply supported slabs
20
> 100 mm ................... (3.16)
15+-+IOPp bla
Where a is the smaller dimension of the slab, b is longer dimension of the slab., /3 p is the ratio between the length of all continuous ed~es to the total perimeter, andh is the yield strength of reinforcin,g steel in N/mm
253
384EJe P L3 /).=
48EJe W L4 8EJe P L3
for fixed end beam with uniform load (w ) for simple beam with uniform load (w ) for simple beam with point load at midspan for cantilever beam with uniform load (w ) for cantilever beam with point load at edg (P)
3EJe
254
...... (3.18)
"·r·' ;:s•. ~.'.
""'<',." .• :,,
Where Ie and L are the effective moment of inertia and the beam span, respectively. Ec is the concrete modulus of elasticity and is given by :
,~
!
I ;
Ec
= 4400K ......................................... (3.19)
The total immediate delectation ~i due to the existence of dead and live loads equals to: ~i = ~DL + ~u ................................................. (3.20) where ~DL is the deflection due to dead loads including the own weight of the member and the weight of the finishes and ~LL is the deflection due live loads.
I
II:
The addition of compression steel reinforcement reduces the long-term deflection significantly. Figure 3.lO presents experimental deflection versus time for beams with and without compression reinforcement. The additional deflection with time is 195% of the initial deflection for beams without compression reinforcement (A's=O), while it is only lOO% of the initial deflection for beams with compression steel equals to the tension reinforcement (A's=As).
E E s::
160
:;:;
120
0
3.4.2.2 Long Term Deflection
0
CI)
Due to the combined effect of creep and shrinkage, the deflection increases with time. The factors affecting long-term deflection include humidity, temperature, curing conditions, ratio of stress to strength, the age of concrete at the time of loading and compression steel content. If the concrete is loaded at an early age, its long-term deflection will be increased. The creep deflection after about five years can range two-three times the initial deflection. It should be noted that more than 90% of the long-term deflection occurs at the first five years after the initial loading. immediate curvature concrete beam curvature after creep
r-:-~:I-
~
0
100 80
....s::
60
E .;:
40
CI)
20
>< w
0
Cii
CI)
a.
A'$=O
140
.... ~
/' IL:::::. /// .,
A's=O.5Jl is
long-ter In deflection
A's=As
Immeat te aenectlOn
o
100
200
300
400
500
Time (days)
immediate trains
- - ;-
cr"""~f ' stram a ter creep
Fig. 3.10 Effect of compression reinforcement on long-term deflection
Based on experimental results, the ECP 203 specifies that additional long-term deflection due to creep ~reep is calculated by multiplying the dead load deflection ~DL by the factor a. For a singly reinforced section this factor is equal to 2. The reduction factor a for sections with compression steel can be computed from the following relation:
(A' )
a = 2-1.2 ~creep
deflection Fig. 3.9 Effect of creep on deflections, curvature and strains.
255
600
.
A: ;: : 0.6 .............................
= a ~DL
•••••••••••••••••••••••••••••••••••••••••••
(3.~1)
(3.22)
Thus the IOl!g-term deflection including the effect of creep equals: ~Iotal =~creep +~DL +~u
256
......................... (3.23)
1110lal
=(1+a)I1 DL +l1u ................. :........ (3.24)
ri i
i
•
I
3.4.2.3 Permissible Deflections As mentioned before, deflections of roofs and floors may cause cracking of brick walls and malfunction of doors and windows. Moreover, deflection due to accumulated water on the roof may cause additional deflections allowing it to hold more water. The ECP 203 imposes the following deflection limits: •
i ! I !
11
•
The total deflection of members in ordinary buildings under the effect of all loads including the effect of temperature, shrinkage and creep, measured from the support level should be limited as follows:
~ 2~0
............................................ (3.25a)
2- For cantilevers: 11/0/01
~
<~ 360
:So ............................................ (3.25b)
where L is the distance between the inflection points for beams or slabs and is the cantilever length (See Fig. 3.1). The value of L is based on the short span for one-way and two-way slabs, and based on the long span for flat slabs.
.................•................................ (3.26)
LL -
The ECP-203 requires that for beams and slabs carrying non-structural elements that are likely to be affected by deflection such as curtain walls, the part of the total deflection that occurs after the execution of the floor finishes and partitions and that results from all loads including the effect of temperature, shrinkage and creep to be limited to: I1p
1- For beams, one-way labs and two-at-slabs: 11 1(1/al
The ECP 203 requires that the immediate deflections due to live loads only for beams and slabs supporting or attached to non-structural elements not likely to be damaged by large deflections, to be limited to:
= I1LL + a
11,,,,,
~
L 480 ................................ (3.27)
where I1LL a I1sus
= instantaneous deflection due to live loads (not likely to be sustained) = long term deflection (creep + shrinkage) due to all dead loads applied after the installation of partitions including any sustained (permanent) live loads
Table 3.2 and Fig. 3.12 summarize the previous rules.
Jk\I One end continuous beam
Simple beam
£
-I L=O.76Lb Continuous beam
Cantilever beam
Fig. 3.11 Definition of L in deflection calculations 257
Photo 3.3 Beam deflection during testing 258
Table 3.2 Maximum permissible deflections
\ Deflection Calculations \
I Type of member
Deflection to be considered
Deflection
Calculate the total deflection under the effect of all loads including the long-term effect !:ito/al and check the following limits:
limit Beams and slabs in ordinary Total deflection (measUred from the buildings
L 1250
for
level of the support) under the beams & slabs
~
L/250
for beams and slabs
~
LI450
for cantilevers
I.
effect of all loads including the
L 1450
for
Calculate other types of deflections and check the satisfaction of code limits
effect of temperature, shrinkage and cantilevers creep
I
Beams and slabs supporting Immediate deflection due to live
LI360
or attached to non-structural loads elements not likely to be
The member carries nonstructural- elements likely to be damaged by large deflections
The member carries nonstructural elements not likely to be damaged by large deflections
- Calculate the immediate deflection due to Live loads + deflection due to sustained permanent: !:i p = !:iLL +a !:isus
- Calculate the deflection due to Live loads only: !:iLL
4amaged by large deflections Beams and slabs supporting Immediate deflection due to live or attached to non-structural elements
likely
to
L 1480
loads plus long-term deflection due
be to all additional loads (applied after
damaged by large deflections construction
of
non-structural
- Check the satisfaction of following limit: !:iLL ~L1360
- Check the satisfaction of following limit: !:i p ~L1480
elements) including flooring and
partitions I
i
!
Fig. 3.12 Deflection Calculations
259
260
3.4.2.4 Deflection of Continuous Beams
For a beam with concentrated negative moment MI at beam end the deflection equals
For continuous spans, the ECP 203 calls for a simple average value for the effective moment of inertia obtained from Eq. 3.10 as follows:
I;
= 0.50 Iem + 0.25x (lei + I e2 )
........................ (3.28)
where I~ is the average effective moment of inertia, Iem is the effective moment of inertia at mid-span and leI and Ie2 are the values of the effective moment of inertia calculated at the negative moment sections. Figure 3.13 shows the application of Eq. 3.28 for the calculation of the average effective moment of inertia for an interior span of a continuous beam. The value of the effective moment inertia at mid-span Iem is calculated form Eq. 3.10 using the maximum moment Mam. On the other hand, the values of leI and Ie2 are calculated from Eq. 3.10 suing the maximum negative moments Mal and Ma2.
=
Ll I
3xL2 MI ....................... ··················· (3.31) 48 Ec I;
Referring to Fig. 3.13 and by using the principle -of super-p~sition, one can concluded that the mid span deflection Ll for a continuous beam IS Ll =
2
5xL 48xEc
I;
[M -O.lx(MI +M 2 )]
••••••••••••••••••
(3.32)
m
where MI M and M2 are the bending moments at end 1, midspan, and end 2 respectiv~ly. To calculate the dead load deflection for example, one should use the dead load moment Mm,DL at midspan and at the two ends (MI,DL and M2,DL)'
Fig. 3.13 Calculation of the effective moment of inertia for continuous beams
For continuous beams in which the exterior support does not prevent any rotation (brick wall), the effective moment of inertia can be approximated by
I;
=0.75 Iem + 0.25 x lei
.................................... (3.29)
Where Iem is the effective moment of inertia at mid-span and leI is the value of the effective moment of inertia calculated at the first interior support. To determine the effect of continuity on the deflection at mid-span, it is easier to express the deflection equation in terms of moment. For example, for a uniformly loaded simply supported beam the deflection can be expressed as: Ll=
5xL2
,Mo ......................................... (3.30) 48 Ec Ie Photo 3.4 Deflection of a simply supported beam during testing
261
262
Step 2: Calculate the cracking moment and the applied moment
Example 3.1 The cantilever beam shown in the figure below carries an unfactored dead load of 11.5 kN/m' and an un factored live load of 6 kN/m'. The beam is located at a typical floor and supports walls that are not likely to be damaged by deflection. It is required to calculate the immediate and the long-term deflections. Does the beam meet ECP 203 requirements for deflections?
=35 N/mm = 10
feu n
2
§
9 . = fetr.lg =3.55x6.4x10 x-1-=56.79kN.m Mer 400 106 Y t
W total
= 11.5 + 6 = 17.5 kN I m'
The maximum negative moment in the cantilever is at the support WDL =11.5 kN/m' W LL =6 kN/m'
150mm I •I • ••
7:-
2 /.clr = 0 •6"leu = 0.6..j35 = 3.55 N I mm
= W total
M a
2
L2
Since Ma < Mer
= 17.5x2.22
2
then
= 42.35 kN:m ... <
Mer (not cracked)
Ie=Ig
3<1> 20
8
Step 3: Calculate the deflection
00
2.20m Beam Section
Beam Elevation
Step 3.1: Calculate the immediate deflection E = 4400'-;;-/. = 4400..j35 = 26030 N I mm 2 c
'" J cu
From the appendix, the maximum deflection for a cantilever beam carrying uniform load equals to:
Solution Step 1: Calculate the uncracked section properties Neglect the reinforcement steel in calculating the gross moment of inertia. Yt=400 mm 3
Recalling that 1 kN/m'=1 N/mm, then wDL=I1.5 kN/m'=11.5 N/mm' 3
I = bxt = 150x800 = 6.4x109 g 12 12
mm 4 ADL
150
W DL
L4
11.5x(2.2x1000)4
= 8 Ee
Ie
= 8x26030x6.4x109 6x(2.2x1000)4 8 x 26030 x 6.4 x 109
0.20 mm
= 0.11 mm
The total immediate deflection Ai equals:
Uncracked section
263
"
264
Step 3.2: Calculate the long-term deflection
Example 3.2
The total deflection due to all loads including the effect of creep equals
The simple beam shown in the figure below is located at a roof f a building and it does not support any partitions. The unfactored dead load is (including own weight) 15.0 kN/m', and the unfactored live load is 9.0 kN/m' . Check whether the beam meets the ECP 203 requirements for deflections. feu =25 N/mm2 • n =10
!::"total
=(I+a)!::..DL +!::..u
Since A's=O then a=2 !::"total
= (1+-2) 0.2+0.11 = 0.71 mm
Step 4: Check the code requirements • The code maximum limit for cantilever beams = 2200/450 = 4.88 mm Since !::"total (0.71 mm) < !::..allowable ( 4.88 mm), the code limit is satisfied. • Since the beam is located at a floor and support walls that are not likely to be damaged by deflection, then 6.0m !::..
< L < 2200 _ 6 11
LL(allowable) - 360 - 360 - .
mm
Since !::..LL (0.11 mm) < !::..LL(allowable) (6.11 mm), the code limit is satisfied. 250mm
I•
•I
o o
\0
•••• Beam Section
,
./
.. .\
-~
.,.1' ,/f(/"
";
,'- :.j ", !.(
·1
.~:(-!
'\.
' ..
265
266
4
Solution Step 1: Calculate uncracked section properties 1 ,250
Neglect the tension steel in calculating gross moment of inertia.
~_.Jz
Yt=300mm I = _bx_t_3 = 250x600
12
g
3
= 4.5x109
12
mm4
8\0
I 250 I
-IIi Uncracked section
Step 2: Calculate the cracking moment and the applied moment fetr
= 0.6.J7: = 0.6.[i5 = 3 N I mm 2
M
= fetr.I g cr
W
total
Yt
= 3x4.5x109 x_1_=45 kN.m 300
10 6
.. I
As=804mm
••••
2
Transformed section
Original section
Taking the first moment of area for the transformed section about the N.A., gives: 250x z x~ = 8040 (550 - z) 2 125 Z2 + 8040 z - 4422000 = 0 z=158.68 mm Calculate cracked moment of inertia Ier
=15+9 = 24 kN 1m'
3
The maximum bending moment Ma is at midspan equals: _ W total L2 __ 24x6 2 Ma 8 8 = 108 kN .m ... > Mer (cracked section analysis) Since Ma > Mer then calculate Ie
I =bz +nAs (d-z)2 er 3 3
I cr
= 250x158.68 +lOx804x(550-158.68)2 =1.56x10 9 mm 3
Step 4: Calculate the effective moment of inertia
Step 3: Calculate the cracked section properties
if
E c = 4400V J cu = 4400.[i5 = 22000 N I mm
As = 411> 16 = 804 mm2 Assume the neutral axis is located at a distance z from the compression force. Transform the area of steel reinforcement into an equivalent area of concrete (nA s )· .,. n As=lO x 804 = 8040 mm2
267
268
2
4
Step 5: Calculate the deflection
Example 3.3
Step 5.1: Calculate the immediate deflection W DL
= 15 kN/m' =15 N/mm'
WLL
=9 kN/m' =9 N/mm'
The T -beam shown in figure is subjected to an unfactored dead load of 20 kN/m' and an unfactored live load of 8 kN/m'. The beam supports partitions that are sensitive to deflection. Calculate the immediate deflection and check ECP 203 requirements, knowing that 30% of the liveJoads are permanent loads. The concrete strength is 20 N/mm2 •
The maximum dead load deflection for simple beam at mid span equals = 5w VL L4 =
!:1
VL
384Ec Ie
1250
5xI5x(6xlOOO)4 =65mm 384x22000x1.77x109 .
120
Since the relation between deflection and load is linear, we can determine the deflection of other loads simply by using ratios of the applied loads as follows: A t.J..
0 0
T
00
Wu 9 u =!:1vL X--=6.5X-=3.9mm W VL 15
•••
A;=3<1>22
1-1 !:1;
200
=!:1VL +!:1u =6.5+3.9=1O.4mm
Step 5.2: Calculate the long-term deflection ,
~,'""""'''''.'
,
The total deflection due to all loads including the effect of creep equals: I
!:1total
I!
= (1 + a) !:1VL +!:1 u
'
I
i.
since A's=O then (1;:::.2
.1
7.20m
!:1total = (1 + 2) 6.5 + 3.9 = 23.4 mm
Step 6: Check the code requirements 1. The code maximum limit for simple beams = 60001250 = 24 mm, since !:1tota1 (23.4 mm) < !:1allowable (24 mm), the code limit is satisfied.
2. Since the beam does not support partitions, no additional checks are needed.
Solution Step 1: Calculate the uncracked section properties Neglect the tension steel in calculating the gross moment of inertia. Since the section is not symmetrical, calculate the center of gravity (c.g.).
Y2 I
Y=250.2 mm o o00
y,=400mm
Al
Y2=60mm
269
Uncracked section 270
Al
= 200 x 800 =160000 mm 2
Step 3: Calculate the cracked section properties
~
= (1250 -
As = 3 22 = 1140.4 mm2
200)x120 =126000 mm 2
Assume that the neutral axis is located at a distance z from the compression force. Transforming the steel reinforcement into equivalent area of concrete gives:
- = 160000x400 + 126000x60 =250.2mm Y
160000 + 126000
= 200 X 800
Ig
3
+160000x(400-250.2)2 + (1250-200)x120 12 12 + 126000 x (250.2 - 60)2
nAs=1O x 1140.4 = 11404 mm2
3
Assuming concrete cover of 50 mm, d=800-50 =750 mm
-11_1_
I --L
1 -_ _ _ 12_5_0_ _
1250
----=..:;...:....::...----1
1-1
Step 2: Calculate the cracking moment and the applied moment
fetT = 0.6fjC = 0.6...fiO = 2.683 N I mm 2 Yt = 800 -
Y = 800 -
assumedc.g
250.2 = 549.8 mm
1--1
200
1250
)
Yc=250.2mm
T
o o
Quick estimate for the c.g.
Exact calculation for the c.g.
120
00
YF549.8mm
!clr
To quickly determine whether or not the c.g. is inside the flange, calculate the first moment of area at the end of the slab. 120 1250x120x- > 11404 x (750 -120) 2 Hence, assume the c.g. inside the flange. Taking the first moment of area for the transformed section about the c.g.
M
=fetr.lg er Yt
W total
= 2.683xI6.83x10 549.8
9
x_1_· =82.15kN.m 106
= 20 + 8 = 28 k!'f I m'
M =
W total L2
a
8
= 28x7.22
8
1250xzx~ =11404 (750- z) 2
625 Z2 181.44kN.m
+ 11404 Z - 8553000 =0
z =108.21 mm < 120 mm (inside the flange as assumed) Calculating cracked moment of inertia Ier
Since Ma> Mer then calculate Ie
271
272
1
_ B Z3 2 Ier --3-+nAs(d-z) 3
Ier = 12S0x108.2 +1l404x(7S0-108.2)2 =S.22x109 mm 4
3
Step 4: Calculate the effective moment of inertia Ec = 4400K = 4400m = 19677 N I mm
Ie
= Ier +(Ig -Icr )( ~:
I
Step 5: Check the code requirements •.. Tile .code maximum limit for simple beams = 720012S0 = 28.8 mm. Since dtotal (19.19 rom) < dallowable (28.8 mm), the code limit is satisfied. • Since the beam is attached to partitions that are likely to be damaged by large deflections, the code also requires that:
2
r
d LL +a d •
d sus
Ie =S.22x109 + (16.83X10 9 -S.22X10 9)( 82.1S) 3 =6.3x10 9 mm 181.44 .
sus
L 7200 :::=:;-:::=:;--:::=:;IS mm 480 480 .
= d DL + 0.3 X d LL
Where d sus is the deflection due to all dead loads applied after the installation of all partitions plus the permanent live loads (given as 30%). d sus = S.64+0.3x2.26 = 6.32 mm
Step 5: Calculate deflection
2.26 + 2x 6.32 = 14.9 mm· < IS mm ..... .o.k
Step 5.1: Calculate immediate deflection WDL
= 20 kN/m' = 20 N/mm'
WLL
=8 kN/m' = 8 N/mm'
The dead load deflection for simple beam equals: d DL
= S W DL L4 =~x 20x(7.2xlOOO)4 = S.64 mm 384 Ec Ie 384 19677x6.3x109
Since the relation between deflection and load is linear, we can determine the deflection of otherloads simply by using ratios as follows: W
8
d u = d DL x~ = S.64x- = 2.26 mm W DL 20
Thus the immediate deflection equals: d i = d DL + d u = S.64 + 2.26 = 7.90 mm
Step 5.2: Calculate long-term deflection The total deflection due to all loads including the effect of creep equals d total
= (1 + a) d DL + d u
Since A's=O then a=2 d total = (1 + a)d DL + d u = (1 + 2)xS.64+ 2.26 =;= 19.19 mm
273
274
Example 3.4
Step 2: Calculate the effective moment of inertia
The floor beam shown in figure is subjected to an unfactored concentrated dead load of 80 kN, and an unfactored concentrated live load of 55 kN (the own weight of the beam may be neglected). The beam supports glass partitions that are likely to be damaged by large deflections. Check the satisfaction of ECP 203 limits for deflection. The concrete compressive strength is!cu=40 N/mm2
Ee = 4400fJ: = 4400.J4(j = 27828N I mm
250
•
4<1>16
A
Beam Section
Ig
3
9
Ie = 3234016475 = 3.23x10 mm
PDL=80kN Pu=55kN
• • ••
+(Ig -IJ(: : )
I = 2.72 X109 + (8.8X109 -2.72XI09).( 88.94)3 e 202.50
.. I
I..
Ie = Ier
2
I-
3
I -L3
4
Step 3: Calculate the deflection Step 3.1: Calculate the immediate deflection
~ -I
=8.8 X 109 mm4
P L3 ,. The deflection for a simple beam carrying a concentrated load equals - - . 48 Ee Ie !J.. . = (80 X1000) X(6000)3 = 4.0 mm DL 48x 27828x3.23x109
Since the relation between deflection and load is linear, we can determine the deflection of other loads simply by using ratios as follows:
Ie r = 2.72 X 109 mm4
!J..
LL
=!J..
DL
X
PLL =4x 55 =2.75 mm 80
P
DL
Solution
Thus the immediate deflection equals:
Step 1: Calculate the cracking moment and the applied moment
!J..i =
felT =0.6fJ: =0.6.J4(j =3.79Nlmm
M
2
9
=fe/J g =3.79X8.8X10 x-1-=88.94kN.m er y/ 375 106
~olal L = 135x6 = 202.5 kN.m 4
+ !J..LL = 4.0 + 2.75 = 6.75 mm
Step 3.2: Calculate the long-term deflection
A~
As
= 2¢ 16 = 0.5 4¢16
-7
a= 2-1.2 (A ASs' ) = 2-1.2 (0.5)= 1.4
~ 0.6 .. ·o.k.
The total deflection due to all loads including the effect of creep equals:
~otal = 80 + 55 = 135 kN
Ma =
ADL
4
!J../otal !J..
= (l+a) !J.. DL +!J.. u
lolal = (1 + 1.4) 4.0 + 2.75 = 12.35 mm
Since Ma >Mcr , then calculate Ie
275
276
Step 4: Check the code requirements
Example 3.5
• The code maximum limit for simple beams = 6000/250 = 24.0 mm. Since Lltota1 (12.35 mm) < Llallowable (24.0 mm), the code limit is satisfied.
The T -beam shown in figure is a part of a roof and it supports a triangular ~oad. The beam supports partitions that are not likely to be damagedby deflectIOns. Does the beam shown in the figure below satisfy the ECP 203 requirements for 2 deflections? The concrete strength is 25 N/mm • Assume of n=lD. All the given loads are unfactored
• Since the beam is attached to partitions that are likely to be damaged by large deflections, the code also requires that:
L
6000
Llu + a Llsus ::; - : : ; --::; 12.5 mm 480 480
Llsus
1400
.. ,
100
=4.0 mm
2.75+1.4x4.0=8.3Smm <12.5 mm ..... .o.k
I\
0 0
T
'D
A's=3<\>16
1-1 250
kN/m' WLL=lO kN/m'
WDL=24
3.60m
Photo 3.5 Cantilever beam during testing
277
278
Solution Step 1:
1400 Ca~culat~
Since the section
!etr
the uncracked section properties
~~------------
Yt=191.51
is, not symmetrical, calculate the c.g. 1400
~
x
100
Y=191.51 mm
o o
\0
Al .
~
, .,:
.t\
Uncracked section
"
.
= fetr.lg = 3.Ox8.66x10
Mer
Yt
'';'
Al = 250x600 = 150000 mm 2
Yl=300mm
~ = (1400-250)x100 = 115000 mm 2
Y2=50mm
Y
Ig
Wtota!
= 24+ 10 = 34 kN I m'
~otal
= 14+8 = 22 kN = Wtotal
M
Taking the first moment of area about x-axis:
a
150000 x 300 + 115000 x 50 - - - - - - - - =191.51 mm
191.51
2
9
x_l_ = 135.73 kN.m 10 6
Lx L + Px L = 34x3.6 X 3,6 + 22x3.6 =152.64 kN.m 32 3
Since Ma> Mer , then calculate Ie.
150000 + 115000
= ~~0;26003
+ 150000x(300-191.51)2 +
(1400-~~0)XI003
+115000x (191.51-50)2
Step 2: Calculate the cracking moment and the applied moment fetr
Step 3: Calculate the cracked section properties
= 0~6K = 0.6.fi5 =3 N I mm 2
As = 3cIl 25 = 1472.6 mm2
Noticing that the tension side for the cantilever is at the top flange, then;
Yt = Y = 191.51 mm
279
A ~ =3cIl 16 = 603.2 mm2
280
)
Assume that the neutral axis at a distance z from the compression force. The reader should notice that the compression part for cantilever is at the bottom of the section.
250x 190.433 + 5428x(190.43-50)2 + 14726x(550-190.43)2 3 = 2.58x109 mm 4
Ier ==
Transforming the steel reinforcement into an equivalent area of concrete, gives: nAs=lO x 1472.6 = 14726 rom2
Step 4: Calculate the effective moment of 'inertia
The steel in the compression is transformed by multiplying with (n-l) to account for the concrete area.
Ec
= 4400JI: = 4400.J25 = 22000 N / mm 2
Ie
= leT +(Ig -Ier )( : :
Ie
= 2.58 X 109 + (8.66x10 9 _ 2.58x109 )(135.73) 3 = 6.86x109 mm
(n-1) A's=(lO-l)x 603.2 = 5428.8 rom2 Assuming concrete cover of 50 rom, d = 800-50 =750 rom nA,=14726
r
152.64
It-~-I 100
o _neglect the cracked zone N
T
>rl >rl
Step 5: Calculations of the deflections Step 5.1: Immediate deflection The deflection for this cantilever beam is the sum of the deflection due to the concentrated load and that due to the uniform load. These deflections are given by ~?e following equations:
Calculation of the c.g. for the cracked section
w L4
30EJe
Taking the first moment of area for the transformed section about the c.g
250xzx~+ 5428.8x(z -50) =14726 (550- z) 2
125 Z2
for cantilever beam with triangular load
for cantilever beam with concentrated load at theedge
+ 20154 z - 8370740 =0
z=190.43 rom
The dead load deflection equals:
Calculate cracked moment of inertia I er.
f1
= W DL DL
b Z3 " 2 2 Ier =-+(n-l) As(z-d) +n A/d -z) 3 .
281
f1DL
L4 + PDL L3 30 E c I e 3 E c I e
24x(3.6xlOOO)4 30x22000x6.86x109
(14x 1000) x (3.6 X 1000)3 3x22000x6.86x109
---..:..---~- +-'-----'-~---'---
=2.33 mm
282
The live l?ad deflection equals:
.& ;
.', J,L
Example 3.6
_ w ii.:L,4::'f,:r:LL :L3 = lOx (3.6 X 1000)4 + (8x 1000) x (3.6x 1000)3 . . 30 is I +'~3 E'1 '. 30x 22000 x 6.86 X 109 3x 22000 x 6.86x109 c e c 'e
The reinforced concrete one-way slab shown in the figure below supports an 2 unfactored dead load of 6 kN/m 2 and an unfactored live load of 3 kN/m • Calculate the immediate and long-term deflections at point (B). !CU equals 30 2 N/mm •
!J.. LL = 1.20 mm
Step 5.2: Long-term deflection
AI
The total deflection due to all loads including the effect of creep equals
~
,a.=:'.2-1.2...(A:) 603 _' =2-1.2 (-) =1.512::0. 6 · .. o.k. A. ' .' 1472
6<1> 14/m'
\~11lm' 3.6m
~,,"
!if
6tj>14/m'
14/
6+
\.
m'
I
.1
3.6m
. :.::'~,'~:r5'{,~ :,~';;:J;::~ . .'ii .
11/0/01
= (1 + 1.51)2:33 +'1:20 = 7.05 mm
Step 6: Check the code requirements • The code maximum limit is = 3600/450 = 8 rom Since I1total (7.05 rom) < l1allowable (8.0 rom), the code limit is satisfied. •
The beam supports partitions that are not likely to be damaged by deflections, then the deflection limit is given by: o
!J.. LL (01lnwable)
oci
L 3600 :s; -:s; - - =10 mm 360 360
Since I1LL (1.2 mm) <
I1 LL(allowable)
(10 rom), the code limit is satisfied.
ii
/
3.6
3.6 1
Floor plan 283
284
1'
Solution Step 1: Calculate the uncracked section properties' Taking a 1m slab width of the (b=1000 mm) Yt=70mm 3
3
I = bxt = 1000x140 = 228x10 6 mm 4 g 12 12 1000
Cracked section at B
. ,.
I I ~.~~
. Step 3.2: Sections A and C
.•
Uncracked section
The positive reinforcement is not developed at supports, hence it will not be considered as compression steel for sections subjected to negative moment at the supports (i.e. A~ =0).
Step 2: Calculate the cracking moment
As = 6<1> 14 = 923.6 mm2
Ec = 4400K = 4400.Ji) = 24099.8 N I mm 2
Using design aids given in the Appendix fctr = 0.6K = 0.6.Ji) = 3.29 N Imm 2 M
cr
= fctr-I g = 3.29x228x10 Yt 70
6
X
jJ,
_1_=1074kN 6 • .m 10
A =bXsd
923.6
= 1000x120 = 0.0077
From the curve kn = 0.0465
The cracking moment is valid for sections A, B and C (refer to the figure).
Ier = K[[ xbxd 3 = 0.0465 x 1000 x 120 3
= 80.3x10 6 mm 4
Step 3: Calculate cracked section 'properties Since the slab is continuous, the moment of inertia of any span depends on the average values of the moment of inertia of positive and negative sections
n=lO
1000
Step 3.1: section B As = 6<1> 12 = 678.5 mm2 Assume concrete cover of 20 mm
0.0465~-~
-7
• • • • •
d =140-20 =120 mm
Using design aids given in the Appendix jJ, 7
~ = 678.5 bxd
= 0.00565 .
cracked section at C
1000 x 120
From the curve with /.1=0.00565, ku=0.0365 3
3
0.0077 6
Icr = K[[ xbxd = 0.0365 x 1000 x 120 = 63.1x10 mm 285
4
286
~20
T
Step 4: Calculate the effective moment of inertia W
lo/ al
= 6+3 = 9 kN 1m 2
Thus, for a 1m width of the slab,
Wtotal
I
=9 kNlm'
Since the slab is continuous with equal spans and loading, the code coefficients for moments in slabs are used as follows: 2
M = w/o/al xL a k
=
9x3.6 2 k
24
A
M a,
Mer
kN.m
kN.m
4.86
10.74
m
I'e
Calculation of the effective moment of inertia (k)
4
L:r,mm
80.3 x 106
228.6 x lOb (lei)
uncracked
11.66
10.74
63.1x106
cracked
192.2 x 10° (lem)*
C
8
14.58
10.74
80.3 x 10°
cracked
139.56 x 106 (ld**
Note the values of the effective moment of inertia (given in the table) for section Band C are calculated as follows: = 63.1x10 6 + (228.6 X106 -63.lx106 )(10.74) 3 11.66
=192.2 X106 mm 4
<.
e
2
= 80.3 x 106
=3 kNlm' =3 Nlmm'
+ (228.6X10 6 _80.3X106 )(10.74) 14.58
Since the slab is continuous, the average value of
I~
5xL , [Mm -O.lx(Ml +M ) ] 2 48xEc Ie 2
2
2
D.DL = 1.93 mm
Since the relation between deflection and load is linear, we can determine the deflection due to live load as a ratio of that due to dead load as follows: W
3
WDL
6
= D.DL x--1£. =1.93x- = 0.96 mm
6
= 139.56xI0 mm
should be calculated.
4
D.i =D.DL +D.u =1.93+0.96=2.89mm
The total deflection due to all loads including the effect of creep equals: D./o/ai = (1 + a) D. DL
+ D. u
Since A's=O, then a=2
D. totaI = (1 + 2) 1.93 + 0.96 = 6.75 mm
287
2
5 X3600 (6X3.6 _0.IX{6X3.6 + 6x3.6 })XI06 DL - 48x24099.8x188.1xI06 10 24 8_
_
The immediate deflection D.i equals:
3
"I c =1
WLL
&
2
D.=
D.u em
4
The deflection for a uniformly loaded continuous beam equals:
10
=I
t' ' 6 Nmm = 6 kNlm=
WDL
B
B
= 11.66
Step 5: Calculation of the deflections L"mm4
status
D.
e,
2
xL 10
= 0 •50xl92.2xI0 6 +0.25x(228.6xI0 6 +139.56xI0 6 ) = 188.1x10 6 mm
(L,=Ig)
•I
=W
M
(=0.50I em +0.25x(Ie\ +I e2 )
The following table summarizes the calculations.
Point
A
288
Step 5: Check the code requirements •
The code maximum limit for one-way slabs =U250, where L is the length between the inflection points. Since the slab is continuous from one end the length L equals 0.87 (3600) =3132 mm. ~allowable=
Since
4
3132/250 =12.53 mm
~total (6.75
mm) <
~allowable (12.53
mm), the code limit is satisfied.
CONTROL OF CRACKING
Photo 4.1 A hotel building in San Francisco, USA
4.1 Introduction In Chapter (1) of volume (1), the concept of limit states design was discussed. The limit states (the states at which the structure becomes unfit for its intended function) are divided into two groups: those leading to collapse and those that disrupt the use of structures but do not cause collapse. These are referred to as the ultimate limit states and the serviceability limit states, respectively. The major serviceability limit states for reinforced concrete structures are,: excessive deflections, and excessive cracking. This chapter presents the ,,, serviceability limit state of cracking.
289
290
4.2 Reasons for Controlling Crack Widths Crack widths should be limited for the following reasons: 1. Wide cracks lead to concern by owners and occupants. Previous studies suggested that cracks wider than 0.25 to 0.33 mm leads to public concerns. 2. Preventing the corrosion of reinforcement. Corrosion of steel OCcurs if wetting and drying cycles occur such that the concrete at the level of the steel is alternatively wet and dry. It does not occur in permanently saturated concrete members because water prevents oxygen flow to the steel. 3. Preventing leakage in liquid-retaining structures.
--T
T
~
(a) Direct tension cracks
4.3 Types of Cracks Tensile stresses induced by loads cause distinctive crack patterns as shown in Fig. 4.1. Members loaded in direct tension develop cracks through the entire cross section (Fig. 4.1a). Slender beams subjected to bending moments develop flexural cracks as shown in Fig. 4.1 b. These vertical cracks extended almost to the zero-strain axis (neutral axis) of the member. Cracks due to shear have a characteristic inclined shape as shown in Fig. 4.1c. Members subjected to pure torsion develop spiral cracks as shown in Fig. 4.1d. Cracks also develop due to imposed deformation such as differential settlement, shrinkage and temperature changes. If shrinkage is restrained, shrinkage cracks may occur. Generally, however, shrinkage simply increases the width of load-induced cracks.
(b) Flexural cracks
-----~ --
c _________ _
(c) Flex~ral shear cracks
(d) Torsional cracks
Photo 4.2 Cracks in a bridge member due to rusting of the reinforcement 291
Fig. 4.1 Types of cracks 292
·1···· j
4.4 Development of Cracks due to Loads
I
Figure 4.2a shows an axially loaded prism. Cracking starts when the tensile stress in the concrete reaches the tensile strength of concrete at some point in the member. When this occurs, the prism cracks. Figures 4.2b and 4.2c show the variation in the steel and concrete stresses along the axially loaded prism. At the cracks, the steel stress and strain are at a maximum value. At the location of the cracks, the stresses in the concrete are equal to zero, while between the cracks, stresses start to develop in the concrete. This reaches a maximum value mid-way between two cracks. The width of the crack, w, is the difference in the elongation of the steel and the concrete over a length A~B equal to the crack spacing:
4.5 Crack Control in the Egyptian Code 4.5.1 Categories of structures The Egyptian Code categorizes reinforce~ co~crete structures according to their exposure to environmental effects as glven ill Jable 4.l.
Table (4.1) Categories of structures according to the exposure of concrete tension surface to environmental effects Category
Degree of exposure to environmental conditions
B
W
= f (cs-cc)
Structure with protected tension sides such as:
d:x .•......••....•.•...••....•.••••....••..... (4.1)
A
where Cs and Cc are the strains in the steel and concrete, respectively, at a given location between A and B and x is measured along the axis of the prism.
One
All protected internal members of ordinary buil~ngs. Permanently submerged members in water (wlthout harmful materials) or members permanently dry. iii- Well insulated roofs against humidity and rains. Structures with unprotected tension sides, such as:
Two
i-
The crack spacing and the strains in the steel and concrete are difficult to determine in practice and empirical equations are usually used to compute the crack width.
-;:
.;;/:::- :~: ' .JJ _{} J. ..J/
. -;l- t .J-i\ (a) Cracked member
-
T
Three
(b) Variation of steel stress along bar Four
iii-
Structures in open air, e.g. bridges and roofs without good insulation. iiStructures of category one built nearby seashores. iii- members subjected to humidity such as open halls, sheds and garages. Structure with severely exposed tension sides, such as:
iii-
Members with high exposure to humidity. Members exposed to repeated saturation with moisture. iii- Water tanks. vStructures SUbjected to vapour, gases or weak chemical attack. Members with tension sides very severely exposed to corrosive influences of strong chemical attack that ,cause rusting of steel i-
(c) Variation of concrete stress along prism ii-
Members subjected to conditions resulting in rust of . steel such as gases; vapour including chemicals. Other tanks, sewerage and structures subjected to sea water.
Fig 4.2 Stresses in concrete and steel in a cracked element 293 294
The Egyptian Code requires a minimum suitable cover for protecting the steel reinforcement. The cover should not be less than the larger value determined from Table (4.2) or the largest bar diameter.
All element except walls
structure - Table
and slabs
(4.1)
where
13= 1.7 1.3
Tab~e (4.2) Minimum concrete cover** (mm)
Category of
1
1.7
Walls and Solid slabs
feu :525
feu )25
feu :525
feu )25
N/mm2
N/mm
2
N/mm2
N/mm2
One
25
20
20
20
Two
30
25
25
Three
35
30
Four
45
40
For cross sections having a width or depth (whichever smaller) between value 300 mm and 800 mm, the coefficient 13 shall be proportionally calculated.
=
Bar diameter in mm. In case of using more than one diameter, the average diameter shall be used.
20
131 =
A coefficient that retlects the bond properties of the reinforcing steel. It shall be taken equal to 0.8 for deformed bars and 0.5 for smooth bars.
30
25
132 =
40
35
Coefficient that takes into account the duration of loading. It shall be taken equal to 1.0 for short term loading and 0.50 for long term loading or cyclic loading.
Coefficient that retlects the effect of bond between steel and concrete between cracks. It shall be taken equal to 0.8 for deformed bars and 1.6 for smooth bars. In case of members subjected to imposed deformation, the values of kl shall be modified to kkl where the value of k is taken as follows:
** The concrete cover should not be less than the largest bar diameter
4.5.2 Satisfaction of Cracking Limit State In order to satisfy the limit state of cracking, the Egyptian Code requires the fulfillment of the following relation: Wk
E,.
=/3.Srm· esm
:$ W kmax •••••••••••••••••••••••••••••• (4.2)
1:
~~ (1-P,P, (
n. . . . . . . . . .
The values of Wk calculated using Eq. 4.2 should be less than Wkmax values given in the Table (4.3).
295
Coefficient that relates the average crack width to the design crack width. It shall be taken as follows: For cracks induced due to loading For cracks induced due to restraining the deformation in a section having a width or depth (whichever smaller) less than 300 mm. For cracks induced due to restraining the deformation in a section having a width or depth (whichever smaller) more than 800 mm.
k=
k= k=
k=
(4.4)
0.80 for the case in which the tensile stresses are induced due to restraining the deformation. For rectangular cross section, the value of k is taken as follows: 0.8 for rectangular section having a thickness ?: 300 mm. 0.50 for rectangular sections having a thickness :::; 800 mm. For rectangular cross sections having thickness ranging between 300800 mm, the value of k can be calculated using linear interpolation. 1.0 for cases in which the tensile stresses are induced due to restraint of extrinsic deformations. Coefficient that retlects the strain distribution over the cross section. It shall be taken equal to 0.5 for section subjected to pure bending and 1.0 for section subjected to pure axial tension. For section subjected to combined bending and axial tension, k2 shall be calculated from Eq. 4.5.
296
Table (4.3) Values of Wkmax (mm)
k2
Where
= 81 +82 ............................................ (4.5) 281
81 and 82 are the maximum and minimum strain values, respectively,
to which the section is subjected. They shall be calculated based on the analysis of a cracked section as shown in Fig. 4.3.
Category of structureTable (4.1)
One
Two
Three
Four
Wk
0.3
0.2
0.15
0.1
+
t a- Strain distribution due to axial tension
b- Strain distribution due to B.M. or eccentric forces with big eccentricity
d
Steel c.g
c- Strain distribution due to eccentric tension with small eccentricity.
• • • • • • •
tcef is the minimum of - 2.5(Cc +
Fig. 4.3 Values of the factor k2 tcef = 2.5(t-d)
is
= stress in longitudinal steel at the tension zone, calculated based on the
Element in tension
Beams
analysis of cracked section under permanent loads.
isr
= Stress in longitudinal steel at the tension zone, calculated based on the analysis of cracked section due to loads causing first cracking (Mer).
In case of intrinsic imposed deformation, fs may be taken equal to fsr.
Pr = Ratio of effective tension reinforcement. Pr
=
::1 .............................................
Slabs (4.6)
where As = area of longitudinal tension steel within the effective tension area. Ael
c = neutral axis depth measured from the compression fibers Cc = clear concrete cover
= area of effective concrete section in tension,(=width of the section x
teel ).
The value of
teel
can be calculated according to Fig. 4.4.
297
298
4.5.3 Code Related Provisions
Table (4.4) Control of cracking for smooth bars by limiting steel stress under service loads or reduction QJdesign yield stress in steel to (Per Iy) .
.
." ""
."'
... ' .f:··,::'~'f.;~ .;\-:~.; ., ,... ~ '~I
The Egyptian Code permits nit carrying out the calculations of the limit state of cracking in accordance with Eq. (4.2) if one of the following conditions is met:
.
·f .". j . ; " , ~:.'. :~·.tI~.J'~;.~;; ~i~ ~:
. ... '" '.
,
1- In ordinary buildings classified as Class No.1 or Class No.2 according to Table (4.1) and where live loads do not exceed 5.0 kN / m
2
four Largest Bar diameter (cj)max) in mm
for the following two cases:
i) Solid slabs of thickness not exceeding 160 mm.
140
1.00
25
18
12
ii) T- and L- beams with the flange in the tension provided that the effective flange width to the web width (Bib) exceeds 3.
120
0.84
28
20
18
100
0.69
2- For elements subjected to bending moments and axial compressive forces exceeding (0.2Ieu Ae }under service load conditions. 3- For elements in which tensile steel stress Is under service loads are equal to or less than the values given in Tables (4.4) and (4.5).
28 "'-:',,"0
•
I~'
•
.
.
fs (N/mm:.!)
Reduction factor
4- In case of using limit states design method, it can be considered that the limit state of cracking regarding the stresses in the reinforcing steel is satisfied by mUltiplying the yield strength h by the factor Perin Tables (4.4) and (4.5).
W.S.D
Per (U.L.D)
5- For structures classified as category 3 or 4 in which water tightness is required, the tension stresses should satisfy Eq. 4.7.
299
... .....f.i
,>~ ~;
. ';,'< .
Table (4.5) Control of cracking for {Ieformed'bars by limiting steel stress under service loads or reduction or'designyield stress in steel to (Per I y) Category "
.
one .
.
"
,
Category
Category
two
three & four
36/52
40/60
220
1.00
0.92
18
12
8
200
0.93
0.83
22
16
10
180
0.85
0.75
25
20
12
160
0.75
0.67
32
22
18
140
0.65
0.58
--
25
22
120
0.56
0.50
--
--
28
Largest Bar diameter (cj)max) in mm
300
.
4.6 Liquid Containing Structures
4.7 Design Aids for Calculating w k
Liquid containing structures should be designed as non-cracked sections. In these structures the tensile stresses induced by loading should be less than the value given by the following equation:
The calculation of the factor Wk is complicated and time consuming. Therefore, design curves may be used to reduce the computation time.
fet = [fet(N) +fet(M)] ::; f etr ............................... (4.7) 17 where fetr= the cracking strength of concrete and is given by: f etr =O.6~ feu .................................................. (4.8)
fet(N) = the tensile stresses due to unfactored axial tension force (negative
sign is used for compressive stresses). fct(M) = tensile stresses due to unfactored bending moment.
Hence, the factors appeared in Eqs. 4.2, 4.3 and 4.4 are evaluated as follows:
k t =0.80
--7
k2 =0.50
--7
deformed bars section subjected to simple bending moment
fit
=0.80 fi2 =0.50
--7
deformed bars
--7
long term loading
fi = 1.70
--7
cracking due to loads
The crack width equation can then be expressed as: '=fi S nnsm B = 1.7 S B 'W k nnsm
The coefficient (17) is determined in accordance with Table (4.6) and it depends on the "virtual" thickness tv calculated from Eq. 4.9.
"~, [I+(~::::J] . . . . . . . . . . . . . . . . . . . . . . . .
The curves were prepared for rectangular sections reinforc~. with deformed bars and subjected to long term loading that result in, pure bending moment.
In which
S nn =(50+0.25k J k2
(4.9)
.................... (4.10)
:J
As jlxbxd P =-= r
...;.mhere t is the actual thickness of the cross-section.
Aee!
Table (4.6) Values of the Coefficient 17 Virtual thickness, tv (mm) Smaller than or equal to
Greater than or equal to
Coefficient fI
Pr
Aee!
Aee!
= 2.5x(t -d)xb jlxb xd 2.5x(t -d)xb
2.5 (t Id -1)
s ~ ~(50 +0.25xO.8x0.5x ;, ) ~(50 + 0.25 x ~
(0:
100
1.00
200
1.30
400
1.60
The previous equation is a function of tid, the bar diamet~r reinforcement ratio I!. The values of Sm are given in the Appendix.
600
1.70
An example of such design aids is given in Fig. 4.6.
301
302
-I») ....... (4.11) ,
and the
,
Similarly, the second tenn
..
tim;ca:~~tr:~:::rf:~O)I:O):S~ esm .
rlt '/32
1.
.' .: :~~~i:if¥'~-.l{,.:,~~
.,.; ,
. I
...;, ...,';1 .. ;.:: .... :..... (4.12) [s . ./:...~:~':'f~'y<,;> .
bxc 3
A (d er =--+n 3 s
_C)2 ........................ (4.16)
The ratio hils can expressed a s : . '.. .7."
To calculate the steel stress~s; t,· f116 tracked moment of' inehia··~·eed to be computed. Referring to Fig. 4.5;-the;neutral axis distance is obtained by taking the first moment of area of the transformed section as follows:
.
. f =nxMer X(d -c) sr
Is
................................ (4.17)
Ier
M = nX -xed -c) .................................. (4.18) Ier
I..
b
-I
I..
_J~
___ _ " ,'" . ."
:,. t 1'~ I, -t.: ''', ,
.•••• As Cracked section
linear stress distribution
b
Isr
-I
f s',
~_J:
1
,
............................................... (4.19)
M .' '
"
Mer. ":"'f .' x!.L = 0:6'fj-:-·~b:~t3./12= 0 1 ~ b t 2 - dr .' .', ..jJ.I.. eu. ' / 2'. . eu y
I· ,
.
•
t· ."
.(,.~.:.:.":~. ~·l ... .',· : ....
....:.. ; ';·l·:r;;:.:: );'ii;:Y' .
.-,-.~~~~~~\~~'@ :..~.:.:-.-.- ..; .,
= Mer
"J
.
3,-' :.
. 2
".'. ,:.',
;2
nAs
.( t J2
M.··· ,b. =0.1$:. : ' .. .~
d
........................... (4.21)
,
Transformed
e
Fig. 4.5 Determination of the neutral axis and cracked transformed moment of inertia calculations
sm
nXMX(d-C)(1-0.80xO.5 (Mer)2) ............. (4.22 ) 6 xl. 2x10 M . c.r 2
2
2
b xc /2-n As (d -c) = 0 ..................... (4.13)
Subsisting with c=Ad and !-i =A/b d gives: 2
nAs (d -.:id) =0 ..................... (4.14)
2
Dividing by bd , substituting with f.ln= (n 1-1-), and solving for A gives:
.:i=~2!-in +!-in 2 -!-in ................................ (4.15) Having determined the neutral axis distance c, the cracked moment of inertia Ier can be computed as
'(Mer/bd2 )2] e= nX M /b d X(1-.:i)( 2 1-0.80xO.5 sm
2x106 xl cr /b d
M /bd
•••••••••••
(4.23)
The previous equation is a function of MId b2, tid, and the reinforcement ratio 1-1-. For each value of the concrete strength !cu, design curves are plotted and given in the Appendix.
An example of such curves is given in Fig. 4.6 and the rest are in the Appendix Take kr =1.7 esm X 104 • Knowing MId b2, tid, and the reinforcement ratiQ 1-1-, the value of kr is obtained using the design aids. The value of Wk can be obtained using the following equation: W k
=Sm xkr
X 10-4
.................................. (4.24)
The use of !hese curves is illustrated in Example 4.3.
303
(4.20)
Normalizing the cracking moment by'divIrig by (b d ) gives;
Recti on
b (.:id)2
•••••••••
304
Wk
factor for sections subjected to bending only
Example 4.1
fcu=50 N/mm 2 , t1d=1.05, ribbed bars, n=10 ~'-.
70
65 60
Vl'--Q Po2
. 4•
•••••
55
/
50
/
45
II
~ 35
I
30
/
V
/
/
V
·V
/
/ /
V
V
/
/
/
/
It is required to design the cross-section of a wall comprising a part of an ;o:oQ4
/
)7
/
I
40
/
~ ~.003 V
/
Cl={).oos /
/"
/'
./ . / V
V
/"
/'
Solution 0.006
./
0.007
./
./"
0.008
V ;7 / /./"'" ~ ~ I~:~~~ / / V / /'/" ~ ~ ~ ~ r::::::: :::::::IK8g .... 0.015 / v/ /:::: ~ ~ :8 ~ ~ ~ ~ /~ ~ ~ ~ ~ ~ ~ ~
I /
25
/
/'
v/
20 15 10
o 0.0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
2.2
2.4
2.6
2.8
Mlbd 2
0.001 0.002 0.003 0.004 0.005 0.006 0.007 0.008 0.009 0.010 0.011 0.012 0.013 0.014 0.015
12 200 125 100 88 80 75 71 69 67 65 84 63 62 61 60
14 225 138 108 94 85 79 75 72 69 68 66 65 63 63 62
16 250 150 117 100 90 83 79 75 72 70 68 67 65 84 63
2- The steel reinforcement should be designed to resist the tensile forces
developed at ultimate stage. The stresses developed in the steel reinforcement at this stage should not exceed Pcr fy where Per is a factor less than one and depends on the bar diameter.
18 275 163 125 106 95 88 82 78 75 73 70 69 67 66 65
3.0
Step 1: Uncracked section analysis
Assuming, t
Bar Diameter
10 175 113 92 81 75 71 68 66 84 63 61 60 60 59 58
1- The concrete dimensions of the cross-section must be chosen such that the tensile stresses developed due to the unfactored straining actions are less than the tensile strength of concrete.
The concrete dimensions of the cross-section are determined such that the tensile stresses developed in the section when subjected to the unfactored straining actions are less than the tensile strength of concrete.
Values ofSm
.).1
In water containing structures, the Egyptian code requires the satisfaction of two conditions:
---
",
5
elevated reinforced concrete water tank. The section is subjected to an unfactored bending moment of 85 kN.m/m' and an unfactored tension force of 110 kN/m'. The material properties are.fcu=30 N/mm~ and/y =360 N/mm2
20 300 175 133 113 100 92 86 81 78 75 73 71
69 68 67
22 325 188 142 119 105 96 89 84 81 78 75 73 71 70 68
25 363 206 154 128 113 102 95 89 85 81 78 76 74 72 71
28 400 225 167 138 120 108 100 94 89 85 82 79 77 75 73
32 450 250 183 150 130 117 107 100 94 90 86 83 81 79 77
The tensile stresses in the section are' calculated according to the following equation: fet
= fet(N) + fct(M)~fetrl1J
N fct(N)=A c 3
11Ox10 0.20N Imm 2 f.ct (N) -- 1000x550 fet(M)
Fig. 4.6 Example of design curves for calculating the factor Wk
305
= 550mm
6M =-2
bt
306
eS =e
6
f.
(M)= 6x85x10 =1.69Nlmm 2 et 1000 X550 2
fct = 0.2 + 1.69 = 1.89 N 1mm fetr
2
es
v
= 528mm
MilS =Nu xes = 154xO.528 = 81.3kN mlm
For h =360 N/mm2, Table 4.5 is used. The value of Pcr for 16 mm diameter bar can be taken as the average between
2
=; factor that is determined from Table (4.6) according to the following
equation: t
12 + cover
es = 770-550/2+ (25 + 16/2)
= 0.6~ feu
fctr =0.6.J3Q=3.28Nlmm
11
-t
R P cr
= 0.85 +0.75 = 080 2
1
=tX{1+ fet(N)} fct{M)
fetr = 3.28 1] 1.7
Reduction factor
Category
Category
W.S.D
I3cr(u.LD)
one
two
-17';::1.7 -
tv = 550X{1+ 0.20}=615mm 1.69 =1.93N Imm 2
f,(N/mm")
Category
(
)
three &
'- four 2
> fet = 1.89N Imm ;: ................Ok. ' .:_ :" T · · · • -
220 200
36/52
40/60
1.00
0.92
18
12
0.93
0.83
22
16
Largest Bar diameter (CPmax) In mm
......-----....
1
....-'-. 12
Step 2: Cracked section analysis
180
( 0.85 \
0.75
25
20
(
According to ECP 203, the load factor for liquid containing structures is 1.4
160
'-Q2Y
0.67
32
22
'-.!V
Mu = 1.4x85= 119 kN.mlm
140
0.65
0.58
--
25
22
120
0.56
0.50
--
--
28
Nu =1.4xUO=154kN.mlm
d =t-(clearcover+¢12)
)
According to Table 4.1 the structure is classified as class 3. For such a class, Table 4.2 gives a minimum concrete cover of 25 mm. Assume the reinforcing bars used are of 16 mm diameter. d
=550-(25+16/2) =517mm d=c j
[lIt bXfcu
CI =9.93
119 e== O.77m = 770mm 154
517=c j
__ US_
d
Since e > tl2, the section is subjected to normal force with big eccentricity and Mus approach can be used.
307
As
=
(c) d
c -< -
min
81.3x10 6 1000 x 30
c take - = 0.125 d
81.3x10 6 154x103 + 0.80x360xO.826x517 0.80x360/1.15
308
and
j =0.826
= 1276mm 2 ....... .use7¢16Im
Example 4.2 .
A reinforced concrete raft (categorized as category one) of a thickness 900 mm and is subjected to an un factored bending moment of 700 kN.m/m. The material properties are!cu=30 N/mm2 and/y =360 N/mm2. .
/
"
In order to design the steel reinforcement satisfying the limit states of cracking, the Egyptian Code gives two options to the designer:
For category one structures and deformed bars of diameter 32 mm (decided by the designer), the value of Per can be obtained from Table 4-S as 0.7S. 6
A = s
1- Design the steel reinforcement such that the stress developed at the ultimate stage is Per /y. The reduction in the stresses developed in the steel is intended to guarantee a limited crack width at service loads. This is a simple straightforward approach that usually leads to uneconomic design 2- Design the steel reinforcement such that the stress developed at the ultimate stage is /y. However, the designer should check the satisfaction of the Egyptian Code (Eq. 4.2) in order to guarantee a limited crack width at service loads. This approach needs an extensive amount of calculations but usually results in an economic design.
lOS0x10 6 Cl=4.S1 & j=0.817 1000x30
Mu A, = - - - " - - - . Pcrxfyxjxd
It is required to design the steel reinforcement to resist the applied moment and to check the satisfaction of cracking limit state in the Egyptian Code.
Solution
8j4=Cl
lOS0xlO = S640mm 2 0.7Sx360xO.817x844
Use 7<1>32
Approach 2 This approach is based on designing the steel reinforcement to develop the full yield strength at ultimate stage and to check cracking status using Eq. 4.2.
Step 1: Cracked section analysis -Minimum clear cover = 40 mm ~Ultimate
Moment = Ultimate Factor x Bending Moment
Ultimate Moment = 1.Sx700=10S0kN.m
Approach 1 As mentioned above, this approach is based on designing the steel reinforcement based on usable stresses of = Per X fy at the ultimate stage. -Minimum clear cover =40 mm -Ultimate Moment = Ultimate Factor x Bending Moment Assuming the factor = 1.S Ultimate Moment = 1.S x 700 = lOS0 kN .m - The effective depth (d) = total thickness - clear cover - <1>12 Assume the use of reinforcing bars of diameter of 32 mm. From Table (4-S) for Category II and assuming ¢= 32
---7
Pcr = 0.7S
Assume the use of reinforcing bar of diameter of 32 mm. d =900-40-32/2=844 mm
Jk
u d=C1 - b xfeu
6
844=Cl lOS0x10 Cl = 4.S1 & j =0.817 1000x30
= __M--'u"---_
A
d = 900 -40 -32/2 = 844.0mm d=C1
_ The effective depth (d) = total thickness - clear cover - <1>12
S
fyxjxd 6
Mus bxfcu
A = s
309
lOS0xlO = 4230mm 2 Use 6<1>32 360xO.817x844 310
Step 2: Calculation of the value of
Step 2.3: Calculation of steel stresses, fs
Wk
Step 2.1: Calculation of the depth of the neutral axis, c
M =nx-x(d -c)
Is
Ier
The first moment of area of the cross-section about the neutral axis must be equal to zero.
6
=lOx 700x10 x(844.0-241.17) = 190.03N Imm 2 22.21x109 .
c2 1000 x - = lOx (6x804)x (844 -c) 2 Solving quadratic equation for c, c = 241.17 mm.
. N.A.
1000
I..
] §
As
• • • • • fs
N.A.
1000mm
I·
o o
•
Cracked cross section
0\
As
• • • • •
•
6<1> 32
Cracked cross section
Step 2.4: Calculation of cracking moment, Mer
Ig
Mcr=lctr x -
I Step 2.2: Calculation of
dr
Icr
y
=0.60xJi: =0.60x.j30 = 3.286N 1mm 2
I g
=~Xb xt 3 12
=~XlOOOX9003 = 60.75 X109 mm 4
3
12
1000x241.17 + lOx (6 x 804) (844-241.17)2 = 22.21 X109 mm 4 3 . M
er
311
9 = 3.286x 60.75 X10 x_1_ = 443.7 kN .m 900/2 106
312
Step 2.5: Calculation of steel stress fsr For n=1O, c= 241.17 mm, Icr = 22.21 X 109 mm4 M
isr =nx-E-x(d -c)
Step 2.7: Check the value of Wk
Snn
Wk
=/3.s rm'C sm
=(50+0.25k) k2 : )
Ier
=lOX443.7XlO: x(844.0-241.17)= 120.44N /mm 2 22.21xlO
Srm
=(50+0.25XO.80XO.50X~) 0.0345
S,m
= 142.75
C
= 190.035 (1_0.80XO.50X(I.20.44)2J 2x10 190.03
Step 2.6: Calculation of P r As
Pr=~ eef Acej tee! =
=bxtcej
sm.
2.5x(clear cover + ¢/ 2)
=0.000797 3
tee!
=2.5X(40+ ;)=140.0mm
W k
=1.70xI42.75xO.000797 = 0.1935 mm
From Table 4.3,
6x804.0 r P 1000x140.0 =0.0345
Wkmax
for category one is equal to 0.3.
Since W k =0.1935 <0.30 the structure stratifies the limit state of cracking.
Note; It can be determined that:
It can be noted that the calculations needed in Approach 2 are lengthy and
k) =0.80
-t deformed bars
k2 = 0.50
-t simple bending moment applied
A =0.80
-t deformed bars
/32 = 0.50 /3 = 1.70
-t long term loading
cumbersome. However, it results in economic design when compared to Approach 1 as noted in the amount of steel reinforcement resulted from each design.
-t .cracking due to loads
313
314
Example 4.3 Wk
It is required to calculate the factor Wk for the raft given in example 4.2 (Approach 2) using the design aids given in the Appendix.
factor for sections subiected to bending only fcu=30 N/mm2, tld=1.05, ribbed bars, n=10
70
Solution
65
Step1: Calculate curve parameters
60
I~o.oo
~
!..- = 900 = 1.066
= 900-40- 32 = 844 mm
J
/
50
d 844 2 The computed reinforcement from example 4.2 (Approach 2) is 6<1>32
45
/
40
;. =~= 6x804 =0.00572=0.572% 'Jl b xd 1000 x 8442
20
Wk
15
Step 2.1: Determine kr using the design charts
13.7
10
M
6
700 x 10 = 0.983 b xd 2 = 1000 x 844
5 0 0.0
Since no chart is available for (t1d=1.066), interpolation should be made between the charts available (t1d=1.05 and t1d=1.15), (refer to Fig. EX 4.3 given below). Using charts with t1d=1.05 gives kr = 13.7, and t1d=1.15 gives kr = 12.6. Interpolating, one gets kr = 13.5.
/
/'
/
./
/
/
/
/
/
/'
./
/
0.2
~
0.4
0.6
0.8
1.0
1.2
1.4
L6
Mlbd
,/
./
V
./
1.8
2.0
2.2
2.4
2.6
2.8
Using the previous design charts. For t1d=1.05 ~ Sm = 120, and for t1d=1.15 ~ Sm = 260. Interpolating, one gets Sm =142, (refer to Fig. EX 4.3).
Step 2.3: Calculate the factor W k
= kr xS m xlO-4
W k
= 13.5x142x10-4 = 0.192 rom
Wk
The systematic application of Eq. (4.2) results in w,FO.193 IDIll. Such a close agreement with the value obtained from the use of the design aids confirms their accuracy. .
315
(
W k
12 200 125 100 88 RO 75 71
69 67 65 64 63 62 61 60
14 225 138 108 94 R5 79 75 72 69 68 66 65 63 63 62
16 250 150 117 100 90 83 79 75 72 70 68 67 65 64 63
18 275 163 125 106 95 88 82 78 75 73 70 69 67 66 65
=Sm xkr xlO- 4
20 300 175 133 113 100 92 86 .81 78 75 73 71 69 68 67
,.,
-
22 325 188 142 119 05 96 89 84 81 78 75 73 71 70 68
25 363 206 154 128 13 102 95 89 85 81 78 76 74 72 71
Fig. EX 4.3 Using design curves for Wk factor 316
3.0
2
--
Bar Diameter
10 0.001 175 0.002 113 0.003 92 ...... 04 81 0.005 '.75 0.006 ./ 71 . 7 68 0.008 66 64 0.009 0.Q10 63 0.011 61 0.012 60 0.Q13 60 0.014 59 0.Q15 58 u
lO.006
V
,/
Values ofS m
Step 2.2: Determine Sm
0.005
~
)OOQ
25
Step 2: Calculate
11=( 1.004
/"" . /lo.007 J.008 / /v / /' / ' /"" . / ' /~ I V 1/ . / . / . / ' /V ~ ...-::: 0.010 / / i/V /'" / / :::::::~ ~ ~ 1/ L ~ ~ % ~ ~ ~ ~ ~ ;:::::::: 0.015 ;::::::::::;I /~ 0 0 ~ ~ ~ ~
30
'11= 1.0, (ribbed bars)
/
/
/
35
:.:.~
/
'.003
-/
/
-tf:',,-,~,:
55
d
V'
28 400 225 167 138 12
( 32
210 113
r
loll"\" 100 94 89 85 82 79 77 75 73
J
130 117 1UT 100 94 90 86 83 81 79 77
120
)-+,
Example 4.4
t es ! =--e-cover 2
The critical cross section of a reinforced concrete member that is a part of a structure with unprotected tension side (categorized as category II) is subjected to an unfactored bending moment of 100 kN.m and an unfactored tension force of 400 kN. The concrete dimensions of the member (b x t) are (350 mm x 900 mm). It is required to design the steel reinforcement of the section satisfying the requirements of the limit states of cracking in of the Egyptian Code. The . material properties are!cu=25 N/mm2 and/y =360 N/mm2.
Assuming the cover = 40 mm
Solution
Nu xe s2 l(fJ I I s) As! = d-d' cr y Y
In order to design the steel reinforcement satisfying the limit states of cracking, the Egyptian Code gives two options to the designer: 1-
2-
Design the steel reinforcement such that the stress developed at the ultimate stage are Pcr /y. The reduction in the stresses developed in the steel is intended to guarantee a limited crack width at service loads. This is a simple straightforward approach that usually leads to uneconomic design. Design the steel reinforcement such that the stress developed at the ultimate stage is h . However, the designer should check the satisfaction of Eq. 4.2 in order to guarantee a limited crack width at service loads. This approach needs an extensive amount of calculations but usually results in economic design.
~s! =450-250-40 = 160mm t
e.\·2 =2"+e-cover
es2 =450+250-40 = 660mm
From Table (4-5), for Category II and assuming ¢J= 22
--7
Pcr
= 0.75
3
A sl
A.v2
= 600x10 x660 1(0.75x360/1.15)=2057mm 2 860-40 .
•••••••••••
xes! l(fJ = Nu d _ d' cr x I y I Ys )
From Table (4-5), for Category II and assuming ¢J= 12 =
A
Use 6<1l22
s2
--7
Per = 1.00
2 600x103 x 1 6 0 · 1(1.0x360/1.15)=374mm ......... Use 4<1l12 860-40
Approach 2
Approach 1 As mentioned above, this approach is based on designing the steel reinforcement based on usable stresses of Pcrl y at the ultimate stage. Cross-section of beam = 350 mm x 900 mm N u = 1.5 x 400 = 600 kN M u = 1.5 x 100 = 150 kN.m
This approach is based on designing the steel reinforcement to develop the yield strength at ultimate stage and to check cracking status using Eq. 4.2.
Step 1: Cracked section analysis Cross-section of beam = 350 x 900
mm
Mu e= __
Nu
150 t . . c e = - - = 0.25m =250mm < - = 450mm .................eccentrIc tenslOn lorce 600 2 e = 150 = 0.25m =250mm < ~ = 450mm ......... small eccentric tension force 600 2
317
318
r'
• • • • 4<1> 12
Step 2: Calculation of Step 2.1
~ o
fs!
o
0'1
Calc~lation
of the steel stress f s
Nxe s2 d -d' 1 As! 3
As • • • • 4<1>22
400.0 X 10 x 660 11520 = 211.8N 1 mm 2 860-40
--
. . ..
0 0
0\
es ! =450-250-40 = 160mm
--
1350
.
es2 =450+250-40 = 660mm
A
s!
ASl
A $2
d -d'
Y
1
Ys
fsl
••••
es 2 =-+e-cover 2
= N U xeS2/ (f
fs2
S S
t es! = --e-cover 2 Assuming the cover = 40 mm
t
Wk
\
mml
Step 2.2: Calculation of steel stress f sr
)
In order to find the steel stress
600.0 X 103 x660 2 = 860-40 1(360/1.15) = 1543mm ........... Use 4¢22 xes! I(f 1 = Nu d -d' Y Y.,,)
I str ' one has to calculate the combination
and Ncr that result in first cracking of the section. It should be clear that one has to assume that the eccentricity of the tension force will be unchanged during the history of loading. fetr =0.60x~feu 11]
3
As2
= 600.0x10 x160.0 1(360/1.15) = 374mm 2 ••••••••. Use 4¢12 860-40
fetr
= 0.60x.J25/1.7 = 1.76N Imm 2
1 6xe fdr =Ncr(-b- + - b 2)
xt
319
Mer
xt
320
1.76 = Ncr X10 3 ( Ncr
"I = -660 x 0.00156 = 0.00643 160
1 + 6x250 ) 350x900 350x900 2
= 207.9kN k2
0.00643 +0.00156 = 0.621 2xO.00643
Ncr xe s2 1A d -d' .sl
--
3
x 10 x660 11520.0 = 1l0.lN 1mm 2 f sr = 207.90 860-40
Step 2.3: Calculation of Peff
0 0 0\
As rAce!
tee]
= 2.5x(clearcover+¢12)
tee]
= 2.5 X(30 + 22/2) = 102.5 mm
-'--
1520.0 = 0.042 350x102.5
Step 2.5: Check the value of kl =0.80 PI =0.80 P2 = 1.0 P =1.70
="I +"2 2
£1
••••
\
I?50 II1D11
Step 2.4: Calculation of kz k
£2
§
P =--
Pejf
• • • •
2£1
~
~
~ ~
Wk
deformed bars deformed bars short term loading case that includes loads
The strains 81 and 82 are calculated through the analysis of the transformed section. Assuming
" = 360/1.15 = 0.00156 2 2xlOS
321
srm
. 22 ) = 50+0.25xO.80xO.621x-( 0.042
Srm
= 115.06
322
(l-P,A(;:
E,. {
n
211.8 ( 1-0.8x1.0x (110.1)2) t:"m =---5 -2xlO
211.8
t:sm = 0.00083 W k
5 DESIGN OF FOUNDATIONS
= f3xsrm xt:sm = 1.70x115.06xO.00083 = 0.162 mm
From Table 4.3 Since
wk
Wkmax
for category one is 0.3
=0.162 mm <0.30 the structure stratifies the limit state of cracking.
Note; It can be noted that the calculations needed in Approach 2 are lengthy and cumbersome. However, it results in economic design when compared to Approach 1 as noted in the amount of steel reinforcement resulted from each design.
Photo 5.1 Foundation of a bridge column.
5.1 Introduction The main purpose of footings and other foundation systems is to transfer column loads safely to the soil. Since, the soil bearing capacity is much lower than the concrete columns; the loads need to be transferred safely to the soil by using larger areas usually called shallow foundations. If the soil has low bearing capacity, or the applied loads are very large, it may be necessary to transfer the load to a deeper soil through the use of piles or caissons usually called deep foundations.
323
324
Foundation design requires both a soil investigation; to detennine the most suitable type of foundation, and a structural design; to establish the depth and reinforcement of the different foundation elements. It is customary for the geotechnical engineers to carry out the soil investigation, and propose the best foundation system that fits a particular location. It is the responsibility of the structural engineer to establish the size and amount of reinforcement for each component of the proposed foundation system. This chapter addresses the structural design of shallow foundations and piled foundations. Traditional analysis and design procedures are explained. The chapter also explains the use of the finite element method for the analysis and design of complicated foundation systems such as shallow rafts and rafts on piles.
column
RC footin PC footing
(a) Wall footing
(b)Isoiated footing
5.2 Types of Foundations The choice of a particular type of foundation depends on a number of factors, such as the soil beating capacity, the water table, the magnitude of the loads that needs to be transferred to the soil, and site constraints such as the existence of a property line. Generally, foundations may be classified as follows: •
Shallow foundations: This type includes sttip footing, isolated footings combined footing, strap footing, and raft foundation
•
Deep foundations: This type includes isolated pile caps or raft on piles
column
column
exterior
interior
:lJ:~:=n=S~=tra{'; :.~,:?eam_~7==C=Ol~ ....
RC footin o PC footing
I
~
(d) Strap footing
(c) Combined footing
Fig. 5.1 shows some types of foundations that are usually used in structures. A strip footing is used under reinforced concrete walls to disttibutethe vertical loads over the soil as shown in Fig. S.la. The load is transferred mainly in one direction perpendicular to the center line of the wall. Isolated footings are the most common type of foundations in ordinary structures. They used to disttibute column load on relatively large area of soil as shown in Fig. S.lb .. They transfer the load in two directions. If two columns or more are closely spaced or the required footing sizes overlap each other, the two footings are combined in one big footing called combined footing (Fig S.lc). If one of the footings is very close to a property line, then a stiff beam is used to connect this column to an intetior column. This type is called strap footing as shown in Fig. S.ld. If the applied loads are heavy or more than 60% of the isolated footings overlap, a raft foundation is used to support the entire structure as shown in Fig. S.le. This is similar to an inverted flat slab in which it contains column and field sttips. Finally, if the applied loads are large or weak soil encountered, it may be practical to support the structure into deeper more stiff soil through the use of pile foundations. Pile caps are used to disttibute column loads to a group of piles as illustrated in Fig. S.H.
325
RCrnat PCrnat
(e) Raft foundation Fig. 5.1 Types of foundations
326
_
Applied load
:.:.:.:;:.:;:.:;:.:;:.:;:.:;:.:;:.:;:.:(:;
:.
::
:.:/.:.:
I'~:~))'~:~'))~:?~
:::
Pile cap ~:~:~: :.:.:.
B?':::':::'
:'
5.3 Soil Pressure under concentrically Loaded Footings
~:~:~':':':':':'
r :.:
In addition to the variation of soil distribution under different types of soils, the stiffness of the footing itself adds more complexity to the problem. For design purposes, the bearing soil distribution is assumed uniform regardless of the type of soil or the stiffness of the footing as shown in Fig. 5.2c. The assumption of uniform pressure simplifies the calculation of the acting forces and speeds up the design process. Experimental tests and the performance of the existing buildings indicate that this assumption results in conservative designs.
Section
:--,
.....
:......
..... .... 0
"
column
....
•
0
....
:-",
....
:-".
The actual bearing soil pressure differs significantly according to the type of soil, stiffness of the footing and loading conditions. In general, the distribution under the base of the footing is non-uniform. Assuming the loading is concentric and the footing is rigid, the soil pressure distribution under sandy soil (cohesionless soil) may take the parabolic shape shown in Fig. 5.2a. The part of the soil under the column is likely to be pressured more than the part at the edges. The soil particles near the edges escapes from under the footing providing less support and producing less pressure. In contrast, in a clayey soil (cohesive soil), the stresses near the edges are larger than those at the middle as shown in Fig. 5.2b. This is attributed to the shear stresses developed near the unloaded portion (surrounding the footing) of the soil near the edges. This additional support results in producing high stresses near the edge than those developed at the center of the footing.
......
:-
:-", .....
Piles
Pile cap
....
:-",
Plan
(0 Pile foundation
Fig. 5.1 Types of foundations (contd.)
327
Photo 5.2 An isolated footing during construction
328
load
5.4 Soil Pressure under Eccentrically Loaded Footings Foundations may be frequently subjected to eccentric loading resulting from lateral forces due to wind or eatthquake. The moments developed at the base of the footing produce a non-uniform soil pressure that needs to be taken into account. If the eccentricity of the load is small, compression stresses develop across the contact between the footing and the soil as shown in Fig. 5.3a. The maximum stress III/ax should be checked against the allowable bearing capacity. As the eccentricity of the load increases, the difference between the maximumj;nax and minimum j;llill stresses increases. The· classical stress equation is used to determine the distribution of the soil pressure as follows:
.:.
a- Footing on sandy soil
load
P M lmax =-±Y ................................. ,............ (5.1)
~.
min
I I
A
I
Where P and M are the unfactored axial load and moment, respectively, and y is the distance from the c.g ofthefooting.
RC footing
For rectangular footings (Lxb) in which A = b xL, I =b X L3 112 and y = Ll2, the previous equation may be written in the following form
I
1--
-"'----
b- Footing on clayey soil
load
RCfooting
II
c- Assumed uniform pressure
Fig. 5.2 Soil pressure distribution under footings.
329
~:
I:: = b ~L ± b6
X:
2
••••••••••••••••••••••••••••••••••••••
(5.2)
1::=b~L(I±~e) ..................................... (5.3) At a certain limit (e=U6), the minimum stressin'ill becomes zero at the edge as shown in Fig. 5.3b. Any further increase in the eccentricity of the load will result in negative pressure (tension). However, the previous equations are only valid when no tensile stresses are developed. This is because tensile stresses cannot be transmitted between the soil and the concrete, and redistribution of stresses should occur. For a rectangular footing of length L, if the eccentricity e exceeds U6, a triangular stress distribution will develop over part of the base as shown in Fig. 5.3c. For equilibrium to occur, the centroid of the soil pres~ure must coincide with the applied load Pu• If we denote the distance from the applied load Pu to the footing edge a, then the length of the base on which the triangular stress distribution developed is 3a. Applying the equilibrium equation gives: I -lmaxxbx(3a)=Pu ...................................... (5.4) 2
330
p
f max = 3::~b L
L
2
2
........................
(5.5)
Where-+e +a = L or a =--e PC footin_W:i;;;;:;:~;;;;;;:;:~==""':.:.:w;.a
The maximum developed pressure fmax should not exceed the soil bearing capacity. The assumed pressure distribution is expected to deviate from the reality because of the non linear stress-strain relationship of the soil. The amount of deviation increases as the amount of eccentricity increases. However, experience over the years showed that this simplified analysis gives a safe design. Footings subjected to high moments tend to tilt and undesirable differential settlement develops. Therefore, it is recommended to minimize the eccentricity of the applied load as much as possible. In some other cases the footing may be subjected to eccentricities in both directions. This produces biaxial moments on the footing. Only one comer point is subjected to the maximum stress. The soil stresses may be obtained using the stress equation as follows:
_ P
Mx
My
A
Ix
Iy
Elevation
bI ,. -..-..-_.------'-----'
-i.. -··-··-··- '-"-"-
----.--------_
Plan
L
'l////////////////////' "//////////.///////////,
,./////////////.//./////h. '/////////////////////~
fmax - - ± - y+-x ............................... (5.6) min
Hand calculations of such problems are difficult, and computer programs are usually used to determine soil distribution and the acting forces. a)small eccentricity e ::;; Ll6
p
b )eccentricity e = Ll6
Photo 5.3 Foundations of a high-rise building during-construction 331
c)large eccentricity e ~ L 16
Fig. 5.3 Soil stress distribution for eccentrically loaded footings
332
Example 5.1
The concrete footing shown in figure is designed to support a dead load of 1260 kN and a live load of 820 kN. The allowable soil pressure is 320 kN/m2. Determine and check safety of the developed soil pressure if the eccentricity equals: a) e=O b) e=0.3m c) e=0.8 m
Case b
Since e = 0.3 m < U6 = 0.567m, the soil bearing pressure can be obtained using the following equation:
P- (1+6e) i::--_0 bXL -L °
f max
s
o
cri
Pu
_ .. - .. _ .. _ .. _ .. -f.-e-.. _ .. - ._ ... .
f min
!71 I
2080 (1+ 6XO.3) = 311.88 kN/m 2 3.0x3.4 3.4
=
2080 (1- 6XO.3) = 95:96 kN/m 2 3.0x3.4 3.4
2) is less than the (F -311. ' 88 kN/m . . d pressure Villa;, Since the maXImum apphe . allowable soil pressure (320 kN/m\ the footing IS consIdered safe.
I
3.4m
=.
~I
2080kN
Solution
The total applied working loads (unfactored) equals: P = PDL + PLL = 1260 + 820 = 2080 kN
-r+r
Case a
~
~
I
For a concentrically applied load (e=O), the soil pressure simply equals the load over the area of the footing.
f =~= 2080 A
3.4X3.0
I I,:
=203.92 kN 1m 2
95.96 kN/m2
L
!
-
Since the applied r,ressure (203.92 kN/m2) is less than the allowable soil pressure (320 kN/m ), the footing is considered safe. P=2080kN
f=203.92 kN/m 2
333
334
11. 88 kN/nl
5.5 Gross and Net Soil Pressures
Case c Si?ce e = 0.8 ~ > U6 = 0.567m, the soil bearing pressure can be obtained usmg the followmg equation: L 3.4 a="2-e = 2 - 0 .8 =0.9 m
f max
2Pu 2x2080 2 =-3-x-a"--Xb- = 3xO.9x3 = 513.58 kN/m
Since the m~imum applied pres~ure (fmax=513.58 kN/m 2 ) is larger than the allowable sod pressure (320 kN/m ), the footing is considered unsafe.
If a concrete footing is located at the foundation level without any column load as shown in Fig. 5.4a, the total downward pressure from the footing and the soil above is 51 kN/m 2 . This is balanced by an equal and opposite (upward) soil pressure of 51 kN/m 2 • Therefore, the net effect on the footing is zero and neither moments nor shear develops in the footing.
20S0kN O.S
-
0.9
When the column load column is applied, the pressure under the footing is increased by 120 kN/m 2 as illustrated in Fig. 5.4b. Thus the total pressure on the soil becomes 171 kN/m2 • This is the gross soil pressure and must not exceed the· allowable soil pressure qallowable. When the bending moments and shear forces are computed, the upward pressure and downward pressure of2 51 kN/m 2 cancel each other leaving only the net soil pressure of 120 kN/m to produce the internal straining actions on the footing as shown in Fig. 5.4c.
r-
~ I
~'-
The soil pressure may be expressed in terms of gross or net pressure at the foundation level. The gross soil pressure is the total soil pressure produced by ail loads above the foundation level. These loads consist of (a) the service column load at the ground surface, (b) the weight of the plain and reinforced concrete footings, and (c) the weight of the soil from the foundation level to the ground level. On the other hand, the net soil pressure does not include either the weight of the soil above the base of the footing or the weight of the footing. It can be simply obtained by subtracting from the gross soil pressure the weight of I-m square of soil with a height from the foundation level to the ground level.
~
3a =2.7m
' -............ 513.58 kN/m2
I 1
In design, the area of the footing is chosen such that the applied gross 'pressure does not exceed the allowable soil pressure. The net soil pressure is used to calculate the reinforcement and to check the shear strength of the footing. The area of the plain concrete footing is calculated as follows: Area = Pgross(column 1000+ jooting+soil)
............................... (5 .7)
qallowable
The pervious equation can be further simplified by assuming the weight of the footing and the soil above is about 5%-10% of the column load. Assuming this ratio to be 10% the area of the footing can be obtained using Eq. 5.8 as follows:
Area =
1.1xPcolumn qallowable
336 335
••••••••••••••••••••••••••••••••••••••••••••
(5.8)
load=O
t
Example 5.2
soil wei ht
For the footing shown in the figure below, calculate the gross and the net soil pressures at the base of the footing. The densities of the plain concrete, the reinforced concrete and the soil may be taken as 22 leN/m3 , 25 kN/m 3 , and s?il= 18 kN/m 3 , respectively.
o \0 d
PDL= 820 kN P LL= 350 kN
51 kN/m2
a) Self weight and soil weight load=1080 kN q
.."
=1:...= 1080 =120 kNI11l2 A
3x3
G.L=zero
= ,~
-
~~~ ~<:»»~:»
e-
I
'"
h=1.3
1
! !
---RC (2.1
x2.1 x 0.4)
_ _ PC (2.6 x2.6 x 0.3)
I I I I I
2
I I I I I
Solution
qgro",,= 36+15+120=171 kN/m2
b) Gross soil pressure load=1080 kN q
""
F.L -2.0
j15+120=135 kN/m
I
-
"-i
llll!illll~l:~l'jl:il!illl! I ;mm;:;'im"~~~::~i ~~~ ><~
'~
Column 0.30 xO.60
<::::>
1~1~~~1~1~1~1~1~1~1~j~1~j~1~1~j~1~ \1~
-
The total loads above the foundation level are calculated as follows: 1. Column load
820 + 350 = 1170 kN
2. weight of the PC footing
22 x 2.6 x 2.6 x 0.3 = 44.6 kN
3. weight of the RC footing
25 x 2.1x 2.1 x 0.4 = 44.1 kN
4. weight of the Soil
18x2.1x2.1x1.3=103.19 kN
P 1080 =-=--=120 kNlm 2 ..,' A 3x3
.......... .......... ......... ..
.......... ......... .......... ......... ...... .......... .........
~Olal
=1170+44.6+44.1+103.19=1361.91 kN
The gross soil pressure equals: 1/1111111111111111111
o
f gross
\0
d
= p = 1361.91 = 201.46
A
2.6 x 2.6
kN 1m2
The added (net) soil pressure (due to adding the footing and column load) 2
qnel=120 kN/m
f""1 = fgross -weight of 2m of soil = 201.466 -18x 2 = 165.466 kN 1m
c) Net soil pressure Fig. 5.4 Gross and net soil bearing pressureS. 337
338
2
5.6 Design of Isolated Footings 5.6.1 Introduction The design of the isolated footings must consider bending, development of the reinforcement, one-way shear and punching shear. Since shear reinforcement is not permitted by the ECP 203 for one-way shear and two-way shear. Accordingly, shear rather the bending moment normally controls the depth of the footing. One-way shear reinforcement is not allowed in the footings because (1) determining of the effective pattern of shear reinforcement is difficult to establish when the footing is bending in two directions, and (2) the depth of the compression zone may be not sufficient to anchor the shear reinforcement that is intended to reach the yielding stress at failure. Punching shear reinforcement (two-way shear) is permitted by some international codes. Because of the difficulty of placing such reinforcement, the Egyptian Code insists in depending on concrete only in resisting two-way shear. The soil pressure causes the footing to deflect upward, producing tension in two directions at its bottom fibers. Therefore the reinforcement is placed at its bottom of the footing in two perpendicular directions without the need of top reinforcement. It is common in Egypt to construct a plain concrete footing above which a reinforced concrete footing of smaller dimensions is resting. Such an arrangement proves to be more economical than using a reinforced concrete footing resting directly on soil.
5.6.2 Design Steps . Step 1: Dimensioning of the Plain Concrete Footing
The plain concrete footing size is computed suing the allowable soil pressure. It is customary to assume that the weight of the soil and the footing equal to 5-10% of the column lo~d. The loads used in the calculations are the working loads (unfactored). Thus, the area of the plain concrete footing (A) equals: A = 1.1x(PDL +FLL )
••••••••••••••••••••••••••••••••••••••••••••
The dimensions of the footing are chosen such that an equal amount is projecting all around the column. Referring to Fig. 5.5, the dimensions of the footing are taken as
LxB = LX[L+(bc -aJ]= A .............................. (5.9b) Dimensioning the footing in such a way will ensure producing the same bending moment in all· four sides. Thus, the reinforcement in the reinforced concrete footing will approximately be equal in both directions. The thickness of the plain concrete footing is usually assumed from 250-500 mm depending on the soil type and the magnitude of the applied loads.
--;:;
.
a"
E:
..t:>"
-
:--
'--
+
...:J
.D
l:q
-
II
E:
l-
RC footing
-II-
':I
m
I
J l I
PC footing
m
I
L
Fig. 5.5 Dimensioning of the plain concrete footing Photo 5.4 Example of isolated footing reinforcement 339
(5.9a)
Qo1lowable
340
1 Step 2: Dimensioning of the Reinforced Concrete Footing The plan dimensions of the reinforced concrete footing are determined by subtracting a distance x from each side dimension of the plain concrete footing. The value of x depends on the soil bearing capacity. and the thickness of the plain concrete footing. The value of x is usually assumed '----6;8-1.0 the thickness of the plain concrete footing. Ar = L - 2x
and B r = B - 2x
More refined analysis can be obtained by equating the tensile strength of concrete to the tension developed in the plain concrete footing at sec 1-1 as shown in Fig. 5.6. 6M
J CI =JCI(M)
2
=--2-= bt
6(Pa x /2)
1xt
2=3.0 Pa
(X)2 :::;0.6 JJ:: 11] -
i
Table 5.1: xft values
!cu
Allowable soil pressure P a (kN/m') 2
100
125
150
175
200
225
250
300
15.0
1.23
1.10
1.01
0.93
0.87
0.82
0.78
0.71
17.5
1.28
1.15
1.05
0.97
0.91
0.85
0.81
0.74
20.0
1.32
1.18
1.08
1.00
0.94
0.88
0.84
0.76
22.5
1.36
1.22
1.11
1.03
0.96
0.91
0.86
0.79
25.0
lAO
1.25
1.14
1.06
0.99
0.93
0.89
0.81
30.0
1.47
1.31
1.20 .
1.11
1.04
0.98
0.93
0.85
N/mm
t
Where Pa is the allowable soil pressure and 11 is a coefficient that depends on the thickness (can be assumed=1.7) and t is the thickness of the plain concrete footing obtained from step 1. The previous equation can be solved to obtain the distance x. A factor of safety of 3 applied to the allowable tensile strength of concrete is assumed - to obtain the values listed in Table 5.1. Knowing!cu and the allowable soil pressure, one can get the value of xlt from table 5.1 and hence x is known.
The thickness of the reinforced concrete footing should not be less than 300 mm or the smallest column dimension which ever is greater.
Step 3: Design for Punching Shear The factored pressure qsu at the bottom of the reinforced concrete footing is obtained using the factored load as follows: =
q su
x Reinforced concrete Plain concrete
1
•••••••••••••••••••••••
(5.10)
Punching shear failure is referred as two-way shear. In the ECP 203, the critical perimeter for punching shear is at a distance d/2 from the face of the column as shown in Fig 5.7. The critical shear perimeter is given by
Critical section for plain concrete footing
---
Pu = 1.4PDL + 1.6 PLL ArxB r ArxB r
Soil pressure Pa
bo =2(a+b)=2(ac +d)+2 (bc +d) ............... (5.11) Where ac and be are the dimensions of the column, and d is the average effective depth in the two directions.
The punching shear load is obtained by subtracting the factored pressure multiplied by the punching area from the column load as follows .
Qup = ~ -qsu (axb) ............................................ (5.12) The punching stresses
Fig. 5.6 Dimensioning of a reinforced concrete footing quP
= bQ:d
:::;qcup··················:······························(5.13)
o
341
342
r ·1
I; I
I ! 1
Step 4: Design for One-Way Shear According to the ECP 203, the critical section for one-way shear is at dl2 from the face of the column as shown in Fig. 5.8. The shear stress developed in the footing is obtained from the factored soil pressure. Referring to Fig. 5.8, the total shear force at sec 1-1 equals:
a Qu =qsu ·(A r -2)'B r
............................... (5.15)
The corresponding shear stress is calculated as follows:
qu
Q
= _u_
.
.. ~ ........................................... (5.16)
Brxd
dJ2
Fig. 5.7 Punching loading area and perimeter. Since punching shear reinforcement is not allowed by the ECP 203, the developed shear qup should be less than concrete strength qcu given by the least of the following three values:
1.
qcuP =0.316 !,cu ::;1.6N Imm 2 .......................... (S.14a)
2.
qcuP = 0.316
rc
.
(O.SO+~) !,cu b
3.
qcup
Critical section for shear
= 0.8 (0.20 + ad)
bo
rc
............................ (S.14b)
Critical sectiot). for shear
!,cu ............................. (S.14c)
rc
Where a is a factor equals to 2, 3 ,4 for corner, exterior, internal footings respectively and bo is the critical punching shear perimeter. If the applied punching shear stresses are less than the concrete strength qcu , the footing is considered safe, otherwise the footing depth has to be increased.
-'---"-"-'---,' a.:.....1.,,;;;,,\+-";;;:_-..L.;:::"'_..;;1
Area considered for one-way shear in long direction
Fig. 5.8 Calculation of one-way shear stress The ECP 203 states that the one-way shear stress should be resisted without any shear reinforcement. The concrete shear strength is given by:
qcu
343
Area considered for one-way shear in short direction
=0.16~f;: 344
......................................... (5.17)
Step 5: Design for Flexure The ultimate soil pressure induces moment into two perpendicular directions. Frequently, the minimum reinforcement requirement controls the design.
Asmin
=~~6 b d
........................................... (5.18)
The critical section for moment is taken at the face of the column. A 1m strip is usually used to calculate the reinforcement per meter. Referring to Fig. 5.9, the moment per meter equals Mu
=qsu
Column reinforcement should be well anchored in the footing using column dowels. The length of these dowels inside the column should not be less than 40 the largest bar diameter as shown in Fig. 5.10.
Long direction rft
Short direction rft.
(Ar -ac )2 ............................................ (5.19)
8
Plain concrete /fOOting
s::
j. (Ar-ac)/2
•
I~c'I'
--,----
4fi (Ar-ac)/2
.j
critical section bending
I
~
bJl
s::
.£ s:: ...... ~
'- Rft in short direction
I~ Area considered for moment
,.
Reinforced concrete footing
¢:l
-
I
L
"·1
Fig. 5.10 Typical reinforcement and dimensions of isolated footings
Fig. 5.9 Critical section for bending 345
346
Example 5.3 Design an isolated footing for a rectangular column (0.25 x 0.8 m) that carries unfactored dead of 780 leN and unfactored live load of 440 leN, respectively. Design data: Allowable soil pressure =125 leN/m2 (1.25 kg/cm2) . 2 feu =30 N/mm (reinforced concrete) feu =20 N/mm2 (plain concrete)
h
=360N/mm
2
Thus, the dimension (B) must be greater than (L) by the difference in column dimension as follows B =L+(bc -ac )=L+(0.8-0.25)=L+0.55
The area of the plain concrete equals L (L + 0.55) = 10.6
Solving the previous equation for L gives 2
Solution Step1: Dimensioning of the plain concrete footing
L = -o.55+.J0.55 +4xl0.6 = 2.99 m 2
sayL=3.0m
The total working load equals
B = 10.54 = 3.513 m 3
sayB=3.55 m
Pw = 780 + 440 = 1220 kN The weight of the footing and the soil are assumed (5-10% of the acting working loads) say 8%
The plain concrete dimen~ion is chosen (3 x 3.55 ms)
The required area of the plain concrete footing equals
Step 2: Dimensioning of the reinforced concrete footing
Area = 1.08xpw = 1.08 x 1220 = 1O.54m 2 125 qoIlowable
From Table 5.1, xlt=1.18
The thickness of the plain concrete is chosen equal to 350 mm.
~
Assume x=t=O.35 m
Ar = L -2xO.35 =3-0.7 = 2.3 m
To have uniform soil pressure and economic design, the dimensions of the footing are taken such that the cantilever distance (m) is same on all sides of the column.
Br
=B-2xO.35=3.55-0.7=2~85 m
Pu = 1.4PDL + 1.6 PLL = 1.4x780+ 1.6x440 = 1796 kN
The factored net soil pressure qsu equals llc=0.25
m t::! I
" +
'-
~
II I:Q
-00
f--
c:i
II ~
-
m
I-
r
-i l-
ti ...\:)
qsu = A xB
m
I
II I I
r
1796 == 274 kN 1m 2 2.3x2.85
Assuming that the thickness of the RC footing is 0.55 m, the chosen dimensions are (2.3 x 2.85 x 0.55 ms).
m
Reinforced concrete footing Plain concrete footing
L
347
.j 348
rI
Step 3: Design for punching shear
1 \
Generally, the thickness of the isolated footing is governed by punching shear. The critical section for punching shear is at dl2 from the face of the column. Assuming 70 mm concrete cover, the effective depth d equals 480 mm
q q
=0.316 (0.50+ aC ) cup be cup
= 0.8 (0.20 + ad) U
~fcuY
=0.316 (0.50+ 0.25) 0.8 c
~cuY
c
{30 =1.15 N
VLs
= 0.8 (0.20 + 4X0.48) 4.02
Imm
{30 = 2.42N 1mm VLs
2
2
a = ac + d = 250 + 480 = 730mm
qcup= 1.15 N/mm2
b =bc +d =800+480 = 1280mm
Since the applied shear stress (0.798) is less than concrete shear strength (1.15) , the footing is considered safe
U = 2 (a+b) = 2 (730+1280) =4020 mm
Step 4: Design for one-way shear The critical section for one-way shear. is taken at dl2 from the face of the column as shown in figure. a = 0.25+d 12+d 12 = 0.25+d = 0.25+0.48 = 0.73 m .
250
H
Punching area
f = Ar -a = 2.3-0.73 = 0.785 m
2
~I
2
~
d/2=0.24
column
* - - - - 250x800 mm
0
00
N
......
td=0.48
I·
730
·1 critical section for shear
The punching load =column load - the load acting on the punching area Qup =Pu -qsu (axb) =1796-274 (0.73 x 1.28) =1540 kN
quP
=~= 1540xIOOO =0.798 N U xd
I
Imm 2
4020 x 480
The concrete strength for punching is the least of the three values
qcup=0.316~fcu =0.316~30 =1.41Nlmm Yc
2
1.5
I349
2.3
350
·1
T Qu = qsu . l.B r = 274 x 0.785 x 2.85 = 613 kN
=~= 613xlO00 =0.45 N
.
2850x480
b xd
qu
qeu =0.16
Step 5.3: Check the development of the reinforcement For simplicity, the values listed in the Egyptian code to determine the development length is used. For high grade steel without hooks the development length LtF60 cI>. For 16 mm diameter, LtF960 mm Bar extension past the face of the column equals
Imm 2
~/eu =0.16 ~30 =0.715 N Imm 1.5 1.5
2
Since qu is less than qcu the footing is considered safe in shear
,
!
Step 5: Flexural design
II
2300-250 - - - - = 1025 mm > Ld .....o.k 2
Step 5.1: Reinforcement in the short-direction The critical section is at the face of the column, and taking a strip of 1m: M u 1m' =qsu (Ar
_a~)2 x 1.0= 274 (2.3- °.25)2
= 143.93 kN.m 1m'
8 R =
6
Mu = 143.93 X 10 = 0.021 leu xb xd 2 30x 1000 x 480 2 .
I,
From the chart with R=0.021, the reinforcement index m=O.0245
I 30 As =(J)x~xbxd =0.0245x-x1000x480=980mm 2 Iy 360 0.60
0.60 360
II
t=5;r t=38= Plam . concrete
)
2
As woo =--xbxd =--x1000x480=800 mm
.
Iy
0
.
As=980 mm2
Use 5cI>16/m' (1000 mm
Vfooting
-
I
o
2 )
I(")
00
M
Step 5.2: Reinforcement in the long direction
~ \0 .....
eo
I(")
Reinforced concrete footin g
The critical section is at the face of the column, and taking a strip of 1m .Mu
~ qsu
(B r -be )2 = 274 (2.85 - 0.80)2 = 143.93 kN .m 1m'
8
II
5 161m'
-
8
Since the moment in the long direction is the same as the moment in the short direction, the reinforcement is taken identical (same) to that of the short direction.
I·
J
2300 3000
Footing reinforcement details 351
352
5.7 Combined Footings Combined footings are used when either one of the columns falls on a property line or when the two columns are close to each other such that the footings overlaps. The geometry of the footing is chosen such that the resultant of the two columns coincides with the centroid of the footing. This can be achieved by using trapezoidal footing (Fig. 5.l1a) or by adjusting the center of the footing at the resultant as shown in Fig. 5.l1b. The resulting pressure is uniform under the footings and help to prevent differential settlement. It is common to place the reinforced concrete footing above a plain concrete footing to reduce cost as shown in Fig. 5.11c. In some cases the resulting moments between the columns may become large and it may be economical to use an inverted T-beam to increase the effective depth and reduce the reinforcement as shown in Fig. 5.Ud. The basic assumption for the design of a combined footing is to assume that the footing is rigid and is subjected to a linear soil pressure. In actual practice, it requires very big thickness to make rigid footing. However, the assumption of rigid footing has been used successfully over the years. The combined footing can be designed as beam on elastic foundation that usually leads to more economic solutions. However, this method is time consuming and is not suitable for design office calculations.
IF-----~---m-II IF-----~---m11 d)Rectangular combined footing with PC base and T-beam
c)Rectangular combined footing with PC base
Fig. 5.11 Type of combined footings (cont.) In combined footings, soil pressure is resisted by a series of strips running in the longitudinal direction as shown in Fig 5.12. The load is then transmitted to the cross beams AB and CD, which transmit the pressure to the columns. The cross (hidden) beams are assumed to extend dl2 from the face of the column. The main top longitudinal reinforcement is placed between the two columns, while the main bottom longitudinal reinforcement is placed under the columns. Main transverse reinforcement is placed at the bottom at locations of the cross beams.
.-.-.-.-.-.~.~.-.
dI2
Property line
a) Trapezoidal combined footing Resultant Low load
High load
cracks
transverse reinforcement
b) Rectangular combined footing 353
main long. (bottom) main long. (bottom) reinforcement
Fig. 5.12 Analysis of combined footings 354
It is customary in Egypt to construct reinforced concrete footings on top of
plain concrete footings mainly for economical reasons as shown in Fig. 5.13a. However, it is also popular around the world to use reinforced concrete footings directly resting on soil after providing a thin layer of plain concrete (100 mm) for leveling as shown in Fig. 5.13b. Such a design approach is also adopted in Egypt in some few projects. The analysis is carried out in a similar manner to that to that explained before with the exception of ignoring any contribution of the plain concrete. Therefore, the dimensions of the reinforced concrete footing should be chosen to distribute the applied loads safely to the soil.
/( pilnf'...·rPfl
Example 5.4: Combined footing with PC Design a combined footing to support the two columns shown in Fig. EX 5.4. Column C} has a cross section of (0.3 m x 0.4 m) and supports a working load of 1320 kN. Column C2 has a cross section of (0.3 m x 0.7 m) and supports a working load of 1960 kN. Assume that the allowable soil pressure2 is 175 kN/m2, and the material properties arefcu=25 N/mm2, andfy=400 N/mm . OAm
lo.7m
~
0.3
4
•
I
I
I
l C1
i C2
mI • .-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.•. To.3 m
concrete footing
- - - - - - - S=3.6 m - - - - - - -
Fig. EX 5.4 Layout of Columns
Solution 1----
L
Step 1: Dimensions of the plain concrete footing
Plain conCrete (300-600 mm)
(100 mm-J50 mm)
a) Plain concrete is used in the design calculations.
b) Plain concrete is not used in the design calculations.
The location of the resultant force is determined by taking moments of all forces about any point. Taking moment about the c.g. of column Cl, one gets:
: - - - - - - S=3.6 m - - - - - - - -
3280kN
Fig. 5.13 Reinforced concrete combined footings with or without plain concrete footings
I-t----
xr=2.15
---1----
1.45
Example 5.4 illustrates the design of a combined footing that is resting on a plain concrete footing, while Example 5.5 illustrates the design of a combined footing that is resting directly on the soil. 3.0
3.0
355
356
·1
PC2 xS PCI +PC2
=
r
= 2.1S m
1960x(3.6)
I
(1320+1960)
To ensure unifonn pressure throughout the footing, the centroid of the footing must coincide with the resultant. Assume that the length of the footing is L. L
= 2x r + thickness of C1I2 + thickness of C2/2 + (1- 2m) "" 6.0m
The width of the footing is determined from the allowable soil pressure. Assuming that the weight of the footing is about 10% of the total applied loads, the width of the footing equals: B
= 1.1
(PCI + PC2 ) ami xL
1.1 x (1320 + 1960) = 3.44 m 17Sx6
Rounding B to the nearest 50 mm
Step 2: Dimensions of the reinforced concrete footing
,
To ensure that a unifonn pressure is acting under the reinforced concrete footing, the centroid of the footing must coincide with the resultant. Assume that the distance x = thickness of the plain concrete = 0.4 m.
I
LI =L-2x =6-2x0.4=5.2m
j
I
Bl =B -2x =3.4S-2x0.4 = 2.65 m
Assume the thickness of the RC footing is 0.8 m. Hence, the dimensions of the RC footing are (5.2 m x 2.65 m x 0.8 m). The ultimate pressure is used to calculate the moments and shear forces. Assuming that the live loads are less than 75% of the dead loads (the usual case), the ultimate loads equal:
B=3.45 m. PU(CI) = 1.5xP = l.Sx1320 = 1980 kN
The plain concrete footing dimensions are (6.0 m assumed 400 mm.
X
3.45m) and its thickness is Pu (C2)
1.1 (1320 + 1960) 2 =174.3kN 1m <175 ...... .o.k 6.0 x 3.45
The pressure (aact)=
Resultant =3280kN
Pcl=1320
~~-.----------------~- ~om------------------~I 0 f.4 I 5.2 1 .4
Pc2=1960
3.0m
U2=3.0m
~----------,------.----~ Dr I :!' iI : ~! l :
O.4
!.
i!
!
""le:)
.-~
I!
J
= 1.5xP =1.5x1960 = 2940 kN
0.85!
I.' -:-
.
2.15m
36
!
.
-
i i
~:'om
i
3·f5m
i
- 1.55 m 1
-I
:
J
--
•.
10.7m I -• , • , _.- .~.---.-.-.-.-.---.-.-.-.-.---.----- ,, ,, O.4m 1--:--1
;,-- - - - - - - S = 3 . 6 m - - - - - - - ,
:
, I
:
Dimensions of the plain concrete footing
357
358
1980kN : - - - - - - - 3.6m
Step 3: Design the footing for flexure
2940kN 1
--------'1
Step 3.1: Longitudinal direction 4920kN
The ultimate pressure under the reinforced concrete footing is calculated for the total width B1 , thus the load acting on 2.65 m width equals: = Put + PU2 1980 + 2940 = 946.1538 kN / m I Lt 5.2 The computation of shear and moment may be carried out in a normal fashion. For example, for the location at (x=3.0 m), the forces equal:
1--1--1---1--- xr=2.15 - - - 1 - - -
/
Qu =/·x
x
o
-P"t =946.15x3~1980=858 kN
Ultimate soil pressure=946.15 kN/m' 1
2.6
2.6
M u = 946.15x32 /2-1980x(3-0.45) = -791.3 kN.m
( -)
Bending Moment xo=2.09 --1------.-,.
1-1_ .
-£i~ 8
,Q)
,N
I'+-< ,0
', ..... ..... ,, ,~
,0 ,0..
Critical 1851.9
1
·425.8
Shear Force
Photo 5.5 Foundations during construction
1088.1 1554.2
359
360
The calculation of the shear and moment may become tedious; therefore a computer program was used to generate the straining actions at different points as shown in the table below. Plots of the shear and moment are also given in the following figure.
Design the section of maximum negative bending moment The section of maximum negative bending moment requires top reinforcement. Since the maximum moment is calculated for the full width of the footing, its value shall be divided by the footing width to get the moment per meter.
Program Foundation: output file: combined
M max
Location (x)(m) 0.00
Shear kN 0
Moment kN.m 0
1m' = M max = 1180.8 == 446 kN.m 1m' Bl 2.65
Notes Assume the effective depth d =t -.70mm =800-70=730 mm 6
446 X 10 = 0.0335 25 x 1000 x 7~02 .
0.25
236.5
29.6
face of left column
0.45
425.8
95.8
C.L. of left column
0.45
-1554.2
95.8
C.L. of left column
0.65
-1365.0
-196.1
face of left column
1.00
-1033.8
-615.9
1.50
-560.8
-1014.6
2.09
0.0
-1180.8
2.50
385.4
-1102.3
Use 6
3.00
858.5
-791.3
3.70
1520.8
41.4
face of right column
4.05
1851.9
631.6
C.L. of right column
Secondary bottom reinforcement in the transversal direction should be provided with an area of at least 20% of the main reinforcement. Therefore, provide 5
4.05
-1088.1
631.6
C.L. of right column
4.40
-756.9
302.6
face of right column
5.20
0.0
0
From the chart with R=0.0335, the reinforcement index 0)::0.040
As = OJxfcu xb xd = 0.040 x 25 x1000x730= 1825 mm 2 1m' fy 400 Asmin = 0.6 xb xd = 0.6 x1000x730 = 1095 mm 2 1m' fy 400 .
point of zero shear, Mmax
To determine the maximum moment, the point of zero shear force is calculated as follows:
946.15x 0 -1980 = 0
Asmin =1095 rnrn
2
Design the section of the maximum positive bending moment The section of maximum positive bending moment requires bottom reinforcement. The critical section for the maximum positive bending is at the face of the right support. 08 2 M = 946.15x-·- = 302.8kN.m (Refer also to the output table) 2
M 1m' = M = 302.8 = 114.25 kN.m 1m' Bl 2.65 6
xo=2.093 m Thus, the value of the maximum moment equals: M max = 946.15 X 2.0932 12-1980x(2.093-0.45) = 1180.8 kN.m
361
114.25 X 10 =0.0086 25xl000x7302 Since the intersection point is below the chart, the factor ro can be approximately evaluated as OJ == 1.2 R = 0.0103. 362
The calculations of the reinforcement are summarized in the following table
_feu b X d = 001 25 . A s -wx-x . 03x-xI000x730=471 tnm 2 1m' fy 400
0.60 b 0.60 A smin =--x xd =--xI000x730=1095mm 2 Im' fy 400 Use 6cI>16/m' (1206 ~/m')
Step 3.2: Design of the footing for flexure (transversal) !o ?~tain the pressure if) under each cross-beam (hidden beam), column load IS dlVlded by the footing width (2.65 m). The breadth of the cross beam (be) is ~ss~medat d/2 ~r?m the column face (in the perpendicular direction) as shown m fIgure. The cntlcal section for moment is at the face of the support. T~e
transverse bottom reinforcement is placed on the top of the longitudinal remforcement, thus the effective depth is=730-20=710 mm 1980 kN
2940 kN
Item
Cl
C2
LoadPu, kN
1980
2940
pressure f ' = Pu 12.65
747.17
-1109.43
M=f'x;/2
515.8
765.856
d(mm)
710
710
be(mm)
= 0.25 + 0.4 + -
0.71 2
Mu
= 0.7 + 0.71 + 0.71 2 2
0.041
0.043
OJ
0.0492
0.0522
As = W feu I fy b d
2194
3267
1070
1502
2194
3267
R=
feu be d
2
= 1.41
xe=1.17
1.175 m
Asmin
= (0.6Ify)xb. d
As,required As,chosen
j'=747.17 kN/m'
I.
= 1.005
2.65m
,I
I.
['=1109.43 kN/m' 2.65m
a---0.7m
O.4m
• • • • -i •
............
be= 1.005
Provide secondary rft of 5<1> 121m'
,
"
AsI
j
'i
Effective width of cross beams
363
:, :
•
,
(mm:.!)
2
A sI=6cI>22 (2281 mm
2
)
A s2=9cI>22 (3421 mrn
)
Step 4: Design for shear The critical section for shear is at dl2 from the face of the column. Referring to the shear force diagram and the computer output table, the maximum shear at the face of column C2 is (1520.8 kN). Hence, at a distance of dl2 from the left
C2
Transversal section
Cl
,I
(mm:.!)
,: "" ::
l'i- • •As2• • -i'1 be=1.41
face of the support Qu equals: Qu =Q -f
,(~) = 1520.8 -946.15 (0;3) = 1176kN
This shearing force is resisted by the full width of the footing (B=2650 mm), hence the nominal shear stress is given by: Qu 1176 x 1000 2 =0.61N Imm qu = B xd = 2650x730
364
This shear stress must be resisted by the shear resistance of concrete, which is given by the following equation: qcu
=0.16~/cu =0.16 [25 =0.65N Imm 1.5 1J~
1. q
=0.316~/cuY
cup·
=0.316
c
2
[25 =1.29N Imm
2
1J1.5
Il:
a 0.3 [25 2 2. qcUP =0.316 (0.50+-;;\rt =0.316 (0.50+ 0.7!1J1.5 =1.20N Imm
Since qu is less than qcu, the design for one-way shear is considered adequate. Step 5: Design for punching shear
The critical perimeter is at d/2 from the face of the column. For the interior column, the critical perimeter equals:
a d
U
fJ:
(
4XO.73) [25 2 )Vt-=0.8 0.20+ 4.92 1J1.5=2.59N Imm
qcup= 1.20 N/mm2
a=c 1 +d =300+730=1030mm
Since the applied punching shear stress (0.67) is less than concrete shear strength (1.2), the footing is considered safe. The exterior column should also be checked for punching. The ultimate punching shear stress equals 0.54 N/mm2 which is less than the concrete strength (calculation not shown).
b =c 2 +d =700+730=1430 mm
U = 2 (a +b) = 2 (1030 + 1430) = 4920mm
I.
3. qcUP =0.8 (0.20+
c2=700
.1
r--------I I I I I I
L ________
I·
b=1430
I I I I
2
·1
The pressure acting on the footing is given by: 12 =L= 946.15 =357.04 kN/m 2 B 2.65
The punching load equals:
Qup = Pu -12 (axb) = 2940-357.04 (1.03 x 1.43) = 2414 kN
quP
= Qup = 2414x1000 =0.67 N Imm 2 U xd 4920 x 730
The concrete strength for punching is the least of the following three values:
365
Photo 5.6 Portal bridge spanning 146 m (pont du bonhomme, France)
366
Example 5.5: RC combined footing resting directly on soil Design a combined footing to support an exterior column C 1 (0.3 m x 0,4 m) carrying a total service load of 1100 kN and an interior column C2 (0.3 m x 0.6 m) carrying a total service load of 1600 kN. The plain concrete is used only for leveling the reinforced concrete footing. 2 Assume that the allowable soil pressure is 185 kN/m , icu=30 N/mm2 and /y=400 N/mm2 ~.
I Itr-
C]
r
)
616/m'
0.60
~
C2 ---I
• ________________ 1
)
l
0040
p r1-+-o p e r t y / i i_i line !i-_
712/m'
620/m'
~
[I ;-
I I I
I I I
i 1
I
4.2 m - - - - - -1
1_ . _ - - - -
Longitudinal reinforcement
Solution Step 1: Estimate the dimensions of the RC footing 7<1> 121m'
1
5<1> 121m'
• • •
6<1> 161m'
•
1
1 Transverse reinforcement (Sec A-A)
1
.,
6<1>20/m'
The location of the resultant force is determined by taking moment about point A (see the figure below):
..
Assume that the weight of the footing is about 10% of the total applied loads. The width of the footing is determined from the allowable soil pressure as follows:
B = 1.05 x (1100 + 1600) =2.84m 185x5,4
J Transverse reinforcement (SecB-B)
6<1>16/m'
1
r
= 1100xO.2+1600x(4.2+0.2) = 2.69 m (1100 + 1600)
To ensure uniform pressure throughout the footing, the centroid of the footing must coincide with the resultant of the loads @ 2.69 m. Thus the length of the footing will be 5.38 m, say L=5,40 m.
9<1>22
5<1> 121m'
-.
x
1 367
The pressure (o-act)
-7
Take B =2.9m
= 1.05 x (1100 + 1600) =181 kN 1m 2 <185 kN 1m 2 5,4X2.9
6<1>22
Assume the thickness of the RC footing is 700 mm. 368
.....
ilk
Program Combined Foundation: output file: combined P2=1600
Resultant
Location (m) Shear force Bending moment 2.7m
x r =2.7m
II ---------1r----~i
Q7it ~
L.._ _ _
~d-----------------;-~ Ii 4 2m il
o.2o--!It-·_------.- - - - - - - I - _ - - i
~
L=5.4m
Step 2: Calculate the bending moments and the shear forces The ultimate pressure is now used to calculate the moment and shear force. Assuming that the live loads are less than 75% of the dead loads (the usual case), the ultimate loads equal:
(kN)
(kN.m)
0.00
0
0
0.20
150
15
0.20
-1500
15
0.40
-1350
-270
1.00
-900
-945
2.20
0
-1485
3.00
600
-1245
4.10
1425
-131
4.40
1650
375
4.40
-750
375
4.70
-525
184
5.40
0
0
Pul =1.5xP = 1.5 x 1100 = 1650 leN Pu2 = 1.5xP = 1.5 x 1600 = 2400 leN
To determine the maximum moment, the point of zero shear is calculated as follows:
The load for the full 2.9 meters equals:
750y-1650=0
U1 u2 = 1650+2400 = 750 kN 1m. f = P +P L 5.4 .
I
The computation of shear and moment may be carried out in a normal fashion. For example, for the location at 3.0 m, the forces equal:
y=2.2m The value of the maximum moment is given as:
M max = 750x2.2 2 /2-1650x(2.2-0.2) =-1485 kN.m
Q = 750x3 -1650 = 600 leN M =750x3x1.5-1650x(3-0.2) =-1245 1eN.m
The calculation of the shear and moment may become tedious; therefore a computer program was used to generate the straining actions at different locations as shown in the table below. Plots of the values of the shear forces and bending moments are also given in the following figure.
369
370
2.7
Step 3: Design the footing for flexure
2.7
Step 3.1: Longitudinal direction Section of maximum negative moment The section of maximum negative moment requires top reinforcement. The maximum negative moment per meter is given by:
M
ultimate soil pressure=7S0 kN/m'
max
1m' = M max = 1485 =512 kN .mlm' B 2.9
Assuming that the distance from the c.g: of the reinforcing steel to the concrete surface is 70 mm;the effective depth equals:
0.2°1_':-----4-.2-m-s:::.:...4=-------+__"i_"_l.o_m-l:I
d =t-70mm =700-70= 630mm 6
512x10 = 0.043 30 x 1000 X6302 From the chart with R=0.043, the reinforcement index {():::0.052 As = OJ x feu xb xd = 0.052x 30 x 1000 x 630 = 2457 mm 2 1m' fy 400 . Bending moment
~~~~~~----------~~~~~p-~~--~dia~am 1
15
:
y=2.2 : til ~-"----~---------: ]
I
1 1
'"
1 1
.....
1
1 I
1 1 1 1 1
Section of maximum positive moment
I1l
N
0
.....
I=:
....
critical shear
The critical section for the maximum positive bending is at the face of the support, from the output table this moment equals 184 kN.m'
0 0.
, M 184 M 1m =-=-=63.4 kN.m B 2.9
1
1 1
150
Use 7
0
1 4-< 1 I
375
max. positive=184
Asmin = 0.60 xbxd = 0.60X1000X630 = 945 mm 2 /m' fy 400
1 1 1 1
...::jr-,~r__r--r_----~',----....L-L.-I.....&...i--+.,..._--.,. Shear force dia~am
R =
6
Mu = 63.4x10 2 2 feu x.b xd 30 x 1000 X630
The point is below the chart, use 1500 Values of the shear forces and bending moments for the combined footing
371
0.0053
OJ "" 1.2
R == 0.0064
As = OJ x feu xbxd = 0.0064 x 30 x1000x630=302mm 2 /m' fy . 400 .
372
0.60
0.60
The calculations of reinforcement are shown in the following table
A smin =--xbxd =--xI000x630=945 mm 2 1m' fy 400
Item LoadPu, kN
Since As< Asmin , use Asmil! Use 5 161m' (1000 mm 2)
pressure F=P,/2.9
Interior column 1650 568.97
M=f'x;12
Step 4.2: Design the footing for flexure (hidden beams) Transverse strip under each column will be assumed to transmit the load from the longitudinal direction to the column. The load under each column is divided by the footing width (2.9 m) t get the load per meter for the hidden beam. The breadth of the beam is assumed at d/2 from the column face. The critical section for moment is at the face of the support.
b(mm) d(mm) Mu
R=
feu be d
2
(J)
The reinforcement of the hidden beam is place on top of that of the footing. Hence, the effective depth is=700 -70 -20=610 mm
As = (J) feu I fy b d As,min
(mm:.!) As,chosen (mmL) As,required
l.3m
xe=1.3 m
l.3m
Exterior column 2400 827.59
480.8
699.310
705 610
1210 610
0.06
0.05
0.0759 2447
0.0635 3513
645 2447
1107 3513 A s2=1022 (3810 mm2 )
AsJ=722 (2661 mm2)
xe=1.3 m
Step 4: Design for shear
/'=568.97 kNlm'
The critical section for shear is at d/2 from the face of the column. The maximum shear at the centerline of the interior column is equal to (1650 kN) , thus at a distance of d/2 from the face of the support Qu equals:
/'=827.59 kN/m'
11 -I Exterior column I 2.90m
I
-I
·2.90m
I.
Q =Q-f u
(~+~)=1650-750(0.6+0.63)=1188.75kN 2 2 2 2
Interior column
This shearing force is resisted by the full width of the footing (B=2900 mm).
=~= 1188.75 x 1000 =0.65 Nlmm 2 qu -O.4m
O.6m
....... I--l
be=O.705
2900x630
Bxd
•
~"
As2
,,~
• I•••••••• e€.· •
This shear stress must be resisted by the concrete shear strength, which is given by the following equation: •
qeu 5tP121m'
be=1.210
=0.16~fcu =0.16~30 =0.72Nlmm2 1.5
1.5
Since qu is less than qcu, the design for one-way shear is considered adequate.
373
374
Step 5: Design for punching shear
qcup= 1.41 N/mm 2
The critical perimeter is at dJ2 from the face of the column. For the interior column, the critical perimeter equals: d 630 a=c1 +-=300+-=615 mm 2 . 2
The exterior column should also be checked for punching because its perimeter is only from three sides. The ultimate punching shear stress equals 1.08 N/mm2 which is less than the concrete strength (calculations are not shown).
d 630 b = c 2 +- = 600+- = 915 mm
2
Since the applied shear stress is less than concrete shear strength, the footing is considered safe.
2
7<1>221m'
U = 2 (a+b) = 2 (615+915) = 3060mm
--------""1
I I I I I I I I IL _ _ _ _ _ _ _ _I
I·
·1
b=915
The acting pressure underneath the footing is given by: 12 = 750 = 258.62 kN/m 2 B 2.9 The punching load equals column load minus the load inside the punching area.
=L
Qup =pu
-/2 (axb) = 2400-258.62 (0.615xO.915) = 2254.5 kN
= Qup = 2254.5xlOOO =1.17 Nlmm 2 quP Uxd 3060x630
5<1> 161m' 7<1> 121m'
7<1>22/m·
I
l
r
,
) )
5<1> 16/m'
Section
I.
5Am ...--
1-
-I
-
-
The concrete strength for punching the least of the three values
1.
N N
qcup=0.316~/cu =0.316~30=1.41Nlmm2 Y 1.5
09
0
r--
c
2.
qCUP =0.316 (0.50+5..)
c2
3.
qcup=0.8(0.20+
a
~/cu Yc
d)~/cu
U
Yc
=0.316 (0.50+ 0.3) {30 =lA1N Imm 2 0.6
=0.8 (0.20+
Vi5
4XO.63)~30 =3.66Nlmm 2 3.06
~
1.5
~ N .....
~ N
tn
tn
......
09
09
09 0
......
.~
I~
~ 7<1> 121m'
7<1>22/m'
, ~
I5<1> 161m'
.-
'--
Plan
,375
N N
376
-
1
.~',
5.8 Strap Footings
Example 5.6
If one of the columns in a building is constructed near the propet1y line, the column will be eCGentric with respect to the center of gravity of the footing as shown in Fig. 5.14. The eccentric position of the footing causes uneven soil pressure distribution, which could leads to tilting of the footing. To avoid such a tilting, the exterior footing is connected to the interior footing with a massive beam called strap beam.
Design a strap footing to support an exterior column (0.30 m x 0.50 m) and an interior column (0.30 m x 0.90 m). The unfactored dead and live loads carried by each column are shown in the figure below. Assume that the allowable soil pressure is 150 kN/m2,!cu=25 N/mm2 and/y=360 N/mm2
The dimensions of the strap are chosen such that it is very rigid compared to the footing. J. E. Bowles recommended that the rigidity of the strap beam is at least twice that of the footing (Istrap I hooting >.2).
I "
j
The dimensions of the footing are chosen such that the bearing pressures are uniform and equal under both bases. Therefore, the centroid of the combined area of the two footings must coincide with the resultant of the two loads. The strap beam joining the footings should not bear against the soil.
PlDL=380 kN P ILL=305 kN
P2DL=820 kN P2LL=450kN
j
I
I
- -j._0.90
It is common to neglect the strap weight in the design. The strap should be adequately attached to the both the column and the footing by the use of dowels such that the footing and the strap act as one unit. The footing is subjected to one-way bending. The strap beam is reinforced with main reinforcement at the top between the columns and at bottom under the interior footing.
I..
..I
4.9m
beam
Solution Exterior footing
Step 1: Estimate the dimensions of the plain concrete footing The working loads are calculated as:
I.
.I
L
section
~
~ ~
~~
~
~ ~
~/
P2 = 820+450 = 1270 kN
The location of the resultant of the loads may be determined by taking moment about point o.
I I I
PI = 380 + 305 = 685 kN
Strap beam
I I
I
~
y
685xO.25+1270x5.15 =3.433 m 685+1270
The length of the exterior and interior footings should be assumed such that the pressures under the two footings are almost the same. This is achieved by having the resultant of the loads coincided with the c.g. of the footing.
plan
Fig. 5.14 Strap footing 377
378
The final chosen dimensions of the plain concrete footings are Item Exterior footing Interior footing Total O.50m
L(m) 2.2 3.35
B (m) 2.8 2.6
Area (m~) 6.16 8.71 14.87> 14.34
O.90m
The c.g. of the footings can be obtained by taking moment of area about point o.
y = 0
m
I
4.05m I
RJ
02j~.
3.433 m 2.20m
.. I
Note that the center of gravity of the footings (3.47 m) is very close to the location of the resultant of the loads (3.43m).
R2 R
~
.. I
1--
4.9m
335m
-I
.. I
The weight of the strap beam, the footings, and the soil above may be estimated as 10% of the total loads. ~Ola/
6.16xl.1 +8.71x5.15 =3.47 m 14.87
= 1.1 (PI + P2 ) = 1.1 (685 + 1270) = 2150.5kN
Step 2: Dimensions of the reinforced concrete footings The dimensions of the reinforced concrete footing can be determined as shown in the following table. Item
Ll (m)
Bl (m)
Area (m")
Exterior footing
=2.2-0.4=1.8
=2.8-0.8=2.0
3.6
Interior footing
=3.35-0.8=2.55
=2.6-0.8=1.80
4.59
Total
8.19
The total required area of the plain concrete footing under Cl and C2 equals to:
Area = ~Ola/ q allowable
2150.5 = 14.34 m 2 150
The thickness of the plain concrete is assumed to be 400 mm. Assume that the length of the exterior footing is 2.2 m and the length of the interior footing is 3.35 m. To reasonably determine the width of the footings, the reactions Rl and R2 are calculated by taking moments about R 2.
R = I
(1.1x685)X4.9 =911.64kN (4.9+0.25-2.2/2)
R2 = 2150.5 -911.64 = 1238.9 kN
To ensure the uniform stress distribution, the c.g. of the reinforced concrete footings should also coincide with the resultant as much as possible (usually within 10% is acceptable) .. The distance measured from the c.g. to point 0 equals:
y=
3.6x1.8/2 + 4.59x5.15 =3.28 m 8.19
The location of the c.g. is close enough (to the location of the resultant.
B = 911.64 =2.76m-72.8m I 150x2.2 B = 2
"379
1238.9 150x3.35
= 2.46 m -7 2.6m 380
2
Step 3: Calculate the ultimate pressure
M
To ensure that the strap beam will distribute the pressure uniformly, the concrete dimensions are taken 0.4 m xl.3 m. The own weight of the strap beam is usually neglected; however, it can be approximately added to the dead load of each column as follows: W bean
= Yc xb Xt xL = 25x0.4x1.3x4.9 == 63 kN
PIDL=380+6312=411.5 kN
P2DL=820+6312= 851.5 kN
The ultimate loads for the columns are calculated in order to calculate the ultimate moment and shear.
15 = 681.5x-·--1064x(1.5-0.25) = -563.3 kN.m 2
. 1064 Pomt of zero shear = - - = 1.56 m 681.5 A computer program was prepared to generate the straining actions at different locations as shown in the table below. Plots of the shear and moment is also in the following figure Program Foundation: output file: strap Location
Shear force Bending. Notes (kN) moment (kN.m) 0.0 0.0
Pul =1.4xPIDL +1.6x~LL =1.4x41l.5+1.6x305:::::1064kN
0.00
Pu2 =1.4xP2DL + 1.6 X P2LL =1.4x851.5+1.6x450:::::19P kN
0.25
170.4
21.3
C.L. of left column
To determine the magnitude of Rul ,take the moment about R u2.
0.25
-893.6
21.3
C.L. of left column
0.50
-723.3
-180.8
face of left column
1.00
-382.5
-457.3
intermediate point
1.50
-41.8
-563.3
intermediate point
1.56
0.0
-564.6
point of zero shear, Mmax
1.80
162.7
-545.2
3.00
162.7
-349.9
intermediate point
3.50
162.7
-268.6
intermediate point
3.88
162.7
-207.6
face of right column
4.70
728.7
160.1
5.15
1037.4
557.5
C.L. of right column
5.15
-874.7
557.5
C.L. of right column
5.60
-566.0
233.3
face of right column
6.43
0.0
0.0
=
R ul
Ru2
1064 x 4.9 = 1226.7 kN (4.9+0.25-1.8/2)
= PU1 + P"2
- RUI = 1064+ 1912-1226.7 = 1749.3 kN
The pressure under the exterior footing equals 0i = 1226.7 1.80 The pressure under the interior footing equals
(j2
= 681.5 kN / m 2
= 1749.3 = 686 kN / m 2 2.55
The resulting pressures are slightly different under each footing (681.5, 686). More uniform pressures can be attained by adjusting the dimensions of the footings. However, the attained accuracy is quite satisfactory (1 % difference).
Step 4: Design of the strap beam Step 4.1: Draw bending moment and shear force diagrams The computation of shear and moment may be carried out in a normal fashion. For example, at a distance of 1.5 m from the left edge, the forces equal:
Q = 681.5x1.5 -1064 = -41.8 kN
381
382
Step 4.2: Design for flexure
Pu2=1912kN
Design of section 1 0.50m
Assuming that the distance from the c.g. of the reinforcing steel to the concrete surface is 70 mm, the effective depth equals
O.90m
d =t -70mm =1300-70=1230 mm
,.
I
~ 2.55 m -,
RuJ=1749.3
1--------
I
..
1.56 m
--I. j
4.9 m ----_.~I
Critical shear section
103704
686kNlm'
The maximum moment equals 564.6 kN.m
I
I
R=
6
Mu = 564.6 x 10 = 0.037 feu xb xd 2 25 x 400 x 12302
From the chart with R=0.037, the reinforcement index OJ=0.045
As = mx feu xb xd = 0.045 x 25 x 400 x 1230 = 1537 mm 2 fy 360 _ As min
-
{ smaller of
0.225.JJ: b d = 0.225../2s x 400 x 1230 = 1536 mm 2 fy 360 .
FlOo4
1.3As =1.3x1537=1998mm
2
Use 8cI>16/m' (1608 mm2)
~o 893.6
Design of section 2
~
Shear force diagram
t)
874.7
s::::
The critical section is at the face of the column, from the output table the maximum moment equals = 233.3 kN.m
o.
0.g
I
.gj
R =
...lj
6
Mu = 233.3 X 10 . = 0.0154 feu xb xd 2 25x 400 x 12302
From the chart with R=0.0154, the reinforcement index OJ=0.019 sec 2
As = mx feu xb xd = 0.019x 25 x400x1230 = 649 mm 2 fy 360
.JJ:
As min
Bending moment diagram' 557.5
383
b d = 0.225../2s x400x 1230 = 1536 mm 2' 0. 225 = smaller of fy 360 { 1.3As =1.3x649=844mm 2 .J>As ... useAs,min
0.15 2 But not less than --x400x1230 = 738 mm 100 384
As=844mm2
Exterior footing
Interior footing
Use 4
Item pressure (J' (kN/m')
681.5
686
Step 4.3: Design the strap beam for Shear
Footing width B' (m)
2.00
1.80
Pressure if) = (J'I B' (kN/m.l)
340.8
381.1
Moment = f x (B ' - bstrap )2 18 (kN.m)
109.06
93.37
d(mm)
430
430
B(mm)
1000
1000
0.024
0.02
(J)
0.0284
0.0235
A s,required(mm2)= (J)x(fcu I fy)xBxd
848.1
701.7
716.66
716.6
848.1
716
1005.31
1005.31
(5D16)1m'
(5D16)/m'
The critical section for shear is at the free span of the strap beam.
Qu=162.7 kN qu
=~= 162.7 X 1000 =0.33 N Imm 2 b xd
qcu =0.24
400x1230
~fcu =0.98 N Imm 1.5
2
R =Mu l(feu B d
Since qu < qcu, provide minimum stirrups. In addition, since the width of the beam equals 400 mm, stirrups with four branches shall be used. Assume spacing of 200 mm.
2
)
0.4 b 0.4 Astmin = - x xs=-x400x200=133.3 . fy 240
As,min(mm.l)=0.6ify B x d
Try four branches 5
Reinforcement
As,chOSen(mm.l) Max of(As min, Asrequired)
2
Ast = 4x50 = 200 mm > Ast,min ...... o.k I
Step 5: Design of the footings
--;r:r
- -
OAm
0.8
0.80 I
Step 5.2 Design the footings for shear
Step 5.1: Design for flexure A strip of 1m width is taken to determine the area of steel for the footings.
t t t t f f
, &~II~ I-
QI=340.75 kN/m'
ql = O'i = 681.5 =340.75 kN 1m 2 BI 2
I.
2.00m
·1
The moment is taken at the face of the strap beam as follows:
= qlX(BI-bstrapi = 340.75x(2-0AO/ 8
=109.04kN.mlm'
8
B=l.BO
N
T
m column
Assume that the depth of the footings is 500. the calculations may summarized in the following table
-I
d/2=0.215 0
MI
critical section for shear
Fl
F2
I-
~~ column
0.40
Critical section for shear
385
386
-I
~~ J=~
strap beam
t
B=2.25
II ~
~
......
The critical section for shear is at dl2 from the face of the strap beam. Noting that the depth d=0.430 m, the distance x equals to: X
B -bs/rop =---'-2
8
!!:.. = 1.8 2
2
0.4
0.43 == 0.485 m 2
Noting that the pressure under footing F2 equals 381.1 Qu equals Qu = f
qu
·X
5~8/m'lt±=_k_d_=_±_=_k_~ __~,~r+~1-+-~,*,~-r--~-r--~-=-F-~--~-1--~-~~1
kN/m 2 ,
the shear force
~---4~~
b xd
cu
IL -________________
4
~
4
47L30xlOOO =0.43 N Imm 2 (2.55xlOOO)x430
l
=0.16~fcu =0.16 (25 =0.65Nlmm 1.5 ViS
4
~,..--,.------:;.----..
The shear stress should be less than the concrete shear strength given by the following equation:
q
I I
I
·b =381.1 (0.485)2.55 == 471.30 kN
=~=
.
4
-r-
Since qu is less than qcu, the footing is considered safe for shear
"I
1.80
I·
2
I-
2.55
·1
-,.- 1-------.
The design of Fl for shear is summarized in the following table Item pressure kN/m" b(m) x(m)
Qu (kN) qu(N/mm.l)
Fl 340.8 1.8 0.585 358.90 0.46
5
-I-
It should be noted that the presence of the strap beam eliminates the need for calculating punching shear stresses for the footings.
5
-'-1--------
-'--
-'--
1-1;,,-...=.:2.=20..=;m'----t-I._
n
l ·--...::::.3.::::::35!!!.m----J"1
n ___ nl-
column..$" ~ ~ 4
0
00
0
C']
.....
5
c:i
-
2
2
I-
0
II"l
c:i
4
Il
J
~ ~m~j~j~~:j !:~~j~fljjj~j1j~ ~j~j~~~ 1jlTIjj~ljljjj~j· Section A-A -'-
387
~ 5
388
5
'r I
5.9 Raft Foundations 5.9.1 Introduction When the bearing capacity of the soil is low, isolated footings are replaced by a raft foundation. In such a case, a solid reinforced concrete rigid slab is constructed under the entire building as shown in Fig. 5.15. Structurally, raft foundations resting directly on soil act as a flat slab or a flat plate, upside down, i.e., loaded upward by the bearing pressure and downward by the concentrated column reactions. The raft foundation develops the maximum available bearing area under the building. If the bearing capacity of the soil is so low that even this large bearing capacity is insufficient, deep foundations such as piles must be used. Apart from developing large bearing areas, another adyantage of raft foundations is that their continuity and rigidity that helps in reducing differential settlement of individual columns relative to each other, which might be caused by local variations in the quality of subsoil, or other causes. The design of raft foundations may be carried out by one of two methods: • •
The conventional rigid method and; The finite element method utilizing computer programs.
The conventional method is easy to apply and the computations can be carried out using hand calculations. However, the application of the conventional method is limited to rafts with relatively regular arrangement of columns. In contrast, the finite element method can be used for the analysis of raft regardless of the column arrangements, loading conditions, and existence of cores and shear walls. Commercially available computer programs can be used. The user should, however, have sufficient background and experience.
5.9.2 Conventional Rigid Method The raft foundation shown in Fig. 5.16 has dimensions (B x .L) .. Columns' working loads are indicated as PI, P 2, P 3, ••• etc. The apphcatlOn of the conventional method can be summarized as follows:
Step 1: Check soil pressure The resultant of columns working loads equals: ~otal == ~
i=1l
+P 2
+ P 3 + ..... == L~
.......................... (5.20)
i=1
Assuming that the raft foundation is rigid, the soil pressure at any point can be obtained using the classical stress equation as follows: q
==
~otal + M A
x
y + My x
Ix
-:;;'qallowable ••••...•.••..•••••.••.••
(5.21)
Iy
Where A = area of the raft (B x L) It = moment of inertia of the raft about x-axis == B L3 /12 Iy = moment of inertia of the raft about y-axis == L B3 /12 Mx = M
y
=
moment of the applied loads about the x-axis '''' ~otal e y + Mx(lateralload)
moment of the applied loads about the y-axis = ~otal
ex
+M
y
(lateral load)
Where ex and eyare the eccentricities of the resultant from the c.g. of the raft. The coordinates of the eccentricities are given by: X' == ~
X1
+ P2
X2
+ P3
X3
+ ............................... (5.22)
~otal
Where Xl,
X2, X3
are the X-coordinates of PI, e ==X' x
y' == ~
RCrafi
P2, P 3, Pi, ...... , P n .
_Ii.2 ................................... (5.23)
Y1 +P2 Y2 +P3 Y3
+ ............................... (5.24)
~otal
Where YI, Y2, Y3 are the y-coordinates of PI, PCrafi
P2, P 3, Pi....... , P n.
e ==y I _~ y 2
.........................................
(5.25)
Compare the maximum soil pressures value with net allowable soil pressure. Fig. 5.15 Raft foundation 389
390
Step 2: Draw the shear force and bending moment diagrams Divide the raft into several strips in the X-direction(Bj, B2, B3) and in the ydirection (B4, B 5, B6, B 7) as shown in Fig. 5.16. Referring to Fig. 5.16, the interior strip GBIHEJ is used as an example for illustrating the procedure for drawing the shear force and the bending moment diagrams for the strips. The procedure may be summarized in the following steps: .
Y
Y'
I---! A
c
B
P5
1. The soil pressure at the center-line of the strip is assumed constant along the width of the strip. Referring to Fig. 5.17, the distribution of the soil pressure at the center-line of strip GBIHEJ is determined by calculating the pressures at points B (O,Ll2) and E (O,-Ll2) as follows:
1_--1--_I
.
qB
I
I
P6
o ex E9
I
1---~ ---.- ~ t---~~-+----t+=-I
~
•••••••••••••••••••••••••••••••••••••••
....................................... (5.27)
qavg
= qB +qE .......................................... (5.28) 2
I
This value shall be used in the analysis of the strip.
Ps
Ii
P1
!
j---t---r---t--1__
Ip_4_ _ _
P8
I ------
E
Bl
B2 B
Fig. 5.16 Eccentricity of the raft
I I I
H~------------------------------------~
P 12
F
J
B3
X'
21
Pg
P7
P6
G
Ps
E
.-.-.-.-.-.-~-.-.-.-.-.-.m-.-.-.-.-.-.-
B
J
1-1~_____________-ll
I
L
Fig. 5.17 Soil pressure distribution at the center BE
391
(5.26)
The average pressure equals:
x
I I
P~al + ~x
qE = ~otaJ _ Mx £ A Ix 2
Ptotal
I
=
392
2. The total soil reaction (RB-E) for the strip B-E is equal to: RB- e
=qavg
xB 2 xL ............................................. (5.29)
6. The shear and bending moment can be computed using regular structural analysis.
Where B2 is the width of strip B-E. The same process should be carried out for all the strips in the raft foundation.
The total applied load acting on this strip equals: PB- e
= P5 + P6 + P7 + Ps ....................................... (5.30)
3. To achieve equilibrium, columns' loads and soil reaction must be modified such that the sum of the forces is equal to zero. This is achieved by obtaining the average load on the strip Pavg . Pavg =RB-e+PB-e 2 .............................................. (5.31)
For each strip the maximum positive and negative moments can be obtained. It should be clear that negative moments need top reinforcement and positive moment needs bottom reinforcement. The moment per meter is obtained by diving the moment by the strip width: 1M M = - ............................................................... (5.34) B2
4. The modified soil pressure equals: Pavg
qmod
Step 3: Design for flexure
=T····················································........ (5.32)
5. The modified columns' loads are obtained by multiplying each of the applied loads by the factor a. given by:
The ultimate moment is obtained by multiplying the working moment by a load factor of 1.5. Mu
=1.5 M
I
.......................................................
(5.35)
The 'design of different sections can be carried using design curves such as R-O). Pavg
a =- - .............................................................. (5.33) PB - e
Thus the modified columns' loads are a. Ps, a. P6. a. P7• and a. P8• This modified loading is shown in Fig. 5.1S.
Step 4: Design for punching shear The punching load for each column is calculated by mUltiplying the applied working load with the load factor. Pu = 1.5 Pi ................................................ (5.36)
aP5
aPs
E
The critical perimeter is at dl2 from the face of the column. The critical shear perimeter U is calculated as shown in Fig. 5.19, and the applied punching load Qu is obtained after subtracting the load of the punching area (a x b) by the ultimate pressure at this point qsu . Thus: B
qmod:
Fig. 5.18 Modified soil pressure for strip B-E
Qup
= Pu
-qsu (axb) ................................ (5.37)
The applied punching shear stress qup equals:
Q
.
quP ='U:d ............................................... (5.3S)
393
394 '
Step 5: Reinforcement Arrangement 1- - - - - - - I
III 1
1
1
1
1
1
Cl
1
L ______ I
1
·1
b
Critical perimeter (U)
The bending moment distribution is similar to upside down flat slab. 1 ~l1.is, at the locations of the columns in a raft foundation the bending moment is positive and requires bottom reinforcement shown in Fig. 5.20. (compare tont.f:Jtive bending moment and top reinforcement in flat slabs). Moreover,.at a location between columns in a raft foundation the bending moment is negf.~ive and requires top reinforcement as (compare to positive bendi'lg moment arA bottom reinforcement inflat slabs). . It is customaI"j to reinforce the raft with a bottom bask reinforcing mesh and a
Fig. 5.19 Critical punching shear perimeter
basic top reinforcing mesh. Additional reinforcement is provided at locations where the capacity is exceeded.
The concrete strength for punching is the least of the following three values: 1.
2.
qcuP
qcuP
=0.316
= 0.316
lZ:~1.6N Imm Vr:
2
••••••••••••••••••••• (5.39a)
(0.50+~)!r c rc
.......................... (5.39b)
)lCU
., ......................... (5.39c)
2
3.
qcuP
= 0 •8 (0 •20 + aUd .
a=2
for comer columns
a=3
for exterior columns
a=4
for interior columns
rc
The raft thickness is considered adequate if qup < qcu, otherwise increase the thickness of the raft.
Top steel
Top steel
-
Bottom steel
Fig. 5.20 Reinforcement arrangement 395
396
1 5.9.3 Analysis of the Raft Using Computer Programs Raft foundations can be analyzed using commercially available computer programs. Such programs are based on the finite element method.
5.9.3.1 Modeling of the Raft The raft is divided into finite plate bending elements or shell element as shown in Fig. 5.21. The practical dimensions of each element range from O.S m to 1 m. It is recommended that the aspect ratio of each element not to exceed 3.
Calculation of spring stiffness The spring stiffness =Coefficient of sub grade reaction (ks) x area served. The coefficient of subgrade reaction is a relationshjp between the soil pressure and its settement. If a foundation of width B is subjected to a load per unit area q, it will undergo a settlement D. Then, the coefficient of sub grade reaction ks can be defined as: . ks
node
, \
3
The unit of the coefficient of the subgrade reaction is kN/m . The value of the coefficient of subgrade reaction differs according to the type of soil. In general, the higher the bearing capacity, the higher the coefficient is. Its value depends on several factors, such as the type of soil, the length L, the width B of the foundation, and the foundation level of raft.
element
\
H
= ~ ................................................. (5.40)
B
..
·I
x
Fig. 5.21 Finite element model for the raft foundation
t
5.9.3.2 Modeling of the soil
t t t t -t t t t t t t
t- t
The soil is represented by elastic springs located at the nodes as shown in Fig. S.22. The elastic constant of these springs is named the spring stiffness (Kj , K 2 , .... )(kN/m). Fig. 5.23 Definition of coefficient of subgrade reaction
t - -....- -....- -....- -.....- -....- -....--'-:..-... as shell elements Soil modeled as spring
To determine the value of the coefficient of subgrade reaction, a field test may be performed. In such a test, the load is applied to a square plate of dimensions (0.3 m x 0.3 m) and the corresponding settlement is recorded. The value of coefficient for a large foundation of dimensions (B x B) can be obtained in the light of the value obtained for the small plate ko.3 as follows: ks
= kO.3 (B ~~.3)2
Fig. 5.22 Modeling of the soil 397
398
for sandy soil ........................ (S.41a)
ks = k O.3
(~3)
for clayey soiL ........................... (5.41b)
For rectangular foundation having dimensions of B x L ks
=k
Bx8
(1 + B I L)
1.5
............................................. (5.42)
The loads are applied to the raft at the columns' locations. The structure is analyzed as plane grid sys~m, in which only z, Rx, R y are allowed. Area served A
B
~
IS: ~
I Os: ~
Where KBxB is the coefficient of subgrade reaction for a square foundation with dimensions (BxB)
~
:sJ
Typical values for the coefficient of subgrade reaction leo.3 for sandy and clayey soils are given in Table (5.3) Table 5.3 Values of the coefficient of subgrade reaction Soil Sand (dry or moist)
Sand (saturated)
Clay
Type Loose Medium Dense Loose Medium Dense Stiff (q=100-200 kN/m") Very stiff(q=200-400 kN/m2 ) Hard (q>400 kN/ml)
ko.3 (MN/mJ) 8-25 25-125 .. 125-375 10-15 35-40 130-150
H x=O.50m
Fig. 5.24 Finite element model for the raft foundation
12~15
25-50 >50
An approximate estimate of the coefficient of subgrade reaction is obtained as follows:
ks (kN 1m 3 ) = (100 -7120)xsoil bearing capacity (kN 1m2) ...... (5.43) Figure 5.24 shows a plan of a raft foundation that is divided into plate bending elements of dimensions (0.50 m x 0.50 m). These elements are intersected at joints or nodes. The soil at each joint is modeled as a spring with stiffness K. The stiffness of each spring is obtained by multiplying the coefficient of subgrade reaction by the area served of each node as follows: K A = k s x y = 0.0625 k s
4
K8 =ks x y =0.125 ks 2
Photo 5.7 A raft on piles during construction
Kc =ks x Y =0.25 ks
399
400
5.9.3.3 Analysis of the Computer Output The computer output of the raft foundation consists of bending moments acting in the two directions MIl and M22. Most of the available commercial programs represent the output in graphical forms. The graphical representation is usually in the form of contour lines, in which each contour line represents a certain bending moment value. It should be mentioned that closely spaced contour lines indicate concentration of stresses. This usually occurs at the locations of the columns.
When designing the bottom reinforcement of the raft one should use the value of the bending moment at the face of the column (Sec. 1-1 and Sec. 2-2) as shown in Fig. 5.26. In other words, the contour line located inside the columns should be ignored. 2
1
Typical output for MJ J is shown in Fig (5-25). This bending moment requires reinforcement in the direction 1 of the shell. Basic top and bottom reinforcement meshes are usually provided throughout the raft and additional bottom reinforcement is usually provided under the columns.
2
Fig. 5.26 Contours at column location The reaction at each joint spring can be determined from the computer output. However, it is important to note that the soil capacity should be checked using the classical stress equation (Eq. 5.21) and not using the spring reactions. This is attributed to the concentration of forces at the location of the columns.
2
t-l Fig. 5.25 Computer output
Photo 5.8 Placing the reinforcement of a raft foundation 401
402
Example 5.8: Raft using the Conventional Method Figure EX 5.8.1 shows a raft foundation for an office building. It is required to design the reinforced concrete raft foundations. The cross section of all columns is 400 x 400 mm. The allowable soil pressure is 125 kN/m2 • The material properties for concrete and reinforcing steel are 25 N/mm2 and 360 N/mm2, respectively. Columns working loads (unfactored) are also shown in figure.
Solution
y'
-~
Step 1: Check soil pressure P
M
~f--K
My
x
3
3
L B· = 15.4xI2.4 =2446.8m 4 I =J:"2 12 Y
The total vertical unfactored loads = 440 + (1360 x 2) + 370 + (1150 x 2) + (2880 x 2) + 500 + 1360 +1440 + 440 = 15330 kN. The center of gravity ofthe applied loads can be obtained by taking moment of the loads about point D.
-
1 15330
X = - - [0.2 (440+ 1360 x 2 +370)+6.2 (1150x 2+2280x 2)
+ 12.2 x (500 + 1360 + 1440 + 440)] %=6.282 m
e x
~S
I
I - .- . -
- t - -:-
1
I
I 2880 kN
--r- - -
:~082
-
L
I
J I
1360 ~ ~
NI
P'otal
P
~,
:f-- 1-,
- -'-_~-'- ~70kN 1~
3.0 m
R
2880 kN
kN
1
1«0
I
I
1
1
- 1--- - --L - -
---L - -
1
I -
t~
~~kN ~ ~~~
! H
E
3.0
J
3.0
FI
3.0)
________~1~2.~00~m~_ _ _ _ _ _ _ _~
L
Fig. EX. 5.8 Layout of the raft
403
r I
f--,L --+' --- - rIi iIx--1,I-~4'_- Ilr{f.l~360 i 1 i i ~
ID
2
~
1
e =Y-y
1
SIlO
I
1
~-+-.--lfHf.ll~ M I .
!
Similarly, in the y-direction, one can get:
I
--j- -
_
=x _~=6.282_12.4 =0.082 m 2 2 -
rbl,,1360 kN
12.4xI5.4 =3774m4 12
12
'~ " ' " kN
I
N,
3
=B L3
kN
I
N
q=_+_x y + - x A Ix Iy Where A = area of the raft =15.4xI2.4 = 190.96 m 2 I
--j""
B
G
404
X
-
1
Y = 15330 [0.2 (370+1150+440)+5.2 (1360+2880+1440) + 10.2x (1360 x 2 + 2880) + 15.2(440+ 1150+ 500)]
Step 2.1: Strip ADHG (width= 3.2 m) The average soil pressure for the strip can be obtained by taking the average values of the pressures at points A and D.
Y- =7.751 m e y =7.751_
Step 2: Calculation of the shear forces and bending moments
15 .4 =0.051m 2
78.69+75.50 =77.09 kN 1m 2 2
The resultant applied moments are given by:
The total soil reaction RADHG
M x = ~otal ey = 15330x 0.051 = 781.83 kN.m
L
Bl
= 77.09x3.2xI5.4 =3799 kN
On the other hand the total vertical on this strip equals:
My = ~otal ex = 15330x 0.082 = 1257.06 kN.m
PADHG = 440 + 1360 + 1360 + 370 = 3530 kN
The soil bearing pressure can be obtained by applying the following equation:
P +Mx My 15330 781.83 1257.06 "I:Y+I;x =190.96+ 3774 y+ 2446 x
Now, we shall use the average value 0 of the total reaction and PADHG Average load =P
q= A
= R ADHG + PADHG = 3799 + 3530 = 3664.5 kN
2
avg
2
The modified soil pressure (per the strip) =Pave , L
The results are summarized in the following table
Point
x (m)
y(m)
q(kN/ml)
A
-6.2
7.7
78.69
B
0
7.7
81.87
C
6.2
7.7
85.06
D
-6.2
-7.7
75.50
E
0
-7.7
78.68
F
6.2
-7.7
81.87
M
-6.2
2.5
77.61
0
0
2.5
80.80
N
6.2
2.5
83.98
The lllaximum soil pressure (85.06 kN/m2 ) is less than the allowable soil pressure (safe).
= 3664.5 = 237.95 kN 15.4
Im
I
The column loads are modified in the same manner by multiplying the load of each column by the ratio (PavIPADHG)'
a
= Pavg
= 3664.5 = 1.0381
PADHG
Item 1 2 3 4
3530 P actual (kN)
440 1360 1360 370
456.77 1411.82 1411.82 384.1
The shear force and the bending moment diagrams are shown in the figure given below. Three points of zero shears exist. They are calculated as follows:
= 456.77 = 1.92 m
x 1
405
= qavg
237.95 456.77 + 1411.82 + 1411.82 237.95
= 456.77 + 1411.82 = 7.85 m
x 2
=13.79 m
406
237.95
The maximum negative moment equals:
Step 2.2: Strip GHJI (width =6.0 m)
1922
= 237.95x-·--456.77(1.92-0.20) =-347.1 kN.m 2 456.77
) I
1141.82
384.1
1141.82
!
JI
qavg
I 11
.
---It-----·It-· 5.0 5.0
0.2011--1-
The average soil pressure for the strip can be obtained by taking the average value of pressures at points Band E.
237.95 kN/m'
I 1-0.20
---i'
5.0
= 81.87 + 78.68 = 80.28 kN / m 2 2
The total soil reaction RGHJI=qavg Bl L = 80.28x6.0x15.4 = 7417.74 kN On the other hand the total vertical on this strip equals: PGHJI = 1150 + 2880 + 2880 + 1150 = 8060 kN Now, we shall use the average value of the total reaction and PADHG •
780.6 558.5
Averageload=P
336.4
=
RGHJI
avg
Shear (kN)
+PGHli = 7417.74+8060 =7738.87 kN 2 2 ..
The modified soil. pressure (per the strip) = Pavg = 7738.87 = 502.52 kN / m I L 15.4 The column loads are modified in the same manner by mUltiplying each column load by the ratio (PavglPGHJI)
ex = Pavg = 7738.87 = 0.9602 PADHG
Moment (kN.m)
8060
Item
P actual (kN)
Pmod(kN)
1
1150
1104.18
2
2880
2765.25
3
2880
2765.25
4
1150
1104.18
The shear force and bending moment diagrams are shown in figure. Three points of zero shears exist. They are calculated as follows:
1
~op stee; 1 .
. I. Bottom steel
.1
x = 1104.18 = 2.20 m _ x = 1104.18 + 2765.25 = 7.70 m· 1 502.52 ' 2 502.52
ITop steel
Shear and moment for strip ADHG
x = 1104.18 + 2765.25 + 2765.25 = 13.20 m 3 502.52
407 408
1104.2
2765.3
I
!
t I .20
-II·
5.0
·1 .
!
!
t
·1·
5.0
Step 2.3: Strip ACKL (width = 2.70 m)
1104.2
2765.3
I t 5.0
The average soil pressure for the strip can be obtained by taking the average value of the pressures at points A and C. 502.52 kNlm'
·11-°·20
qavg
= 878.69 + 85.06 = 81.87 kN / m 2 2
The total soil reaction R
ACKL =q{Ng
Ll B = 81.87x2.70xI2.4 = 2741 kN
On the other hand, the total vertical on this strip equals:
1509
1256.2
POHJl = 440 + 1150 + 500 = 2090 kN
1003.6
Now, we shall use the average value of the total reaction and PADHG • Shear
A verage Ioad= P
avg
=
RACKL+PACKL
2
(kN)
2741+2090 =- - - = 2415.5 kN 2
The modified soil pressure (per the strip) = PlNg = 2415.5 = 194.8 kN / m' B 12.4 .
1003.6
The column loads are modified in the same manner by multiplying each column load by the ratio (PavglPGHJ[)
1256.2 1509
a=
P{Ng P ACKL
= 2415.15 = 1.156 2090
992.3
992.3
Item
Moment (kN.m)
P actual
(kN)
PmoikN)
1
440
508.54
2
1150
1329.14
3
500
577.89
The shear force and bending moment diagrams are shown in figure. Two points of zero shears exist. They are calculated as follows: 1273.2
1273.2
Bottom steel
Bottom steel
Xl
= 508.54 =2.61 m x = 508.54+1329.14 =9.43 m 2 194.8 ' 194.8
Top steel Shear and moment for strip GHJI
409
410
Step 2.4: Strip KLPR (width =5.0 m) 1329.1
508.5
1
f f 0.20
-II·
·f 6.0
The average soil pressure for the strip can be obtained by taking the average value of the pressures at points M and N.
577.9
1
f
f f
~ I-
6.0
I
1 194.8 kN/m'
·11-°·20
qal'g
= 77.61 +2 83.98 = 8080 kN I 2 . m
The total soil reaction R KLPR=
qal'g
Ll B
= 81.87x5.0x12.4 = 5009.4 kN
On the other hand, the total vertical on this strip equals:
PGHJ1 = 1360 + 2880 + 1360 = 5600 kN
699.2 538.9
Now, we shall use the average value of the total reaction and PADUG.
Shear (kN)
5600 53047 = RACKL 2+ PACKL = 5009.4+ =. 2
A verage Ioad = Pal'g
kN
. pressure (per the stnp) . =-Pavg =5304.7 The modified sOlI - - - = 427 .80 k N I m ' B 12.4 The column loads are modified in the same manner by multiplying each column load by the ratio (PavIPGUJI)
629.9
a = Pavg = 5304.7 = 0.947 PACKL
562.1
Moment
5600
Item
Pactual (kN)
1
1360
1288.28
2
,2880
2728.13
3
1360
1288.28
(kN.m)
3.9 The shear and moment are shown in figure. Two points of zero shears exist. They are calculated as follows:
I·
Top steel
= 1288.28
x
692.9
·1· Bottom steel' I..
1
427.8
3.01 m
, x2
_ 1288.28 + 2728.l3 _ 9 39 -. m 427.8
-
Top steel • 1
Shear and moment for strip ACKL
411
412
Step 3: Design for flexure 1288.3
2728.1
!
!
f 0.20
I I I
-11 .
6.0
1288.3
!
I I
·1·
I t
Step 3.1: Reinforcement for strip ADHG The maximum positive moment is equal to 933.2 kN.m. This positive bending moment needs bottom reinforcement. 427.8 kN/m'
To obtain the reinforcement per meter divide the above value by the width of
~
strip (B=3.2 m) 6.0
M ' = 933.2 = 291.63 kN .m I m I
3.20
·11-°·20
To design this critical section, calculate the ultimate moment by multiplying M' by the load factor 1.5.
1364.1 1202.7
M u = 1.5 M' = 1.5 x 291.63 = 437.45 kN.m
Shear (kN)
Assuming that the distance from the c.g. ofthe reinforcing steel to the concrete surface is 70 mID and the total thickness is 750 mID. The effective depth equals: d =t -70mm =750-70=680 mm 6
1202.7
437.45 X 10 = 0.0378 250 x 1000 X 680 2 1364.1
From the chart with R=0.0378, the reinforcement index UFO.046
f
~.?
A = OJx...E!..xb xd = 0.046x-xl000x680 =.2172 mms ~ 360
Moment (kN.m)
Asmin -- sm aller OJ,{"
0.6b d = 0.6 xl000x680=1133 mm 2
{
fy
360·
.
1.3As = l.3x2172 = 2823 mm 2
Use 7
Similarly, the maximum negative moment is equal to 778.7 kN.m. M' = 778.70 = 243.34 kN.m I m I
3.20 Shear and moment for strip KLMN
To design this critical section, calculate the ultimate moment by multiplying M' by the load factor 1.5. M u = 1.5 M' = 1.5 x 243.34 = 365.02 kN.m
413
414
365.02xl06 =0.0315 250 x 1000 X 680 2 From the chart with R=0.0315, the reinforcement index ar=0.038 A = s
OJ x feu
~
xbxd
=0.038x~xl000x680=1794mm2 360
0.6 b d = 0.6 xl000x 680 = 1133 mm 2 Asmill = smaller of fy 360 { . 1.3As = 1.3 x 1794 = 2332 mm 2 Use 7<1>18/m' (1781 mm2) with additional (3.5 <1> 161m') (Top) Thus in this direction use a bottom mesh 7<1>20/m' and a top mesh 7<1>18 1m'
Step 3.2: Reinforcement for strips GHJI, ACKL and KLPR To avoid lengthy calculations, the following table illustrates the required steps to obtain the reinforcement. Strip
Strip GHJI
Strip ACKL
Strip KLPR
Reinforcement
Bottom
Top
Bottom
Top
Bottom
Top
M(kN.m)
1273.2
992.3
692.9
562.1
492.6
1682.1
B(m)
6.0
6.0
'2.7
2.7
5.0
5.0
M' (kN.mlm)
212.2
165.4
256.6
208.2
98.5
336.4
Mu (kN.mlm)
318.3
248.1
384.9
312.3
147.8
504.6
b(mm)
1000
1000
1000
1000
1000
1000
d(mm)
680
680
680
680
680
680
.. R
0.0275
0.0215
0.0333
0.0270
0.0128
0.0437
0)
0.0330
0.0250
0.0400
0.0320
0.0150
0.0530
As (mm2/m)
1558
1181
1889
1511
708
2503
Asmin (mm2/m)
2026
1535
2078
1964
1020
2078
As,req. (mm--z/m)
2026
1535
2078
1964
1020
2503
7
7
7
7
7
7
-
-
-
3.5<1> 161m'
-
3.50 181m'
Rft
**
Additional
** A bottom mesh of7 <1> 201m' (2199 mm2) and a top mesh of7 <1> 181m' (1718 mm2) are provided(Refer to Fig. EX. 5.8.2). Additional reinforcement may be placed at the location ofthe larger capacity.
Photo 5.9 Reinforced Concrete building 415
416
Step 4: Design for punching shear The maximum vertical load occurs at the column that carries 2880 kN. Thus, the ultimate load is obtained by multiplying this load by the load factor of 1.5.
The concrete strength for punching the least of the three values: 1. qellp =0.316 !Jeu =0.316
re
Pu =1.5 Pmax = 1.5 x 2880 = 4320 kN
The critical perimeter is at d/2 from the face of the column. For the interior column, the critical perimeter equals:
2. qcuP =0.316
{25 =1.29 N
Vu
(0.50+~)lell b rc
Imm 2
=0.316 (0.50+ 0.4) 0.4
{25 =1.94N Imm 2
Vu
d =680 mm
fill. (. rc
a =c( +d = 400+680 = 1080 mm
a d 3. qCIIP =0.8 (0.20+--) U
b =c 2 +d =400+680=1080mm
=0.8 0.20+ 4xO.68 )H.f5 - =2.71 N Imm 2 4.32 1.5
U =2 (a+b)=2 (1080+1080)=4320mm
j" - - - - --. o o
00
i
I
• • • L •
I
_____ _
I·
b=1080
•
·1
Since the applied punching shear is larger than concrete punching shear strength, the raft is considered unsafe against punching failure. The designer may use one of two solutions: 1- Increase raft thickness to 800 mm to decrease the punching stress to 1.26 2 N/mro • The reinforcement may be redesigned for more economic solution. 2- Increase the concrete compressive strength to 31 N/mm 2 to increase qCIIP to 1.42 N/mro 2 •
The pressure at point O· (refer to the table) is equal to 80.8 kN/m 2 Thus the ultimate soil pressure
qsu
= 1.5x 80.8 = 121.19 kN 1m 2
The punching load equals:
Q• =Pu -q ru (axb)=4320-121.19 (1.08 x 1.08) =4178.6 . kN
quP
= Qup = 4178.6xlOOO =1.42 N Imm 2 U xd 4320x680
417
418
Y
Y'
Example 5.9: Raft design using computer analysis Figure EX. 5.9 shows the axes and columns of a twelve-story building. The bearing capacity of the soil equals 200 kN/m 2 at F.L. The material properties are feu =35 N/mm2 and h = 360 N/mm2. Based on the recommendations of the geotechnical report, it is decided to use a rigid raft as a foundation system.
-
_--1- _____ 1
:3.5~81-J..1P..18/m
,-
VI
Top rft
"""
71/J20/m
1- The total unfactored moment (My) due to earthquake =16000.0 kN.m (reversible). The resultant of the un factored gravity load at the foundation level = 68000.0 kN and is located as shown in Fig. EX S.9a. !
..§
C'i
~
~=§:
a
0
-q-
~ VI
1
C'i
The building is provided with relatively rigid shear walls in the two orthogonal directions to resist the lateral loads. Consequently, analysis of the building under lateral loads could be carried out in each direction independent of the other. The following data are available from the analysis of the building in the X-direction:
-t tI I( (U I I
x
IIEI..§I
I~~I ~I~I
<'if-
2- Structural analysis of the building under the case of the emthquake acting in the Xdirection and under the critical load combination has resulted in the following straining actions at the foundation level: Column
Ultimate My (kN.m)
Ultimater load (kN)
(A-I) (WI) (A-4) (B-1) (B-2)
0 8000 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 12000 0
9S0 4200 13S0 18S0 40S0 49S0 27S0 21S0 6500 8900 3200 21S0 3200 2150 47S0 5800 3200 1300 7000 1900
(B-3)
I I l I I 3.0m
(B-4) (C-l) (W3) (W4) (C-4) (D-l) (D-4)
3.0 12.40m
(E-l)
(E-2) (E-3) (E-4)
column 40x40
(F-l) 71/J20/m
(W2) (F-4)
sec. 1-1 3.51e 18/m
3.51e 18/m
'7ye18/m
71/J18/m
I,
7¢p20/m
,
~.
"
71e 2O/m t
419
,
t
I 7ye20/m
I
Analysis for the building for the case of the earthquake acting in the in Y-direction provides straining actions that are not given since the example will be worked out only for the case of the earthquake acting in the in X-direction.
420
2
4
3
Step 1: Dimensions of the raft
i4.75m 3.875
5.00
5.875
Wherever possible, it is recommended to extend the raft beyond the edge columns by a distance that ranges from 0.5 m to 1.0 m. In this building, it is decided to extend the raft by 0.75 m from all the edge columns, except those located near the property line as shown in Fig. Ex .5.9b.
W2
F
As a role of thumb, it is a common practice to assume the thickness of the raft for multistory buildings to be equal to the number of stories multiplied by (80 mm to 100 mm). Accordingly, the thick;ness of the raft is assumed 1100 mm.
to ..... C?
u)
450 x 800 (Typ.)
~
.,.
-
Step 2: Check stresses on soil In order to check the stresses on the soil, one has to calculate the area of the raft (A), the moment of inertia about the X-axis and the moment of inertia about the Y-axis.
0
to
..t
~10
E
to .....
M C\I
C?
A = .15.75 x 25.5 = 401.6 m R
1. .,
~
3:
0
to u)
Solution
2
3
3
= 15.75x25.5 = 21763 m 4 12
I = 25.5x15.75 = 8302.3m4
&
y
12
The resultant of the gravity loads does not coincide with the center of gravity of the raft. It can be easily proved that the eccentricities ex and ey, as shown in Fig. EX 5.9b, are given by: ex =0.3 m
Since the moment due to the earthquake is reversible, one should consider the direction in which the moment due to the earthquake and that due to the eccentricity of the resultant of the gravity loads have the same sign.
II
(My)total = Moment due to earthquake + Moment due to eccentricity of the resultant of the gravity loads
Wi
My)total = My+ (ex x N) (My)total = 16000 + 0.3 x 68000 =36400 kN.m
5.875
5.00
3.875
i4.75m
3
2
Fig. EX. 5.9a Axes and Columns
e y =0.5m
4
(Mx )total = Moment due to earthquake + Moment due to eccentricity of the resultant of the gravity loads (Mx )total = Mx + (ey x N) (Mx)total = 0+ 0.5 x 68000 = 34000 kN.m
421
422
y
1
2 3.875
5.875
5.001
I®
ci
r-.
1
W2
--:-
I
•
.:e
I()
.,.
r- -
1
t
0
I()
E
.,; C\I
0
I()
-
+M
y(IOlal)
x
~-
.,;
~
0
-1~ C.G
~
-®
•
I()
~
f = 68000 + 34000 12.75 + 36400 7 .875 = 223.76 KN 1m 2 < (1.3 X 200) A
B
.j-
1
100
1"'0
.,.
1
.j-
I()
Y
Ix
401.6
21763
8302
f = 68000 + 34000 (-12.75) + 36400 (-7.875) = 114.87 KN 1m 2 < (1.3 x 200)
r-. <':!
.,;
I@
-®
,..;
I()
C?
I®
A
I()
It)
r-.
x (Ialal)
Iy The coordinates of points A and Bare (7.875,12.75) and (-7.875,-12.75), respecti veJy.
15.75m 0.87!
- N- .+ M _
f
4
3
••
401.6
21763
8302
According to the Egyptian Code for Foundations, the allowable bearing capacity of the soil can be increased to 1.3 of its recommended value whenever the earthquake load is considered. Hence, the stresses on soil are safe. y
@ x
-
0
It)
.,;
E
_-r--_ My =16000
1--
0
.1()
.,;
C\I
.. -
I
I-
I© 0
I()
.j-
..
I()
r-.
ci ~
ci
I
r 1
t
-
· I
I -
MX(lOtal)
A
Mx =0
I()
.j-
0.5
••
-®
x
I()
1
W1
-
-------+------~
-©
•
0
I I 100.
® I@
I
-
-
I
.
r-.
0.3
ci ~
-@
B
0.875
3.875
5.875
5.00 15.75m
1
3
2
Fig. EX 5.9b Plan dimensions of the raft
4
f.=114.87
~ 424
423
f,=223.76 kN/m'
Step 3: Computer analysis of the raft
Distribution of loads on (W 1)
Step 3.1: Modeling the raft and the soil
The wall is subjected to a normal force (-4200 kN) and a bending moment (8000 kN.m). The force at each node is evaluated by the superposition principle as follows:
The raft was modeled using shell elements and the soil was modeled using spring elements. Many commercial computer programs are well documented and can be used. In this example, the well-known structural analysis program SAP-2000 was used in the analysis. Figure 5.9d shows the finite element mesh used in the analysis.
A-Normal force This wall is modeled using 22 nodes. Hence, the share of each node is equal to: No
=
I
The majority of the elements had dimensions 0.5m x 0.5m. At some locations, however, smaller element dimensions were used. An approximate estimate of the coefficient of subgrade reaction is obtained as follows: k s = 120x soil bearing capacity = 120 x 200 =24000 N/m3 The soil at each joint is modeled as a spring having a stiffness K The stiffness of each springi3 obtained by multiplying the coefficient of subgrade reaction by the area served of each node as follows: ' at a corner no de K = k Area Stl'ffness 0 f a spnng - = 24000 x 0.0625= 1500 kN / m s 4 Stiffness of a spring at an exterior node K
= k, Area
2
=24000 x 0.125 =3000kN 1m
Stiffness of a spring at an interior node K = k, xArea = 24000xO.25 = 6000kN 1m
Step 3.2: Modeling the acting forces and moments A: Columns Interior columns were represented by three nodes to take into account their relatively large dimensions. Forces and moments acting on each column were assumed to be acting on the three nodes. Exterior and corner columns were represented by two nodes.
B: Shear walls
N No. of Nodes
= -4200 = -190.1 kN .t 22
B-Bending moment I = b Xt 12 (J
= M x
I ~
3
3
= 0.25x5 = 2.604 m 4 12 = 8000 2.5 = 7680 kN 1m 2 2.604
1 . =Pc =-x7680xO.25x2.5=± 2400 kN
2
Where Ptand Pc are the tension and compression forces, respectvely, resulting from the bending moment. Since we have two rows of nodes (2 xU), the share of each row is given as (refer to the figure): P' =
Pc = -2400 = -1200 kN No.of rows 2
c
To distribute the forces along the nodes, a conservative approach shall be followed. It shall be assumed that the loads at the nodes are proportion to their distance from point of zero stress.
Where Pi is the force at node i and Xi is the distance from node i to the center of gravity of the wall.
In order to model the forces and moments acting on the shear walls, it was assumed· that the gravity load could be divided among all the points representing o:he wall, whereas the moment could be represented by compression forces and tension forces acting at the nodes.
L> p. I
425
i
= 2.5 + 2.0 + 1.5 + 1.0 + 0.5 = 7.5 ms
= 2.5 x -1200 = -400 kN .t 7.5
426
2.0 7.5
I
=~X-1200 =-240 kN' "-
P2 =-x-1200=-320 kN -v
P3
P4 = .!:Q.x-1200 = -160 kN "-
0.5 I P5 =-x-1200=-80 kN -v 7.5
7.5
7.5
Distribution of loads on (W 2) The wall is subjected to a normal force (-7000 kN) and a bending moment (12000 kN.m). the force at each node is evaluated by the superposition principle as follows:
C- Total force
A-Normal' force
The total force at each node is given in Table EX 1.
This wall is modeled using 26 nodes. Hence, the share of each node equals:
22 21 20 19 18 17 16 15 14 13 12
Nodes numbering
I : : : : : : : : ': I 11 10 9
8
7
6
5
2
3
4
1
N, = I
B-Bending moment 3
3
1= b xt = 0.30x6 = 5.4 m 4 12 12
~
M
0-
=~x = 12000 3 .0 = 6666.7 I
;r//////////////////////////////////h
Wall WI
N = -7000 =-269.2 kN "No. of Nodes' 26
kN 1m 2
5.4
5.0m PI =P =.!..x6666.7xO.3x3.0=±3000 kN c 2
Pt
Since we have two rows of nodes (2 x13), the share of each row is given by (refer to the figure): Stresses diagram and the resultant forces
p'
Pc
C
No.of raws
= -3000 = -1500 kN 2
To distribute the forces along the nodes, it shall be assumed that the loads at the nodes are proportion to their distance from point of zero stress. P6 P5 P4 P3 P2 PI
~ ~ ~ ~ ~ ~
Transformation of moment into nodal forces
ttttt ~ P11 PIO P9 P8 P7 I
I>i = 3.0+2.5 +2.0+1.5+1.0+0.~ =10.5ms 0
0
0
l.5m
2m 2.5m
PI = 3.0 x -1500 = -428.6 kN "-
P2 = 2.5 x-1500 = -357.1 kN "-
P3 = 2.0 x-1500 = -285.7 kN "-
P4
10.5
10.5
10.5
=~x-1500=-214.3kN
Transformation of moment into nodal forces for wall WI
427
428
10.5
"-
P5
1~ = 10.5 x-1500 = -142.9 kN
I
P6
-v
0.50
= 1O.5x-1500=-71.4kN
J,
Table EXl Total force for the shear walls at each node
Wl
c-Total force
Resulting force at each node
25
-269.2
357.1
87.9
26 Total -4200.0
-269.2 -7000.0
428.6
159.3 -7000.0
(])
"0
13 12 11 10 9
8
7
6
5
4
3
2
1
V/b'/////////////////#/#/##///#/##/fi
Wall W2
6.0m
Pt Stresses diagram and the resultant forces
P7 P6 P5 P4 P3 P2 PI Transformation of moment into nodal forces
! !!!!!! JJ,tLt t. ttl I I I o
0
0
0
0
0
2m 205m
I
W2 Resulting force at each node
Force resulting form bending moment -428.6 -357.1 -285.7 -214.3 -142.9 -71.4 0.0 71.4 142.9 214.3 285.7 357.1 428.6 -428.6 -357.1 -285.7 -214.3 -142.9 -71.4 0.0 71.4 142.9 214.3 285.7
0
26 25 24 23 22 21 20 19 18 17 16 15 14
I :::::::::::I
Force resulting form bending moment --400.0 -320.0 -240.0 -160.0 -80.0 0.0 80.0 160.0 240.0 320.0 400.0 -400.0 -320.0 -240.0 -160.0 -80.0 0.0 80.0 160.0 240.0 320.0 400.0
Force resulting form Normal force -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2 -269.2
The total force at each node is given in Table EX 1.
Nodes numbering
Force resulting form Normal force -190.9 -190.9 -190.9 -190.9 -190.9 -190.9 -190.9 -190.9 -190.9 -190.9 -190.9 -190.9 -190.9 -190.9 -190.9 -190.9 -190.9 -190.9 -190.9 -190.9 -190.9 -190.9
Z
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24
-590.9 -510.9 -430.9 -350.9 -270.9 -190.9 -110.9 -30.9 49.1 129.1 209.1 -590.9 -510.9 -430.9 -350.9 -270.9 -190.9 -110.9 -30.9 49.1 129.1 209.1
-697.8 -626.4 -554.9 --483.5 -412.1 -340.7 -269.2 -197.8 -126.4 -54.9 16.5 87.9 159.3 -697.8 -626.4 -554.9 --483.5 -412.1 -340.7 -269.2 -197.8 -126.4 -54.9 16.5
3m
-4200.0
Transformation of moment into nodal forces for wall W2
429
430
The concrete punching strength is the least of the three values: In the computer model, the forces and moments acting on the columns were assigned to the joints. For shear walls, however, the resulting forces given in Table EX 1 that represents the applied. moments and normal force were assigned to the nodes of the shear walls. The output of the program is shown in Fig. EX9.5d
1. q cup
~fcu Y c
2. q
Step 4: Design of the raft Step 4.1: Check of punching d = 1100 - 70 = 1030 mm 3.q Qup = Pu= 5800 kN
= 0.316
cup
=0.316
= 0.316
V{35 1.5 = 1.52N Imm
(0.50+~)~fclI b Y c
=0.8(0.20+ad)~fru cup U Y
2
< 1.6. N Imm 2 ..... iJ.k
=0.316 (0.50+ 0.45) 0.80
=0.8 (0.20+
c
a=c 1 +d =450+1030=1480mm
(35 =1.62N Imm VLs
2
4X 1.03) {35=3.17Nlmm 2 6.62
VLs
ok
b =c2 +d =800+1030=1830 mm
u
=2
Step 4.2: Flexural Design
(a +b) = 2 (1480 + 1830) = 6620mm
Step 4.2.1: Critical sections
3
= 5800x10 = 0.85N Imm 2 quP 6620x1030
Critical punching perimeter
c2=800
r--j'----J---V-I
o 00
"
]
I
:
:1
I
I
I I
I I
I
I
I I
I I
/.
The computer output of the raft foundation consists of bending moments acting in the two directions Mu (x-direction in this case) and M22 (y-direction in this case). The graphical representation is in the form of contour lines, in which each contour line represents a certain bending moment value as shown in Fig. EX. 9.5d . It should be mentioned that closely spaced contour lines indicate concentration of stresses. This usually occurs at the locations of the columns. When designing the bottom reinforcement of the raft one should use the value of the bending moment at the face of the column.
0
I(")
It 0
-/
b=1830
432 431
Step 4.2.2: Design of sections The design for flexure for a critical section of 1.0 m width is carried out as follows: Using the design aids (Cl-J) curve
1030=C\
Mil
35 x 1000
Get C 1 from (Cl-J) curve and the corresponding value of J. Mu 360xJ x 1030
~A. SlTUn
0.6 0.60 2 I A'min =-b d =-xlOOOx1030 = 1716 mm (5iP22Im) . fy 360
It is decided to use a mesh 5 cP 221m / top and bottom, and use addtioal reinforcement where needed. It should be mentioned that the above procedure should be repeated for the case in which the earthquake load acting in the X-direction but in the reversed direction. In such a case, the moments acting on the shear walls will be reversed and the procedure described for transforming the moments and the normal forces acting on the shear walls into nodal forces will be followed. Moreover, the raft should be analyzed for the case in which the earthquake load is actin in the Y-direction (straining actions are not given for that case). The final reinfocement of the raft should cover all the cases.
Fig. EX 9.5d Computer output
433
434
Additional top rft. Additional bottom rft.
2
1
------
4
3 15.75m
0.87
,...
5.875
5.0
3.875
~
'®
~
,...
ll)
~
~-
~ N ~ EIE
.
~I..J
(')
tq
3m
l
~NI
ll)
1=
~~ .- ~ 2m -
M
E ll) u; N
u;
©
(')
E
~ i~
C\i
C\i
~~@
~., ~ f.J"
2.5 22. In L 3m
ll)
E co
'@oj
I
E co j EE
-
'1fT
~~r:
::lIT
,...co ci
I 2.5 22
11
1= L=~ ~E
~
b
(')
~
N
"'""~ !.\
2.5~221l
-E (')
L=~ ~E
arT tq
E
"''''c... '@o !.\
arT
.
~ ~
E
~~
.~ 2rT N
~
N
~
4m
ll)
C\i,m
5.875
5.0
2
3
Fig. 5.9c Reinforcement of the raft
435
ll)
E
~ ~£" ~ --'
II
15~75m
1
,...
co
~t?
(')
3.875
-® M
L=9m
~ bn;-i
-.i
~ ~r
§
5~221m
E
0.87!i
I
I
N
co
@
-©
'@o .:i"
~2rT
1~ ~
M
E ll) u; N
ll)
-.i
ll)
tq ll)
ll)
,...
-@
~ ~ N
ll)
~~
®
0
-.i
E
E co
-®
~ ~ N
ci
ll)
-
m
!-
~
5~221m
2.5 22 L= ~m
~
I
ll)
u;
Basic Mesh Top&Bottom
E
~N
~13m I
ll)
E
T~.!l am
_
N
,...
-®
~~ ~ P"1
L=~EE
(')
I~j am tq
1 ~ ~-
®
2.5l 22 m -E
~
~I
'@ol
L;=~_EE
-.i
iF~
ll)
L=9m
2.5 22m
~~
<& -
m
5~25/m
,§l!;i. ~j3 ....
~ ~~
E ...,.
NI';l
u;
I®
,...
ll)
ll)
4
,...<0
ci
@
5.10 Design of Pile Caps
5.10.1 Introduction Piles are structural members used to transmit surface loads to lower levels in the soil mass. This transfer could be made by a vertical distribution of the load along the pile shaft or by a direct application of load to a lower stratum through the pile base. A direct load application is made by an end-bearing pile as shown in Fig. 5.27a and a vertical distribution of the load is made using a friction pile as shown in Fig. 5.27b. In general, most piles carry loads as a combination of side resistance and point bearing except when the pile penetrates an extremely soft soil to a solid base. Pile Cap
Photo 5.10 Reinforcement of a pile Pile
soft soil
t
t
t
t
Piles are commonly used for the following purposes: • To carry the superstructure loads into or through a soil stratum. • To resist uplift such as for basement rafts below the water-table. • To resist overturning such as for tower legs subjected lateral loads .. • To control settlements in case the structure is underlain by a highly compressible stratum.
Rock or hard layer
a) End-bearing Pile Pile Cap
I
1I~
skin resistance 1 I If\ produces major
1I~ 1I~
part oflt
1
~
b) Friction Pile Fig. 5.27 Friction and end b~aring piles 437
Photo 5.11 Construction of pile caps 438
5.10.2 Configurations of Pile Caps
5.10.3 Design of Pile Caps
Unless a single pile is used, a cap is necessary to spread the vertical and horizontal loads and any overturning moments to all the piles in the group. Pile caps take different shapes according to the number of piles used as shown in Fig. 5.28. The pile cap has a reaction that is a series of concentrated loads at the locations of the piles.
Pile caps may be designed using one of the following methods:
The acting loads on the pile cap includes the column loads and moments, any soil overlying the cap (if it is below the ground surface), and the weight of the cap.
5.10.3.1 Design using the conventional Method
1. Conventional design method. 2. Finite element method. 3. Strut and Tie method
Step 1: Determine the load of each pile For a concentrically loaded pile cap, the load per pile is given by: 1.05xN
---~Pallowable •.......•••••........•.....••...•••..•.•
n
,l '4\ ,
\
,
I
, ji-' " \, .
.--.
, / .... _"'"
\
I
(5.43)
in which P = = 1.05 n = N = Pallowable
, /
Pile working load factor taking into account the pile cap self weight (5% ofthe load) Number of piles Working load ofthe column = Allowable pile load
.... _<11'
For eccentrically loaded pile caps, the load per pile is given by: a) 4 Piles
b) 3 Piles P pile
_N
My
Mx
n
L,.X
L,.Y
--+" . 2 X + ".
2 Y
~Pallowable
............•....•.•.•
(5.44)
where
Mx,My x,y
= =
moments about x and y axes, respectively distances from y and x axes to any pile
= summation ofthe square distance from pile group center.
Step 2: One-way shear strength of pile-caps The critical section is located at di2 from the face of the column; where d is 'the depth of the pile cap. c) 6 Piles
Fig. 5.28 Pile cap shapes according to the number of piles
439
With reference to Fig 5.29, the computation of the one-way shear on any section through a footing supported on piles shall be in accordance with the following: •
The entire reaction from any pile whose center is located l/J/2 or more outside the critical section shall be considered (case (a». 440
•
The reaction of the pile is neglected if the pile center is located at
Step 3: Two-way (Punching) shear strength of pile caps
•
For intermediate positions of pile center, the portion of the pile reaction to be considered as producing shear on the section shall be based on straightline interpolation between full value at
The calculation of the punching load for a pile cap is minimally addressed in the literature. TheECP 203 does not give explicit procedure for calculating the punching load for pile caps. In this text, an approximate procedure is proposed. It should be emphasized, however, that such an approximate procedure does not reflect the actual complicated behavior.
Column dI2
4>12
Case b
4>12
I-draw the critical section at d/2 from the column. 2-draw the boundaries @ fPl2 from each side of the critical sec. 3-draw the exact location of the pile and calculate (a) 4-calculate the Preduced at the pile location
Consider the pile cap shown in Fig. 5.30. The critical section for punching is located at d/2 from the face of the column. It will be assumed that parts of the piles located inside the punching perimeter shall participate in reducing the punching load. Referring to Fig. 5.30, the punching load can be calculated as follows: .
it =
hatched area of the pile gross area of the pile
.......................... (5.45)
Case a
Case c
Preduced
¢=pilediam.
a
a
=
Percentage of effective pile load used in shear calculation
critical punching surface
.§ -0
II)
'" t;; o
Fig. 5.30 Critical section for punching
'.p
'1::
U
Q up
Case (a) 100%
Case (b) 0%
Case (c) interpolate 0-+ 100
=(Column ultimate load + o. w. of pile cap within the punching perimeter) - 2 XA. x pileload
The punching stress q up
=~ ............................................................... (5.46) U xd
Fig. 5.29 Effective pile load for one-way shear 441
442
The concrete punching strength is given as the least ofthe following values:
1.
qcUP
=0.316,jf :::;1.6 N Imm 2 •••••••••••.•••••
2.
qcuP
= 0.316
~ ••••• (S.47a)
(o.so+~)lCU ............................ (S.47b) b Y c
qcup= 0.8 (0.20+ a d
3.
u
)lCU ............................(S.47c) Yc
.
where qcup is the punching shear strength provided by concrete; (a/ b) is the ratio of long side to short side of column, a= 4, 3, and 2 for interior, edge, and comer columns, respectively, d is the effective shear depth of the pile cap (average flexural depth in the two directions), U is the perimeter of the critical section, and feu is the concrete compressive strength. Check of punching should be performed around the individual pile.
Step 4: Design for Flexure The ECP 203 requires the critical section for flexure to be taken at the face of the column as shown in Fig. S.31. Pile caps must be reinforced in two perpendicular directions. In most cases, an isolated centrally-loaded pile cap supporting a single column needs only bottom reinforcement. However, eccentrically loaded pile caps and pile caps supporting more than one column might need top reinforcement as well. The minimum cover for the reinforcement is 70 mm (concrete cast against soil).
5.10.3.2 Finite Element Analysis of Pile Caps The number of piles can be determined using the procedure mentioned in step 1 of the conventional method. Pile cap bending moments can be obtained using the FEM. Such a procedure can be carried out using commercially available computer programs. It should be mentioned, however, that one-way shear and punching shear can not be obtained from such an analysis. One-way shear punching shear calculations should be made according to the procedures mentioned in the conventional method. The pile cap is modeled using shell elements while the piles are modeled using spring elements as shown in Fig. 5.32. Due to the fact that pile caps are usually thick, the use of shell elements that do not consider the effect of shear deformation is not advisable. Past experience, however, proved that the use of ordinary (thin) shell elements is adequate for design purposes. Deign moments should be calculated at the face of the column. It is a common practice to calculate the spring constant of piles based on the permissible settlement of the pile during the pile load test. In other words, the pile spring constant Kpile is calculated as follows:
K pile
Pile working load
- - - - = - - - - ...................... (5.48) Permissible settlement
Loads
Column Cap modeled as shell elementS Nodes I
"+t-' "
/ ,
\
' I
"'-"
~' ,/
I '
I
--I
\
\
1
I
.... _"'
Fig. 5.31 Critical section for flexure Fig. 5.32 Modeling of the pile cap 443
444
5.10.3.3 Design using The Strut and Tie Method The Egyptian Code ECP 203 allows the use of the Strut-and-Tie method for designing pile caps. The structural action of a four-pile group is shown in Fig. 5.33. The pile cap is a special case of a deep beam and can be idealized as a space truss with four compression struts transferring load from the column to the piles, and four tension ties equilibrating the outward components of the compression struts. The tension ties have constant force in them and must be anchored for the full horizontal tie force outside the intersection of the pile and the compression strut. Hence, bars must either extend a distance equal to the anchorage length past the centeriines of the piles, or they must be hooked outside this point. For the pile cap shown in Fig. 5.33, the total tie force in one direction can be calculated from the force triangular shown.
Example 5.10 Design and give complete reinforcement detailing for a pile cap that constitutes a part of a deep foundations system of a high-rise building. The design data are as follows: Column dimensions Unfactored column load Factored column load Pile diameter Pile working load feu /y
= 900 mm x 900 mm =5000 kN = 7500 kN =800mm = 1400 kN 2
=40N/mm = 360 N/mm2
Column load
Solution Step 1: Dimensions of the· pile cap
A A
In order to determine the dimensions of the pile cap, one has to determine the number of piles. · Numberof pies 1
(b) internal forces in pile cap
(a) Pile cap Pu
Unfactored load of column x 1.05 =----------Pile working load
5000x 1.05
1400
3.75
Choose 4 piles. It should be noted that the multiplier 1.05 takes into consideration the own-weight of the pile cap. The spacing between the piles is usually taken (2.5 - 3 <1». In this example, the spacing between piles is taken = 2.2m. The distance from the centerline of the pile to the edge is taken (0.8 -1 <1». The dimensions of the pile cap are shown in the following figure. The thickness of the pile cap shall be assumed equal to 1.0 m. Unfactored own-weight of the pile cap = 3.8 x 3.8 x 1.0 x 25 =361 kN
Pul4 L
Pul4
(C) Force in tie A-B
unfactored column load + own weight of pile cap Exact pile load = ____________ _ ___o.. number of piles ~_~
=5000+361 = 1340.25kN < 1400kN ... fJk 4
Fig. 5.33 Strut and Tie method for a pile cap
445
446
00
c::5
-
......
.....<
-
/17\ ~ .....
S
<=> OC!
\
<')
...... ......
-- ...
'....
I
I
.\ :=tt/ \
.I I
o.o~
;-/
' ... /
I
I
00
c::5
0.8
1.1
1.1
I
0.8
3.80m Critical section for shear
0.4 : 0.4= +12
%100 0.585
SEC(1-1)
Step 2: Design for shear Step 2.1: One-way shear Ultimate load of pile = factored load of column + factored O.W. of piIecap 4 Ulti rnate Ioa d '0 f'l pI e = 7500+ 1.4x361 4 d = 1000-70 = 930mm
2001.35 kN.m
The critical section for one-way shear is at d/2 from the face of the column as shown in the following figure.
447
According to the ECP-203, the pile load that should be considered when checking the shear strength of pile caps can be reduced depending on the location of the center of the pile with respect to the critical section. Preduced
=reduced pile load for checking shear strength
Preduced
=reduction factor x ultimate load of pile = 585 x2001.35 =1463.487
kN
800
448
Qu =2xreduced pile load - O.W. of pile cap outside of the critical section (hatched
area) Qu =2xI463,487 -1.4x25x3.8xO.985xl.O =.2796 kN
Referring to figure, it can be noted that very small area of each pile is located inside the critical punching area (3.5%). According to the previous procedure, the punching load could be calculated as follows:
/L = hatched area of the pile = 0.035 gross area of the pile
Critical section
,-, I
\
I \
I
'-'
I
s
o00 c
,-, I
\
I
I \
'-'
I
1·°·985. I 2796 X 103 2 q" = bxd = 3800 x930 0.79 N Imm Qu
qcu =0.16
fi
I I
ow
~;!d~~ 1
~ o
= 0.16 - = 0.826 N I mm 2 Yc 1.5 .
--E.!!-
punching surface
Since qu < qcu , the thickness of the pile cap is considered adequate for one-way shear.
Qup = (Column load + O.W ;of pile cap within the punching perimeter)- 4 x Ax pile load
Qup = (7500+ 1.4x25x1.83x1.83xl.0)-4xO.035x2001.35 = 7337 kN
=~= 7337 X 1000 = 1.07 N I mm 2
Step 2.2: Punching shear
The critical section is at d/2 from the column face as shown in the figure below. al =c 1 +d =900+930=1830mm =1.83m
quP
U xd
7320x930
Column load= 7500 kN
bl =c 2 +d =900+930=1830mm =1.83m U = 2x(al +b l ) = 4x1830= 7320mm The ECP 203 does not give explicit procedure for calculating punching load for pile caps. However, it can be assumed that the punching load equals to the column load minus the parts of the piles' loads located within d/2 from the face of the column. It will further be assumed that the load resisted by a certain area of a pile is equal to the total load resisted by the pile multiplied by the ratio of that area to the gross area of the pile. 449
450
The concrete strength for punching is. the least of the three values: 1.
qcuP
= 0.316
~cuY
The critical section for flexure is at the face of the column. =
0.316
c
2.
3.
qcUP
qcuP
Step 3: Design for flexure
{40 = 1.63N/rom
'11.5
2
> 1.6 N/rom
2
-7=
1.6 N/rom
2
Mu = 2xfactored load of pilexO.65- moment developed due to the O.W. of
Ii
the hatched part of the pile cap
a --E!- = 0.316 (0.50+-) 0.90 ~O = 0.316 (0.50+-) - = 2.44N Imm 2 b Yc 0.90 1.5
O 8 (0 .20 +a-d=.
Since quP
U
)Jf-=0.8 (0 .20+ 4xO.93 )~O - =2.92 N I mm Y 7.32 1.5 cu
. 2
145 M u = 2X2001.35XO.65-1.4X25X3.8X~2 == 2462 kN.m Critical 2
c
E o00
C<)
Note: The reader might notice that the reduction of the punching load due to the existence of the parts of the areas of the piles within the perimeter of punching complicates the calculations. Accordingly, the designer could conservatively neglect such a reduction in cases where it has trivial effect on the results.
Check of punching for individual piles Pile load = 2001.35 kN
d=C1
From the figure U=3.40 m
=~= 2001.35 X1000 =0.63N Imm 2 -7 safe quP
U xd
ft5 u
--
930=C
feu B
C 1 =7.3 -7
U=3.4m~
As
6
u
f y .J.d
2462x10 8902 mm 2 360xO.825x930
A /m=8902=2342
3.8
s
2462x106 40x3800
Take c/d=0.125 -7 J =0.825
3400x930
M
1
mm 2 1m'
Check the minimum steel requirement A
. = 0.60 X b X d =0.6 X 1000 X 930 =1550 mm 2
s,mln
Choose 5¢251m' (2454 mm
451
2
)
452
Example 5.11 Design and give complete reinforcement detailing for a pile cap that constitutes a part of a deep foundations system of a factory. The design data are as follows:
•
~
12@250mm tt~-
I
Plain concretel
......... .. . . . . . .. . . y
• • •
I
Diameter of circular Column Unfactored column load Factored column load Pile diameter Pile working load
feu
h
= 850 mm = 4500 kN = 6750 kN =800mm = 1750kN =35 N/mm2 = 400 N/mm2
5 f/25/m
Solution Step 1: Dimensions of the pile cap Reinforcement Details
In order to determine the dimensions of the pile cap, one has to determine the required number of piles. · Unfactored load of column x 1.05 1 = N urnb ero f pIes Pile working load
=
4500x1.05 2 = .7 1750
Choose 3 piles. The multiplier 1.05 takes into consideration the own weight of the pile cap. The spacing between the piles is usually taken (2.5 $ - 3 $). In this example, the spacing between piles is taken = 2.2 m. The distance from the centerline of the pile to the edge is taken (0.8 $ -1 $). The plan dimensions of the pile cap are shown in the following figure. The thiclmess of the pile cap shall be assumed equal to 1.3 m. Unfactored own weight of the pile cap = 5.0 x 4.33/2 x 1.3 x 25
Photo 5.12 Reinforcement arrangement of a pile
=
·1 I d unfactoredcolurnn load +own weight of pile cap Exact pI e oa = -----------~==---!...--~ number of piles 4500+351.8 _ _ _ _ = 16'17.35 kN . . <1750 kN ...... LJk 3
453
454
351.8 kN
Critical section 1 The critical section for one-way shear is at dl2 from the face of the column as shown in the figure below. co co
'"
According to the ECP-203, the pile load considered when checking the shear strength of pile caps can be reduced depending on the location of the center of the pile with respect to the critical section.
Pile cap arrangement
From the figure, the distance (x) from the center of gravity of the column to the center of gravity of the pile equals = 1.1Icos 30° =1.27 m. Preduced = reduction factor x ultimate load of pile
Step 2: Design for shear
630 = -x2414.2=1901.2 leN 800
Step 2.1: One-way shear ' I d f'l factored load of column +factoredO.W.ofpilecap UI tlmate oa 0 pI e = --------------~--''----''3 · 1 d f'l Ul tImate oa 0 pI e
= ------6750+1.4x351.8 3
Qu
=reduced pile load - O.W. of pile cap outside of the critical section (hatched area)
YI
= 2.88- 0.85 -0.615 = 1.83
Xl
=
"
2414.2 "leN
d = 1300-70 = 1230mm There are two possible sections for one-way shear as follows:
1.83 sin 60
2
= 2.11 m
O.W. of the pile cap
= O.W. of the hatched part in the following figure =1.4 x 2.11 x 1.8312 x 1.3 x 25 = 87.8 leN
455
456
'.
Step 2.2: Punching shear The critical section for punching shear is at dJ2 from the column face as shown in the figure below.
00 00
c-.i 1:==::J041--- P reduced
Dj =
Dcolumn
+d = 850+1230 = 2080mm =2.08m
U =1& D J =1&x2080=6535mm I
I
1\
,
\
I
\
Qu =1901.2 - 87.8=1813.4 kN
qu
=~= b xd
3
1813.4 X 10 =0.70 N I mm 2 . 2110 x1230
qcu =0.16
~fcu
Since qu
Yc
= 0.16
(35 = 0.77 N
Vu
I mm 2
Critical section 2
critical punching surface
The punching load could be calculated as follows:
From the figure below, it is clear that Qu at the center of gravity of the pile is almost equal to zero. Therefore, the section is considered adequate.
/L = hatched area of the pile gross area of the pile AutoCAD)
= 0.12
(hatched area is calculated using
Qup = (Column load + O. W.of pile cap within the punching perimeter)- 3x Ax pile load
Qup
= (6750+1.4x25x1& X (2.08)2 x1.3)-3xO.12x2414.2 = 6035.5 kN
4
Qup 6035.5x1000 quP = U xd = 6535x1230
457
0.75N Imm 2
458
Step 3: Design for flexure
The concrete strength for punching is the least of the three values
The critical section for flexure is at the face of the column 1. qcup =0.316
rr::: =0.316 V{35 Vr: 1.5 = 1.53N Imm
2. q
(0.50+~)Jlcu b Yc
=0.316 cup
3. q
cup
d
a ) = 0.8 (0.20 + U
=0.316 (0.50+1)
Ii ( ...E!!..
Yc
2
x 2 = 2.455 = 2.83 m sin 60 M = factored load of pileoy- moment developed du~ to the O.W. of the u . hatched pile cap k 2.455 x 2.83 2.455 Mu = 2414.2xO.845-1.4x25x1.3x . 2 X --=1910.6 N.m 3
<1.6 N Imm 2
{35 =2.29N Imm 2
V1.5
= 0.8 0.20 + 4x1.23 6.535
)Jg5 - = 3.68 N I mm 1.5
2
ci
g.
qcup= 1.53 N/mm2
U
II.l
I
Since q up
=a y=o.845
I===k---·J:'ue load= 2414.3
-- - ' - ' - ' - ' - ' -
~
Check of punching for individual piles
Mu=19 10.6
Pile load = 2414.3 kN From the figure V=2.90 m
quP
I• x2=2.83
=~= 2414.3x1000 = 0.68N I mm 2 -7 safe U xd
2900 x 1230
d=C1
u --
leu ~ Mu
As U=2.9m
A s
,-, l
I y .J .d
Take c/d=0.125 -7 J = 0.825 6
191O.5x10 -4701 mm 2 400xO.825x1230
1m = 4701 =1658 2.83
Check the minimum steel requirement
I
'-~
191O.5x106 1230=C\ 35x2830
B
C\ =8.86 -7
·1
As ,min
= 0.60 xb xd= 0.60 xlOOOx1230=1845 mm 2
Iy.
400
Since As < A smin , use Asmin 2 )
Choose 6 <1>20 1m' (1884 mm
460
Example 5.12 Design and give complete reinforcement detailing for a pile cap that constitute a part of a deep foundations system of an office building. Design data:
12 @2S0mm
.•
~--------------~ ~
•• • Plain concretJ
•
••••••••••••••••••••
I
y
6
I
# 201m
I I
6#201m
Column dimensions Unfactored column load Factored column load Pile diameter Pile working load feu
h
= 600 mm x 1200 mm' =7000 kN = lOSOOkN = 800mm = 13S0kN 2
=3SN/mm = 360 N/mm2
Solution Step 1: Dimensions of the pile cap
Reinforcement details for the pile cap
In order to determine the dimensions of the pile cap, one has to determine the number of piles. ' N urnberof pI les
= Un factored load of column x 1.0S Pile working load
7000xl.0S S.44 13S0
Choose 6 piles. The multiplier LOS takes into consideration the won weight of the pile cap. The spacing between the piles is usually taken (2.5 - 3 <1». In this example, the spacing between piles is taken = 2.0m. The distance from the centerline of the pile to the edge is taken 0.80 m. The plan dimensions of the pile cap are shown in the following figure. The thickness of the pile cap shall be assumed equal to 1.4 m. Unfactored own weight ofthe pile cap = 2SxS.6 x 3.6 x1.4
= 70S.6 kN
'1 1 d unfactored column load + own weight of pile cap Exact pl e oa = --------------'''---''----''number of piles
7000+70S.6 6
461
= 1284.3kN
462
< 1350 .... ok
Critical section 1-1 The distance between the e.G. of piles and the critical section for one-way shear is more than d/2 (0.665). Hence, no reduction in pile loads.
QII =2xI914.6 - 1.4x25x 3.6x(1.535)x 1.4 =3559 kN
I
-,
,_ ....
I O.8m I
2.0m
I
I O.8m I
2.0m
....
,
,_....
I,
I
-, ,
,_ ....
....
,
,_ ....I
I
I .. 1 0.665
·1 1.535
3
Qu 3559 X 10 2 qu = b xd = 3600 x1330 0.74 N Imm
qCII=0.16~CII Yc
Pile cap arrangement
=0.16
[35 =0.77Nlmm
2
V1.5
Since qu
Step 2: Design for shear Step 2.1: One-way shear Ultimate load of pile = factored load of column +factored O.W.of pilecap 6
Ultimate load of pile = 10500+1.4x705.6 6 d
=1400 -
1914.6 kN
Critical section 2 - 2 Preduced =
reduction factor x ultimate load of pile
= 435 xI914.6=1041.1 kN 800 Qu =3 x reduced pile load - O.w. of pile cap outside of the critical section(hatched area)
70 =1330 mm
The critical section for one-way shear is at df2 from the face of the column as shown in the following figure.
463
Qu =3xl041.1-1.4x25x5.6xO.835x 1.4=2894.1 kN
464
Step 2.2: Punching shear ; I
-... ,
,_ .... I
; - ... I
,
; I
,_ .... I
The critical section for punching shear is at d/2 from the column face as shown in the figure below.
- ... ,
,_ .... I
~
=c I +d = 600+1330= 1930mm =1.93m bi =c 2 +d =1200+1330= 2530mm =2.53m
Critical section
U =2x(a1 +b 1 )=2 (1930+ 2530)= 8920mm
O.665
f
Referring to figure, it can be noted that the areas the piles that are located inside the critical punching area (A=45%) of two piles. According to the previous procedure, the punching load could be calculated as follows:
0.835
I· Qu qu = b xd
=
2894.1 X 103 5600x1330
. 1
5.6
0.39 N / mm 2
Since qu
o
00
o
1.40
2.0
critical punching surface
Qup = (Co\umn load + O.W. of pile cap within the punching perimeter)- 2. A. pile load Qup = (10500+ 1.4x25x1.93x2.53x1.4)- 2x0.45x1914.6 =9016.1 kN
0.80
465
I
2.0
2.0
I
0.80
quP
=~= 9016.1x1000 =0.76N Imm 2 U xd
8920 x 1330
Column load= 10500kN
466
Section 1
The concrete strength for punching is the least of the three values:
Mu = 2· factored load of pile· x I
1. qcuP = 0.316
~fcu
2. qc.up =0.316
(0.50+~)~fcu
Yc
= 0.316
{35 = 1.53N I mm 2 < 1.6 N
I mm 2
VLs
=0.316 (0.50+ 0.60) Yc 1.20
moment developed due to the O. W. of the
hatched pile cap (=1.4x Yc xB xt xXw 2 12) 1.2 xI =2.0=1.40m
{35 =2.23N Imm
VLs
3. qcuP = 0.8 (0.20 + a d )/Jcu = 0.8 (0.20 + 4X1.33) U Yc 8.92
-
T
2
XW
{35 = 3.08 N
VLs
I mm 2
=2.8-
Step 3: Design for flexure
e
1330=C
u
--
feu B
1
6 4934x10 35x3600
C 1 =6.72 ~
Take c/d=0.125 ~
A
4934X106:::::12476 mm 2 360xO.825x1330
S
The critical section for flexure is at the face of the column. There are two critical sections:
=2.2 m
T
222 M u = 2xI914.6x1.4-1.4x25x3.6x1.4x-·- == 4934 kN.m 2
d=C 1 Since quP (qeup, the thickness of the pile cap is adequate for punching shear.
1.2
Mu fy.J.d
A /m = 9032.6 = 3465 S 3.6
J = 0.825
mm 2 1m
Check the minimum steel requirement 0.60 0.60 2 As min = --xb xd =--xlOOOx1330=2217 mm 'fy 360 Choose 6281m' (3695 mm2)
I \
"~i+"" 'I
" ./ .... _-'
..
- - (\~~""II I
4
'-
I
\
"_" ./ .....
2.0
"
'-
"
Critical section 1-1
-,
I J ,_ .....
....'-
'--"
I ./
o 00 d
2.0
6 281 m' x..r=2.2.m
467
468
-r-
-r-
Section 2 Mu = 3· factored load of pile· x f
-
#12@250mm
moment developed due to the O. W. ofthe
hatched pile cap ( =1.4 x Yc x B x t x x w 2 I 2 ) 4
,
x
f
Xw
=1.0- 0.6 =0.70m 2
-
• 0
~ .-
=1.8- 0.60 =1.5 m 2
1.5 Mu =3x1914.6x O.70-1.4x25x5.6x1.4x1.5x-=3877 kN.m
~
2
3877x106 35x5600
1330=C1
.
.
.
•
.
1-
V
1 6 #281m
6 # 201m
Section A-A C 1 =9.46 ~
Take cjd=0.125 ~ J = 0.825
A
3877x10 =9802 mm 2 360xO.825x 1330
s
Mu fy.J.d
6
A~s jm = 9802 = 1750 5.6
mm
Use As=As.min=2217 mm
2
I
m
2
!! 0
N
Choose 6
; I
...... \
'-'"
Critical section 2-2
I
;
...... \
I
I
'-'"
; ......
I
-
,
,_ .... I
e
A
\0
6
Plan
Reinforcement details of the pile cap
I-
5.6
469
.I 470
-
A
STRUT· AND -TIE MODEL
Photo 6.1 Yokohama Bay Bridge
6.1 Introduction In a structure, forces tend to follow the shortest possible path to transfer loads. In a beam subjected to concentrated loads, the shortest paths to transfer load are the straight lines connecting the points of loading and the supports.
471
For deep beams, those shortest paths are possible paths, see Fig. 6.1a. The load is directly transferred to the supports through compression struts with reasonable inclination. For slender beams, however, those shortest paths are not possible paths as . shown in Fig. 6.1b. In such beams, the compression struts would be very flat. In order to develop a vertical component that is large enough to equilibrate the applied force, the actual force in the strut will be too large to cause concrete crushing. Vertical web reinforcement (ties) provides possible paths, as shown in Fig. 6.1d, since it increases the inclination of the struts. CO!llparison between Fig. 6.1c and Fig. 6.1d indicates that the strut-a~d-tie model is a special case of the truss model in which no vertical ties are statIcally needed.
6.2 Principle of Band D Regions B-region A portion of a member in which the Bernoulli hypothesis of plane strain distribution is assumed to be valid.
Discontinuity A discontinuity of the stress distribution occurs at a change in the geometry of a structural element or at a concentrated load or reaction. St. Venant's principle indicates that the stresses due to axial load· and bending moment approach a linear distribution at a distance approximately equal to the overall height of the rriember away from the discontinuity (See Fig. 6.2). For this reason, discontinuities are assumed to extend a distance h from the section where the load or change in geometry occurs.
D-region
/
/
/
Possible path
/
, Impossible path
a)The shortest path in deep beam
/
"
/
/
A
....
"-
"-
b)The shortest path in slender beam
,
crStrut and tie model for deep beam
d) Truss model for slender beam
It is the portion of a member within a distance equal to the member height h from the face of discontinuity. The plane section assumption is not valid in such regions. Those disturbed portions are designated D-regions, where n denotes discontinuity or disturbance. Typical structures in which D-region behavior dominates are brackets and deep beams. Figure 6.2 shows some typical D-regions. The regions between D-regions can be treated as B-regions. At disturbed or discontinuous regions of a structure such as comers, openings or concentrated loads and supports,plane sections do not remain plane, and the behavior is very different from that in B-regions. In such members the load carrying mechanism may be idealized as a truss made up of concrete compression struts and steel ties. Crushing of the concrete struts is one of the major failure modes for D-regions ~nd the ultimate load is very dependent on the compressive strength of concrete. Because. of transverse tension and cracking in the region of the strut, an effective concrete strength generally less than the cube strength, must be used in the design of the concrete strut.
Fig. 6.1 Possible load paths for beams
472
473
D-Region
D-Region
D-Region
A- At locations of concentrated loads D-Region
1
E- Beam column joint B- Near openings D-Region D-Region
c- Sudden variation in beam thickness D-Region
D-Region
F- Deep beam D- Tapered beam G- Short cantilever
Fig. 6.2 Typical D-regions
474
Fig~
6.2 Typical D-regions (contd.)
475
6.3 Components of the Strut- and -Tie Model
• •
The Strut-and-Tie model consists of: • • •
The strut-and-tie shown in Fig. 6.3 can fail in one of three ways:
Major diagonal compression diagonals (struts) Tension ties (or Ties) Truss nodes.
•
The tension tie could yield. One of the struts could crush when the stress in the strut exceeds the effective compressive strength of concrete. . A truss node could fail by being stressed .greater than the effectIVe compressive strength of concrete.
Since a tension failure of the steel will be more ductile than either a strut failure or a node failure, a deep beam should be proportioned so that the strength of the steel governs.
p Truss node
According to the Strut-and-Tie Model shown in Fig. 6.3, the shear strength can be calculated as: Q =Astrut f.ce sinB ................................. ·········(6.1) Compression strut
where A strut is the cross sectional area of the strut, f~e is the effective compressive strength of concrete and B is the angle of inclination of the strut.
force, T
Fig. 6.3 Strut-and-Tie model for a deep beam
In Fig. 6.3, the concentrated load, P, is resisted by two major inclined diagonal struts, shown by the light shaded areas. The horizontal component of the force in the strut is' equilibrated by a tension tie force, T. The three darker shaded areas represent truss nodes. These are wedges of concrete loaded on all sides except the side surfaces of the beam with equal compressive stress. The loads, reactions, struts, and ties in Fig. 6.3 are all laid out such that the centroid of each truss member and the line of action of all externally applied loads coincide at each joint.
Photo 6.2 A Cable-stayed bridge during construction
476
477
The validity of a Strut-and-Tie model for a given member depends on whether the model represents the true situation. Concrete beams can undergo a limited amount of redistribution of internal forces. If the chosen Strut-and-Tie model requires excessive deformation to reach the fully plastic state, it may fail prematurely. An example of an unsuitable model is given in Fig. 6.4 that shows a deep beam with two layers of longitudinal reinforcement. One layer is located at the bottom and the other at' mid-depth. A possible Strut-and-Tie model for this beam consists of two trusses, one utilizing the lower reinforcing steel as its tension tie, the other using the upper reinforcing steel. For an ideally plastic material, the capacity would be the sum of the shears transmitted by the two trusses Q1 + Q2. It is clear, however, that the upper layer of reinforcing steel has little effect on strength. When this beam is loaded, the bottom tie yields first. Large deformations are required before the upper tie can yield. Before these can fully develop, the lower truss will normally fail.
6.4 Design of the Struts In the design using Strut-and-Tie models, it is necessary to check that crushing of the compressive struts does not occur. The cross-sectional area of the compressive struts is highly dependent on the details at their ends.
6.4.1 Idealization of the Strut The most common types of struts utilized in design are: PRISMATIC STRUT
Struts could be idealized as prismatic compression members (prismatic struts) as shown by the straight line outlines of the struts in Fig. 6.3. it. TAPERED STRUT
If the effective compression strength at the two ends of the strut differs due to different bearing lengths (See Fig. 6.5), the strut is idealized as a uniformly tapered compression member (tapered strut).
p
~
///
/
'/
//
/
/
"', ,
, -, "
-
/ 1/
/
--
~
II
Truss node
.......
"" , "
Tapered
Mechanical Anchor
Mechanical Anchor
Fig. 6.5 Tapered strut. Fig. 6.4 Invalid Strut-and-Tie model
478
479
BO'ITLE-SHAPED STRUT p
Is a strut located in a part of a member where the width of the compressed concrete at mid-length of the strut can spread laterally. The curved solid outlines in Fig. 6. 6 approximate the boundaries of the bottle-shaped struts. A split cylinder test is an example of a bottle-shaped strut. The spread of the applied compression force in such a test leads to a transverse tension that splits the specimen. To simplify design, bottle-shaped struts are idealized either as prismatic or as uniformly tapered. Crack-control reinforcement is provided to resist the transverse tension. The amount of such reinforcement can be computed using the Strut-and-Tie model shown in Fig. 6.6 with the struts that represent the spread of the compression force acting at a slope of 1:2 to the axis of tJ.e applied compressive force. .
~
'"
j\ \
/ / /
Idealized
.'"
\
""
(a)
Bottle-shaped strut
\
Crack
Local strut
Width used to com ute strut area
Fig. 6.6 Bottle shaped strut:(a) bottle-shaped strut in a deep beam, ~b)cracking of a bottle~shaped strut; (c) strut-and-tie model of a bottle-shaped strut Photo 6.3 Double short cantilevers supporting a composite bridge 480
481
6.4.2 Strength of Un-reinforced Struts The compressive strength of an un-reinforced strut (Fe) shall be taken as the smaller value of the compressive strength at the two ends, given as: Fe = fed' Ae ................................................... (6.2) where Ae =cross-sectional area of the strut at the strut end under consideration fed
Strut
=the smaller of (a) and (b):
(a) The effective compressive strength of the concrete in the strut; I
(b) The effecti ve compressive strength of concrete in the nodal zone.
The compressive strength of concrete in the strut is given by: fed =0.67 f3s feu lYe ................................... (6.3)
(a) Struts in a beam web with inclined cracks parallel to struts
The strength coefficient, (0.67 !cJre), in Eq. 6.3 represents the cube concrete strength under sustained compression. The factor f3s is a factor that takes into account the stress conditions and the angle of cracking surrounding the strut. The strength coefficient The value of f3s is given in Table 6.1. (0.67 /3,. feu / Yc) represents the effective concrete strength of the strut. The material strength reduction factor Yc is taken 1.6.
Cracks
Strut
Table 6.1 Values of the Coefficient f3s Strut condition
A strut with constant cross-section along its length
f3s 1.0
(for example a strut equivalent to the rectangular stress block in a compression zone in a beam) Bottled-shape strut parallel to the direction of the cracks (Fig. 6.7a) provided that there are reinforcing bars normal to the
0.70 (b) Struts crossed by skew cracks
center-line of the strut to resist the transversal tensile force. Such force can be assumed spreading with inclination of 26 degrees to the centerline of the strut. Bottled-shape strut that is not parallel to the direction of the
0.60
Fig. 6.7 Types of struts
cracks (Fig. 6.7b). Struts in tensiop members or the tension flanges of members.
0.40
All other cases
0.60 482
483
If the value of f3. =0.70 specified in Table 6.1 is used, the axis of the strut shall be crossed by reinforcement proportioned to resist the transverse tensile force resulting from the compression force spreading in the strut as shown in Fig. 6.8. Otherwise, one has to use f3. =0.60.
The designer may use a local strut-and-tie model to compute the amount of transverse reinforcement needed in a given strut. In the American Concrete Institute Code (ACI 318) , for concrete strengths not exceeding 40 N/mm2, the requirement is considered to be satisfied if the axis of the strut being crossed by layers of reinforcement satisfies the following equation:
I
Asi sin Yi b Si
~
0.003 ................................. (6.4)
6.4.3 Strength of Reinforced Struts In order to increase the strength of the strut, it is permitted to reinforce it with compression reinforcement that satisfies the following requirements: •. The compression reinforcement should be placed within .the strut and parallel to its a x i s . ' . The reinforcement should be properly anchored. • satisfying the • The reinforcement should be enclosed in ties or spirals conditions applied to columns. An example of a deep beam with reinforced struts is given in Fig. 6.9. The strength of a reinforced strut is given by: .
Fc =Ac f cd +As
where Asi is the total area of reinforcement at spacing Si in a layer of reinforcement with bars at an angle Yi to the ax.is of the strut.
Where fed
=
0.67feu
f Y lys ................................ ··(6.5)
R p,
Ye Y. = 1.3 , Ye = 1.6, f3s is obtained from table 6.1, As is the area of the
reinforcing steel parallel to the direction of the strut and/yis the yield strength.
I
p
~ Strut
~ /
/
S2
Stirrups Reinforced strut
ain reinforcement
/
/
.. I
S1
:fie force, T
Fig. 6.8 Reinforcement crossing a strut. Fig. 6.9 Reinforced strut
484
485
6.5 Design of Ties
6.6 Design of Nodal Zones
6.5.1 Strength of the Tie
6.6.1 Types of Nodal Zones
The strength of the tie is calculated as Tu~ =Asfy
Irs ........................................... (6.7)
where Tud = design tension force. As = cross-sectional area of steel. /y =yield strength of steel. =1.15
The locations of the intersection of the truss members are called the nodes of the truss. They represent regions of multi-directionally stressed concrete or nodal zones of the Strut-and-Tie model. The compressive strength of concrete of the nodal zone depends of many factors, including the tensile straining from intersecting ties, confinement provided by compressive reactions and confinement provided by transverse reinforcement. To distinguish between the different straining and confinement conditions for nodal zones, it is helpful to identify these zones as follows:
r,
a) CCC - nodal zone bounded by compression struts only (hydrostatic The width of the ti~ is detennined to satisfy safety conditions for compressive stresses at nodal pomts for struts and ties meeting at that node. Such a width can approximately be taken not more than 70% of the width of the largest strut connected to the tie at the node.
6.5.2 Development Length of the Reinforcement The reinforcement in a tie should be developed with a length equal to ends of the tie as shown in Fig. 6.10.
node) b) CCT _ nodal zone bounded by compression struts and one tension tie c) CTT - nodal zone bounded by a compression strut and tension ties d) TTT - nodal zone bounded by tension ties only Figure 6.11 illustrates the different types of nodal zones.
at the
Lbd
,
C
\
I
,
I
)-----C
strut
(---- T I I
I I I
IC
C
~~ / e
C
I
(b) C-C-T Node
(a) C-C-C Node
T
--r---/.,.------------..
-Tie
T
I·
T
(d) T-T-T Node
(c) C-T-T Node
Fig. 6.10 Calculation of the development length at .nodal zone Fig. 6.11 Classification. of node~
486
487
6.6.2 Strength .of the Nodal Zones The compressive strength of a the nodal zone is given by ~n =Aen . fJn (0.67/eu lYe) ...................................... (6.6)
in which Acn = the area of the face of the nodal zone taken perpendicular to the direction of the strut. 'Yc = material strength reduction factor for concrete = 1.6. fJn = factor that takes into account the stress conditions at the nodal zone
In order to determine the dimensions of nodes subjected to tension and .compression (CCT or CIT), the height U of the tension tie can be calculated as follows: •
In case of using one row of bars without providing sufficient development length beyond the nodal zones (Fig. 6.13a): U
•
=0 ............. :.................................. (6.7a)
In case of using one row of bars and providing sufficient development length beyond the nodal zones for a distance not less than 2c, where c is the concrete cover (Fig. 6.13b): U
= ffJ+ 2c
........................................... (6.7b)
Where tj> is the bar diameter.
Table 6.2 Values of fJn Type of Node
fJn
C-C-C
1.0
C-C-T*
0.80
C-T-T orT-T-T
0.60
•
In case of using more than one row of bars (Fig. 6.13c) and providing sufficient development length beyond the nodal zones for a distance not less than 2c, where c is the concrete cover: U :;::rp+2c+(n-l)s .................................. (6.7c)
Where n is number of bars and s the center line distance between bars. strut
strut
* In C-C-T nodes, the value f3n = 1.0 can be utilized if the tie is extended through the node and is mechanically anchored as shown in Fig. 6.12 Tie
-;-
/.
a)U = 0
b)U =¢ +2c ::-...
>2c
>s/2
s
¢ c
-r
H
'B)
I
t
/
/
-r-
Tie
u
/
c) U =¢+2c +(n -l)s
Fig. 6.12 Mechanical anchorage of tie reinforcement 488
Fig. 6.13 The height (U) used to determine the dimensions of the node 489
Finally, Fig. 6.14-h shows a Strut-and-Tie model for a box girder bridge supported on a pier and a shallow founda~ion. !n spite of t~e fact that such a bridge structure can be easily analyzed usmg SImpler tools, the shown model gives some insight into the flow of forces.
6.7 Applications The choice of a Strut-and-Tie model is a m~or issue and different engineers may propose various models for the same application. Figure 6.14 presents some appliCations of the Strut-and Tie model for designing deep beams. Struts are indicated as dashed lines; solid lines represent ties. The struts and ties are positioned by considering the likely paths' of the loads to the supports and the orthogonal reinforcement pattern. The"' forces in the shuts and ties are detelmined by equilibrium. As long as the reSUlting model satisfies equilibrium, and the struts, ties and nodal zones satisfy the provisions previously discussed in his chapter, the structure should develop the ultimate strength required.
\ \
Figure 6.14-a shows a simply supported deep beam that supports two planted columns and contains two web openings. The locations of the openings do not interfere with shortest load path between the loads and the supports. Hence, a simple Strut-and -Tie model, similar to that developed in a solid deep beam, can be proposed. It should be noted that the existence of the openings might limit the width of the strut. Figure 6.14-b shows a simply supported deep beam that supports two planted columns and contains two web openings. The locations of the openings interfere with shortest load path between the loads and the supports. Hence, the vertical load of each column has to travel around the opening. Accordingly, a tie has to be located above the openings, together with the traditional one located at the bottom part of the beam. Figure 6.14-c shows a deep beam having an opening near the left-hand side support. The beam supports a planted column. The Strut-and-Tie model for such a beam is developed based on engineering judgment about how the force paths might flow around the opening. The model demonstrates that the main reinforcement of the beam shall follow the directions of the ties. The designer should provide light reinf9rcement mesh on both sides of the beam to control cracking and to enhance the performance of the struts. Figure 6. 14-d shows a deep beam that is bottom loaded through two hangers. A simplified Shut-and-Tie model that is suitable fur design is also shown. It is assumed that the bottom load is transferred to the beam by bond stresses between the vertical stirrups, that hang-up the load, and the concrete. Figures 6.14-e-f-g show Strut-and-Tie models for cantilever and continuous beams subjected to different loading conditions ..
[]\
..
...
a) Deep beam with symmetrical openings
/ /
I
/ /
..
...
0..
"-
0 ... ,
f
"\ \
\
I)
b) Deep beam with openings interfering with the shor~est load path. Fig. 6.14 Typical Strut-and-Tie applications. 491
490
~
_---
....
"..."\ "...
/
\
.
...
\ \
0\\
//0
f
\
"...
\ \
\
II
a) Deep beam with symmetrical openings
c) Deep beam with an eccentric opening
----/
L. I
I I
...
...
0..
f
"-
0 ...
~
/1-1'\ \
/
\
\
11
Fig. 6.14 Typical Strut-and-Tie applications. ~
I \ I \ \
/
t
b) Deep beam with openings interfering with the shortest load path.
L -_ _ _ _ _ _ _ _
/
I I
--'-
hanger
hanger
d) Bottom loaded deep beam Fig. 6.14 Typica~ Strut-and-Tie applications (cont.)
_ _ _ _ _ _ _ _ _- - - - - - .
492
493
Example 6.1
I
/
A transfer girder supports two planted columns, each having a factored load of 1500 kN as shown in the figure given below. The material properties are leu =30N Imm 2 and Iy = 400N Imm 2 • Design the beam using the Strut-andTie method presented in the ECP 203.
/ /
1500 kN
1500kN
./
-
I-r-
-r-
2200
1900
I I
1900
i
i I I I I I I I I I I I I
--e) Deep beam having a cantilever loaded at the edge
H 500
H
H
450
450
6000mm
/
/
fI
/
\
/
H 450
/
\ \
.. .
I I I I I I I I I I I I
_W-L
-Li-
/
I I
/ \
/
If
. Step 1: Check bearing capacity at loading points and at supports The area of the cross section of the column is (450 mm x 500 mm). The bearing stresses at points loading and at supports are:
I = Pu = 1500xlOOO = 6.66 N I mm 2 b
Ae
450 x 500
1) Deep beam having a cantilever with two concentrated loads
The nodal zones beneath the loading locations are (C-C-C) Nodes. The effective compressive strength of such type of nodes (~n=1.0) is limited to:
Fig. 6.14 Typical Strut-and-Tie applications (cont.)
494
led
=0.67xfJn
X
/eu =0.67xl.Ox 30 =12.56 N Imm 2 Ye
1.6
495
The nodal zone over the support location is a compression-tension (C-C-T) Node. The effective compressive strength of this node (Pn=0.80) is limited to:
I cd
~ .Be
= 0.67 x Pnx lcu = 0.67 x 0.80 x 30 = lO.05 N I mm 2 Yc . 1.6
Since the applied bearing stresses (6.66 N/mm2) are less than the limiting values at the loading locations and at the supports, the area of contact is considered adequate
The horizontal position of nodes A, B is easy to determine, but the vertical position of these nodes must be calculated. To fully utilize the beam, the positions of these nodes have to be as close to the top of the beam. In other words, the lever arm (jd) of the force couple must be set to the maximum and this means that the width of strut BC, wS , and the width of the tie AD, WI, must be minimum.
i
1900
I I I I I
2200
1900
.. . ~;J 1500
I
i I
/.
.. ..
.
..~~- - F:S: -- -~, , .. Fu,AD
!
,,
,,
,
I I I I I I
(e''''~ t
6000mm
496
~.AD
must reach the node capacity to
Yc
Since W,
~.BC
-
= Fu •AD , it can be easily proven that:
=1.25w s
The distance between the compression and the tension force jd equals: I . =t -wsw ---= t -W-s - 1.25 W Jd 2 2 2 2
=t -1. 125 W
s
s
The moment of the forces about point A gives: Pu xLx
= ~.BC xjd
Pu xLx
= 0.67 x fJ. x lcu Yc
bw s (t-1.125w.)
30 1500 (1000) x1900 = 0.67x1.0x- 500w s (2200-1.125 W s) 1.6
1500
I
!
To minimize WI. the force in the tie anchor the tie as follows:
.
A simple Strut-and-Tie model is shown in the figure below. It consists of a direct strut AB (or CD) from the applied load to the support. To equilibrate the truss, tie AD and strut BC needs to be. established as shown in figure. From equilibrium:
I
= 0.67 x fJ. x lcu bw s where Ps=1.0 for prismatic struts Yc
Fu AD = 0.67xps xlcu bw I' where Ps=0.80 for (C-C-T) node
Step 2: Establish the Strut-and-Tie model
1500kN
To minimize ws, strut force BC, Fu •BC must equal its capacity as follows:
I 1500
The previous equation is quadratic in Ws. Solving for Ws gives: W s
= 234.3mm
WI
= 1.25 W s
Choose
=1:25 x 234.3 = 292.9mm W s
= 250 mm and
w, = 300 mm
The depth of the deep beam equals: W 300 . d =t - - I = 2200--= 2050mm 2 2
The distance jd equals: . wsw I 250 300 Jd =t ----=2200----=1925mm 2 2 2 ' 2
497
Step 4: Design the nodal zones and check the anchorages The 90° standard hook is used to anchor tie AD. The required anchorage is given by:
I
i
Lx=1900
_af37]/ y 4/
L
l rs
rp
d -
bu
Ld can also be directly obtained from the tables provided in the ECP 203. Ld = 50 for!cu =30 N/mm2 FU,AD
1500
I
-7
Ld = 50 = 50 X 25 = 1250 mm
The Egyptian code requires measuring the development length from the point where the centroid of the tie reinforcement leaves the nodal zone and enters the span. However, for simplicity, it can be measured from the end of the column. The distance from the column to the end of the beam is about 400 mm as shown in figure below and the bent part is about 850 mm.
The force in the strut and the tie equals: F
= Pu xLx = 1500 x1900 = 1480,5 kN
jd
u,BC
1925
~I
The angle of the strut AB equals:
0= tan-I (jd) = tan-I (1925) = 45.37° Lx 1900 F u,AB
r;;
=~= 1500x1000 =2107.6 kN sinO
sin45.37
Step 3: Select the tie reinforcement
4 cP25
5 cP25
Step 5: Check the diagonal struts
The tie reinforcement can be obtained as follows: ~,AD =As
X/
The force in the diagonal strut AB equals:
y Irs
u,AB
1480.5 x 1000 =As x400/1.15 As = 4256.5 mm
=~= 1500x1000 =2107.6 kN
F
~,AD = ~,BC = 1480.5 kN
sin 45.37
Referring to the figure below, the width at the top of the strut is given by:
2
Choose 9 25 mm (2 layers)
sinO
'--7
498
W st
=csinO+ws cosO
W
= 450sin 45.37 + 250 cos 45.37 = 495.89 mm
sl
499
1500
1500kN 450
2200
1900
1900
B
1500
6000mm
1500
Step 6: Provide minimum web reinforcement The minimum vertical web reinforcement required by the code is given by:
c=450
A,'V = 0.0025 b s
The minimum horizontal shear reinforcement required by the code is given by: The width at the bottom of the strut is given by:
AVh
= 0.0015 b s
W sb
= c sin 8 +W t cos 8
Choose s =200 mm
W sb
= 450sin 45.37 + 300 cos 45.37 = 531.01 mm
Asv = 0.0025 500 (300) = 250 mm 2
Ws
is taken as the smaller of Wsb and Wst
The Strut AB is expected to be a bottle-shaped strut. By assuming that sufficient crack control reinforcement is used to resist the bursting force in the strut (l3s=0.7), the capacity of strut AB is limited to: fcu
F" ,AB
= 0.67 x fJs x
FU,AB
30 =O.67xO.7x- 500x495.89 = 2180.36 kN 1.6
Yc
b
For one leg, Asv = 125 mm 2 ----+ A,./or 14 = 154 mm 2 Choose
@
200 mm
=0.0015b (300)=mm
2
For one leg, ASh = 150mm 2 ----+ As for 10 = 78.5 mm 2
Ws
Choose
@
200 mm
The arrangement of the reinforcement is shown in the following figure.
Because this is higher than the required force, strut AB (or CD) is considered adequate.
500
501
r
Example 6.2
WWOOG@V~¢P
'I
. wwooc:c: ~
'§, C')
EV E
E E
0 0
0 0
@J
@J
I:'!
I~
E
E o ~
<
@J
~~IIJ!
Give a complete design for the bracket shown in figure using the Strut-and-Tie method presented in the ECP 203 according to the following data:
~ cl
feu =30N Imm 2 andfy =400N Imm
00
tlllO
~
"
0
:i
=240 Nu = 56
Qu
Factored vertical load
"
I:'!
~
2
I:'! I:'!
Factored horizontal load
~
leN leN
Pu=1450 leN
<
o
Qu=240 leN 200
.., == ....=
I
!:5 l"r
200
Nu =56 leN
Qu=240 leN
1..-==--. --01.....- Nu =56 leN
"Q
....
= e
I
E E 0
<0
10 I:'!
I
LO
'§,
'§,
"
10
I:'!
0 0
I:'! I:'!
'§, en f-
LO
I:'!
,..
oS ,S
o
:8 -'o
o«)
~
.-I
'§,
I.C
C')
~ f;;r;l
....ei> ~
o o
0)
400 <
~I
-I-
-I-
I-
E
-E
500mm·
400
<
I
-'--
I I Colurim cross-section
502
503
I
1~
Step 1: Determine the bearing plate dimensions
F",BC
=fed
The nodal zone underneath the bearing plate is a compression-tension (C-C-T) node (130=0.80). The effective compressive strength of this node is limited to:
F",BC
1450 = 240 + -2- = 965 kN
b
W s
f 30 . fed =0.67xfJn x--E!...=0.67xO.8x-=1O.05N Imm 2 Ye 1.6
The nodal zone B is an all compression (C-C-C) node and strut CB is of prismatic type, the effective compressive strength/cdis given by:
A = S1... = 240 x 1000 = 23880 mm 2
fed
e
= 0.67 x fJn x feu =0.67xl.Ox 30 = 12.56N Imm 2 Ye
10.05
fed
Choose a (300 mm x 150mm) bearing plate (Ac=45000 mm 2).
965x1000 = 12.56 x450xw s Ws
I
125-1
1150 I
=170.7 mm
Bearing plate (300 mm x 150 mm)
400
1.6
725
725
Resultant line ,
,,
125
D'
" D
, ,, 200 ,
xz=11.67-1 '_,--0-1
a
:B
240
-f-
56
a a«)
, ,,
56
a-Or)
... I I I
t ...t' I I I I I I
Step 2: Establish the Strut-and-Tie model The figure below shows the geometry of the Strut-and-Tie model. The location of the tie AA' is assumed to be 50 rom from the top of the corbel. d = 650 - 50 = 600 mm
As shown in the figure, 'the column axial load, Pu is resolved into two equal loads acting in line with strut CB. The location of the centerline of strut CB can be found by calculating its width, ws. This width can be obtained from:
504
505
I
I
,
A'
The corbel is subjected to a vertical force of a value 240 kN and a horizontal force of a value 56 kN. The resultant of these forces shall be used in establishing the Strut-and-Tie model. The direction of the resultant can be obtained from the triangle of forces.
Step 4: Select the tie reinforcement F",AA' =As xfy Iys F",AA' = 174.8 kN
82
= tan-1 (
56 ) 240
= 13.130
174.8 X 1000 = As x400/1.15 I I I
I
Asmin = 0.03 fc.u bd fy
0
~
= 0.03 X
30 x450x600 = 607.5mm 400.
As = 678mm 2
Choose 6 12 mm
Step 5: Design the nodal zones and check the anchorages
56 The distance X2 form the concentrated load to the node A equals:
x2
The width Ws of the nodal zone B was determined to be 170.7 mm (refer to Step 2). Therefore, only nodal zone A is checked in this section.
= 50 tan 13.13 = l1.66mm
Tb satisfy the stress limit of nodal zone A, the tie reinforcement must engage an effective depth of concrete WI that can be obtained from: fcu FuAA ' =0.67xPn x bW t ---+---+Pn =0.80 , Yc
This fixes the geometry ofthe Strut-and-Tie model.
Step 3: Determine the required truss forces 8
= tan-1(
FAB
600 ) 200+ 11.67 + 170.7/2
=~ . 8 = sm
2
= 63.66
0
. . -240 6 66 -- - 267.8 kN .......................................... (compressIOn) sm 3.
30 174.8 x 1000 = 0.67xO.8x- 450 W t ---7 WI = 38.65 mm 1.6 As shown in figure, this limit is easily satisfied because the nodal zone available is 2x50=100 mm.
FAA' = FAB cos8+ N u = 267.8 cos63.66 +56 = 174.82 kN ................. (tension)
Step 6: Check the struts
FBB , = FAB sin 8 = 267.8cos 63.66 = -118.8 kN ......................... (compression)
Step 6.1: Strut AS
The following table summarizes the forces in all members. Note that positive sign indicates tension and negative sign indicates compression.
Strut AB shall be checked based on the sizes determined by nodal zones A and B. Other struts shall be checked by computing the strut widths and verifying whether they will fit within the space available
Member
AA'
BB'
AB
CB
BD
F;,s =- 0.67 x Ps x Force (kN)
174.8
-267.8
-118.8
-965.0
-725.0 Wst
fcu
Yc
b
W
sl
is taken as the smaller width at the two ends of the strut as shown in figure.
The width at the bottom of the strut can be accurately computed using AutoCAD program as shown in figure below or approximately as follows: 506
507
W SI =ws
sinO
W
sl
= 170 sin 63.33
~
W
sl
= 152.98mm
Strut AB is expected to be a bottle-shaped strut. By assuming that sufficient crack control reinforcement is used to resist bursting force in the strut (138=0.7), the capacity of strut AB is limited to '
F"s
30 = 0.67 xO.7 x 1.6 450x152.98 = 605.38 kN
Since the node strength FilS is higher than the required force to the table in step 3), strut AB is considered adequate.
D
FuAB
Step 6.2: Strut BD Fu BD
.
fcu
= 0.67 x fJ" x
Yc
b
W,. BD
'
13s=1.0 (inside the column zone) F.,BD
= 725.0 x 1000=0.67 x1.0x ~.~ 450 W.,BD
ws,BD
= 128.24mm
(=267.8, refer
'
D'
Since the required width for strut CB is less than the available for the node (170.3 mm), the design is considered adequate.
Step 6.3: Strut BB' Fu BB
= 0.67 x fl,. x
Fu,BD
=
,
100mmI
W s,BB'
fcu
b W.
Yc'
BB
---+---+---+13s=1.0
118.8X1000=0.67Xl.OX~.~
450w s,BB'
= 21 mm ---+---+Choose 50 mm width for strut BB'
Step 7: Calculate the minimum reinforcement Step 7.1: Vertical reinforcement Assume that the spacing of the vertical stirrups is 200 mm. ASI
I I I~
IU I ....
170.3
15 ICZl
§ 0
I(')
I
I - I
fAl
UI
..1 51 CZlI
=Pminb
S
= O.4xbxs = 0.4 x300x200=100mm 2 fy 240
Choose vertical stirrups with diameter =8 mm (two branches) spaced at 200 mm The available area =50 x 2 = 100 mm2 (O.K.)
I
J
C
C'
Dimensions of the Strut-and-Tie model components
508
509
Example 6.3
Step 7.2: Horizontal reinforcement Ah
= (As
An
N =__ u_=
Design and give complete reinforcement detailing for a pile cap that constitutes a part of a deep foundations system using the Strut-and-Tie method. Design data:
-An)
i y Irs
56x103 =161.0 mm 2 400/1.15
Ah =0.50(A,. -An) =0.50(502-161) = 170.5 mm 2
Choose 4 closed stirrups with diameter = 10 mm (two branches) Ail =78.5x2x4 =628 mm > 170.5 mm (O.K.) 2
2
200mm
!cu h
. d 600 A v g .spacmg = - - = - - = 200 mm -7o.k
n -1
@
Column dimensions Unfactored dead column load Unfactored dead column load Pile diameter Pile working load
4-1
=750
mrnX 750 mrn
= 2200 kN = 1100kN =500mm =750 kN 2 =30N/mm = 360 N/mm2
Solution 6
12
Step 1: Arrangement of piles The total loads acing on the pile cap are given by: P =PDL +PLL = 2200+1100 = 3300kN
The required number of piles is given by:
n=
1.05xP
1.05 x 3300 =. 462 pIes '1 750
Choose 5 piles. The arrangement is shown in the following figure. Assume that the thickness of the pile cap is 1200 mm.
IlL- _--.J!
The ultimate applied load is given by: Pu =1.4 PDL + 1.6 PLL = 1.4 x 2200+ 1.6x1100 =4840 kN
p
. = 4840 =968 kN 5
UlpIle
Reinforcement details of the corbel
510 .
511
Step 2: Establish the Strut-and-Tie model
H~PU=4840kN
The column load is divided into 5 equal loads of 968 kN each. Each of these loads is connected to the center of one pile through an inclined strut as shown in the figure.
,.....--
968
~
428.~
~
'~168
e
// //
!
I I I I
I I I I
/
I I I I
Fl /
/
/
I
,I,.
F2'
1250
1250
I
i 625
\ , ,
"" Fl "" "" ""
I
I
/
c 968t
/
,
/ / .:~~
3750
""
1 \ "
/
/
625 i
I \
, I , I , I
/
I
J" "
968,; ,; 8' -; ,__ ; :...t '..,; F 2 " "
/
I
968
a /
968
/
968
The location of each load at the column cross-section should be determined in order to establish the Strut-and-Tie model. Such locations are determined based on satisfying the stress limits of the struts. The figure given below shows the cross-section of the column divided into 5 areas, each of them is connected to one strut. The area Al of the vertical strut (Bottle -shaped strut) at the top node can be found from: 3
! 625 !
I
0.67xO.7x30j1.6
!
! 1250
968 X 10 = ------;---
1250! 625
3750
Pile cap arrangement
Accordingly, the area Az of the intersection of the inclined strut with the top node (with the cross-section of the column) is found from: 2
A2
(700
2 -
332
)
= 113069 mm 2
4
512
110078 mm 2::::: (332 mm x 332 mm)
513
Step 3: Calculate the forces Assume a clear concrete cover of 70 mm, and that the distance from the centerline of the bottom tie to the bottom concrete fibers is 150 mm. Assume that the thickness of the top horizontal s!ruts is 300 mm. Hence, the distance between the bottom tie and top horizontal strut equals: ec =1200-150-30012=900 mm
ab =ad = 1250-428.24/2 = 1035.88 mm 2
ac = .J1035.882 + 1035.88 = 1465mm
I·
750
900) - ) =tan -\ ( - = 31 .56° e = tan -\ (ec ac 1465
·1
/
The center of gravity (C.G.) of the area A2 can be easily obtained as shown in figure (calculations not shown).
c
= 160.88mm
Xc
The force in the strut FJ
968 = 1849 kN sin 31.56
The force in the tie is obtained as follows: F(1C = 1<; cose = 1849xcos31.56 =1575.6 kN
=700-2xI60.88=428.24mm
It is assumed that the center-line of the inclined strut connects the C.G. of the area A2 and the C.G. of the pile.
F,ie = F(1C cos45 = 1575.6 cos 45= 1114kN (compressi on)
Similarly, F2=1114 kN c=160.88
I
xc=428.24
. I~
"
'j'
I
..
o
Step 4: Select the tie reinforcement
160.88
The tie reinforcement can be obtained from the following equation:
oc
1114x1000=As x360/1.15 As
Irl
{'-
= 3559 mm
2
Choose 8 25 mm in 2 layers
-+
As
= 3927 mm 2
Provide AsmilZ at locations other than the ties.
.•. I
._._c.d _._.
A
A2
. s,mm
750
A
fy
(d
= 1200 -100 = 1100 mm )
. = 0.6 x 1000 x 1100 = 1833 mm 2 1m' --t S,mm
514
= 0.6 b d 360
515
Use 8 181m'
Step 5: Check the struts
At top node
Step 5.1: Strut F1
Required area of the strut at the top node
At bottom node
F;, = 0.67 x f3s xfeu
w, =2c +r/J Since it has been assumed earlier that the distance from C.G. of the tie to bottom outermost concrete fibers is 150 mm -+ Wt = 300 mm.
=c sine +W, cose
W sb
= 500sin31.56 +300 cos31.56 = 517.3 mm
Fes = 0.67 x /3,. x
W sb
= 245337.9 mm
2
Assume that the diagonal struts are square in shape. The side dimensions of the struts ( h2) can be obtained as follows:
The capacity of the inclined strut is given by: feu
30 1849.2xlOOO =0.67xO.60x- AcsT 1.6 ACST
W sb
A = 0.60
AcsT
Ye
h2
= .J245337.9 = 495.32mm
. (b is the pile diameter)
xb
Ye
Step 5.2: Strut F2
for bottle-shaped strut inclined with the cracks without special reinforcement
30 Fcs = 0.67xO.60x- x500x517.3 = 1949.6 kN 1.6 Because this is higher than the required force (1849 kN), strut Fl is considered adequate. 1849
The top node is the node where the inclined struts, the horizontal top struts and the top load meet. At this node, the horizontal area A2 and the inclined area of the inclined strut form parts of the nodes. To calculate the thickness hI, an average width (h3) for the area A2 is used. Thus,
h = A2 = 113069 = 228.2 mm 3 h2 495.32 h2 = h3 sin
e + hi
cos
e
495.3 = 228.2 sin 31.56 + hi cos 31.56 hi
= 441mm
fe
= F;, cos e = 1849xlOOOxcos 31.56 =7.2N Imm 2 hi xh 2 441x495.32
w,=300mm A pile
2 feu 30 =12.56 N Imm f en =0.67x PRn x Y =0.67x1.0x 1.6 e
(1311 =1.0 for (C-C-C) node) .
Since fe is less than fell' the design is consider adequate.
516
517
r j
-
#12 @ 250 mm
r-'-----,.---
:
~I
:
.. . ...;=..=~
.~..:= ..~~ ·;:··~3~:7~...:;: [~~.~.~=..;:::; IV I Plain concrett~ I dX 8iY'25 I
,
]
I
I I
F,COS
e
_
I
I
'--~ __
I
{\
_
I I ~L-_
I
__
_
8# 181m
I I _ L - '---
j1
r'\
8# 181 m
I 8# 25
J 8# 181 m
J Step 6: Reinforcement arrangement Section 6-7-1-4 of the ECP 203 states that when the Strut-and-Tie model is used for designing pile caps, the tie reinforcement must be distributed in a distance greater than three times the pile diameter if the distance between the centerlines of the piles is more than 3D where D is the pile diameter. In this example, the distance between the centerlines of the piles is less than 3D. The reinforcement of the tie is arranged such that the distance between the bars is 100 mm (the minimum accepted distance).
Reinforcement Details
Other locations should .be reinforced with the minimum reinforcement calculated in Step 5. 518
519
7 INTRODUCTION TO PRESTRESSED CONCRETE
Photo 7.1 Prestressed concrete girder during grouting
7.1 Introduction The idea of 'prestressing was introduced to overcome the main disadvantage of concrete which is the low tensile strength. Introducing compressive longitudinal force, called prestressing, prevents the cracks from developing by reducing or even eliminating the tensile stresses at critical sections. Thus, prestressing is a technique of introducing compressive stresses of a pre-determined magnitude 520
into a structural member to improve its behavior. Therefore, all sections can reach the full capacity of concrete in compression. Although prestressed concrete has many benefits, it requires more attention to specific design considerations that are not usually considered in construction of ordinary reinforced concrete. . Prestressed concrete is used in buildings, towers, tanks, underground structures, and bridges. The wide spread use of prestressing is mainly due to the new technology of developing high strength steel or fiber reinforced plastics (FRP) and the accumulated knowledge of computing the short and long-tenn losses. Prestressing significantly reduce the dead weight of flexural members. The small span-to-depth ratio accompanied by short construction time makes prestressed concrete very attractive solution as a construction material. The idea of prestressed concrete can be traced back to 1872, when P.H Jackson, an engineer from California, USA, developed a prestressing system that used a tie rod to build beams and arches from individual blocks. Early attempts of prestressing were not successful because of prestressing losses over time. In 1920s, the concept of circular prestressing was introduced but with a little progress because of the unavailability of high strength material that can compensate the long-tenn losses. Linear prestressing continued to develop in Europe especially in France through the work of Eugene Freyssinet. In 1928 he proposed the use of high strength steel to overcome the losses. P.W. Abeles of England introduced the concept of partial prestressing. The work of T. Y. Lin of developing the load-balancing technique simplifies the design process particularly in indeterminate structures. Since 1950s, the number of buildings and bridges constructed of prestressed concrete has grown enonnously.
7.2 Systems of Prestressing Prestressed members are classified into two main groups; pre-tensioned and post-tensioned. The member is called pre-tensioned, if the steel is stressed before casting the concrete. The member is called post-tensioned, if the steel is stressed after hardening of the concrete.
Photo 7.2 Sample of prestressed concrete bridges 521
522
7.2.1 Pretensioned Concrete
7.2.2 Post-tensioned Concrete
Figure 7.1 illustrates the procedure for pre-tensioning a concrete member. Such a procedure can be summarized as follows: 1- The prestressing tendons are initially tensioned between fixed· rigid walls and anchored. 2- With the formwork in place, the concrete is cast around the stressed steel tendons and cured. 3- When the concrete has reached its required strength, the wires are cut (or released from the rigid walls). 4- As the tendons attempt to contract, the concrete is compressed. Prestress is transmitted through bond between the steel and the concrete.
The procedure for post-tensioning a concrete member is shown in Fig. 7.2.
Pretensioned concrete members are often precast in pre-tensioning yards that are usually long enough to accommodate many identical units simultaneously. Anchorage
Abutment
1. With the formwork in position, the concrete is cast around the hollow ducts, which are fixed to any desired profile. 2. The steel tendons are usually in place, unstressed in the ducts during the concrete pour, or alternatively may be threaded through the ducts later. 3. When the concrete has reached its required strength, the tendons are tensioned. Tendons may be stressed from one end with the other end anchored or may be stressed from both ends. 4. The tendons are anchored at each stressing end. In post-tensioning, the concrete is compressed. during the stressing operation and the prestressing is maintained after the tendons are anchored by bearing of the end plates onto concrete. The ducts containing the tendons may be filled with grout under pressure. In this way, tendons are bonded to the concrete and are more efficient in controlling the cracks and providing ultimate strength. Bonded tendons are also less likely to corrode. It should be mentioned that most in-situ prestressed concrete is post-tensioned.
Stressed tendons
a) Stressing the tendons before pouring the concrete Concrete is poured
Post-tensioning is also used for segmental construction of large-span bridge girders.
x;; ... ~ (a) Concrete cast and cured
.
b) The concrete is poured over the stressed tendons (b) Tendons stressed and prestress transferred Wires are cut
(c) Tendons anchored and grouted
c) The wires are cut and the prestressing force is transferred to concrete Fig. 7.1 A Pre-tensioned beam during manufacturing 523
Fig. 7.2 A post-tensioned beam 524
7.3 General Design Principle
7.4 Materials
Flexural stresses in prestressed members are the result of internal prestress' . t i d ' cable configuration (P. e), and mg forc e P, th e l~ erna moment ue to eccentnc the extern.al apphed mome~ts (M). The prestressing force results in stresses that are OPP.oslte to those resu~tmg from the e~ternal loads. The entire section is mainly s~bJ~cte? to compresslOn stresses and IS free from cracks. Fig. 7.3 illustrates the dIstributIOn of the stresses at mid-span. It is clear that the tensile stresses that result fr~m the applied loads are eliminated by the compressive stresses due to prestressmg
7.4.1 Concrete The Egyptian Code ECP 203 presents an idealization for the stress-strain curve of concrete in compression. The initial part of the curve is a parabolic curve up to a strain of 0.002 and the second part is a straight horizontal line up to a strain of 0.003, as shown in Fig. 7.4. Referring to Fig. 7.4, the equation of the concrete stress (fc) in terms of the concrete strain (Ec) can be expressed as:
< 0.002
for
Ce
for
0.002 ~ c e
..................... (7.1)
wkNlm'
_.-._._.-.-._.-.-.-._.-._._._._._.-._.-._._._.-.
P-~~=========================t~p~ I·
L
h were
*
1.e=
0.003
0.67 feu
Ye
To take the full advantages of prestressed concrete, concrete with high compressive strength is usually used. The ECP 203 specifies the concrete grade that should be used in prestressed concrete as shown in Table 7.1
·1
a- Loading
e
~
Table 7.1 Concrete compressive strength used in prestressed concrete
_E A
pxe
(N/mm 2)
M
+-Zwp
I Concrete grade I 30
Z/oP
135
145
150
155
160
.9.:~? fc;/.Jc_ --------------':";--:,; -; .;-- .....,-----i
_E A Beam
prestressing
_pxe Zim/
eccentricity
M
resultant
+Zbo/
external loads
resultant
b -Stresses Fig 7.3 Distribution of stresses in a prestressed beam
o
0.001
0.002
Concrete strain
0.003
Ec
Fig 7.4 ECP 203 idealized stress-strain curve for concrete 525
526
The advantages of using high-strength concrete in prestressed concrete construction can be summarized in the following points: 1.
Due to its speed in gaining strength, the shattering can be removed faster reducing time and cost.
2.
It minimizes losses in prestressing force by reducing creep, elastic shortening and shrinkage.
3.
It reduces the size and weight of the member.
4.
It reduces the required area for shear reinforcement.
5.
It produces the high bond strength required to anchor the strands used in pre-tensioned construction.
7.4.2 Non-prestressing Reinforcement The behavior of the non-prestressing steel reinforcement is idealized by the Egyptian code as an elasto-plastic material as shown in Fig 7.5. The reinforcing steel stress can be calculated using Eq. 7.2.
Is Is
= Es xEs = Iy Iys
when Es
7.4.3 Prestressing Reinforcement Prestressing reinforcement is available in different forms such as cold drawn wires, cables, and alloyed steel bars. The most common type of prestressing reinforcement is the seven wire strands cable as shown in Fig. 7.6. The ultimate tensile stnmgth of these cables is several times that of non-prestressing reinforcement. For example, the ultimate strength· bf wires and cables ranges from 1700-1900 N/mm2 (about 4-5 times that of high grade steel). This high strength is attributed to adding alloying elements (manganese and carbon), and by the use of heat treating and tempering. The favorable high tensile strength is accompanied by a loss of ductility and toughness. Therefore steel reinforcement with yield point above 1900 N/mm2 is not commonly used because of their extremely brittle nature. . . A typical stress-strain relation for prestressing reinforcement is shown in Fig. 7.6. It is clear that the prestressing steels lack a sharply defined yield point. Therefore, most codes including the ECP 203, specifies the yielding point as the stress associated with a 1% strain. For high strength bars, the yield strength is frequently specified as the stress associated with the intersection of the curve and a line parallel to the initial slope starting at strain of 0.002. The yield stress Ipy for stress relieved steel equals to approximately 85% of/pu and equals to 90% of/Pll for low relaxation steel.
The modulus of elasticity Eps can be taken as 200 GPa (200,000 N/mm2) for bars and wires and 180 GPa (180,000 N/mm2) for strands.
Iylys --
Strand or wires
I:
<,.!?,
en
Ii
t:Il
~ CI)
Es=200,OOO N/mm2
ty/ys
I I I I I I
J-~
~
____-/Pll
en
I I I I I
t/ys
compression
tension
I I I I
til
~
High-strength bars
CI)
Strain, ts
U
I
t--
-/ylrs 0.002
Fig 7.5 Idealized stress-strain curve for non-prestressed steel 527
0.01
Strain, Cps
Fig. 7.6 Stress-Strain curve for prestressing reinforcement 528
7.5 Losses in Prestressed Members
~
7.5.1 "Introduction The applied prestressing force after jacking undergoes a number of reductions. Some of these reductions occur immediately and others occur over a period of time. Therefore it is important to establish the level of prestressing at each loading stage as shown in the diagram below. Following the transfer of force from the jack to the member, a loss in tendon stress ranging from 10-15% of the initial force occurs.
tendon
(a) 7-wire monostrand tendon
(b) Multi-strand tendon tendon
Prestressed losses can be categorized in two groups. Immediate losses: These are the losses "that occur during fabrication, including elastic shorteningLlfpe' anchorage loss LlfpA and frictional losses Llfpj. Time-deponent losses: These are the losses that increase over time, including creep Llfper' shrinkage Llfpsh ' and steel relaxation LlfpR .
Immediate losses --------------~) Jacking force (c) single bar tender
Time-dependent losses
Pi
--------------~)
Prestressing force immediately after transfer
(d) Multi-wire tendon
Pe
Final or effective prestressing force
sheath
strand
Some types of these losses occur only in post-tensioned members. An example of such losses is the friction losses that develop between the tendon and the concrete at the time of jacking. The following is a summary for the losses that need to be considered for each type. Pretensioned members
wed'ge ancborhead
LlfpT
= Llfpe + Llfpsh + Npcr + LlfpR
Post-tensioned members
(e) Multi-wire tendon
Fig.7.6 Prestressing tendons (cont.)
529
530
.......................•...... (7.3)
7.5.2 Anchorage Slip Losses (A)
where NpA
= anchorage slip losses
J1fpe
= Elastic shortening losses
Npw
= wobble friction losses
N
= curvature friction losses
Pf
J1fpsh
= shrinkage losses
J1fpcr
= creep losses
NpR
= steel relaxation losses
At transfer in post-tension construction, when the jack is released, a small amount of tendon shortening occurs because of the anchorage fitting and movement of the wedges. The magnitude of this slip is function of the anchorage systeni and specified by the manufacturer. It usually varies from 2-6 mm. From Hook's law, the loss of stress in the cable AhA due to slippage is given by: J1fpA
In the following sections, each type of losses is briefly discussed, and step by step examples for losses calculations are given.
=~Ep L
................................................ (7.5)
where J1A = magnitude of slip L = tendon length (the horizontal distance can be used) Ep = modulus of elasticity of the prestressing steel The loss in prestressing steel stress due anchorage slip is inversely proportional to the length of the cable. Hence, the loss of stress due to slippage decreases as the length of the cable increases. At, transfer, if the tendon can be stressed by additional increment of length equal to the predicted anchorage slip without overstressing the cable, the loss in stress due to slippage can be eliminated.
Photo 7.3 Prestressed concrete girders during construction Photo 7.4 Prestressing tendons at the anchorage plate 531
532
7.5.3 Elastic Shortening Losses(e) When the prestressing force is transferred to the concrete, the concrete shorten and part of ,the prestressing is lost. To establish the loss of tendon stress due to elastic shortening, we shall consider the defonnations of pre-tensioned member stressed by a tendon at the centroid of the beam (Fig, 7.8). Since the concrete and the tendon are fully bonded, the strain experienced by concrete must equal to that in the prestressing steel. This compatibility of strain can be expressed as:
Eei = I1E,. .............................................. (7.6) where &ci is the concrete strain and I1Es is the reduction in steel strain due to elastic shortening. Applying Hook's law to the previous equation gives: fei
For post-tensioned members, the calculations of the elastic shortening losses is more complicated because the losses vary with the greatest losses occurring in the first strand stressed and the least losses occurring in the last strand stressed. For this reason the ECP 203 requires that for post-tensioned members to use only half the value calculated for pre-tensioned members as follows: 111'pe !l
1 Ep
=--f. (forpost-tensionedmembers) .......... (7.1O) 2E. PCI
CI
This type of losses equals to zero if all tendons are jacked simultaneously because the jack that elongates the tendon simultaneously compress the concrete and the elastic shortening takes place before the tendon is anchored.
I1fpe
- = - .......................................... (7.7)
Eei Ep where!ci is the concrete strain at the centroid of the tendons, Ed is the concrete modulus of elasticity at the time of transfer, and L1/pe is the loss in prestressing force as a result of elastic shortening of the beam. Rearranging, Eq. 7.7 gives:
Ep I1fpe = -fpc; ............................................... (7.8) Eei If eccentric tendon is used, the eccentricity of the tendon and beam self-weight should be taken into account. The stress in concrete at the level of prestressing steel is given by:
P;
fei = - - A
Pxexe Mow Xe + I I
................................"'. (7.9) .
tendon
I Pi
l
r
.... "1.
L
I
7.5.4 Wobble Friction Losses (W) This type of losses exists only in post-tensioned members due to the friction between the tendons and the surrounding ducts. When the ducts are positioned in fonns, some degree of misalignment is unavoidable because of workmanship. Actually, it is impossible to have a perfectly straight duct in posttensioned construction, and the result is friction. Fig. 7.9 shows· the misalignment in a duct for a straight tendon. These deviations occur both in elevation and in plan. At each point of contact a nonnal force, which is proportional to the tendon force, develop between the tendon and the surrounding material. Because of the nonnal force, frictional forces develop at the point of contact. This type of friction is called the length effect. If the variation of the tension in the cable is neglected and the cable force is taken equal to the tension at the ends of the cable, the loss in force due to friction can be expressed as: ~=
0
P,,' e- kx ••••••••••••••••••••••••••••••••••••••••••••••••• (7.11)
--Pi
.
.
before shortening
I-
Where, Px is the force at a distance x, Po is the required force to produce Px at any point x along the tendon profile, x is the distance from the end. k is coefficient of friction between the tendon and the surrounding due to wobble effect. It equals 0.0033 for ordinary cable and equals 0.0017 for fixed ducts. The wobble losses equal:
I1fpw
= Po -
after shortening
Fig. 7.8 Elastic shortening of a concrete member 533
534
Px .....•....................................... (7.12)
where rps is the radius of ducts that contain the tendons as shown in Fig. 7.10 and J.t is the friction coefficient and can be assumed as:
Direction of tendon movement
..
J.t=0.55 J.t=0.30 J.t = 0.25
case of friction between steel and concrete case of friction between steel and steel case of friction between steel and lead
It is worth noting that the quantity (fl' x I rps) represents the losses due to curvature. The code permits the use of a simplified expression for calculating that type of losses if(fl' x I rps ) :=::; 0.2. Such an expression is given by:
I
a --r!
Px = Po (1- fl' P
P Thus, the curvature losses equal to:
! . . ----1---... - -L
I1fpf = Po - Px ................................................. (7.15)
-I
Furthermore, the code permits combining the wobble and the curvature losses in one formula by approximating the logarithmic relation by straight line given by:
Fig. 7.9 Wobble friction losses P,
7 .5.5
Curv~ture
x) .....................................:....... (7.14)
rps
=~
(1 +X+ ~;,X}} ................................ (7.16)
Friction Losses (F)
This type of losses is also limited to post-tensioned members. The resulting loss is due to the friction between the cables and the duct. These friction losses are a function of the curvature of the tendon axis and the roughness of the surrounding material. As a result, the force in the tendon decreases with the distance from the jack. If a certain force is required at any desired section, the friction force between that section and the jack must be estimated and added to the required force to establish the jacking force. It should be noted that the maximum frictional losses occur at the far end of the beam. Although, friction losses vary along the beam span, such calculation is not usually performed and the maximum value is used.
With the condition that the looses is less than 20%:
(
k ·x+
X fl'
):=::;0.20 ........................................... (7.17)
rps
Thus the total frictional losses in this case equal: fl'X) ....................................... (7.18) I1fp(w+J)=Po k·x+-(
rps
or The ECP 203 gives the following formula to estimate the force at distance x produced by jacking force Po as follows: Px
I1fp(w+J)
= Po -Px ............................................... (7.19)
-P.x) ........................................................ (7.13)
= Po·e(-;;:
535
536
Differentiating the previous equation gives the angle ex. at any point.
y '= tana= 8 ~m
(x - ~) .......................... (7.24)
Since the ratio of the depth of the beam to its span is small, it is sUfficiently accurate to assume that ex. = tan ex. and L= length of rhe arc. At x =0, a
y
rps
=_ 4 11m L
&
4 11m atx= L , a = - L 8 = 2a = 8 11m .....•..........•..............•••......•..... (7.25) L
P
P
Assuming the curvature of the tendon is based on that of circular arc, then L"" rps ·8
L
x rps
<"'-
8
L2
= - - ........................................... (7.26)
811m
7.5.6 Shrinkage Losses (sh) Fig. 7.10 Evaluation of the tendon profile curvature To evaluate the radius of curvature for a parabolic tendon, the following formula is assumed: y = a( x -
r. . . . . . . . . . . . . . . . . . . . .
~
(7.20)
where a is a constant to be evaluated by applying the boundary conditions atx=O ~ y=l1m
L2
11m = a
4 ................................................. (7.21)
4 11m
a=U············ .. ··· .... ··· .... ·...................... (7.22)
y=4~m(x~.~r . . . . . . . . . . . . . . . . . . . . . . (7.23) 537
The losses in tendon stress due to shrinkage in a prestressed member depend on many factors. They include the amount of mixing water, the relative humidity, the curing period, and size and shape of the cross section. The shrinkage losses are approximately 7% in pre-tensioned members and 5% in post-tensioned ones. Approximately 80% of the shrinkage takes place in the first year. The code specifies an average value of the ultimate shrinkage in Code Table 2.8.A according to the size of the member and the relative humidity. In cases where the environmental factors are not known, the following table (7.2) is used Table 7.2 Values of the shrinkage strain &11 Prestressing system Shrinkage strain Pre-tensioned members (3-5 days after 300 x lO-o casting) Post-tensioned members (7-14 days after 200 x lO-o casting) In case of stage construction, the code permits assuming that half the amount of shrinkage occurs in the first month and 75% during the first six months. The shrinkage losses are given by the following·equation: 538
Alpsh
= Esh
X Ep .••.....•...•...••.....•••••••..•.•.•.•....•.•.•
(7.27)
For post-tension members, the loss in prestressing force due to shrinkage is less tha? that for pre-tensioned members. The code states that the only amount of shnnkage that needs to be considered is that occurred after transferring the force to the member.
I
'
7.5.7 Creep Loss (CR) Experimental research over the years indicates that deformations continue to increase over time. This deformation under constant longitudinal force is termed creep. The amount of creep depends on the applied load, duration, properties of concrete, curing conditions, the age of element at first loading, and environmental conditions. It should be emphasized that losses due to creep result only from sustained loads during the loading history of the structural element. Since the relationship due to creep is linear, it is possible to relate the creep strain Ecr to the elastic strain Eel such that a creep coefficient $ can be defined as
. ¢ = Ecr
.....•.•.•••••••.•.......•.••.........•......•..•.
(7.28)
Eel
The creep strain Ecr can be taken from Table 2-8-b in the code or from Table 7.3 in the absence of environmental factors. The value of the creep coefficient $ ranges from 1.5 to 3. The Egyptian code permits the use of $=2.0 for pretensioned members and $=1.6 for post-tensioned members. Table 7.3 Values of creep strain tCr
Prestressing system Pre-tensioned beams (3-5 days after casting) Post-tensioned beams (7-14 days after casting) Photo 7.5 Prestressed concrete bridge during construction
£Or for every N/mm2 of the working stress Concrete stress at the time of prestressing!ci
lei >40
lei ::;;40
48 x 10-6
48 x (401!ci) x1O-6
36 x 10-6
36 x (40!fci) x1O-6
If the working concrete stresses at service loads is greater than 113 the concrete strength !cu, the creep strain should be increased by the factor a determined from Fig. 7.11. This increased strain value (E*cr) is given by the following formula: E*cr
539
= Ecr·a •••..•••.••••••••••••••••••.•..•••••••.•••••.•... (7.29)
540
1.50
,
7.5.8 Steel Relaxation Losses (R)
i
1.25
----1J33
t$ 4-<
0
--r-l---+---
Relaxation is defined as the loss of stress under constant strain, while creep is defined as the change in strain under constant stress. This type of losses occurs under constant loading due to the elongation of the tendons with time. A typical relaxation curve showing relaxation losses as a function of time for a specimen that is initially loaded to 70% of its ultimate strength and held at a constant strain, is shown in Fig. 7.12. The loss in stresses due to relaxation depends on the duration and the ratio of initial prestressed/pi to the yield strength/py.
I
i
1.00
Il)
::l
";
>
0.75
100 0.50 0.25
0.30
0.35
0.40
0.45
0.50
0.55
'" '" ~
!5'"
0.60
:-2
!clfcu
10
----
.8 4-<
0
Fig. 7.11 Values of a with respect to concrete stress
~
'" .s'" '"'"
Another formula for determining creep losses for bonded prestressed members is given by: llfpcr
= ¢:p
1.0
~
t1)
.':I
(I)
0.1
fes ............................................... (7.30)
10
e
where Ep = the prestressing steel modulus of elasticity. Ec = the concrete modulus of elasticity. !cs = the stress in concrete at the level of centroid of the prestressing tendons. In general, this loss is a function of the stress in the concrete at the section being analyzed. The ECP 203 expression forfcs is;
L------
100
1000
10000
Time (hours)
Fig. 7.12 Typical stress relaxation losses . The ECP 203 gives the following equation to estimate the relaxation losses:
fes = fe: - fe:d .................................................. (7.31)
llfpR
1
fp; xlog t· (fp; k fpy -0.55 ...................... (7.33) 1
where
Ics = stress in concrete at level of steel cg immediately after transfer. Icsd = stress in concrete at level of steel cg due to all sustained loads applied after prestressing is completed.
/Pi t
kJ
Equation 7.30 can be expressed as: llfpcr
where Ll/pr
=¢ {p (Ie: -
fe:d) .................................. (7.32)
= steel relaxation losses due to relaxation = initial prestressing stress before time dependent losses
=time elapsed since jacking (max 1000 hrs.)
=coefficient depends on prestressing steel type and is taken: • •
10 for normal relaxation stress relieved strands. 45 for low relaxation stress relieved.
e
541
542
This relationship is applicable only when the ratio /Pi/fpy is greater than 0.55. If a step-by-step loss analysis is necessary, the loss increment at any particular loading stage can be determined from:
I1!PR =
!Pi x (logt 2-10gt1) (!Pi ) . --0.55 ................. (7.34) kl !py
where t1 is the time at the beginning, and from jacking to the time being considered.
t2
is the time at the end of interval
Examples 7.1 and 7.2 illustrate the procedure for calculating the losses in pretensioned and post-tensioned beams respectively.
Example 7.1: Calculations of losses for a pre-tensioned beam The prestressed beam shown in the figure below is pre-tensioned. Calculate the prestressing losses knowing that the beam is prestressed with normal relaxation stress relieved tendons. (Note: calculate relaxation losses after 200 days) , Data iF = 1360 N/mm2 Aps = 2097 mm22 feu = 40 N/mm feui = 30 N/mm2 Ep = 190000 N/mm2 Cover =100 mm Un factored super-imposed load =4 kN/m'
1
1 L =22m
L
1- 700 -1
200
,I
TT 8
I
150-
§
I-
00
1l l e 200
T
I
1- 700 -1 Beam cross section
543
544
T
The initial prestressing stress JPi equals to the prestressing stress after the occurrence of immediate losses.
Solution Step 1: Calculation of elastic shortening losses
= 1360-98.06 =1261.94 N Imm f pI. = f p -I:1F ~ pe
The cross sectional area (A) equals:
A = 2x700x200+800x150 =400000 mm 2
P;
=
fpi
Since the section is symmetrical; Ytop = Ybottom= 600 mm 3
3
I =2X(700X200 +700X200X(600-100)2)+ 150x800 =7.733x10 1O mm 4 12 12
f poi
xA = 1261.9 x 2097 =2646.4 K.N ps 1000 2646.4 x 1000 400000
fpci =
2
= -11.26 N/mm
6
2646.4x1000x500x500 605xl0 x500 7.73x1010 + 7.73xlOlO
2
The modulus of elasticity at the time of prestressing Ed equals:
E ci = 4400.Jfcui = 4400
Fo = 24099.8 N I mm
For pre-tensioned beams, <1>=2.0. Hence, the loss of the prestressing force due to creep is given by:
2
P =fp xAps = 1360 x 2097/1000 = 2852 kN The concrete stress at the level of the prestressing tendons is given by:
. =_~_ P f~ A
XeXe
+ Mow
I
= 2.0 190000 (11.26 - 1:56) = 132.46 N/mm 2 27828
Xe
I 6
f .=
2852x1000 _ 2852x 1000 x 500x500 + 605x10 x500 400000 7.73 X1010 7.73 X1010
pel
-12.44 N/mm 2
Step 3: Calculation of shrinkage losses For pre-tensioned beams, the shrinkage strain
Csh
is equal to 300x 10 -6. 2
The loss of prestressing force due to elastic shortening is given by:
Npsh =cshxEp =300x10-:-6 x 190000=57 N/mm
Ep I:1fpe =-fpd Ed
Step 4: Calculation of steel relaxation losses
2 = 190000. 12.44=98.08N Imm 24099.8
K 1=1O
Step 2: Calculation of creep losses 2
M
d s
=
wsd
8
= 4x 222 = 242 kN.m
*
- Msd Xe
ad -
I:1fpr
=fPi xlog(t) (fPi -0.55J= 1261.9xlog(1000) (1261.9 -0.55) . Kl fpy 10 1700
I:1f pr
= 72.8 N
8
The additional stress due to the superimposed dead load is given by:
f
=200 x 24 = 4800 hours
The Egyptian Code ECP 203 requires calculating the relaxation losses at a time of not more than 1000 hours. Hence, assume t = 1000 hour.
The moment due to the superimposed dead load equals: L2
stress relieved tendons
Time (t) = 200 day
The modulus of elasticity of concrete at full strength equals:
Ec = 4400fi:, = 4400.J4Q = 27828 N I mm
--7
I
I mm 2
6
242 x 10 x 500 =1.56 N/mm 2 7.73 X1010
545
546
Example 7.2: Step by step computation of losses in post-
The total losses can be summarized in the following table Type of loss
Stress (N/mm2
)
Percent of total losses
Elastic shortening losses
98.08
27.22%
Shrinkage losses
132.46
36.76%
Creep losses
57.00
15.82%
Relaxation losses
72.80
20.20%
Total losses
360.34
100.00%
tensioned beam A simply supported post-tensioned beam is shown in the figure below. The area 2 2 of the prestressing tendons is 1200 mm and .t;,u=1900 N/mm • Compute the prestressing losses at the critical section of the peam' at 100, days knowing that normal stress relieved strands are used inside steel ducts. ' . Data WDL
= 3.5 kN/m'
= 35 N/mm2 = 26.25 N/mm2 Ep = 193000 N/mm2 Anchorage slip = 4 mm
I' jeu I'
Jcui
Stress before losses
1360.00
Stress after losses
999.66
Losses (%)
26.5%
520
._.-.-.-._._.-.-._._._._.
22m
I2
Aps=1200 mm
80mm
400mm
547
548
·1
Solution
Step 4: Curvature friction losses
Step 1: Calculate section properties
222 r ="'--= =116.35 m ps 8xe 8x(520/l000)
The radius of curvature
A = 400 x 1200 = 480000 mm 2 3
3
- b xt _ 400 x 1200 _ 576 1010 I ----. x mm 4
12
can be approximated by:
e
The stress after frictional losses equals:
12
= Z/oP
Zbo/
rps
= 5.76xlOlO = 96xl06 mm 3 = -600 I
Ybo/
P
x2
= P .e ( -
px ) r",
( Oo3x22) = 1292e - 116.35 = 1220.75 N I mm 2
0
Losses = 1292-1220.75 =71.25 N/mm2
e = 600-80 = 520 mm
Total frictional losses = iJ./pj= 90.47+71.25 =161.73 N/mm = woow
Yc
xA = 25x 480000 = 12kNlm' 1000000
2
Net force = Px= 1292-161.73 =1095.18 N/mm2
For normal relaxation stress relieved stands, the ECP 203 specifies the yield stress as:
Alternative method
fpy =0.85xfpu =0.85xI900=1615 N/mm2
The quantlty a = k·x + - - = 0.0033x22+ 0.30X22)_ - 0.1293 rps 116.35
The initial prestressing force at the time of jacking equals:
Since this quantity a is less than 0.2, the net force after the frictional losses is
f = smaller of 0
pI
0.70 fpu =0.7xI900 = 1330 N/mm 2 { 0.80 fpy =0.8xI615=1292 N/mm 2
.
(
jl'X) (
px = P0 (1- a) = 1292(1- 0.1293) = 1124.9 N/mro
2
Step 5: Elastic shortening losses
/Pi =1292 NImm2
The modulus of elasticity at the time of prestressing Eci equals:
Step 2: Anchorage slip Losses
EoCI = 4400Vi~ = 4400 .J26.25 = 22543.3N Imm cui
o
The strain due to anchorage slip iSEA = LlA = 4 =1.818xlO-4 L 22 x 1000 The loss in stresses due to anchorage slip is given by: LlfpA
= EA X Eps = 1.818xlO-4 x 193000 = 35.09 N I mm 2
2
At transfer, the beam self weight is the only acting moment that equals: 2
M
= ow
wow
xl! = 12x22 = 726 kN.m
8
8
The tTotallosses including (anchorage + Wobble + friction losses) equals: 2 =35.09+ 161.73=196.82 N/mm
Step 3: Wobble friction losses The code specifies k=0.0033 for normal conditions, thus the stress at the end of the beam equals: P"1 = p" . e-kx = 1292.e(-M033X22) = 1201.5 N I mm 2
Net prestressing stress =1292-196.82 =1095.18 N/mm2
Losses = 1292-1201.525 = 90.47 N/mm2
The concrete stress at the level of the prestressing tendons is given by:
549
_
P; - f pi xAps
= 1095.18x1200 =1314.22 kN 1000
550
.=_p;_p;XeXe+MowXe
f pel f
I
A
.= pel
Step 7: Calculation of shrinkage losses
I
1314.22xWOO
1314.22xWOOx520x520 + 726 x 106 x 520
480000
5.76xWlO
5.76 xl 010 ;
For post-tensioned beams, the shrinkage strain &sh is 200xW-6. Il.fpsh = csh xEp
= 200xW-6 x 193000 = 38.6 N/mm 2
Step 4: Calculation of steel relaxation losses
f pci = -2.35 N/mm 2
K1=W for normal stress relieved tendons & t= 100 day = 100 x 24 =2400 hours. The loss of prestressing force due to elastic shortening is given by: Ep 193000 2 Il.fpe = - f pci = 2.35=20.15 N Imm Ed 22543.29
The code requires calculating the relaxation losses at a time not exceeding 1000 hours. Thus, t = 1000 hour.
fpi =W95.18-20.15=W75.03N Imm 2
Step 6: Calculation of creep losses P. =f . xA I
pI
ps
Il.f p
= W75.03xI200 = 1290.04 kN 1000
The modulus of elasticity of concrete at full strength: Ee = 4400K = 4400.Ji5 = 26030.7 N I mm 2
wsd
L2
8
0.55) = 37.30 N Imm
Wobble friction losses Curvature friction losses
= 3.5x222 =211.75 kN.m
8
Elastic shortening Shrinkage losses
The additional stress due to this load is given by:
Creep losses J*csd
Relaxation losses 1290.04xl000 480000
1290.04xWOOx520
5.76xWlO
2
+ 726 x 106 x520 = -2.19N/mm 2 5.76xWIO
For post-tensioned beams, $=1.6. The creep loss equals: Ep (. .) Il.fper = ¢ fcs -fesd =1.6 193000 ( 2.19-1.91 ) =3.30 N/mm 2 . Ee 26030.7
Total immediate losses Total time dependent losses Total losses Stress before losses
35.09
11.8%
90.48
30.5%
71.25
24.1%
20.15
6.8%
38.60
13.0%
3.30
1.1%
37.30
12.6%
216.97
73.3%
79.20
26.7%
296.16
100.0%
'. 1292. .. 995.84
Stress after losses Losses (%)
551
2
T he itemized losses can be summarized in the followin2 table % of total losses Stress (N/mmz ) Type
Anchorage slip losses
The moment due to the superimposed dead loads equals: Msd =
= 1075.03 x log (1000) (1075.03 10 1615
22.92%
552
7.6 Anchorage Zones
7 .6.2 Stress Distribution
7.6.1 Introduction
In post-tensioned concrete structures, failure of the anchorage zone is perhaps
In prestressed concrete structural members, the prestressing force is usually transferred from the prestressing steel to the concrete in one of two different ways. In post-tensioned construction, relatively small anchorage plates transfer the force from the tendon to the concrete immediately behind the anchorage by bearing. In pre-tensioned members, the force is transferred by bond between the steel and the concrete. In either case, the transfer of the prestressing force OCcurs at the end of the member and involves high local pressures and forces. The length of the member over which the concentrated prestressing force changes into a uniformly distributed over the cross section is called the transfer length (in the case of pre-tensioned members) and the anchorage length (for post-tensioned members). The stress concentrations within the anchorage zone in a pre-tensioned member are not usually as sever as in a post-tensioned anchorage zone. In pre-tensioned beams, there is a more gradual transfer of prestressing. The prestressing force is transmitted by bond over a significant length of the tendon and there are usually a number of tendons that are well distributed throughout the anchorage zone. In addition, the high concrete bearing stresses behind the anchorage plates in post-tensioned members do not occur in pre-tensioned construction. Only post-tensioned concrete anchorage zone are given attention in design and will be treated in details in this text.
the most common cause of problems arising during construction. Such failures are difficult and expensive to repair and might necessitate replacement of the entire member. Anchorage zones may fail due to. uncontrolled cracking or splitting of the concrete from insufficient transverse reinforcement. Bearing failures immediately behind the anchorage plates are also common and may be caused because of the inadequate dimensions of the bearing plates or poor quality of concrete. Consider the case shown in Fig. 7.13 of a single square plate centrally positioned at the end of a member of depth t and width b. In the region of length La immediately behind the anchorage plate (i.e. the anchorage zone), plane sections do not remain plane and beam theory does not apply. High bearing stresses at the anchorage plate disappear throughout the anchorage zone, creating high transverse stresses. The spreading of stress that occurs within the anchorage zone is illustrated in Fig. 7.13. The stress trajectories are closely spaced directly behind the bearing plate where the compressive stresses are high, and become more widely spaced as the distance from the anchorage plate increases. In order to enhance the compressive strength of concrete, spiral reinforcement is usually provided as shown in Fig. 7.14. The confinement of concrete due to the spiral reinforcement enhances its strength and ductility. Stress trajectories
Prestressing force -
-1----.If----_
I· Photo 7.6 Anchorage zone of a prestressed concrete beam 553
·1
Fig. 7.13 Idealized stress paths in end block with single load 554
grouting tube spiralreinforcernent
St Venant's principle suggests the length of the disturbed region for the single centrally located anchorage is approximately equal to the thickness of the member t. The high compressive stresses vanish after a short distance and tensile stresses form as shown in Fig. 7.15. The transverse tensile forces (often called bursting or splitting forces) need to be estimated accurately so that transverse reinforcement within the anchorage zone _can be designed to resist them. Splitting
~ress
:Tt
p
__ ..J 1
...~~-Il1 Distance from loaded face
Compression Fig. 7.14 Spiral reinforcement at the anchorage zone
Width of the anchorage zone (La)
Fig. 7.15 Stress distribution at the center line of an anchorage zone
On the other hand, the stress trajectories for an eccentrically loaded member are not equally spaced as shown in Fig. 7.16. The length of the disturbed zone La is approximately equal to twice the distance of the prestressing force to the edge. High bursting tensile stresses developed along the axis of the plate. Moreover, end tensile stresses develop at the edge above the bearing plate. These tensile stresses called the spalling stresses and are usually exist in eccentrically loaded end zone. Stress trajectories
Tension (spalling) Compression
ISteel duct protecting tendons ~
Before casting the concrete
~
After casting the concrete and removing the duct ,
tension
La Photo 7.7 Anchorage zone in a bridge deck before and after .:ai>iing the concrete 555
Fig. 7.16 Stress contours for an eccentric loading 556
7.6.3 Methods of Analysis The design of the anchorage zone for a post-tensioned member involves both the arrangement of the anchorage plates, to minimize transverse stresses, and the determination of the amount and distribution of reinforcement to carry the transverse tension after cracking of the concrete. The ECP 203 states that the anchorage zone should be designed to withstand a force equals to 1.2 the jacking force.
7.6.3.2 Beam Analogy
The spreading of the prestressing forces occurs through both the depth and the width of the anchorage zone and therefore transverse reinforcement must be provided within the end zone in two orthogonal directions. The reinforcement quantities required in each direction are obtained from separate twodimensional analyses, i.e., the vertical transverse tension is calculated by considering the vertical spreading of forces and the horizontal tension is obtained by considering the horizontal spreading of forces. The methods of analysis are:
The beam analogy model is illustrated in Fig. 7.18 for a single central anchorage, together with the bending moment diagram for the idealiz~d beam. Since the maximum moment tends to cause bursting along the axiS of the . anchorage, it is usually denoted by Mb and called the bursting moment. By considering the free-body diagram of one-half of the end block, the burst.mg moment Mb required for the rotational equilibrium is obtained from statl~s. Referring to Fig. 7.18 and taking moment about any point on the member axiS, one gets:
An alternative model for estimating the internal tensile forces in the anchorage zone is to consider it as a deep beam loaded from one side by the bearing stresses immediately under the anchorage plate and resisted on the other side by the statically equivalent, linearly distributed stresses in the beam. The depth of the deep beam is taken as the anchorage length La.
1. Strut-and-Tie method 2. Beam analogy 3. Finite element method
Mb
7.6.3.1 Strut-and-Tie Method
112
Tb ~ ;~
=:(1-7). . . . . . . . . . . . . . . . . . . . . . . .
bursting crack
..£. •
h
I
114
wl hl2 h/4
-
PI2_ PI2-
~IT~
~.
(7.35)
The lever arm between Cband Tb is approximately equal to tl2. Hence,
The internal flow of forces in each direction can be visualized in several ways. A simple model is to consider truss action within the anchorage zone. For the anchorage zone of the rectangular beam shown in Fig. 7.17, the truss analogy shows that transverse compression exists directly behind the bearing plate, with transverse tension, often called the bursting force at some distance along the member. The truss analogy can be used in T -beams for calculating both the vertical tension in the web and the horizontal tension across the flange.
:.
=~ (~-~)= ~ (t-h) .......................................
•
P/2
Idealized Beam
Side elevation
Bursting Moment
112 .. P/2
114
Fig. 7.17 Strut and Tie model for an anchorage zone
Fig. 7.18 Bursting moment at the end zone 558
(7.36)
Expressions for the bursting moment and the horizontal transverse tension resulting from the lateral dispersion of the bearing stresses across the width b are obtained by replacing the thickness tin Eqs. 7.35 and 7.36 with the width b.
Example 7.3 The figure given below shows the anchorage zone of a flexural member. The square bearing plate is 315 mm x 315 mm with a duct diameter of 106 mm. It is to design such an anchorage zone according to the beam theory Data
= 3000kN = 60 N/mm2 2 h = 280N/mm Pj
feu
480
• 1
r-.--------.., _.-. I·
342.5
Photo 7.8 Increasing beam width at the anchorage zone area
7.6.3.3
Finite Element Method
Computer programs are commonly used to analyze the anchorage zone. These programs are based on the finite element method. The anchorage zone is modeled using the shell element and the external prestressing is applied through a series of concentrated loads. Typical output is shown in Fig. 7.19.
--
315
3000KN
-I-
342.5
_L._ Sid Elevation
End Elevation
Fig. 7.19 Stress distribution in the anchorage zone 559
560
The allowable stress for Iv =280 N/mm2 is 160 N/mm2 • The amount of vertical transverse reinforcement equals:
Solution Step 1: Check of bearing 7C
2
Al =315x315--xI06 =90400 mm
2
4 = 480 x 480 = 230400 mm 2 The bearing stresses equal:
I~
A2
f = 1.2xPj = 1.2x3000x1000 =39.82 N Imm 2 Al
b
1A2 = AI
fbeu = 0.67 feu 1.5
~ vA:
~ ok
.j 480
= 0.67 60 x 1.59 = 42.8 N 1mm 2 < 39.8 ..... .ok 1.5
Step 2: Design of transverse reinforcement Step 2.1: Vertical plane Consider moments in the vertical plane (vertical bursting tension). The forces and bursting moments in the vertical plane are given by: Mb=
p-(t -h) = 3000 (1000-315) X 108
8
3211 mm 2
This area of transverse steel must be provided within the length of the beam located from (0.2 t) to (1.0 t), i.e. (=800 mm) from the loaded end face. Two 12 mm diameter stirrups (four vertical legs) are to be provided. =4x112=448 mm 2 . 3211 The number of stlrrups n = - - = 7.16 448 The spacing between stirrups s = 800 = 111 mm 7.16 Use Two 12 mm @ 100 mm
~ use
100 mm
Step 2.2: Horizontal plane Now, consider the moments in the horizontal plane (horizontal bursting tension). The forces and bursting moments in the horizontal plane are obtained by replacing t with b = 480 mm. The bursting moment and horizontal tension are: M b = P (b -h) = 3000 (480-315) X 10-3 =61.9 kN.m
8
3
3
ASb
90400
230400 = 1.59 < 2.0 90400
A = Tb = 514.0xl0 sb fs 160
8
=257.0 kN.m __ M b = 61.9x10
T
Mb 257.0x103 Tb = - = 514.0kN t/2 1000/2
b
b 12
480/2
3
258.0 kN
3.0kN/mm
6.25KN/rnrn
9.52KN/rnrn
Mb=61.9 kN.rn
480
J Bursting in the horizontal plane Bursting in the vertical plane
561
562
The amount of horizontal transverse reinforcement equals:
A = Tb = 258.0xlO sb Is 160
J
Example 7.4 The figure given below shows the anchorage zone of a T-beam. The jacking 2 force equals 2000kN,/y=280 N/mm2, and the concrete strength is 60 N/mm . Design the anchorage zone using:
1611 mm 2
Such an amount is required within the length of the beam located between 96 mm (0.2 t) and 480 mm (1.0 t) from the loaded face. Try 2-12 mm stirrups.
•
Beam analogy
•
Strut-and-Tie method
Asb =4x112=448 mm 2 . 1611 The number of stirrups n = - - = 3.59 448
1000
1-
The spacing between stirrups s = 0.8 x 480 = 106 mm --7 use 100 mm 3.59
150
Use Two 12 mm
T
@ 100 mm
Four pairs of closed 12 mm stirrups (i.e. four horizontal legs per pair of stirrups) at 100 mm centers (Asb =1760mm 2 ) are provided. To satisfy horizontal bursting requirements, this size and spacing of stirrups should be provided from the loaded face for a length of at least 480 mm.
550
I -1----1--
428.3
11
11-12mm dim. stirrups at at 100mm centres
I ~r----s~tirr-u-p~s-'~--~st~irr-u~ps--~
40
closed III
open
(fJ
12mm stirrups atl00m~es
--9-- - 1 - - - - - -
I"
265
1139.2
2ls
--t
.. I
295.8
1 a-3S0~
Solution Step 1: Check of bearing
I
AI = 265 x 265 = 70225 mm 2
[
Section
Elevation
Ib
~ C'.\
..s~ Ar----" ____ _
.
= 1.2 Pj = 1.2x2000x1000 =34.17 N Imm 2 AI 70225
~A2
350
= /122500 = 1.32 < 2.0 --7 ok AI 70225
563
-----II
-;.:,:;.-1
AiL--
A2 = 350 x 350 = 122500 mm 2
The design load is 1.2 Pj
r- - - -
564
Ibeu =0.67 leu 1.5
E = 0.67 1.5 60 x1.32 =35.4 N Imm 2 < 34.17 .... .ok VA:
j
j ~
~
"¢ 00
Step 2: Design of transverse reinforcement (using beam method)
.,;
~ N
Step 2.1: Vertical plane 0
2000 11 =--=7547 kN Imm 265
;::l
0
A = 1000 x 150 + 350x550 = 342500 mm
~--,
2
~
to
II
1
"
t-l
I
.~
~
~ ...... en
= Pj = 2000 = 0.005839 kN 1mm 2 avg A 342500
;--,
e
=5839N'1 mm 2 < 0.5610; < 0.56 (0.75 x 60) <168NI . mm 2 .... .0.k I avg' 1.5 Ye
Iweb =Iavg xb =0.005839x350=2.044kN Imm
~ ~ :
~ ~
r-:
r-:
to
~
-I
x =405.7 mm
.
0\
~
L./2
543/2
The allowable stress for h =280 N/mm2 is 160 N/mm2. The amount of vertical transverse teinforcement in the web equals:
00
f--
~T'~ ~ N
\0 N
r-I
Taking moment about point (0) gives the maximum moment Mb : M b = (2.044X405.7 2 /2-7.547X(405.7 -295.8)212)/1000 = 122.6 kN.m
b
I
i !
o
§ t-
I-~ N
· ·I · J
1 1 1 1 1 l(')--J-0
§
~I
l'~ ~
0-
to~
N
«>"0
l~~
b s
= Tb = 451.7x1000 = 2823 mm 2 Is 160
""-/
~-I
"¢
-I ~ I - - : g - l
565
«>
1 1 1
«>
566
§
.-. I()
to-j-N
«>
L--
A
~ ~
j
Referring to Fig. EX 7.4.1d, the maximum moment occurs at point of zero shear (x). Such a point is obtained as follows:
T = Mb =122.6XI000=451.7kN
I..S'S6'l -I
"¢
to
The distributed region distance Le equals twice the distance of the prestressing zone to the top edge. L. = 2 x 271. 7 = 543 mm
~
$lCJ 6
I flange =Iavg xB = 0.005839x1000 = 5.84kN Imm (Refer to Fig. EX. 7.4. lb.)
2.044x = 7.547 (x -295.8)
¢.:.
'"
Po.
;--,
0
'-'
This area of steel must be distributed within the length of the beam between 0.2 (Le =109 mm) and (Le =453 rom) from the loaded surface. Use stirrups with diameter of 16 mm over the full depth of the web and 12 mm stirrups immediately behind the anchorage as shown in Fig. EX. 7.4.3. Asb,provided =2x201+2x113=628mm . 2821 The number of stIrrups equals-- = 4.5 628 The required spacing
453-109 4.5
. =96 mm ~ use 90mm spaczng
Use 12 mm +<1> 16 mm @90 mm
Step 2.1: Horizontal plane Referring to Fig. EX. 7.4.1c, the stresses in the flanges equal: 12 =Iavg xts =0.00584x150=0.876kN Imm
This area of steel must be distributed within the length of the beam between (0.2 B=200 mm) and (B=1000 rom) from the loaded surface. . d spacmg . =1000 - 200 = 139 mm The reqUire 5.75
Step 3: Design of transverse reinforcement (using strut-and-tie) Step 3.1: Distribution of forces Another approach for solving the same previous problem is the strut-and-tie approach. In this approach, the prestressing force is distributed to the flange and to the web through a series of struts and ties as shown in Fig. EX. 7.4.2. The area of the cross section equals A
= 1000 x 150 + 350 x 550 = 342500 mm 2
The average stress equals
=
I
Due to symmetry, the point of zero shear is located at the middle. Thus the bursting moment in the horizontal direction equals;
Fflange =1avg xAj/ange
M b = ( 4.088;l75 +0.876x325x(175 +325/2) -7.547x (265;2)2 )11000 Mb
= 92.4kN .m
The bursting moment is resisted by horizontal tension and compression in the flange. T = M b = 92.4 x 1000 b BI2 500
185kN
The area of the horizontal reinforcement required in the flange equals: A
sb Jlange
= Tb Is
= 185 x 1000 =1156 160
mm 2
130mm
Use 16 mm @ 130 rom
13 =1avg xt = 0.00584 x 700 = 4.088 kN I mm
2
~
avg
= Pj A
2000 342500
= 0.005839 kN I mm 2 = 0.005839 x 1000 x 150 = 876kN
The force in the flange is located at the c.g of the flange (75 mm from the top) Fweb = P - 0/ange
= 2000 -
876 =1126 kN
The force in the web is divided into two forces, each equals 563 kN. Each force is located at quarter points of the web depth tweJ4 = 550/4=137.5 rom The truss extends from the bearing plate into the beam for a length about the distance of the prestressing zone to the edge=271.7';::;272 mm The forces at the bearing plate must equal those in the flange and the web but with different spacing as shown in figure. 876
=7.547 kN Imm I I = 2000 265 = Fflange = 876 = 116.1mm YI II 7.547
lt1
563
...,f
r--
lt1
S S lt1 \0
N
563
...,f
r--
Using top bars of 16 mm, the total number required is:
= Fweb = 563 = 74.5 mm Y2 II 7.547
n = 1156 = 5.75 201
The distance between the force in the flange and the web=(Yl+Yz)/2=95.3 rom 567
568
Step 3.2: Vertical direction
T
+ 197.2
867KN
95'=-t- S63KN_
"I'~rn 333.0
L
A
-961 KN
+'~~
So.- -563
D
~'693 KN
~ 405KN
.1
= tan- I 333 -137.5 = 35.706" 272
~t
563 = 693 kN cos 35.706 The tension in the tie equals=693xsin35.7 = 405kN The area of steel required to carry the force in the tie The force in the strut equals=
275
""'l.!.--
(J,
212.5
563KN
KN
F.
T
.
The inclination of the bottom strut equals
876 KN
I
I
A
137.5
sb
--..L
I-- 272--l
= Tb = 405 x 1000 = 2531 mm 2 Is 160
This area of steel must be distributed within the length of the beam between 0.2 Le =109 mm and Le =453 mm from the loaded surface. Use stirrups with diameter of 16 mm over the full depth of the web and 12 mm stirrups immediately behind the anchorage as shown in Fig. EX. 7.4.3
(a)Vertical dispersion of prestress (elevation)
Asb,provided
-r 250
J;; >-,,,
--od~-"-~l- ""'--r
±; l-1-
j161KN
~~
500
----467 _ _ _ _ _ _ _ _KN _______ .
~
_438KN K
250
I - 272 01- .
500
=2x201+2xl13=628mm
. . 2531 The number of sturups equals-- = 4.03 628 . d spacmg . The reqUIre
453 -109 =.107 mm 4.03
~ use
' 9O mm spacmg
Step 3.3: Horizontal direction The horizontal spreading of the forces into the flange is shown in Fig EX. 7.4.2. The total force is applied at the quarter point of the flange (250 mm for the edge). The location of the horizontal force is at 272 mm from the edge. The distance at which the truss is formed equals B/2=500 mm. At the bearing plate the force is located at the quarter points =(265/4=66.25 mm) The inclination of the strut equals B=tan-I 250-66.25 =20.18° 500
----.0-11
The force in the strut equals
438 cos 20.18
= 467 kN
(b)Horizontal dispersion of prestrells (plan) The tension in the tie equals=467 xsin 20.18 = 161kN Fig. EX. 7.4.2 Stress dispersion of the prestressing force /
\
569
570
The area of steel required to carry the force in the tie
8
= Tb = 161x1000 = 1006mm2
A
sb
Is
160
Using top bars of 16 mm, the total number required is n
= 1006 = 5 201
This area of steel must be distributed within the length of the beam between 0.2 B=200 mm and B=1000 mm from the loaded surface. s
=
1000-200
5
FLEXURE IN PRESTRESSED CONCRETE BEAMS
= 160 -7 take 130mm 16mm bars at ~ centres
40 I 909090909090
-11 1 1 1 I 1 1
Ir
11
I--
1------11
12mm @ 90 mm
Regular shear rft.
580
Cross Section
Elevation
9-16mm bars atl30mm centr~e:Ls-+I--I--I--l--I-..J--I-I-l
-
'--1- ._-1-
.-----C-1.-11
-.-
1-.-
Photo 8.1 Prestressed box -girder bridge during construction
=----
8.1 Introduction 8x130=1040
Regular shear rft.
Plan Fig. EX. 7.4.3 Reinforcement details for the anchorage zone
571
The basic principles used in the flexural design and analysis o~ presn:essed concrete beams are presented in this chapter. Two steps are consldered m the analysis and design of prestressed beams in flexure namely; • •
The analysis under service loads. The analysis at the ultimate state.-
572
The fundamental relationships used in the service load analysis are based upon the basic assumptions of elastic design. However, at the ultimate stage, stresses and strains are not proportional and the ultimate limit analysis should be carried out. Deflections under service loads together with the prestressing forces should be calculated to confirm the compliance with the applicable design criteria.
B.2 Analysis of Prestressed Concrete Members under Service Loads
wkNlm l
P-~-t========================~r-pp~
I·
a- Loading B
Flexural stresses in prestressed members are the result of the prestressing force P, the internal moment due to eccentric cable configuration, and the external applied moments (M). Calculations of stresses are based on the properties of the
gross concrete section. The resulting stresses at any point in the beam caused by these forces can be written as:
Ytop
Tts
'1j"-
P PXe _Mxy i=--±--y+-- ............................... (8.1) A I I
I---l
Ybot
b- Cross-section M
pxe
+--
The resulting stresses should be checked against the allowable values specified by the code and given in Tables 8.1 and 8.2. For calculation of stresses at the extreme fibers, it is usually more convenient to express the quantity IIy as the section modulus (Z). For non-symmetrical members such as T-sections, the section modulus at the top Ztop is different from the section modulus at the bottom Zbot. For a simply supported beam, as the one shown in Fig. 8.1, the stresses. at the top and bottom fibers of the beam can be calculated from:
top
ZtoP
P A
PXe
M
Ztop
Ztop
P
PXe
M
Zbot
Zbot
J. = - - + - - -
bearnC.G.
P PXe M = - - - - - + - ............................................. (8.2) A
Zbot
Zbot
_ pxe hop
1
b
where y is the distance from the C.G. of the section to a certain point; A is the cross sectional area, I is the gross moment of inertia of the section, P is the prestressing force and M is the external applied moment.
ibot
·1
L
8.2.1 General
=
P
PXe
M
- - + - - - - ............................................. (8.3) A
Ztop
Ztop
Zbol
prestressing
eccentricity
M
+-Zbot
external loads
fbot
=
-----+-A
resultant
In which, I
Zbot
=-Ybot
I
ZIOP
c- Stresses
=-YllJP
It should be clear that the stresses induced due to (P.e) are opposite to those induced due to the external applied moment M. 573
e
Fig. 8.1 Stress distributions in a concrete section due to The prestressing and the applied loads 574
8.2.2 Allowable Concrete and Steel Stresses 8.2.2.1 Allowable Steel Stresses Prestressing steel is most commonly used in the form of wires or strands. The code specifies the ratio of the yield strength /py of the prestressing steel to its ultimate strength/pu as follows:
/P//pu = 0.80
for deformed bars.
/P//pu =0.85
for normal relaxation stress-relieved strands, wires and bars.
/P//pu =0.90
for low relaxation stress-relieved strands and wires.
The strength reduction factor IPs for prestressing steel is taken the same as nonprestressed steel. Hence, the strength reduction factor for flexure IPs is taken as 1.15. The tensile stresses allowed by the ECP 203 for prestressing wires, prestressing 'strands, or prestressing bars are dependent upon the stage of loading. At jacking, the maximum allowable stress is the lesser of 0.75 /pu or 0.90/py . When the jacking force is first applied, a stress of 0.70 /pu is allowed. Immediately after transfer of the prestressed force to the concrete, the permissible stress is 0.70/pu or 0.80/py whichever is smaller. The previous values are applied also in case of post-tensioned members. The ECP 203 allowable stresses in prestressing steel are summarized in Table 8.1 Table 8.1 Allowable tensile stresses for prestressing steel Maximum stress produced by jacking (before transfer)" Maximum tendon stress at tensioning process Maximum tendon stress immediately after transfer not to
0.90/py or 0.75/pu 0.70/pu 0.80/py or 0.70/pu
exceed the smaller of Maximum stress in post-tensioned tendons at anchorages
0.80/py or 0.70/pu
and couplers immediately after anchorage of the tendons not to exceed the smaller of
• Not to exceed the stress recommended by the manufacturer of the prestressing system 575
8.2.2.2 Allowable Concrete Stresses Concrete with high compressive strength is normally used in prestressed members. This is because of its high modulus of elasticity (less creep and elastic shortening losses). In addition, its high bearing capacity permits the use of small anchorage zone. The allowable stresses in concrete are dependent on the stage of loading. The ECP 203 gives these stresses in two stages namely; at transfer and at service loads. The allowable stresses at transfer are given in Table 8.2. At the service load stage, the ECP-203 classifies prestressed concrete elements into 4 cases depending on the tensile stresses developed in the section. These cases are as follows: ' Case A: (Full prestressing) These are elements in which there is no tensile stresses are allowed (developed tensile stress equals to zero). These elements are: • Structural elements subjected to cyclic or dynamic loads. • Structures with tension side severely exposed to corrosive environment of strong chemical attack which cause rusting of steel (category four according to ECP 203). Case B: Uncracked sections These are elements in which the tensile stresses due to all loads are less than:
0.44 .JJ:: ............................................ (S.4a) Examples of structural elements deigned according to case Bare: • • •
Solid slabs and flat slabs. Prestressed concrete elements with unbonded tendons. Structures with severely exposed tension side (category three according to ECP 203).
Case C: An intermediate case between full and partial prestressing Structural elements are subjected to tensile stresses larger than case B but less than the cracking strength of concrete given by: far
= 0.6.JJ::
~ 4.0 N Imm 2
.............................
(SAb)
Case D:Cracked sections (Partial prestressing) These are elements in which the tensile stresses due to all loads (using uncracked sections properties, I g ), are less than O.SS.JJ:: .
576
In addition, the tensile stresses developed in the section due to permanent loads, which might include permanent live loads, should be less than 0.6..JJ: .
Table 8.2 Allowable concrete stresses (N/mm 2 ) At the time of initial tensioning before time dependent losses produced by
For cases C and D, ordinary reinforcing steel or non-prestressed strands are provided to resist the tension force developed in the section at the working stage.
creep, shrinkage, or relaxation have occurred (At Transfer) 1. Maximum compressive stress
0.45 !cUi
2. Maximum tensile stress except as permitted in Case A
( -)
Maximum tension
Zero
CaseB
CaseC
CaseD
·1
0.22/1::
item 3 3. Maximum tensile stress at the ends of simply supported members
( -)
(-)
0.44Ji:
0.60Ji:
(-)
0.85Ji:
O.44~fcUi
Service load flexural stresses, assuming all prestressed losses have occurred (At Service Loads) 1. Maximum compressive stress due to prestressed 0.35 feu plus sustained loads 2. Maximum compressive stress due to prestressed 0.40!cu
plus total loads
3. Maximum tensile stress in pre-compressed zone Case A- zero tensile zone !cu
Full
(N/mm2)
prestressing
Section
40
0
2.78
3.79
5.38
45
0
2.95
4.02
5.70
50
0
3.11
4.24
6.01
55
0
3.26
4.45
6.30
60
0
3.41
4.65
6.58
Uncracked Transition
Partial
Case C- 0.60Ji:
Prestressing
Fig. 8.2 Maximum allowable tension at full service loads
577
CaseB- 0.44.JI:
:s; 4N Imm 2 Case D- 0.85..JJ: Axial coml!.ression 1. Maximum compressive stress
0.25feu
where !cui is the concrete characteristic strength at the time of transfer (N/mm2 ) !cu is the concrete characteristic strength at service load (N/mm2 ).
578
8.2.3 Calculations of Stresses at Transfer
8.2.4 Calculations of Stresses at Full Service Loads
After applying the prestressing force to the beam, the beam deflects upward (camber) and the only external applied moment is due to the self-weight of the beam Mow as shown in Fig. 8.3. The bottom fibers are subjected to high compression stresses while, the top fibers are subjected to tension stresses. The concrete strength !cui used in the calculation of the permissible stresses should be at the time of transfening the force to the concrete. Furthermore, the prestressing force (Pi) used in stress expressions is the initial prestressing force before losses.
After the application of the superimposed dead loads and the live loads, the prestressed member shall be subjected to the total service moment Mtotat. The full intensity of such loads usually occurs after the building is completed and some time-dependent losses have taken place. Therefore, the prestressing force used in the computation of stresses is the effective prestressing force (Pe) as shown in Fig. 8.4. The total unfactored load on the beam is given as:
F Jbot
~ ~ Xe Mow 0.45 Jcui F = -----+--~ A
F Jt()P
Zbot
•••••••••••••••••••••••••
W totaL
Pe
(8.5)
Zbot
Ztop
= Pi xli-losses (%)] ............................................ (8.7b)
The maximum bending at mid span for simple beam equals:
~ ~xe Mow 0 ~ = --+-----~ .22 VfCUi ..•••.•.••.•....•.•.•• (8.6)
A
= wow + W OL + Wu •.......•.•••........•...•.••.•.......••...... (8.7a)
M totat
=
Wtotat
XL2
8
Ztop
e
~---------------~ ------- -~ Pi --:::.::.::::::::umum-Tu_:-::::-~-~-?~ , \
Initial camber
-----------1 J
I.
./
L
Loads at the service load stage
/rop< 0.22~ fCUi ~--~------------~~
~I~ Mtotal
/rop
v
fbot<0.45 !cUi
Stresses at mid section
fbot
Fig. 8.3 Stress distribution and allowable stresses at transfer
Stresses at mid section Fig. 8.4 Stress distribution and allowable stresses at full service loads
579
580
The stresses are calculated using Eq. 8.8 and Eq. 8.9. The stresses at mid-span section should not exceed the limits allowed by the code and given in Table 8.2. f
P. P. Xe M - - - + - - - -loloJ- ............................................. (8.8) -
lOp
A
fboll om
ZIOP
ZIOP
= - p. _ p. Xe + M loloJ A
Zbol
•••••••••••••••••••••••••••••••••••••••••
Zbol
(8.9)
8.2.5 Summary Equations for stress computation are used to determine the concrete stress at the extreme fibers for positive and negative bending moments as summarized in Table 8.3. It is important to verify that the stresses for both load cases (at transfer and at full service load) are within the allowably limits. Table 8.3 Stress calculations at top and bottom of sections subjected to either negative or positive bending moments Item
".±, ;>
bO
:a"
"" "
.0 ;> ';:J
[-Jr
At full service load
At transfer !top !hot
.§
P;
p;xe
Mow
A
ZUJP
.Z,op
--+-----~0.22
.
.[1;;;' em
P; - -p;-X+ e Mow -- - S0.45 f cui A ZOOI Zbot .
_ Pe + Pe xe _ A Z,OP
M 'Olal
~ DAD feu
Z,OP
_ p. _ p. Xe + M lOU; ~seeTable8,2 A
ZOOI
Zoot
,',
4"
0.
" ;>
~
~ iii .0
[J:
"
!top
fbot
;> .~
bO
p; -Xe+ Mow -Pi --- - S045 . f ei A Ztop Ztop U . Pi P -Xe- - Mow -+ - - 5022 . .Jj::; cui j
A
""
Zbol
ZOOt
_ Pe _ P. Xe A Z,op
+ MlOlOl ~seeTable8,2
_Fe +
P. xe
A
Zoot
Z,OP
_ M tOlal ~ DAD feu Zoot
In the following example problems, the allowable stresses are usually available and the determination of one unknown (the prestressing force, the span, or the loads) is required. For a certain load case (transfer or service load), two values can be obtained by solving the stress equations at the top and the bottom for the required unknown. Care should be given to the appropriate choice as given in Table 8.4. Table 8.4 Analysis of prestressed sections
At Transfer Photo 8.2 Tendon placement in a bridge box-section
581
At Service load
• Smaller PI
•
Larger Pe
• Smaller Asp
•
Larger Asp
• Longer span
•
Smaller span
• Smaller eccentricity e
•
Larger eccentricity e
• Larger self-weight loads
•
Smaller live-loads
• Larger self-weight moment
•
Smaller moment
582
rr Example 8.1 For the prestressed beam shown in figure and knowing that the beam is fully prestressed determine,
Solution Step 1: Calculate Section Properties The cross sectional area (A) equals: A = 2 x 700 x 200 + 800 x 150 = 400000 mm 2
1. The required force at transfer. 2. The amount of prestressing steel. 3. The stresses at final stage.
Since the section is symmetrical;
Ytop = Ybottom=
600 mm
3
Data !cu !cui
1= 2X(700X200 + 700 x 200 X(600-100)2] + 150x800
12
= 40 N/mm 2 =30 N/mm2 = 1700 N/mm 22 = 2000 N/mm
Zbot
/py /p" LL = 18 kN/m' (unfactored) Flooring weight =4 kN/m' (unfactored) cover =100 mm Losses = 15%
1
,
1
L=22m
L 200
t
1- 700 -1 I I\
f
-
150-
0 0
00
lL I 200
T
I
T 1 0 0 N
......
• I
1- 700 -1
12
=_1_= 7.733xlOlO = 1.289 x 108 mm 3 y bottom 600
ZIOP= Zbol =
w O.w
= r:
c
1.289x 108 mnl
xA
= 25x 400000 = lOkN 1m' 6 10
The allowable compression stress!ci and allowable tension stresses fli can be obtained using the compressive strength of concrete at the time of pre-stressing !cui as follows: !ci = 0.45 xfcui = 0.45 x 30 = -13.5 Nlmm2 fli
= 0.22~ fcui = 0.22-130 = 1.2 N I mm 2
L
1- 700 -1 I I
200
---rt--rt-
o o
~
150 -
\0
£
o
o 00
._.-.
lL 200
T
' - 1-,-,-,-..,.--1-0
o
0
l£)
II
CI.l
1
•
.
"'
584
0
\0
II
I -- :!
1- 700 -1
Beam cross section
583
3
-'-
Step 2: Calculate the initial prestressing force at transfer
_EL A
At transfer, the self-weight of the beam is the only applied load, thus: 2 M = wOW L2 = 1Ox22 = 605 kN.m ow 8 8 The eccentricity of the cable from the C.G. of the section equals: e = Y bot - cover = 600 -100 = 500 mm
_Pi xe
The initial prestressing force should stratify the allowable stresses at transfer at the bottom and top fibers.
/'
P;
P; Xe
Zoo. eccentricity
Mow
Jbottom = - " A - Z + Z bot bot
P;l x 1000 x 500 605x10 6 P;l x 1000 ---'-'-----+---8 8 400000
1.289x10
f
+Mow ZhO. external load
= - Pi _ Pi xe + Mow
. hoi
A
1.289 x 10
PiI= 2852 kN
Final design Pi =Pi1=2852 kN
A second value Pa is obtained from the analysis of the top fibers as follows:
Step 3: Calculate the required prestressing steel
f top
=- Pi + Pi Xe Z
A
top
_
The allowable prestressing stress at time of transfer is given by:
Mow Z
top f
+1.2=
P;2xlOOO + P;2x1000x500 1.289xl08 400000
605x10 6 1.289x10 8
pi
= smaller of { .
0.70 f pu
= 0.7 x 2000 = 1400N Imm 2
0.8fpy =0.8x1700=1360N Imm
2
[Pi= 1360 N/mm2
P i 2= 4281 kN
A ps
~
~
_._._._._._-_.__ __._---_._----------- - ----.
.---" ---- ---
I~
~
.
-----
~
=!L= 2852x1000 =2097 mm 2 f.pI 1360
Step 4: Calculate the stresses at the serviCe load stage The total load is the summation of dead and live loads. W total =wow +wjlooring +WLL =10+4+18=32kN 1m'
22m
585
Zhol
Zhol
resultant
The chosen initial prestressing force is the smaller of the two values, because it will give stress at the opposite fiber that is less than the allowable. In this case, the critical load is 2852 kN giving -13.5 N/mm2 at the bottom fiber. Applying this load at transfer will give stress at the top fiber of -7.6 N/mm2 (calculation is not shown), which is less than the allowable stress at transfer.
Assuming that Pi is in kN, and applying in the previous equation gives PiI -13.5 =
A prestressing
_I
586
r The total moment at the mid-span equals:
=
M tot
= 32 X 222 = 1936 kN.m 8
W tot L2
8
The effective prestressing force at the time of applying all service loads equals: P e =(I-losses) Pi
-7
Pe =(1-0.15) x 2852 =2424.2 kN
I
The allowable stresses at service load stage equals
fie
=zero (no tension is allowed in fully prestressed beams)
lee = Oo4Olcu I bottom
= 0040 X 40 = -16 N
= - Pe + Pe Xe A
Z
_
j
l
I.
i
I mm 2
1--4------ --------1-1 22 m
Loads at the service load stage
M total
top
Z
top
,......-----..-. ........-..................................._............-----, .-
I top
= - 2424.2 X 1000 + 2424.2 X 1000 x500 400000 1.289 X 108
llOP =-11.67 N
Imm 2
•••
6
1936x10 1.289 X 108
<-16(sqfe)
f bottom = - PAe _ PZe Xe + MZ total bot
I bottom Ibottom
=
2424.2x1000 400000
= -0044 N
I mm 2
· --.. . . . . . . . . . .-·--.. . . .-.. .
bot
-·h;;~m=-O.
2424.2 X 1000 x500 + 1936x106 1.289 X 108 1.289 X 108 •••
< zero (sqfe)
Stresses at mid section The beam is considered safe because non of the extreme fiber stresses exceed the allowable stresses.
587
I:'
588
44
Example 8.2
Solution
Figure EX 8.2 shows the cross-section of a simply supported post-tensioned beam. Determine the maximum span of the beam based on the stresses at the transfer. Assume that the beam is made of normal strength concrete withfcu=40 N/mm2, and the concrete strength at transfer (!cui) is 75% of the cube strength. Assume also that the time dependent losses are 12% of the initial prestressing and that the yield strength and the ultimate strength of the tendons are 1700 and 2000 N/mm2, receptively.
Step 1: Calculate Section Properties
Knowing that the beam is categorized as case D, check stresses at full service stage if the beam is SUbjected to an unfactored live load of 12.5 kN/m' and unfactored superimposed dead load of 4 kN/m'. Calculate the required non prestressed steel (fY=4~0 N/mm 2 ).
The cross sectional area (A) equals: A = 350 x 1300 = 455000 mm 2 Since the section is symmetrical; Ytop = Ybottom= 650 mm 3
1= 350x1300 = 6.41xlO lO mm 4 12 lO
Zbol :=
Wo.w
_1_ = 6.41xlO YbOllom 650
=1/ xA = 25x455000 =11.375kN 1m' 6 Ie
2
Aps==lSOO mm
= 98.583x10 6 ",nm 3
10
The allowable compression stress!ci and the allowable tension stress fti can be obtained using the compressive strength of concrete at the time of pre-stressing !cUi as follows: feui = 0.75 x feu =0.75x30=22.5 Nlmm
2
!ci = 0.45 X!cui = 0.45 x 22.5 = -10.125 Nlmm 350mm
fli = 0.22~ feui = 0.22.j22.5 = 1.04 N I mm
2
2
-,...0
tr)
\0
II
B'
;>-
,. I
I-
~ .... 0 0
0
tr)
\0
110
>: Fig. EX 8.2 Beam elevation and cross section
590
~
Step 2: Calculate the prestressing force
Analysis of the stresses at the top fiber, which is tension, gives:
The allowable prestressing stress at time of transfer is given by:
f
0.70 f
pu
+1.04=
fpi=1360 N/mm2
I
ps
Step 3: Calculate beam span At transfer, the self weight of the beam is the only applied load. Since the span is unknown the bending due to own weight equals: 2 M = wOW L2 = l1.375xL =1.42xL2 kN.m ow 8 8 The eccentricity of the cable from the c.g of the section equals:
Analysis of the stresses at the bottom fiber, which is compression, gives: ~ ~xe Mow fboltom =-A"---Z-+-Z bot bot 6
2448x1000x550 + Mow X 10 98.583x10 6 98.583x10 6
2448 x 1000 455000
+
2448 x 1000 x 550 98.583x10 6
The allowable stresses at the bottom and top fibers of the_ cross-section are 10.125 N/mm2 and + 1.04 N/mm2, respectively. The calculation of the span of the beam should be based on the larger of the two values of the bending moments obtained from the analyses of the stresses at the bottom and top fibers (Mow = 878.64 kN.m). This is attributed to the fact that at the case of transfer the self-weight moment produces stresses that are of opposite sign compared to the allowable stresses, both at the _bottom and top fibers as shown in the following table. Mow = 878.64 = 1.42 x L2
Item
bottom condition
Top condition
Allowable stress N/mm~
-10.125
+1.04
Mow (kN.m)
878.64
713.124
Span(m)
24.858
22.395
stress at opposite fiber
-0.635(top)<+ 1.04
-11.804(bottom»-1O.125
safe
unsafe
~~5
~~~~'
condition
~ ~~------------------- -------------.:::: 2448
~
fhottom=-IO.125
I·
6
Mow x10 98.583x10 6
N/mm2
Mow = 878.64 kN.m
2448
Mow Ztop
L=24.858m
e = Ybot -cover = 650-100 = 550 mm
2448 x 1000 455000
_
Mo w= 713.12 kN.m
xf" = 1800x1360 = 2448 kN pi 1000
-10.125 =
= - Pi + ~ Xe A Ztop
= 0.7 x 2000 = 1400 N Imm 2
f " =smaller of { 0.8fpy = 0.8x1700 = 1360 N Imm 2 pi
P. "=A
top
L
591
·1 592
- f!11.8~
1 l
Step 4: Calculate stresses at the service load stage The total load is the summation of dead and live loads. WIOIa!
Step 5: Calculation of non-prestressed steel (As) Since the stresses at the bottom (+5.09 N/mm2) exceeds the tensile strength of concrete (0.6.J40 =3.79N Imm 2 ), the beam must be reinforced with nonprestressed steel. The depth of the tension zone Yten equals:
=wow +W DL +w LL =11.375+4+12.5 = 27.875kN 1m' Y ten
=
The total moment at the midspan equals: 2
M
101
= WlOla! L2 = 27.875 x 24.858 = 2153.2 kN.m
8
8
The tension force equals: T
1 =-1 fbol/ om xY te1l xb =-x5.09x336.8x350/1000 = 300kN
2
The effective prestressing force at the time of applying all service loads is ~
Pe= (I-losses) Pi
P e = (1-0.12) x 2448 = 2154.24 kN
For case D, the allowable stresses at service load stage equals:
fie =0.85.J!:: =0.85.J40=5.4N Imm fee =0.40feu =0.40x40=-16N Imm
2
The allowable working stress fs for the non-prestressed steel ({y=400 N/mm2) is obtained from Table 5.1 of the ECP 203. ~ f,=200 N/mm2 A
s
2
5.09 6 x 1300 = 33 .8 rom 5.09+14.56
=~ = 300xlOOO = 1500 mm 2 ~ Use 4 22 fs
200
2
----------flOP
=
2154.24xlOOO 455000
2154.24xlOOox550 98.583x106
----------+----------~--
ftop =-14.56N Imm 2
24.858 m
--------1/
<-16 (safe)
ftop=-I4.56
P. Xe + Mlata!
=- Pe A
f
= _ 2154.24xlOOO bOl/om
\_.0--_____
Loads at the service load stage •••
f bOl/om
_
2153.2x106 98.583x106
Z
bot
Z
bot
455000
fbol/om =+5.09N Imm 2
•••
6 2154.24 x 1000 x 550 + 2153.2x10 98.583x106 98.583x106 -I---i T _
<5.4 (safe)
.....;.._................_ .. _ .................L . . - - - "
The beam is considered safe because both extreme fiber stresses (at top and bottom) are less than the allowable stress.
fbottom=+5.09
Stresses at mid section
593
594
!
Yten
11 Example 8.3
Solution
Calculate the required prestressing forte at the service load stage if the beam shown in the figure is subjected to dead loads of 8 kN/m'(not including own weight) and live loads of 20 kN/m'. The beam is prestressed with unbonded tendons and the losses may be assumed 16 %. It is also required to check the stresses at transfer. Assume that/cu=45 N/mm2,/cui= 34 N/mm2
Step 1: Calculate Section Properties The cross sectional area (A) equals: A= 1200x150+250x750 =367500 mm 2
Since the section is not symmetrical, calculate the location of the center of ~ = 1200x150x75 + 250x750x525 =304.6 mm gravity. Y 367500 3
3
1= 1200x150 +1200xlS0x(304.6-7SY
12
-\
Ytop= Y = 304.6 mm
Y bot = t - Y top = (150 + 750) - 304.6 = 595.4 mm
Beam elevation
Z
=_1_= 2.77x101O =91.02x10 6 mm3 top
1 ISO
~ 0
tr)
t""-
1200mm
I"
I
Zbot
--I
I
Y lOP Ybot
wo.w
150
•
Beam cross-section
595
1200mm
11-
Aps
I ..2S0-I
595.4
= Yc xA= 25Xl~~~O~~ =9.1875kN 1m'
100
t
304.6
=_1_= 2.77 x 1010 = 46.6x10 6 mm 3
t
l
12
I =2.77 x 10 10 mm4
L=ISm
I-
+ 250x750 + 250x750x(525-304.6Y
0
tr)
t""-
n
•I
I
I
--
Ytop=304.6
-
l00~
-£~.:- Ybot=59S.4
Aps
•
i.-
t
tzsoJ 596
'--
Since the beam is prestressed with unbonded tendons, the beam is categorized as case B. The allowable compression stressfce and the allowable tension stress fte at full service load (case B) can be obtained using the compressive strength of concrete!cu as follows:
=0.44£ == 0.44.J45 == 2.95 N
f. top
Ice =0.40 x!cu =0.40 x 45 =-18.0 N/mm2 fte
The second value for the prestressing force is obtained from the critical condition at the top fibers, which is given by:
I mm 2
== - Pe A
-18.0 ==
+ P. Xe _ Z
Mtotal
top
Z
top
Pe X 1000 + Pe X 1000 X 495.4
91.02x106
367500
6
1045.9 X 10 91.02 x 106
Step 2: Calculate prestressing force at service load stage Wtotal ==W OIV +WDL +WLL ;:::9.1875+8+ 20 ==37.19kN 1m'
2
tot
== W total L2 == 37.19 x15 == 1045.9 kN.m 8 8
Step 3: Check stress at transfer
e == Y bot -cover == 595.4-100 == 495.4 mm The prestressing force should satisfy the allowable stresses at the top and. bottom fibers. The first value for the prestressing force is obtained from the condition at the bottom fibers, which is given by: I'
Jbottom
== _ Pe A
+2.952 ==
_
Pe Xe
Z
bot
P. x1000 367500
+ Mtotal Z
(negative)
The previous load value is negative and means that the prestressing force is tension and therefore it is rejected. Thus, the prestressing force is taken equal to 1460.3 kN (still the principle of choosing the bigger is valid).
The total moment at the mid-span equals: M
Pe2 == -2391 kN
At transfer, the self-weight of the beam is the only
Mow
Pe ==
8
9.1875x15 2 8 == 258.4 kN .m
P; (I -losses)
bot
Pe x 1000 x 495.4 + 1045.9 X 10 6 46.6 X 106 . 46.6x10
6
Pel==1460.3 kN
1460.3==Pj (1-0.16)
P;= 1738 kN
The allowable stress at transfer is given by:
!ci = 0.45 x!cu; == 0.45 x 34 = -15.3 N/mm2 fli == 0.22~ feui == 0.22.J34 == 1.283 N I mm
1--......-------15
2
m-------l.!
Stresses at mid section at serviceload fbottom
597
1738x1000 367500
1738x1000x495.4 46.6x10
258.4x106 46.6x10
------'--+-----:6 6
fbottom
=
fbotlom
==1-17.671 N/mm >1-15.31 N/mm2 (unsafe)
2
598
f
P.
P. Xe
Mow
A
Ztop
Ztop
Example 8.4
=--' +-'- - - top
1738x1000
1738xl000x495.4
-------+------~--367500 91.02 X 106
f lop =+1.89
N/mm
2
> +1.283
The cantilever beam shown in figure supports a balcony in a stadium. It is required to determine the cross sectional area for low relaxation stress relieved strands based on the allowable stresses at transfer. Assume that /pu= 1900 2 N/mm ,!cu=50 N/mm2, !cui= 38 N/mm2. -
6
258.4 X 10 91.02xl06
Calculate the service load stress if the unfactored superimposed dead load is 8.0 k N/m' and the unfactored live load is 14 kN/m'.Assume losses of 15% and that the beam is considered as case B.
N/mm2 (unsafe)
The beam is considered unsafe because both the extreme fiber stresses exceed the allowable stresses.
,j------- ------ ---.:::
~ -----------~1738 1738
100
L ---,.---;-15_0
1- 900 -1--1-1---,I • IT
f f 200-
0
o
t-
0 0
\0
I·
15
·1
LL 150
-----....;..----,-_._.................._...........
T
0\
1
I I 1- -1 400
Beam cross section
Prestressed steel .....•..........•.............••..••....._ .._ ...................................... L-_ _~
hOllom==--17 .67
Stresses at transfer
/
[-- ---- -- -- ---=--- -- -I
I~
6m Beam elevation
59.9
600
-I
The .allowable compression stress!ci and the allowable tension stress !Ii can be obtamed using the compressive strength of concrete at the time of pre-stressing !cui as follows:
Solution Step 1: Calculate section properties A = 900x150+600x200+400x150 = 315000 mm
!ci = 0.45 X !cui =0.45 x 38 =-17.1 N/mm2
2
Sirce the section is not symmetrical, one should calculate the CO.
y
= ~oox 150x 75 + 600 x 200x450 + 400x150x 825 = 360.7 mm 315000 3
3
I = 900x150 +900XI50X(360.7 _75)2 + 200 x 600 + 200x600x(450-360.7)2
12
12 3
+ 400 X150 +400XI50x(825-360.7)2 = 2.887 X lOiO mm 12
4
Ytop= )I =360.7 mm
Z top
1o
Zbot
=_1_ = 2.887x1e Yo~t
= wo,w
Yc
2
Step 2: Calculate the initial prestressing force at transfer At transfer, the self-weight is the. only load that acts on the beam at transfer.
M
2
L2 = 7.875x6 =141'75kN' 2 2 ..m
=
wOW
ow
The eccentricity of the cable from the C.G, of the section equals:
= Y top
e
y bot =t~ - Y = (150 + 600 + 150) - 360.7 = 539.3 mm I 2.887 X 1010 = -- = Ytop 360.7
fa = 0.22~fcui = 0.22.,[38 =1.365 N / mm
-cover = 360.7 -100 = 260.7 mm
The first prestressing force is obtained from the critical condition at the bottom fibers, which is tension as shown in figure and is given by:
6
80.053 X 10 mm 3
J;
-
bottom -
= 53.546x106 mm 3
P; p;xe Mow -A" + --z--- Z bot
539.3
bot
Assuming that Pi is in leN, and applying in the previous equation, one gets:
xA= 25 ", 315000 1,000000
7.875kNlm'
+1.365 =
p;) x 1000 +[;) x 1000 x 260.7 315000
100
L !- -I_...l...-,-_
53.546 X 106
6
141.75 X 10 53.546 X 106
Pi1=2367.7 leN
900
150
TT~ o o
___ : __ Jt
1
_!!.L A
_Pi xe Zbo,
Mow +-Zbo,
1.0
150
T
!- -l 400
601
_!!.L A prestressin
+Pi Xe Z,op eccentricit
602
_Mow Z,~p
external load
- Pi p'xe - - -Mow -f bo, - -A- +Zrop Z,op resultant
The second prestressing force is obtained from the critical condition at the top fibers, which is compression as show~ in figure and is given by:
Step 3: Calculate the required prestressing steel For low relaxation stress relieved strands, the code specify the yield stress as:
= - P; _ p.. Xe + Mow
f lop
A
ZIOP
fpy = 0.9xfpu = 0.9x1900 = 1710 N/mml
ZIOP
The allowable prestressing stress at time of transfer is given by:
6 P;l X 1000 _ P;l X 1000 X 260.7 + 141.75x10
-17.1 =
315000
6
6
80.053x10
80.053 X 10
fP
= smaller of {
0.70 fpu = 0.7 X 1900 = 1330 N Imm 2 0.8 fpy = 0.8x1710 = l368 N I mm 2
bi=l330 N/mm2 The allowable stresses at the bottom and top fibers of the section are -17.1 N/mm2 and + 1.356 N/mm2, respectively. The calculation of the prestressing
A
=.!J.... = 2367.7 X 1000 = 1780 mm 2 f. l330 . pI
force should be based on the smaller of the two values obtained from the analyses of stresses at the bottom and top fibers (Pil=2367.7 kN.m). This is attributed to the fact that at the case of transfer the self-weight moment produces stresses that are of opposite sign compared to the allowable stresses.
Step 4: Calcl,llate stresses at the service load stage The total load is the summation of dead and live loads:
Final design Pi=Pi1=2367. 7 kN
w lotal =wow +WDL +W LL
ps
=7.875+8+14= 29.875kN 1m'
The total moment at the support equals:
A summary of the calculations is given in the following table.
2
M
=w101
2
2
L = 29.875x6 =537.8 kN.m
2
Item
bottom condition
Top condition
Allowable stress N/mm£
+1.36
-17.1
The effective prestressing force at the time of applying all service loads is:
Actual stress
+1.36
-17.10
Pe
Force (kN) N/mm£
2367.7
2934.2
Pe = (1-0.15) x 2367.7 =2012.5 kN
Stress at opposite fiber
-l3.46
2.32
101
The allowable stresses at service load stage for stage B equals; fie = 0.44.Ji: = 0.44
N/mm2
Condition
=(I-losses) Pi
safe
. f
unsafe
603
2
f ce = 0.40 feu = 0.40x50 = -20 N I mm 2
ftop=-17.1
ftop=-13.46
(",_=+1.36·
.J5o = 3.l3 N I mm
unsafe
f7
("'_=-2.~
.
2012.5 x1000 315000
flOP
=
flOP
= 1-6.231N I mm 2
2012.5 x 1000 X 260.7 537.8x106 80.053 X 106 + 80.053 X 106 •• ,
< 1-201 (sofe) 604
fbol/om
Example 8.5
P. P. Xe M total =~A+-Z---Zbot
bot
2012.5 x 1000 + 2012.5 xlOOOx260.7 315000 53.546x106 fbol/om
= -6.63 N
I mm 2
•••
Assuming that the cantilever beam shown in Example 8.4 may be categorized as case D and based on the service load stage, calculate the maximum value of the live load that can be added to the beam.
6
537.8x10 53.546 X 106
Data:
< -20(safe)
/pu =19 N/mro 2 2 feu =50 N/mro feu j= 38 N/mm 2 Losses 15% L=6.0m
The beam is considered safe because non of the extreme fiber stresses exceed the allowable stresses.
.. 900
150
f
\ I
I I
I I
8
1- ---1 I • I,
f 200-
l T
---l_~_
I-
o
o
\0
0\
150
T
II 1- 400 -1 Beam cross section
I I
I
605
100
606
1
!, =_ p. _ p.
Solution
A
top
Step 1: Calculate the maximum moment at service load stage W 101 =w ow +w DL +w LL +wodd = 7.875 + 8 + 14 +W aM
= 29.875 +w add
-
The total moment at the support equals: M 10lal
=
W IOI L2
=
W tot
2
x6
=18 wlot
M
= 0.85..Ji: = 0.85
.J5O = 6.01 N
ZIOP
6
2012.5 xlOOO 315000
2012.5 xlOOOx260.7 + Mlotal2. X 10 80.053 X 106 80.053 x 106
total.2=1517.2 kN.m The chosen moment is the smaller of the two moments, because it will result in opposite fiber stress that is less than the maximum allowable stress (see the comparison table below).
The allowable stresses at service load stage for case D equals: fIe
+ Mlotat
M
2
2
+6.01=
Xe
-ZIOP
total =Mtotal.l=1253.3 kN.m 2
I mm 2 Mlolat
fee =0.40fcu =0.40x50=-20N Imm 2
= 1253.3 = WIOI x 6 2
,
WIOI = 69.6 kN 1m The first critical moment is obtained from the critical stress at the bottom fibers. wtot=29.875+waddl
Thus the load that can be added to the beam equals:
tlllllll~
A
------
1~20
.
Wadd= 39.8 kNlm/
- - . - - - - - - Pr 2012.5
1------6 m----t
f bOllom
=- p.
A
+ Pe Xe Z
WIOI =69.6= 29.875+wadd
Item
bottom condition
Top condition
Actual stress N/mmz
-20.00
6.01
w tot (KN/m')
69.64
84.3
(KN/m')
39.76
54.4
2.72
-26.45
safe
unsafe
_ M lotal
bot
Z
Wadd
bot
Stress at opposite fiber* -20=
6
2012.5 X 1000 + 2012.5 X 1000 X 260.7 315000 53.546x106
Mtolall x10 53.546x106
N/mm2
Condition
Mtotal,1=1253.5 kN.m frop=+2.72
~he
second ~ritical moment is obtained from the critical stress at the top fibers.
f------~
'h
wtop29.875+Wadd2
1..=6.01
A
- ,
I IIIII _
-
-- - -
~-----6m-----~
607
-
Pe=2012.5 -
fboltom=-20
* Calculations are not shown. 608
fro p=6.01
-~
W
fbottom=-26.45-
O
Load
8.3 Flexural Strength of Prestressed Beams
8.3.1 Introduction
failure
The main objective of the prestressing procedure is to produce a member that is almost free of cracks at service loads. However, the satisfaction of concrete and steel stress limits at service loads does not necessarily ensure adequate strength and does not provide a reliable indication of either the actual strength or the safety of a structural member. It is important to consider the non-linear behavior of the member in the ultimate stage to ensure that it has an adequate structural capacity.
Ultimate
Yielding
las tic range: load changes are resisted by stress changes
--- --- ----- -- - --------- ----
J
Transition range: load changes are resisted by stress changes+ shift of the pressure line
If external dead and live loads are applied to the prestressed concrete member shown in Fig. 8.5, various loading stages are noted. A typical loading history along with stress distribution is given in Fig. 8.5 and Fig 8.6. The following is a summary of loading stages: 1.
2.
3.
!c,r
The initial prestressing force Pi is applied to the beam and is transmitted to the concrete together with the beam self-weight. This is usually called the transfer stage. At the serVice load stage, the full superimposed dead load is applied. In most cases, this will produce compression stresses all over the cross section as shown in Fig. 8.6. Most of the long-term losses including creep and shrinkage have occurred leading to net prestressing force of Pe •
1_ _
--
-Iecompre~sion
f=1~
Bru.ored
-----------f
full d=llood
If the load is further increased due to the introduction of the live loads, the upward deflection due prestressing is canceled (or balanced) by the applied external loads, and the resultant deflection is equal to zero. The stress over the cross section is uniform and equals PIA. This is called the balanced stage.
4.
A further increase in loading will produce tension at the bottom fibers and zero stress at the prestressing steel level. This is called the decompression stage.
5.
At this stage the beam probably is at the full service load stage. If the loads are furthered increased the developed tension stresses at the bottom fiber reach the concrete tensile str<:?ngth !ctr. At this stage the beam stats to crack and the inertia of the beam drops dramatically. This called the cracking stage.
6.
Finally, overloading of the member occurs leading to the ultimate condition of the beam and the final collaps~ of the member.
609
Elastic range: load changes are resisted by shift of the pressure line
Deformation .iPi =Initial prestress camber .iPe =Effective prestress camber ilo =self-weight deflection ~D =dead load deflection .iL =live loa~ deflection
Fig. 8.5 Load-deformation curve at different loading stages for prestressed beams 610
T wkNlm'
8.3.2 Calculations of the Ultimate Moment Capacity
P-
I·
L
I
·1
tension
compression
compression
-II-
-II-
I-J
I
compression
H
I
f
I 1
The ECP 203 requires that the moment due to all factored loads not to exceed the ultimate capacity of the section. The ultimate moment capacity Mu is calculated in a manner similar to that adopted for ordinary non-prestressed beams. If a prestressed beam is loaded up to failure, the distribution of the stresses becomes nonlinear and the strain in the steel'continues to increase with noticeable large deformations. The code assumes that the final failure occurs when the concrete strain reaches 0.003. Since the stress-strain curve of the prestressing steel does not contain a well defined yield plateau, the stress in the tendons continues to increase beyond the yield point at a reduced slope. The final steel stress at ultimate iPs must be predicted in order to compute the ultimate capacity of the beam. Referring to Fig. 8.7, eqUilibrium of the internal forces gives C e +Cs =Tp +T ............................................. (8.10)
At transfer
Full dead loads
At full service load
0.67 feu b a + A; xly 1.5 1.15
Ultimate
Fig. 8.6 Stress distributions at various stages
During the loading of a prestressed concrete beam, the neutral axis starts to rise at a relatively uniform rate as the external loads increase. This behavior continues until the beam cracks. After the cracking load has been exceeded the n~u~~ axi~ rate of ~ovement decreases as additional loads are applied, a~d a slg?lflcant m~reas~ m the s.tress in the prestressing tendon begins to take place. This change m actlOn contmues until the applied loads are entirely resisted by proportional changes in the internal forces, just as the ordinary reinforced ~oncrete .. At the ulti~ate stage, additional moment capacity is created by an mc~ease m ~he magmtude of the components of the internal couple rather than by mcrease m the arm of the internal couple as shown in Fig. 8.5. . The fact that the load is carried at the ultimate by different actions that are significantly different than those in the elastic range makes the ultimate strength ca~culations essential for all prestressed members to ensure that adequate safety eXists.
= Aps X fps + As X fy 1.15
...................... (8.11)
1.15
in which Ce is the compression force in the concrete. Cs is the compression force in the non-prestressing steel Tp is the tension force in the prestressing cables T is the tension force in the non-prestressing steel
0.67 feu 11.5 0.003
r----:-:I
I--~c----Cs
,-,---Ce
(
._-------- .-__ _---- .-.
..__._.. ..
I·
..
T=As//1.15
b
Fig. 8.7 Analysis of a prestressed section at'ultimate
611
612
The depth of the compression stress block (a) is determined from Eq. 8.11. For rectangular sections with prestressing steel in the tension side only, the ultimate moment is given by:
Mu . Ap~.::ps
(d p-~) ............................. (8.12)
where dp is the distance from the prestressed reinforcement to the compression fiber. For sections reinforced ·with both non-prestressing steel (tension and compression) and prestressing steel as the one shown in Fig. 8.7, the ultimate moment Mu is given by: .
M= Aps1.15ips (d _E..)2 + As1.15 xiy(d X
u
p
y
_~)+ A; xi (~-dl) .... (8.13) 2
1.15
2
Total amount of prestressing steel and non-prestressing steel reinforcement shall be adequate to develop at least 1.2 the cracking moment Mer given by the ECP 203 (explained in details in Chapter 9). Exception is made for ~exural members with shear and flexuraL strength that exceed twice the ultimate design moment and for unbonded post-tensioned slabs. In all of the above equations, prestressing steel stress at ultimate /ps is unknown because the stress-strain curve is non-linear as shown in Fig. 8.8a;
8.3.3 Calculation of Prestressing Steel Stress at Ultimate fps The calculation of/ps depends on whether the tendons are bonded or unbonded.
8.3.3.1 Calculation of
in Bonded Tendons
A: Calculation of fps Using the Strain Compatibility At transfer, tendon stress is equal to the initial prestressing stress /Pi and the external moment equals the self weight moment. As creep and shrinkage occur, the concrete shortens and the stress in the tendon drops to a value less than/pi as shown in Fig. 8.8b. When service loads are applied, the beam deflects downward and the cable elongate. Since the developed bending strains are small compared to the strains in the prestressing steel, only a slight increase in the tendon force occurs. The increased internal moment (from Mow to Ms ) required to resist the moment produced by the live loads, is created by an increase in the arm of the internal couple (the neutral axis moves upwards) without any significant increase in tendon stress. When the tensile stress in the concrete equals the tensile strength (occurs at Mer), cracking occurs and the tendon stress increases by the amount equal to the tension formerly carried by the concrete. If the load is further increased, the strain in the prestressing steel increases at an accelerated rate and the beam undergoes large deflections and reaches /ps at the ultimate condition (Mu). For under-reinforced beams, the final failure occurs when the maximum compressive strain in the concrete reaches a value of 0.003. Losses due creep, shrinkage, rela,::Ition
/Pi
.-----.J
Increase in tendon stress after cracking
/ps
\
/pe 1 1 1
•
til til
1 1 1 1 1 1 1 1 1 1 1 ·1
(\)
!3
CI)
s:: 0
"t::I
s::
~
Strain, Eps
fps
The ECP 203 provides two different methods for calculating the steel stress at ultimate for bonded tendons. These two methods &re: • The strain compatibility method. • The simplified method.
..
•
Mow
Ms
Mer
Mu
Fig. 8.8a Stress-Strain curve for prestressing reinforcement
Fig. 8.8b Tendon stress as a function of the applied. load
613
614
Moment
T I Calculation of ~e
The ECP 203 states that the strain in the prestressing steel at ultimate Cps can be computed as the sum of three components as follows (refer to Fig. 8.9). Cps
== c pe +cce +c pe
•••••••••.••••••••.•••••••••••••
(8.14)
Where the strain in the prestressing steel due to prestressing after computing all losses.
Eps=
Ece
= the strain in concrete at the level of the prestressing steel due to prestressing after computing all losses (decompression strain).
Epc
= the strain in the prestressing steel determined using equilibrium of forces.
Calculation of ~ The first compone~t Epe is the strain due to prestressing, and can be computed simply by applying Hook's law as follows:
!,
At transfer, the bottom fibers are subjected to compressive stresses due to the existence of the prestressing steel. After applying the service load, the stresses at the bottom fibers decrease gradually until reaching zero. The strain required for the concrete stress to reach zero at the level of prestressing steel is called the decompression strain Cce as shown in Fig. 8.10. From compatibility of the strains, the strain in the concrete must be equal that of the prestressing steel.
l 1
iI
C;. ==
C
=E =p. E fpc p
lAps
•••••••••••••••••••••••••••••••
(8.16)
Ee
where Ec is the concrete modulus of elasticity at full strength and fce is the stress in the concrete due to prestressing force after considering all losses and is given by Eq.8.17. fee
. p.
fee ••••••••••••••••••••••••••••••••••••••••••
(8.15)
==
P" + p" XeXe A
I
......................................... (8.17) . .
p
where Ep is the steel modulus of elasticity, Pe is the effective prestressing forceand Aps is the cross sectional area of the prestressing steel.
tension
compression
......--1.-................._ ...._ .............
0.67 feu 11.5 0.003
1---1-1--- Cs
Mu "0
..j"
(
t-l
~--Cc
••
5 Aps A.
T==As//1.15
b
strain due to '. decompression
prestressing.force only
Fig. 8.10 Stresses in concrete due to prestressing and at decompression stage
Fig. 8.9 Strain and stress distributions at ultimate for a prestressed beam 615
decompression stage
616
,Calculation of lh
B: Calculation of fps Using Empirical Equations
After the decompression stage the behavior of the prestressed beam becomes similar to that of an ordinary reinforced concrete beam as shown in Fig. 8.9. From the decompression stage to the ultimate stage, additional strain .!:pc starts to develop in the prestressed steel reinforcement. Since the maximum concrete strain at failure stated in the ECP 203 is 0.003, the corresponding strain in the steel above the decompression stage can be calculated from: ,
The previous procedure for calculating the prestressing steel stress at failure is reasonably accurate but it is time consuming. The ECP 203 states that the stress in the bonded prestressing steel at failure can be predicted by the following empirical formula only ifhe>0.5 hu as follows:
d -c
c pc = 0.003x-Pc
............................... (8.18)
Ips = Ipu
where dp i& the depth of the prestressing steel, c is the depth of the neutral axis obtained froD! the equilibrium of all forces acting on the section including nonprestressed steel using Eq. 8.11.
[l-17 (J.1p ~+~( OJ-OJ,))l······················ (8.21) 0.8/
where
The material strength reduction factor for the prestressing steel (Yps) is taken as 1.15. The corresponding stress at ultimat~ Ips can be obtained from the idealized stress-strain curve suggested by the code as given by Eq. 8.20 and Fig. 8.11.
OJ' -
J.1' (
Iy
0.801cu
)
As J.1=-bxd
,j _ (cps_cpyIYps) , ( ) Ips - Ipy + x Ipu - Ipy ....•... cps> c py 11.15 (8.20a) (cpu -cpylyps)
= Cps XEp
! 1, j
If the strain Cps is less than the yielding stn b (cylYps), thenhs equals: Ips
1
..........•... :..................... Cps <,:;,cpy 11.15 (8.20b)
j 1
hul'Yps --------------------------------------------------h/'Yps hI 'Yps
'1 ,1 "
I
! I
I·,; ,
17 p is a factor for the type ofthe prestressing steel
=0.68
for h/hu ~ 0.80 = 0.5' for hihu ~ 0.85 = 0.35 for hihu ~ 0.90 d is the depth of the non-prestressed steel dp is the depth of the prestressed steel b is the width of the compression zone. If the beam has a flange, use the width of the flange (B). However, if the neutral axis falls in the web use the width of' the web (b). For the influence of the compression steel to be considered, two limits imposed by the code must be satisfied: 1. (J.1P
~) + ~(OJ - OJ') ~ 0.17 .: ............................... (8.22) 0.8/
2. d'
~0.15
dp
••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••
(8.23)
','
.!:pu
Strain
Fig. 8.11 Idealized stress~strain curve for prestressing steel 617
When the term [(J.1 p Ipu /0.8/cu )+d /d p (OJ-OJ')J in Eq. 8.21 is small, the compression reinforcement does not develop its yield strength and Eq. 8.21 becomes un-conservative. This 1S the reason why the term 618
[(,up fpu 10.8feu )+d Id p (to-a/)] in Eq. 8.21 may not be taken less than 0.17, if the compression reinforcement is taken into account when computing
hs. If the conditions given by Eq. 8.22 and Eq. 8.23 are not met, the compression reinforcement contribution is assumed to be zero (ro'=O) and in this case the term [(,upfpuI0.8feu)+dldp(tO-tO')] may be less than 0.17 and an increased value ofhs is obtained. However, the contribution of the compression steel in calculations ofthe ultimate moment (Eq. 8.13) should be considered.
8.3.3.2 Calculation of
In order to ensure a good serviceability behavior for members with unbonded tendons, a reasonable amount of non-prestressing steel has to be used. This steel COI1trols the flexural cracks and contributes to the ultimate moment capacity. The minimum area of non-prestressing steel As for a prestressed beam with unbonded steel equals.
As
= 0.004 A
............................................ (8.25)
where A is the area of the part of the section between the tension face and the
e.G. of the beam as shown in the figure below.
IPs for Unbonded Tendons
The grouting of the prestressing ducts is always a recommended practice. However, in some situations such as in two-way slab systems or in voided slabs, it is difficult to perform grouting operation in the ducts because the thickness of the concrete section is small.
C.G
Members with unbonded strands lack the bond between the concrete and the prestressing steel and accordingly strain compatibility method cannot be used. Therefore, it is clear that the expressions presented for stress in prestressed bonded steel is not applicable for unbonded steel. However, Eq. 8.12 and Eq 8.13 for the calculation of the ultimate moment Mu are still valid since they are derived from the satisfaction ofthe equilibrium conditions. The ECP 203 presents the following set of expressions to estimate unbonded prestressing steel. •
hs
in
For members with unbonded tendons having a span-to-depth ratio of 35 or less (applies to most beams):
·f
-f ps - pe
+70+( 125feu,up )
(N/mm 2 )
••••••••••••••••••••••••••
(8.24a)
but not greater thanhy and not greater than ((pe+420 N/mm2) • FOr members with unbonded tendons having a span-to-depth ratio greater than 35 or less (applies to most slabs):
fps
= fpe + 70 -+ (
feu ). 375 ,up
(N/mm 2 )
••••••••••••••••••••••••
(8.24b)
but not greater thanhy and not greater than ((pe+200 N/mm2) Photo 8.3 Prestressed concrete bridge with multi levels 619
620
Subsisting with code limit on CVr of 0.28 gives:
8.3.4 Maximum Limits for the Areas of Prestressing and non-prestressing Reinforcing Steel
~ S 0.55 ....................................... (8.32)
The amount of steel in prestressed members should be limited to ensure ductile failure (similar to c/d limitation for ordinary concrete memt>ers). The limitation rarely presents a problem for me!Uber;; with reasonable am::mnt of prestressing steel. The reinforcement index for prestressing and non-prestressing steel shah be limited to:
dp .
For T- sections (refer to Fig. 8.12), if the neutral axis lies inside the flange, the flange width (B) is used instead of the web width b as follows:
Aps p - B xd p
()) -
m, = ( OJ, + :, (OJ- OJ'))" 0.28 ..........................•..... (2.26)
X
fps 0.80feu'
As ( fy ) - B xd 0.80feu'
())-
()), -
A: (
- B xd
fy ) 0.80feu
However, if the neutral axis lies in the web, the reinforcement is given by: . Where
())p
A: (
w, = (w,. + :, (OJ. -wJ) "
Aps- x fps As ( fy ) ()), - - fy ) =())--b xd p 0.80 feu' - b xd 0.80Ieu ' - b xd O.~?feu
Equations 8.26 can be presented in form of cldp, where c is the neutral axis depth obtained using the equilibrium of forces and dp is the depth of the prestressing steel. For example, for rectangular sections the substitution with the values of CUp, (0 and (0' in Eq. 8.26 gives:
ill I
=_1
__
(~xfps +~(~(fL) ~(fL)11 d b xd feu t xd feu ))
0.80 b xd p feu
C4 = (Aps xfps
p
..
0.28 .................................... (8.33)
in which the ordinary reinforcement indices (ffiw,ffiw') should be based on the . web width (b) as follows:
(8.27)
~As xfy -A:Xf y ) ................................ (8.28)
0.80xb xd p xfeu
.
The compression force in the web equals:
0.67 feu b a 1.5
--~--=
Aps X fps As.x fy +--1.15 1.15
A;Xfy .. .................... (8.29) 1.15
Comparison of Eq. 8.28 with Eq. 8.29 gives.
C4 = (compreSSionforce inthewebX1.15) .................... :. (8.30) 0.8xb ):d p xfeu
XbX(0.8C)/1.5~1.15)=0.51;
C/{.=(0.67Xfeu 0.80xb xd p xfeu 621
p
................. (8:31) Photo 8.4 Maysville cable stayed bridge, USA.
622
The prestressing reinforcement index (c.opw) is based on the compressed part of the web as follows:
()) = ·Apw
x
b xd p
pw
Apw
= Aps -
! ps
0.80!eu
Example 8.6: Mu using the approximate equation (I-section) Calculate the ultimate flexural capacity (Mu) for the cross-section shown in the figure below. The beam is pretensioned with bonded tendons having an area of 1780mm2 •
•••••••••••••••••••••.•••••••••• (8.34a)
.{pe=1020 N/mm2
Apf ......................................... (8.34b)
.{py=1710 N/mm2 Apf
= Cf .......................................{8.34c)
x!ps
1.15
.{pu=1900 N/mm 2 icu=50N/mm
C
f
= 0.67X!eu
.<: -b) ts
2
........... ;................ (8.34d)
1
L
1-1._ _ _B_~_---l·1 a 0.67 x feu
I·
900
---j
1
150
1.5 Cs=A~!11.15
Mu
1T 0 0
~
200 - - - -
\0
------------------------l-4t-f..-!:.:~~--=::.--I----
T=As/y
.15
Fig. 8.12 Forces in T- prestressed beam
If the reinforcement index is exceeded, strain compatibility computation must be carried out to determine the strength of the section.· Similar to rectangular sections, the reinforcement index for T -sections (Eq. 8.33) can be simplified to: .
I
I
0 0
LL
100
•
150
T
t-- --I 400
Beam cross-section
0.64 a ~ 0.28 ................................... {8.35) dp
or
!!.- ~ 0.55 ....................................... (8.36) dp
623
624
1
0\
Solution Step 1: Check the applicability of the approximate equation
ll7l--~r-r-r-r""J1'""7~,....;....---:.!J~,--___O._67_:_50 / 1.5
To apply the approximate method the following equation must be satisfied
Ipu
f pe>2 ':1020 >
f
19~0 ,the approximate equation can be used to calculatejps.
150
a=140.3
f
'-'f
o
o
L200-
Step 2: Calculate the ultimate moment Since the section does not contain any non-prestressed reinforcement, the effective stress [ps equals:
IF
~/~ [H,(I" O.{;/J]
dp
= t -cover = (150+ 600+ 150) -100 = 800 mm
Assuming that the neutral axis is within the flange,' the prestressing reinforcement ratio should be based on the flange width of 900 mm.
I
f1 p
I (1710) For......!!L- - ~0.90~~1Jp I pu 1900
Ips = 1900 [1-0.35 (0.00247
00
Aps
= 1780x1821.91 (800_ 140.3 ) 1_ 1 15 X-6 - 2058.2 kN.m . 2 10
.
1900 )] = 1821.91 N Imm 0.80x50
2
Applying equilibrium equation, and assuming that the neutral axis within the flange
0.67 xicu xB xa _ Aps xj ps 1.5 1.15
0.67x50x900xa 1780x1821.91 =----1.5 1.15
a =140.3 mm as assumed <150 mm
625
=1780
M = Aps xips (d _~) u 1.15 p 2
u
=0.350
o
' - -_ _ _...J ---------------------"---~--
M
Aps 1780 =--= =0.00247 B xd p 900 x 800
~ o
\0
626
Example 8.7: Mu using the approximate equation (T -section)
Solution
Compute the ultimate moment capacity for the T -beam shown in the figure below. The beam is pre-tensioned with bonded normal stress relieved tendons.
Step 1: Check the applicability of the approximate equation
Data
To apply the approximate method, fpe > fpu must be satisfied. 2
2
Aps=1500mm
feu = 40 N/mm2 fpu =1800 N/mm
--7 2
Step 2: Compute fps
fpe = 980 N/mm2 Check that the area of the prestressing steel is less than the maximum allowed by the code.
1000mm
I'"
-
§ 0 0
1800 . . 980> -2- , the approxImate equatIOn can be used to calculate hs.
T
I
...
, I
Since no ordinary steel is provided, (0=00'=0
For normal stress relieved strands, the ratio
h!hu = 0.85, thus:
f
For 2L :2: 0.85 --7--7'1] = 0.50 fpu p Assuming that the neutral axis is within the flange, the prestressed reinforcement ratio shall be based on the flange width of 1000 mm.
80
'0
""-
,
Aps
- - -e. I"
"I
250mm
Aps 1500 f..l = - - = =0.0025 p B xd p 1000 x 600 fps=f pu [1-'I]p(f..lp
fpu )]=1800 [1-0.5(.0.0025 1800 )] 0.80xfcu . 0.80x40
fps = 1673.44 N I mm 2 0.67 x 40 1.5
1000
Beam cross-section
80
---------------·---------f-...--f-------....L._---1_ _
627
628
Step 5: Compute ultimate moment capacity Mu
Step 3: Check the neutral axis position
ApplicatiQn of the equilibrium equation gives: Applying the equilibrium equation, the compressed area Ac equals: 0.67 X feu xAe _ Asp xfps 1.5 1.15
0.67x40xAe _ 1500x1694.5 1.5 1.15
'Ips
Since the neutral axis is outside the flange, the reinforcement index should be based on the web thickness of 250 mm. Aps 1500 = 0.01 flp = b w xd p = 250x600 ps
=1800
Asp X Ips 1.15
0.67x40xA c 1.5
1500x1293.75 1.15
The area ofthe hatched flange Al equals:
Since the compressed area Ae is greater than the flange area, the neutral axis is. located outside the flange (a>ts). Hence, our assumption is not correct and hs should be recalculated.
Step 4: Recalculate
Ac
X
Ac = 94450mm 2
=122169 mm 2
Ae
f
0.67 x leu 1.5
[1- 0.50 (0.01 1800 0.8x40
I
I
I I j I
AI = (1000 - 250) x 80 = 60000 mm 2 a = 94450 - 60000 = 34450 = 137.8 mm .
250
2
>ts
Summing the moments about the prestressing steel:
M=Cf(d -~)+. C (d -~) 2 2 u
Mu
)J =1293.75 N / mm
250
p
p
w
0.67 x 40x (1000 - 250) x80 (600 80) 0.67 x 40 x 250 x 137.8 ( 137.8) -- + . 600---
1.5 M u = 927.2kN .m
2
1.5
2
Step 6: Check the maximum reinforcement ratio According to the code, the maximum reinforcement index rot should be less than 0.28. Al
ro, = (""" + 80
~ (ro" -",:))"o.28
Apw Ips ere (j)pw = - x --'--b xd p 0.80lcu
·Wh
A2
o o
\0
-----------------·----·---1-41H---------''----'-:-~
0.67xlcu(B -b) ts 0.67x40 (1000-250)x80 3 = =1072xl0 N 1.5 1.5 ApI xlps =C 1.15 I ApI x1293.75
--'-'.---- =
1.15
629
1072 x 10
3
-+ A pi
630
= 952.89 mm 2
Apw =Aps -A pf =1500-952.89=547.11 mm
a
Example 8.8: Mu using the approximate equation
=~x ips
OJpw
(i),
2
b xd p
= 547.11 x 1293.75 =0.147 0.80icu 250x600 0.80x40
~ (i)~ + :, ("1. - 0 ) ~ (0.147 + 0) ~ 0.147 ( 0
(
0.28 ok.
c = 137.8 =172.25 mm 0.8 c 172.25 - = - - = 0.287 < 0.55 .... .o.k dp 600
= 137.8mm
Note that the applications of the above two procedures lead to the conclusion that the girder contains reinforcement of 52% of the maximum area of steel. •
The first procedure
---?---?
0.147/0.28=52%
•
The second procedure ---?---?
0.287/0.55=52%
Determine the ultimate moment capacity for the bonded low-relaxation stress relieved strands for the rectangular cross-section shown in the figure below. The material properties are
leu =45 N/mm2 2 /pu=1900 N/mm /y =400 N/mm 2
he=1l17 N/mm
2
•
50
250
, !. -\ -t -."-.-."
-,----L-.....- i - - - - i
5;~·-·- .... ·._.- 50 " ..
.....
A ~=640mm2
A ps=580mm2 As =1220mm2
Beam cross-section
Photo 8.5 Trans-America bnilding, USA 631
632
Solution
For low relaxation strands h//Pu=0.9,the coefficient
Step 1: the applicability of the approximate equation
fps
To apply the approximate method fpe '> fpu must be satisfied
fps = 1900 (1-0.35XO.228) = 1747 N / mm 2
1] p
= 0.35.
= f pu(l-1]p XRp)
2
Step 4: Determine the ultimate moment capacity ':1117 > 1900, the approximate equation can be used to calculatehs. 2
0.003
Step 2: Calculate section properties d = 750-50 = 700 mm
0~/1.5
.--·-·-·-··························-'····I~-I-···············~--~~-Cs
d'=50
d p = 750-100 = 650 mm
'----- Cc
A 1220 f.1 = b:d = 250x700 = 0.007
f.1
'=~= bxd
640 =0.0037 250x700
Aps 580 f.1 p = bxd p = 250x650
.15
Aps=580mm2 L-_--IAs =1220 mm2
T=Asf11.15
./
0.0036
Strain and stress distributions for th~ beam
Compute the reinforcement indices 00 and 00' f 400 0; = f.1x-y- = 0.007 x = 0.077 feu 0.8x45 fy 400 0;'= f.1'X- - = 0.0037 x =0.041 feu 0.8x45
0.67 feu b a 1.5
A; fy 1.15
As fy . Aps fps . 1.15 1.15
-----"-=--- + - - =- - + -..::.::~=-
0.67x45x250a 1.5
------ + a=215.5 mm
640 x 400 1.15
= 1220x400 +580x1747 ---1.15
1.15
and c=269.36 mm
Step 3: Determine prestressing steel stress at ultimate f ps To account the compression steel in hs calculations, two conditions must be satisfied: 1.
Check yielding of the compression reinforcement fs
,
c -d' c
= 600 - - = 600
= Aps
M u
=(0.0036X1900 + 700(0.077-0.041))=0.228>0.17"'0.k
R p
2.
0.8x45
650
50 < 0.15x650 = 9.75···.o.k
633
M
fps (d 1.15 p
269.36-50 269.36
400. CompresslOn steel yields
= 488 N I mm 2 > -
1.15
_!!:.)+ As fy (d _!!:.)+ A; fy (!!:.-d') 2 1.15 2 1.15 2
= 580 x 1747 (650- 215.5)+ 1220x400 (700- 215.5)+ 640 x 400(215.5 -50) "1.15 2 1.15 2 1.15 2
Mu= 741.96 kN.m
634
Step 5: Check the maximum reinforcement ratio
Example 8.9: Mu using the strain compatibility method
According to the ECP 203 the maximum reinforcement index rot should be less than 0.28.
Use strain compatibility method to calculateJ;,s for the beam given in example 8.8. The ultimate strain for the prestressing steel is equal to 0.04.
OJt
=
(p p x Ips + : leu
OJ. t
(OJ-
{(j')) ~ 0.28
Data
p
feu =45 N/mm2
= (0.0036X1747 + 700 (0.077 -0.041)) = 0.213 < 0.28 ...o.k 0.8x45
650
/pu=1900 N/mm2 /y =400 N/mm
2
/pe=1117 N/mm2
!!.-. ~ 0.55 dp
Ep=193000 N/mm2
269.36 -c =- = 0.414 < 0.55 ... .o.k dp
650
250
50
-.--l~.",t--I"---i~I T-'~'-'"
5~ -
._._.... _
.-.-e-.-
- ' - - - - . , . - ' - -_ _--.1
50
635
t
636
A~=640mm2
Aps=580mm2 As =1220mm2
This increase in the concrete strain (from compression to tension) is balanced by an increase in the steel strain of the same amount (0.000306).
Solution
0.67 feu 11.5
Step 1: Calculate the initial prestressing strain (epe)
0.003
t---1
I--~!--.--Cs
Pe = A ps xfpe = 580x1117 == 648000 N
'-
!--.--Cc
The initial strain due to prestressing equals: e pe
=
=fpe Ep
1117 =0.0058 193000
_ 1-_-_...1
Step 2: Calculate the decompression strain (eee) 250
The increase in prestressing steel strain as the concrete decompressed by extemalloads equals:
.15
Aps=580 mm2 A, =1220 ,.,.,,.,..4...;...L.i---'"
I
Strain and stress distributions for the beam
Step 3: Calculate strain at ultimate (&pe) The modulus of elasticity of concrete is given by: Ee = 4400
IT:: = 4400 .J4s = 29516 N I mm
2
The stress in the concrete due to prestressing only equals:
f.ee
-
Pe +.....!i.. Pe _ XeXe _
A
The eccentricity of the cable is given by: t 750 e=--cover=--100=275 mm
0.67x45x250a 1.5
. Hence, one can get: _ 648000 + 648000 x 275x 275 =9.03 N Imm 2 fee - 250x750 8.79x109 .
Ee
0.67 feu b a A; fy As fy Aps fps + - - = - - + ---!:.::......:.....!::.. 1.5 1.15 1.15 1.15
-----=.-=--
640 x 400 1.15
= 1220x400 +580x1750 ---1.15
1.15
3
3
= fee
fpy =0. 9x f pu =0.9xI900=1710 Nlmm 2
------+
2
1= bxt = 250x750 = 8.79x109 mm 4 12 12
eee
verified later. Assumefps betweenfpy andfpu For low relaxation steel,fplfpu= 0.9.
Thus, assumefps= 1750 N/mm2 •
I
2
In order to determine the depth of the neutral axis, fps must be assumed and
= 9.03 29516
a=215.8 mm c =~= 215.8 =269.80 mm 0.8 0.8 The increase in' strain from overload to ultimate equals: &pe
= 0.000306
=0.003 d p -c =0.003 650-269.80 =0.0042 C 269.80
638 637
Step 4: Calculate total strain at ultimate (Bps)
Step 5: Recalculate the total strain at ultimate Assume that hs= 1725N/mm2
Bps =cpe+cce+cpc C ps
0.67x45x250a 640 x 400 1220x400 580xl725 ------+--- ----+---1.5 1.15 1.15 1.15
=00058+0.0003+0.0042=0.0103 .
The stress corresponding to this strain can be obtained using the idealized stress-strain curve specified by the ECP 203. Referring to the figure below and recalling that the ultimate prestressing steel strain is given as 0.04, hs can be obtained as follows:
a=213.3 mm c
=~= 213.3 =266.6 mm 0.8
0.8
The increase in strain from overload to ultimate equals:
h .11.15
h /1.15
i--------:::=---r---
cpc
= 0.003 d p -c = 0.003 650 - 266.6 = 0.0043 c 266.6
f
= 1710+ (0.0104-0.0077) x(1900-1710) = 1725.8 N I mm 2
hyl1.l5
ps
(0.040-0.0077)
The calculated hs is very close to the assumed value (usually from 1-2% is close enough), the prestressing steel stress at ultimate and equals=I725 N/mm2 Checkyielding of the compression reinforcement BpJ1.15=0.0077
f py =0.9xfpu =0.9xI900=1710 Nlmm Bpy _ Ys
fpy 1.15xEp
Bpu=0.04
Bps=O.OJ03
2
__1_7_10_ _ = 0.0077 1.15 x 193000
hs=I725.3 N/mm
(0.040-0.0077)
2
2
Since it has been assumed thaths=1750 N/mm ,another trial is required.
639
CompresslOn . stee1· Yle ldS
Note: Comparing the value ofhs obtained using the simplified method (1747 N/mm2) to that obtained using the strain compatibility method, one can notice that the simplified method overestimateshs.
=1710+ (0.0103-0.0077) x(1900-1710) ips
' c -d' 60 266.6 - 50 I 2 400 f s = 600 -c- = O.266.6 = 487 N mm > l.l5
strain
640
8.4 Combined Flexure and Axial Loads. Prestressed members subjected to eccentric loading may be encountered in prestressed concrete construction. The analyses of. such sections at the service load level and the ultimate stage are outlined in the next two sections.
8.4.1 Stresses at Service Loads The stresses at service loads for sections subjected to combined flexure and axial loads can be determined according to the following equation:
f = -(~+~)± P Xe A
A
y
I.
+M
xy ......................... (S.37)
I
Where N is the applied axial load (positive sign indicates a compression force)
8.4.2 Capacity at Ultimate Loads Prestressed concrete members subjected to combined flexure and axial load are . designed using the strain compatibility as outlined in the previous section. The strains in prestressing steel located at the compression and the tension zones are calculated. The stress-strain curve for the prestressing reinforcement is used to determine the stresses. A trial-and-adjustment procedure is carried out to compute the resulting forces and moments. The neutral axis distance c is assumed, and the corresponding forces are calculated. Adjusting c in Eq. S.3S is repeated u~til equilibrium is achieved.
0.67 feu 11.5
J-I Te = Ups A' Xi'ps 11.15 L...--.---.--4-...,Lr----t-----,,-----,
Noting that the force Tc is tension, the equilibrium of the forces gives:
p = 0.67 feu b a u 1.5
A;s f;s 1.15
Having detennined c, cpc and i pc are computed using compatibility of stains as follows:
cpe ,
cpe
d -c
=0.003 - - ..................................................... (S.39a) c
c- d ' c .
To simplify the calculations of Cce and c~e, it will be assumed that the prestressing forces resulting from Aps and A ~s are such that the effective prestressing is at the C.G. of the section, producing unifonn compressive strains as shown in Fig. S.13.
Cee
=c:e =
A:E . . . . . . . . . . . . . . . . . . . . . . . . . e
(S.39c)
e
The total prestressing strains ips and c~s are calculated as follows: C;s
=c;e -(c;e -cee) ..................................... (S.40a)
Cps
= cpe + (cpc + cee ) .................................... (S.40b)
The resulting bending moment is then determined by taking moments of all the forces about the centroid of the section (location of P u ) as follows:
• • "I liPs
Fig. 8.13 Strain and stress distributions for the beam subject to P", Mu 641
,
= 0.003 - - .................................................... (S.39b)
Example S.lO illustrates the calculation procedure.
b
Aps fps --'--'- ...................... (S.3S) 1.15
642
Example 8.10: Strain compatibility method for combined flexure and axial load . If the cross-section shown in figure is subjected to P u=360 kN, compute the ultimate flexural capacity. The losses may be assumed as 12%, and the ultimate strain for low relaxation prestressing strands is 0.045.
Solution The approximate code equation can not be used to calculate iPs when prestressing steel is located in the compression zone. In such a case, the strain compatibility procedure must be used.
Step 1: Calculate the initial prestressing strain (epe)
Data feu =45 N/mm2
For low relaxation strands, fr,y= 0.9 fr,u= 0.9 x 1860 =1674 N/mm2
/p = 1860 N/mm2 f . = smaller of
Ep = 196000 N/mm2
pI
0.70 fpu = 0.7xI860= 1302 N I mm 2 { 0.8 fpy = 0.8x1674 = 1339 N I mm 2
2
50
~
/pi=1302 N/mm
300
...
fpe
•
2 strands, A ~s=150 mm2
§
= (I-losses)
f pi =(1-0.12) 1302=1145.76 Nlmm 2
p. = Aps xfpe = (150+ 150)x1145.76 == 343728
N
The initial strain due to prestressing force equals:
o V') V')
-L. • 50 -r -
e = &' = f pe = 1145.76 = 0.0058 pe
2 strands, Aps=150 mm2
Beam cross-section
pe
E
p
196000
Step 2: Calculate the decompression strain (ece) The decompression strain equals:
p.
e =--=-ee
Ae xEe
The modulus of elasticity of concrete is given by: Ee = 4400 ~ feu
= 4400 ..f45 = 29516 N I mm 2
The eccentricity at of the cable equals: t 550 e=--cover=--50=225 mm
2
&
ee
643
2
= &' = ee
343728 29516 (300x550)
0.00007
644
A- Compression force in the concrete A ~s=150
0.67 feu 11.5 '--_.--._-h--Lr-_ _-I-~I-__.I 1"" ==~s xf;.,11.15
1_ == 4.824 c kN C == 0.67 fcu b x (0.8 c) == 0.67x45x300xO.80 c x_ c 1.5 1.5 1000
B- Strain for the prestressing steel in the, tension zone o o
c
Irl
u
•
•
Aps==150
pc
= 0.003 d p -c = 0.003 500-c c
c
500-c cps == 0.0058 + 0.00007 + 0.003 - c
Cps ==cpe+cce+cpc
,. 300
0.0058
C py
Y.,.
_
f py == 1674 == 0.00742 1.15xE p 1.15 x 196000
Strain and stress distributions for the beam subject to P", Mu (C -0.00742) Ips =1674+ ps X(1860-1674) . (0.045 - 0.00742)
Step 3: Calculate the neutral axis distance (c) The equilibrium equation is obtained by equating the internal forces to the external forces as follows:
C- Strain and stress for the compression zone
Pu == Cc -Tc -Tp
C~c = 0.003 c - d' == 0.003 c - 50
Note: Tp istension
p == 0.67 fcu b a _ A~s I;s u 1.5 1.15
c
prestressing steel in the
c
Noting that the strain in the compression zone is negative, the net prestressing steel strain equals:
p == 0.67 x45x300xO.8 c _ 150>
,,' -- c'pe - (c'pc - cce') -- ( cpe , + cce') - c pc ' lOpS
,
, (cps -0.00742) ( ) , f ps = 1674 + x 1860 -1674 ..... __ .................. C > c py 11.15 (0.045 - 0.00742) ps I;s
645
(
c-~) cps == 0.0058 + 0,00007 - 0.003 c-
= c~s xEp .........•........................................ :........................... c;s 646
~'cpy 11.15
Step 4: Calculate the flexural strength. From the previous table it can be determined that Cc = 685 kN, Tc = 102.3 kN, and Tp= 222.3 kN. The moment strength can be calculated by taking moments about Pu, located at the centroid of the section as follows:
/pil.15
Mu
---r
= C
/P/1.15 I--------=..-r"~
J"J1.l5
Mu
(.!...-~)-Tc2 (.!...-d')+TP2 (.!...-cover)
c22
= 685 (0.~5 0.8X~.142) -102.3 (0.~5 -0.05) + 222.3 (0;5 -0.05)
Mu =176.4 kN.m I I
f~s ~ :
Step 5: Check the maximum reinforcement ratio
I I I I
Using Eq. 8.36
I I
I I
I
I
I
I
I
I I I
I I I
I I
I I
-4--1.£4:_ _ _ _ _ _..1-._ _ _ _ _ _ _ _ _ _
.1..:_ _
E', \ t ps ,--EpY'Yps'
F._,.
F-
c
142
dp
500
- =strain
--+-~ -
c
dp
~
0.68
= 0.284 < 0.68 •... .o:k
=O.045
-pu
-p
Stress-strain diagram for the prestressing steel
The calculations can be summarized in the following table Trial
c
E~p
Esp
f~p
0.0145
/sp
Cc
Tc
Tp
Pu
1
130 0.0041
803.6
1709.0 627.1
104.8
222.9
299.4
2
140 0.0040 0.0136 784.0
1704.6 675.4
102.3
222.3
350.8
3
142 0.0040 0.0135
1704.1
102.3
222.3
360.5
784.0
685.0
It is clear from the table that the neutral axis distance c =142 mm gives very close value (360.5 kN) when compared with the applied force (360 kN).
Photo 8.6 Prestressed concrete .beams in 15th May bridge befor ~ the construction of the concrete deck
647
648
8.5 Proper Beam Shape Selection Some of the prestressed concrete beams are fabricated in precast plants that frequently publish tables containing the properties of the cross-section and the uniform load that can support. However, in most cases the designer may have to establish the shape of the cross-section to be used in a special project. This is typically the case in bridge construction. For a simply supported beam, the eccentricity is inversely proportional to the required prestressing force. The larger the eccentricity at mid-span, the smaller the required prestressing force. A rectangular section is the easiest in· fabrication, alignment and the least in form cost. It is frequently used in buildings and parking garages. Bearing in mind that the dead loads may represent a large portion of the total loads on the structure, flanged sections are structurally more efficient because of their high moment of inertia with respect to their self weight.
T-sections and wide flange I-sections are appropriate if large eccentricity is required as shown in Fig. 8.14. In such a case, the end ·section of the be~ is usually solid to avoid large eccentricity, and to increase the shear capaclty. Double T -sections· are also used because of their stability and ease of handling. They are widely used in floor systems in buildings because they eliminate the need for slabs. Long-span parking garages may 'require I-sections with ' composite slab topping. If the self-weight is small compared to the superimposed dead and live loads, a larger lower flange is needed to carry the heavy compressive strength produced by the prestressing force. For long-span bridges, hollow box sections are ofte~ more economical. These sections have large torsional capacity. Also, thelr flexural strength to weight ratio is ·telatively high compared to other prestressing systems.
8.6 Limiting Eccentricity Envelopes The tensile stress in the extreme fiber under service load conditions should not exceed the limit specified by the code. Thus, it is important to establish the limiting zone in the concrete section. For example, for a simply supported beam at transfer if no tension is allowed for the top fiber, then:
hop = 0 = _ ~ + ~x e .................................. (8,42) lOp
Solving Eq. (8,42) for the eccentricity gives the lower kern point kb as: Rectangular
I-section
T-section
Double T-section
kb =
ZIOP
A
-l,.(below C.O.) .............................. (8,43)
.
If the eccentricity of the tendon exceeds this kern point it will cause tension at transfer.
o
At the final stage, if no tension is allowed at the bottom fibers, then: P
fbOI/Om
I
Box section
Box section With cantilever slabs
Fig. 8.14 Different types of prestressed concrete sections
649
Pexe -Z.............................. (8.44) bOI
k =-
T-section with bottom enlargement
=0=- ~ Zbol
A
(above C.O.) .............................. (8,45) '
.
'If the eccentricity exceeds the upper kern kt, it will cause teI\sion at the final stage.
Similarly, kern point can be established for the right and left parts about the line 2 of symmetry of the section. For rectangular sections, Ztop=ZboFb t /6, giving the kern points as shown in Fig 8;15.
650
t
kb
= kl =6"
(for rectangular sections only) .......... (8.46)
AB can be seen from the previous section, any force falling in the kern area will never cause tension at the section. However, many codes, including the ECP 203, allow tension stress at bottom and top fibers (Cases B, C and D). Thus, it is important to establish the limiting envelope at the maximum allowable tension because it is desirable that the designed eccentricities of the tendon along the span fall within these limits. At transfer, the top fiber is subjected to tension while the bottom fibers are subjected to compression. Thus, the eccentricity eL at transfer (as shown in Fig. 8.16) at which the top fibers are subjected to the maximum allowable tension is given by:
if. =_p;A +p;xeL_MOW ............... (8.47) 1.1t.'1o=0.22 p v J cui· Z Z
-11- b/6···..·•·······
lOP
lOp
1--~-1 Fig. 8.15 Central kern area for a rectangular section
~nsionwnel
I
U4
...
U4
-'---"-+1-'--
-+/---- U4-1
U4 - _..
Fig. 8.16 Envelope permitting tension in concrete extreme fibers. At full service load, the bottom fibers are subjected to tension while top fibers are subjected to compression. The allowable concrete tensile stress should be obtained from Table 8.2. For example, for case B the eccentricity eu (as shown in Fig. 8.16) at which the bottom fibers are subjected to the maximum allowable tension is given by:
fle.bottom
Photo 8.7 Precast-prestressed concrete beam with coved sides
651
= 0.44 Jt:: = - ~
p. xeu + M ZbOI
tolal
••••••••••••••••••••••
(8.48)
Zbot
It is usually sufficient to calculate three points for parabolic tendon (midspan, quarter span, and at support). It should be clear that an envelope that falls outside the section indicates non-economical section. A change in the eccentricity or in the prestressing force improves the design.
652
Example 8.11: Upper and lower envelopes
Solution
The cross-section of a simply supported beam is shown in the figure. The beam is post-tensioned and the prestressing cable is parabolic. Determine the limiting envelopes such that the limiting concrete tensile stress is in accordance with the ECP 203 Case B. Consider the mid-span, the quarter span, and at the support as the controlling points. Assume that:
Pi = 2400 kN Pe = 2050kN
A = 400 x 200 + 150x700 + 400x300 = 305000 mm 2
Since the section is not symmetrical, calculate the location of the center of gravity. Y
2 !cu =40N/mm
= 400 x 200 x 100 +150x700x550+ 400 x 300x 1050 =628.7 mm 305000 3
2 !cui =30N/mm
WOL
Step 1: Calculate section properties
3
1= 400 x 200 + 400 x 200 x (628.7 -lOOY + 150x700 + 150x700x(628.7 -550?
12
=5kN/m
12 3
+ 400x300 +400x300x(1050-628.7? 12 I =4.98 x 10 10 mm4
Wu = 18 kN/m'
1
1 ~
L=21m
-I
ytop= Y =628.7 mm Ybot = t - Y = (200+ 700+300) -628.7 = 571.3 mm
Z/oP
Zbo/
I 4.98xlOlO = 79.16x106 mm 3 = - = 628.7 Y/oP
= _1_ = 4.98xlOlO = 87.11x10 6 mm3 Ybo/ 571.3
200 Tfr"50
§ o
It
o
o
t-
300
·T r-
400
-J
_.- _. ._._--l--
II
Beam cross-section
653
654
Step 3: Upper and lower envelops at quarter point . The moment at the quarter point for a uniformly loaded beam is given by: Wtot =Wow +W DL +W LL = 7.625 +5+18 =30.625 kN 1m'
,
The llllowable tensile stresses at transfer fti and at full service load fie for case B are given by: fti = 0.22J feu; = 0.22.J3(j = 1.205 N I mm
wxL L W (L)2 3 (WXL2) 3 M=--x---x =-x - - =-M 2 4 2 4 4' 8 4 atmid:,pan
2
wkNlm'
jil
fte = 0.44.Ji: = 0.44.J4c) = 2.783 N I mm 2
wLR I.
Step 2: Upper and lower envelops at midspan -M
ow
I I I I 2114
I
I I
'1 }LR
L=21
= WOW XL2 = 7.625x212 = 420.33 kN.m 8 8
M t = Wtot X L2 = 30.625 x 2e = 1688.2 kN.m t0 8 8 The limiting condition at transfer is due to condition at top fibers subjected to self-weight only as follows:
Thus, the self-weight moment at quarter point equals: Mow = 0.75x420.33= 315.25kN;m M tot =0.75x1688.2=1266.2 kN.m
+ 1.205 =
. 2400 x 1000 2400xlOOOxe L 420.33 x 106 + - - - - - ; :6305000 79.16x10 6 79.16x10
The limiting condition at transfer is due to condition at top fibers subjected to self-weight only as follows:
e L =474.7 mm t
/; =_ P; + p;xe L
The limiting condition at full service load is due to condition at bottom fibers subjected to full load as follows:
+ 1.205 =
'f'
__
Jbonom . +2.783=
p.
A
top
Pe xe u Z
bot
Mtotal
+ Z
2050xlOOO 305000
_
Mow Ztop
2400 x 1000 + 2400xlOOOxe L 305000 79.16x10 6
6 315.25x10 79.16x10 6
e L = 430.64 mm t
bot
6 2050x1000xeu + 1688.2x10 87.11x10 6 87.11x106
The limiting condition at full service 10lld is due to condition at bottom fibers subjected to full load as follows: f'
Pe
Jbottom =-A
~~u =420 mm t .'-
Ztop
A
655
656
+ 2.783 = 2050xlOOO 305000 eu
2050 x 1000 x eu 87.l1x10 6
1266.2x106 87.l1x106
8.7 Determination of the Prestressing Force and the Eccentricity in Flexural Members
--------~~+--------~
= 213.8 mm J,
Step 4: Upper and lower envelops at support At support Mow=Mto/a/=O, thus the limiting condition at transfer is due to condition at top fibers subjected to self-weight only as follows: P
PXe L
hop =- ~ +~ top +1.205 = eL
The required equations can be obtained by analyzing the stresses at the top and bottom fibers of the beam for the case of transfer and service loads. This will lead to four governing equations. Plotting these equations will produce the zone of the acceptable combinations of the prestressing force and eccentricity. The procedure is illustrated in the following steps.
2400 X 1000 + 2400 X 1000 X e L 305000 79.16x10 6
= 299.3 mm J,
The limiting condition at full service load is due to cundition at bottom fibers subjected to full load as follows: P
fbottom
= ---Ae -
bot
+ 2.783 = 2050xlOOO 305000
A- At Transfer (top fibers-tension controls) The stresses at the top fibers at transfer should be less than the allowable concrete tensile stress at transfer recommended by the code (fri) as follows:
Pe xeu
Z
The prestressing force that produces safe stresses at transfer may produce unsafe stresses at full service load. The aim of this section is to find the possible combinations of the prestressing force and the eccentricity that ensure the safety of the beam at the transfer as well as at full service load. The procedure developed by Magnel (1948) is very useful as an instructional aid. It illustrates that there are frequently several combinations of prestressing force and eccentricity that will result in compliance with the code requirements of allowable stresses.
= - P; + P; X e _ M ow ~ h; ................................. (8.49)
hop
2050xlOOOxe u
A
87.l1x106
Zwp
Zwp
Rearranging the previous equation gives:
eu = -403.8 mm= 403.8 mm l'
fli
~- P; + P; Xe _ Mow A
Ztop
........................................... (8.50)
Z/()P
The eccentricity that gives the acceptable stress at top should be less than: e ~ "!"[Ztop
P;
Noting that Kb quarter lloint
\-5.25--'1-1-0---5.25--'11-..--~ '!.)-
-I'
5.25~
Upper and lower envelopes for th;e l):.'est~·essing tendor.s
r~s7 ~
....... '
h; + M oJ+ Ztop A
..................................... (8.51)
= Ztop I A e ~ "!"[Ztop
P;
h; + M oJ+ Kb
....................................... (8.52)
This can be rewritten in terms of the prestressing force as:
~ ~ [Ztop e~ ~bM ow] 658
...................................... (8.53)
B- At Transfer (bottom fibers) (compression controls) The stresses at bottom fibers at transfer should be less than the allowable compressive stress at transfer recommended by the code ifcj) as follows: 1'".' .) JI'"bot -_ _ l';_p;xe + Mow>!. - ci (becauseJc,Is negatIve ............ (854) . . A Zbot Zbot
D- At Full service load (top fibers) (compression controls) hop = - Pe + Pe Xe A Ztop
The eccentricity that gives the acceptable stress at bottom should be less than: e::;
~ [- Zbot
fei + M
oJ- Z;t
................................. (8.56)
Mtolal 'C. fee (because fee is negative) ............. (8.63) Ztop
!. ::;_;xP;+;XP;Xe_Mtotal .:........................... (8.64) ee
Thus, fe' ::; - p; _ p; X e + Mow .......................................... (8.55) I A Zbot Zbot
_
e'C.
ZIOP
A
;:~[ZI(JP
Ztop
fce+M'(J,al]+
Z; . . . . . . . . . . . . . . .
(8.65)
The eccentricity that gives the acceptable stress at top should be greater than: e 'C. ; : p; [ZI(JP fee + Mlolal]+ Kb ........................~ ....... (8.66)
I
Noting that K t =Zbot I A, the previous equation can be written in terms of the prestressing force P j .: 1 > e+Kt . p; - [- Zbot fei + Mow] .................................. (8.57)
c-
The minimum prestressing force that stratify code requirements is given by
1.- ::; [ . p;
e - Kb ] ............................ (8.67) Zwp fee + M lotal I;
At Full service load (bottom fibers-tension controls)
The stresses at the bottom fibers at the full service load stage should be less than the allowable concrete tensile stress (fie). Denoting the losses as ex, one can obtain: p. =(1- a) Pi =; p; ................................................ (8.58) fboltom
= - Pe _ Pe X e + M total A
Zbot
::; fie ........................... (8.59)
Zbot
Rearranging the terms: h 'C._;xp; _ ;xp;xe + Mtotal ............................. (8.60) e A ZbDt Zbol The acceptable eccentricity should be greater than:
e 'C. _1_[_ Zbot he + M tDtal ]- Zbot .......................... (8.61) ;xp; A
~ ::; [_ Zbot 659
;:+K;'total]I ; ........................ (8.62)
Photo 8.8 Cable placement in a box girder 660
Example 8.12: Determination of P and e combinations
The four governing equations can be summarized in the following table.
The cross-section of a simply supported beam with unbonded tendons is shown in figure. It is required to: A. Determine the acceptable combinations of Pi and e at mid-span according to the ECP 203 allowable stresses for case B.
~>e-Kb
1>; - [Zt(}P
hi + Mow]
(1)
~>
e+Kt 1>; - [- Zbot fei + M owl
(2)
B. Check the combinations of the following prestressing force and eccentricity:
~<
e+Kt 1>; - [- Zbot /'e + M ta/al ]/ ~ (3)
~<
e-Kb 1>; - [Zwp fee + M total
J/ ~
(4)
All the terms appearing in the previous equations are known and can be determined except P j and e. there are a number of combinations of these terms satisfy all the equations. The right combination can be determined by plotting each equation as shown in Fig. 8.17. In this graph, the horizontal axis represents the eccentricity, while the vertical axis represents the inverse of the initial prestressing force. The hatched area in the figure indicates the acceptable combinations of (lip; and e) that satisfy all code requirements of allowable stress in transfer and full service load stages. It should be noted that some of the possible eccentricities may not be attainable because they might lie outside the limits of the section. Therefore, these points should be excluded from the acceptable zone as shown in Fig. 8.17.
Case
Pi (leN)
e(mm)
1
2700
400.00
2
2000
250.00
3
3000
250.00
4
3000
450.00
Data Losses =15% =45 N/mm2 feu =31.5 N/mm2 fcui =21 leN/m' Wu span =20.0m 500 ~ 1- -1
physical limit
150
Transfer -------Service
Combinations outside the section
TT
L
-.J
200-
-
o o
r-
final (bottom)
ft.
1- -1 800
e
Beam cross-section Fig. 8.17 Graphical representation for the four governing equations 661
662
Solution wow
=Yc xA =25x
WIOI
=
.
Step 1: Calculate .section properties A = 500x150+ 200 x 700 + 250 x 800 = 415000 mm
wow
+ Wu
415000 =1O.375kNlm' 1000000
=10.375 + 21 =31.375 kN I
m'
2
Since the section is not symmetrical, calculate the location of the center of gravity. . = 500xI50x75+200x700x500+250x800x975 =652.1 mm Y 415000 I =5.6 x 10 10 mm4
M ow =
10
M lo,al =
5 2' .37 8x20 =51875kN . ..m
31.375x20 2 8 = 1568.8 kN.m
Step 2: Governing equations
Ytop= Y =652.1 mm Ybol
= t- Y = (150+700+ 250)-652.1 = 447.9 mm
ZIOP
=_1_= 5.6x10 YIOp 652.1
10
K = Ztop b A
K = I
Ybo/
The allowable tension stress at transfer fli is given by:
= 85.83x106 mm 3
fli = 0.22~ feui = 0.22·J31.5 = 1.235 N I mm 2 ~>
6
e-Kb P; - [Z/oP fli +MoJ
85.83x10 = 206.81 mm 415000
- I _ 5.6 X10 Zb 01
Step 2.1: Equation at transfer (top fibers-tension controls)
447.9
10
1 >
-125 106 mm 3 X
P;
6 = 125x10 = 301.2 mm A 415000
~ ~ 1.6 X10-6 (e - 206.8)
ZbOI
~ 150
IT
e-206.8 [85.8x10 6 x 1.235 I 1000 + 518.75x1000]
P;
1-500 -1
e
L. :J 200-
206.8
700
o
7.9 X 10-4
Step 2.2 At transfer (bottom fibers-compression controls)
±r1=------,I •
1-- 800 -1
beam cross section
0\
r-: ~ ~
IL0
;:.
fei =-0.45 feui =-0.45x31.5=~14.175 Nlmm 2 ~>
e+Kt P; - [-Zbol fei +MoJ
-'--
1>
P;
e+301.1 [-125X10 6 X-14.175/1000+518.75X1000]
~~0.436xlO-6 (e +301.1)
.
Pi
663
664
I
e
-301.1
l/Pi
0
I
700
I
4.37
X
10-4
Step 3: Acceptable Pi-eo diagram
I
1"1.
Step 2.3: Equation at full service load (bottom fibers-tension controls)
From the points calculated iti~:Step 2, the acceptable combinations diagram can be plotted as shown in figure. Assuming concrete cover of 70 mm, the maximum acceptable eccentricity emaxequals:
Since the beam has un-bonded tendons, it is classified as case B (refer to Table 8.2). Thus, the allowable tension is given by:
emax =
he = 0.44.fi: = 0.44.J4s = 2.95 N 1mm 2
Locating the points inside the diagram and realizing that any point falling inside the hatched area is considered safe and vice versa, the following table can be established.
.; = I-losses = 1- 0.15 = 0.85
1 -<
F: 1
F:
e+KI [- Zb(}1 he + M lnlal ]/';
Case
e +301.1 6 <{-125XI0 X 2.9511000 + 1568.8XlOOO]/0.85
~ ~0.708xlO-6
Ybol -
(e + 301.1)
cover = 414.3 -70 = 344.3 mm
P(kN)
e(mm)
lIP (x 10-4 )
Status
1
2700
400.0
3.70
Unsafe
2
2000
250.0
5
Unsafe
3
3000
250.0
3.33
Safe
4
3000
450.0
3.33
Unsafe
Pi
e
I
l/Pi
-301.1
700
0
7.09 X 10
I
I
4
I
Step 2.4 Equation at full service load (top fibers -compression controls) fei = -0040 feu = -0040 X45.0 = -18 N 1mm
1 _<
e-Kb
F: - [ZIOP
fee + M IOlal ]1 .;
e-206.8
1
F:
2
< [85.8X10 6 x-18/1000 + 1568.8 X1000]1 0.85
..!...~34.8xlO-6 (e-206.8) F: 206.8
e
I
l/Pi
I
0
225
604 X 104
I 665
I 666
Reason inside the acceptable area but outside the section outside the acceptable area inside the acceptable area outside the acceptable area
Example 8.13: Determination of P and e combinations
c3 c.5 E C'
The cross-section of a simply supported beam is shown in the figure below. The beam is a part of the structural system of a chemical factory. It is required to: A. Determine the acceptable combinations of Pi and e at mid-span according to the ECP 203 allowable stresses for case B. Adjust the cross-section dimensions if necessary.
',
e llla ,
~ +-------------~.,
,,,
,
,----+ : . .-~------.-:
Data Losses =20% 2 =50N/mm feu 2 = 35N/mm feui = 5 kN/m' WDL = lOkN/m' Wu span = 12m
_.._-_ ...
I 2
4-
I. _ _------,~Il
3
1000
I
-~I~
-400 -300 -200 -100
K,
0
100
200 300 /(11
400
500
600
700
800
T
o o
\0
e(mm)
Acceptable combinations of Pi and e
--
•
L..--
H 200
Section A-A
I~ 667
200
668
Solution Ytop=185.6
Step 1: Calculate section properties A = lOoo x 200 + 200 x 400 = 280000 mm 2 Since the section is not symmetrical, calculate the location of the center of gravity. Y
YboF414.3
= lOOOx200xlOO + 200x400x400 =185.7 mm 280000
I =6.88 x lO 9 mm4 Ytop= Y =185.7 mm Ybot
Step 2. Governing equations
= t- Y = 600-185.7 =414.3 mm
Step 2.1 Equation at transfer (top fibers-tension controls) 6 Z top = _1_ = 6.88xlO9 = 37 •03 X 10 mm 3 Ytop 185.7 6 K = ZIOP = 37.03xlO = 132.2 mm b A . 280000 Zbot
=_1_= 6.88x109 = 16.6xlO6 mm 3 Ybal 414.3
K = I
6
= 16.6xlO = 59.27 mm A 280000
fli = 0.22~ feu; = 0.22.J35 = 1.302 N I mm
;- 1 >
P;
2
e-132.2 [37.02XlO X1.302/1000+126x1000] 6
Zbot
w o.1Y =YexA=25x W/o I
The allowable tension stress at transfer fli is given by:
280000 , =7.0kNlm 1000000
= WOIY + W DL + W LL = 7.0+5+10 = 22 kN 1m'
Mow =
~~5.74XlO-6 P;
(e-132.2)
e
132.2
l/pi
o
600 26.8 x
W4
7.0x12 2 8 126 kN.m
Step 2.2 At transfer (bottom fibers-compression controls) MIDtal
22x12 2 = 8 =396 kN.m fe; =-0.45 feu; =-0.45x35 =-15.75 Nlmm
670
2
1 >
-.!:..:=; -2.322 X10-6 (e -132.2)
e+59.27 [-16.6X10 6 X-15.75/1000+126X1000]
P;
-.!:..~2.58xlO-6 P;
t
P;
(e+59.27)
e
I~32.2 600
-59.27
17.01
200
600 4 1 -10.8 x 10
..;.!,
1-7.7 X 10-4
4
10
X
j
Step 2.3: Equation at full service load (bottom fibers-tension cOffl'rols)
/'e
= 0.44fi: = 0.44.J5Q = 3.11 N Imm
I
: Step 3: Acceptable Pi-e diagram
I
. From the points calculated in step 2; the foilowing diagram can be plotted:
2
; = I-losses = 1-0.20 = 0.80
e+ K t
-.!:..<
P; - [- Zbot /'e + Mtotal]/; 1 <
P;
e+59.2 [-16.6X10 6 X3.1l/1000+396x1000]/0.80
-.!:.. :=;2.32 X10-6
P;
(e + 59.2)
e
-59.2
I/pi
o
600 15.3
X
104
Step 2.4 Equation at full service load (top fibers-compression controls)
fei
= -0.40 feu = -D.40 X 50.0 = -20 N 1 mm
-200
-100
o
100
200
300
400
500
600
2
Assuming a concrete cover of 70 mm, the maximum acceptable eccentricity
1 _<
emax equals: e max =Ybot -cover =414.3-70=344.3 mm
e-Kb
P; - [Ztop fee + M total ]1 ; 1 <
P;
e-132.2 [37.02X10 6 X-20/1000+396X1000]/0.80
671
It is clear from the diagram that the acceptable zone does not exist. For example an initial prestressing force of 200 kN (1IPi=5) and an eccentricity of 150 mm give the following stresses: 672
YIOP= Y =250 mm
At Transfer
/rop
-2.44
<-15.75
Safe
-17.62
>-15.75
unsafe
Ybol
Z ' =_1_= 1.63xl0 top Ytop 250
At Final Stage
f top
>3.11
Unsafe
-9.928
<-20
Safe
Zb =_1_= 1.63 x 1010 = 29.57x10 6 mm 3 01 Ybal 550 •
The reason for the unsatisfactory performance of this section is attributed to the fact that its size is not sufficient to resist the applied loads. One of the solutions is to increase the size of the section. Increasing the section dimension by 200 mm gives the following section properties:
;
________1_00_0____
~ ~·1~
._._CG:._._ ._ o00
c
a.1V
I 320000 =8.0kNlm 1000000
M ow =l44kN.m MIOI
= 23kN 1m'
T
•
A= 1000 x 200 + 200x600 = 320000 mm 2 Since the section is not symmetrical, calculate the location of the center of gravity.
Step 4.1.1 Equation at transfer (top fibers-tension controls) The allowable tension stress aHransfer /rj is given by: J+, It
=0 • 22 -V~ Jcui =0.22$s = 1.302 N Imm
~>
2
e-Kb
P; - [ZIOp iii +Mowl 1
p;
e-203.3 > [65.06 x 10 6 x 1.302/1000 + 144 x 1000]
~;:::4.37XI0-6 (e-203.3) p; e
600
203.3
o
17.35
I =1.63 x 10 10 mm4
673
= 414 kN.m
Step 4.1 Governing equations
200
I~O?I
= 1000 x 200 x 100 + 200 x 600 x 500 = 250 mm Y 320000
=Y xA=25x
W
__
250 ..-___+-_-1 o
6
_ 29.57xlO -- 92 .4 mm K '_ -Zbot -I A 2320000
W lal
--
= 65.06x10 6 mm 3
_ ZtoP _ 65.06x10 _ 203 3 K --- . mm b A 320000
Step 4: Adjusting section dimensions
-,-
lo
6
3.685
~
= t- Y =800-250 = 550 mm
674
X
10-4
Step 4.1.2 At transfer (bottom fibers-compression controls) 1
~
Step 4.2 Acceptable Pi-e diagram
e+92.42 > [-29.57X10 6 X-15.75/1Ooo+144X1000]
J..~1.64XlO-6 ~
From the points calculated in step 4.1 ,the following diagram can be plotted:
(e+92.42)
18 16
e
I
-92.42
I
lIPi
Step 4.1.3 controls) 1
~
<
l-
0
600 11.35 X 104
I
I
,-...
~;::..
Equation at full service load (bottom fibers-tension
.
e+92.42
29.57 X106 x3.11/1000 + 414x 1000 ]/0.80
·1
I
10
b.... x
8
....--
6
--200
-92.42
e lIPi
I
12
r::;
J.. s2.48 X10-6 (e+92.42) ~
I
Acceptable combination of Pi, e
14
I
0
4
-100
o
100
200
600
e(mm) 4
I
17.2 X 10-
I
Step 4.1.4 Equation at full service load (top fibers-compression controls) 1 <
~.
e-203.3 l65.07X10 X-20/1Ooo+414X1000]/0.80 6
J..S-9.015xlO-6 (e-203.3) ~ 203.3
e
I
lIPi
I
0
-200
600
I
-3.58
675
X
300
104
I
3.64 x 104
I 676
400
500
600
8.9 Deflection of Prestressed Beams
8.8 Reduction of Prestressing Force near Supports Sections with straight tendons at supports are subjected to zero moment and may suffer from h.igh tensile stresses resulting from the prestressing force. There are two practIcal methods of reducing the high stresses near the supports: 1.
2.
Deflection of prestressed concrete beams is of a great importance because they are more slender than ordinary reinforced concrete beams. At transfer, prestressed concrete beams are subjected mainly to an eccentric compression force that produces reverse deflection (camber). The amount of camber should be controlled for proper drainage of roofs in buildings. Moreover, in projects involving prestressed beams and precast slabs, excessive camber may prohibit proper alignment of the precast members.
Reducing the eccentricity of some cables as the reach the support zone as shown in Fig. 8.18.a. Sheathing .som.e ?f the cables by plastic ~bing as shown in Fig. 8.18.b. ThIS elImmates the transfer of the prestressing force to the ,". concrete at this area.
At the final stage where all the working loads are applied, the upward deflection of the beam (camber) becomes downward deflection. Excessive deflections of beams may cause excessive vibrations, damage to the appearance of the structure, poor roof drainage, and uncomfortable feelings for the occupants. Also, such deflections may damage partitions and cause poor fitting of doors and windows.
CL
raised tendons
8.9.1 'Introduction
I I
-------------------------t--------~.~- ----------------(a) CL I
j;:~~-~~~--~~-~~---------------;----------------------------; i i I
' .
___________
' :
c.g
c:::=::::::
~
I
'
-1
1 - 1_ _ _
tendons sheathed
,
(b)
tendons sheathed
Fig. 8.18 Reduction of prestressing force near support (a) raising part of the tendons. (b) sheathing part of the tendons Photo 8.9 Camber of a prestressed beam at transfer
677
678
T !
8.9.2 Calculations of Deflections - ECP 203
A-Calculation of the effeCtive moment of inertia (Ie)
The procedures for calculating the deflections of prestressed concrete beams are summarized as follows:
The ECP 203 gives the following expression for calculating the effective moment of inertia:
1- The calculation of the expected camber of prestressed beams at transfer should be carried out using the gross moment of inertia of the crosssection Ig • Such a camber should be limited to the values that do not cause problems to the project under consideration. It is the task of the designer to judge the allowable value of the camber. 2- When calculating the immediate (short-term) deflection, the gross moment of inertia of the cross-section Ig is used for cases A, B, and C. For case D, the effective moment of inertia of the cross-section Ie is used. Limits of the short-term deflection for prestressed concrete beams are the same as those for reinforced concrete beams. 3- Long-term deflection of prestressed concrete beams is calculated taking into account all the permanent loads, in addition to the effect of shrinkage, creep and relaxation of prestressing steel. Limits of the longterm deflection of prestressed concrete beams are the same as those for reinforced concrete beams.
f,
=4400K.
........................................... (8.68)
+-(~:) ']
f,: sf, ..................... (8.70)
r
i.e(~: ~1 The previous equation can be simplified as follows: I =1 +(1 -I e
cr
g
)(MM )3 ........................................ (8.71) cr
cr
a
where the cracked moment of inertia (mm4) the gross moment of inert maximum unfactored moment (kN.m) cracking moment (kN.m)
Ier Ig Ma
Mer
Young's modulus of concrete Ec is used in deflection computations. The value of Ec can be computed using the ECP 203 equation as follows:
Ec
=(~:)' f,
M
cr
= ~(O •45 Vleu r;:- +/pee -/cd) ............................ (8.72) Yt
Where Yt is the distance from the neutral axis to the outermost tension fibers as shown in Fig. 8.19.
The values of the deflections can be calculated using the theory of structures with the appropriate value of the moment of inertia according to the case under consideration. Examples of the deflection expressions are given in Eq. 8.69 and the rest can be found in then Appendix. W
L4
384EcI 5w L4
/1=
384EJ P L3 48EJ W L4 8EJ P L3
/ for fixed end beam with uniform load
_ Md Y t
cd-
Ig In which Md= unfactored moment due to dead load.
for simple beam with uniform load for simple beam with point load at midspan .................. (8.69) for cantilever beam with uniform load for cantilever beam with point load at edg
3EJ
Aps
Fig. 8.19 Calculation of the cracking moment 679
680
Having determined the neutral axis distance z, the cracked moment of inertia
B-Calculation of the cracked moment of inertia (Icr)
ler can be computed as:
If we assume that the neutral axis is located at a distance Z from the compression face, the location of the neutral axis can be easily determined by taking the first moment of area about the center of gravity of the section (C.Gg.) as shown in Fig. 8.20 and as given by Eq. 8.73. It should be noted that the center of gravity coincides with neutral axis (no nonnalforce). b X Z2 12 - n As (d - z) - nAps (d p - z)
bx z3 2 2 I cr =--+nAs(d-z) +nAp.(dp-z) ................ (8.74) 3 s
In T-sections, the location of the neutral axis may lie inside or outside the flange as shown in Fig. 8.21. Therefore, hand calculations must be carried out as explained in the illustrative examples.
= 0 ............... (8.73) B
b 1-
'"0
b
I-
• 1
_J
Po
'"0
•I
I
ts
~_l
"0
T n As ---
•
•••
N.A Aps
_I z
'-'7'-'
n As--- •••
•
••
: •
~
I
nAps
_._._. _.fu\~'\\~~';??;;'i"'~1iA.\.
Cracked section
Transformed section
Neutral axis inside the flange z
Aps
neutral
Neutral axis outside the flange z>ts
Fig. 8.21 Determination of the neutral axis for T -sections
Fig. 8.20 Determination of the neutral axis
Fig. 8.10 Deflection of a prestressed beam during testing
681
-----]~
1---1 axis b
I
Aps As
t1 "0 •
I
cracked zone
B
682
Example 8.14 The figure shows a simply supported full prestressed beam with straight tendons at an eccentricity of 100 mm. The initial tendon force is 1200 kN and the effective prestressing force is 950 kN. Compute the initial camber at midspan due to prestressing and self weight of the beam. If the beam is left without being subjected to any additional loads for a long period of time, calculate the long term camber.
Solution Step 1: Calculation of immediate deflection Step 1.1: Deflection due to self weight Ec =4400 "'leu 1f:=4400.J4Q = 27828N Imm 2 = 27.828kN Imm = {250x550)x
w ow
feu =40 N/mm2
M
-
WOW
ow
25 =3.44kNlm' 1000 X 1000
2 XL2 = 3.44x9 = 34.83 kN.m 8 8
Since the beam is fully prestressed (case A), the gross moment of inertia is used in deflection calculations.
o.w o o.....
I
The deflection of simply supported beam subjected to uniform load equals:
ow
9.0m •
3
3
I =b t = 250x550 =3.47x109 mm 4 g 12 12
Ii
..
2
=
5w xL4 ow 384xEc xl g
5x (3.441 1000) X (9000)4 =--'----'--'--'---'::9 384x27.828x3.47xl0
3.043mm J,
Step 1.2: Camber due to prestressing The immediate deflection at mid span due to initial prestressing only equals:
250mm
I..
..I
M. L2 Ii =-''--P 8Ec Ig
The initial moment due to prestressing at the supports Mi equals:
M j = Pj Xe = 1200x100 = 120000kN .mm
•
120000 x (9000)2 = 126 -----'----'---;:. mm i(camb) er 9 8x27.828x3.47x10
Beam Section
683
684
Step 1.3: Immediate camber/deflection
Example 8.15
The immediate camber equals:
Compute the immediate camber at midspan for the beam shown in figure. The initial prestressing force in the broken tendon is 1500 kN and in the straight cable is 300 kN. The beam maybe classified as zone B.icu =45 N/mm2
!:low +p =!:lp -!:low
= 12.6 i -3.043 J..= 9.55 mm
i
Step 2: Long-term deflection Step 2.1 Long-term deflection due to self-weight Since no compression steel is present, the creep coefficient equals 2.
V)
00
!:low (long-tenll)
= (1 + a) x !:low = (1 + 2) x 3.04 = 9.13 mm J..
-.-.-~~-.-.-.-.-.-j-.-.~.-.-.-.-.-.-.-.
Step 2.2 Long-term camber due to prestressing The long-term deflection at mid span due to final prestressing only equals
M L2
!:lp(long-tenn)
= (1 + a)_e=--_ 8Ec Ig
11.0 m
I·
For long term calculations, the effective prestressing force (Pe)is used. Thus, the moment at the supports Me equals:
l I T
-(1 p(long-tenn) -
)Me L2
+ a 8E I c
g
750
.I
1•
Me = P. Xe = 950x 100 = 95000 kN .mm
!:l
.I
1 2
95000 x (9000)2 ( + ) 8x27.828x3.47x109
I
100
29.88mm
i 0 0
Step 2.3: Long-term camber/deflection The long-term camber equals: !:ld+p =!:lp -!:ld
= 29.88-9.13 = 20.75mm
i
(camber)
00
• •
Asp
1---1 200 Beam Section
685
686
0 0
..-<
Solution Step 1: Calculate uncracked section properties
= {75000 + 140000) x
w ow
.
25 1000 x 1000
=5.375 kN I m '
Since the beam is categorized in zone B, the gross moment of inertia is used in the calculations. Since the section is not symmetrical, calculate the C.G. The deflection of simply supported beam subjected to uniform load equals: 5W
l10w =
XL4
384:~c xl
g
=
5x (5.375 I 1000) x (11000)4 384x29.516x13.6x109
2.55mm t
y = 310.46 mm o
ow-5.375 kN/m'
o
00
Ybot=489.53 mm
uncracked section
Step 3: Camber due to prestressing Al = 200 x 700 = 140000 mm 2
Yt=450mm
~ = 750 x 100 = 75000 mm 2
- = 140000 x 450 + 75000x50 =310.465 mm y 140000 + 75000
g
12
End moment (due to eccentricity of the two cables at support)
•
Due to the concentrated load developed from the tendon slope change
+ !1 pw
Deflection due to end moments Llpm
3
= 200x700
•
!1 p =!1 pm
Y bOI = 800 - 310.46 = 489.53 mm
I
The camber due to prestressing is the sum of two components:
3
+ 140000X(450-31O.46)2 + 750x100 + 75000 x (310.46-50)2 12
The moment at the supports due to the broken cable Mil equals MiI=Pilxe I
e l =85 mm
t
Mil = 1500x85 = 127500 kN .mm (positive moment) .
Step 2: Deflection due to self weight The concrete modulus of elasticity equals:
Ec = 4400
K
The moment at the supports due to the straight cable Mi2 equals: Mi2 =P;2 xe 2
e 2 =y bOI -cover = 489.53-100 =389.53 mm = 4400.J45 = 29516N Imm 2 = 29.516kN Imm 2
t
M i2 = 300X389.53 = 116859kN .mm (negative moment) The resultant moment M.F=Mu -Mi2=127500-i 16859= 10641 kN.mm (positive)
687
688
The immediate deflection at mid span due to the positive end moments equals: /). pm
/).pm
=Mre 8E c I g
=
10641 X (11 X 1000)2 9 8x29.516xI3.6xlO
8
0\
C'l......
\0
~ a
Ii'
II
~
;Q
t
.......
8
= 82 = (85 + 350) / 1000 = 0.0791
1
(tan81 + tan ( 2 )
= P;
(81 + ( 2 )
(true for small angles)
5.5
~ .....
~ 8 ~~;Q
0
. .
~
A,..
.......
-c .......
..... C'l
II
I)..
II
\
~.------------ ____ F?______ ---------~= 11.0 m
11.0m
I·
T
+
.1
The camber due to the broken cable can be calculated using an equivalent concentrated load usually called the balanced load. The calculations of such load are as follows:
_ ~~~7f£~:
85
-.L
~).- ~):=
Deflection due to concentrated load
~-------------
= P;
V = 1500x(0.0791 +0.0791) = 237.3 kN
S
~
I.
V
S
.....
:( (: l . I!.
=0.401mm t (Downward deflection)
Alternatively, the equivalent force at midspan may be calculated as follows:
/
5.5m
..
5.5m
-I-
The immediate camber at midspan due to the equivalent concentrated load V equals: V L3 . /). pv = 48E I i c /).
= pv
237.3x(11000)3 48x29.516x13.6x109
=16.4 mm i
------------~
.I
Step 4: Immediate camber/deflection The immediate camber equals:
The effective sage (~)at midspan equals: /).P+ow
=i
/).p -
t
/).ow
=16 -
2.55 =13.45 mm
et = 85 +350 = 435mm VxL --=p;xe t
4
Vx11 = 1500x0.435 4 V =237.3 kN
689
.I
690
i
Example 8.16 The figure given below shows a simply supported partially prestressed beam (zone D). The beam is sUbjected to an initial prestressing force of 900 kN and an effective prestressing force of 740 kN. Calculate the immediate deflection, the long-term deflection and check code limits for deflection. The beam is located on a typical floor and support walls that are not likely to be damaged by deflection. wu=1O kN/m', wsv=3 kN/m' (superimposed load),icu=35 N/mm2 , and n=1O.
Solution Step 1: Calculate uncracked section properties The calculation of the gross moment of inertia shall be carried out by considering the concrete section and neglecting the prestressing steel as well as the non-prestressingd steel. Since the section is not symmetrical, the center of gravity is calculated as follows: 650 120
380 ~
~
T
T 15.0m
120
I
I
L...-_ _..,
1-1
•1
~ 1-1.0-_ _ _6_50_.---------II
Y=335.7 mm
~
~ ._._._._._._~~._._._._._.1._._._._._._._._._._._._._
I·
Y2
180 uncracked section
A = 180x750 = 135000 mm 2
Yl=495 mm
~ = 650x120 = 78000 mm
Y2=60mm
2
A=A +~ = 213000mm2 oV)
135000x495+78000x60 213000
Y
r--
1 100
T
335.7 mm 3
•
1--_ _ -'"
=
I g
Non- prestressing steel
1-1 180
9
4
Ig=15.77 x10 mm Ybot
Beam cross-section
= (120+750) -335.7 = 534.3mm
=~=15.77X109 = 29.53x10 6 Zbot
691
650x120 2 180 7503 x + 135000x (495-335.7)2 + + 78000 x (335.7 -60) 12 12
Ybot
mm 3
534.3
692
Step 2: Calculate immediate deflection / camber Step 2.1: Deflection due to self-weight
11 pm
Since at transfer only the self weight is applied, the gross moment of inertia may be used for deflection calculations
= M i L2 = 31500x(15000)2 = 2.15mm 8Ee I g 8x26.03x15.77x109
t
(u ward) P
Camber due to curved tendon
Ec = 4400..JJ: = 4400.J35 = 26030N Imm 2 = 26.03kN Imm 2 11 =11
The self weight of the beam equals Wow
= 213000 x
25 1000 x 1000
Mi=(31500kNom w,.=l1.04kN/m'
. =5.325kNlm'
=
ow
4
5x(5.325/1000)x(15000)4 =8.55mm t (downward)
xL 384xEe xl g 5wow
384x26~03xI5.77x109
I· et
15.0m . 1
=380 -
•
","3)1500
15.0m
·1
35 =345 mm
The camber due to the curvature of the cable can be calculated using an equivalent uniform load usually called the balanced load. The calculations of such load are as follows:
Step 2.2 Camber due to prestressing The camber due to prestressing is the sum of two components: • End moment (due to eccentricity of the cable at support)
. ,.
The effective eccentricity of the curved tendon at midspan (et) equals:
wow=5.325 kN,m'
I·
,.
j;-n-flITf , If t~t ,-{nus,
The deflection of simply supported beam subjected to uniform load equals: 11
_-------~---
+11
Weq
x15
2
----''---- =900 x 0.345 I1pm
8
Due to the uniform load developed from change of curvature of the tendon I1pw I1p = I1pm + I1pw
Camber due to eccentricity of the cable The immediate deflection at midspan due to the negative end moments equals: 11 pm (due to end mment)
M.e
= 8~
c
15.0m
I~
I g
The moment at the supports Mj equals:
M j = P; Xe = 900x35 = 31500 kN.m 693
694
.I
W DL =Wow +W SD = 5.325+3 = 8.325 kN 1m'
W,q =11.04 kN 1m' 1 4
!:l. pw
5W,q xL =---"'-384xEc xl g
2
M DL = W DL L2 = 8.325x15 = 234.14 kN .m
5x(I1.0411000)x(15000)4 = 17.72mm 1 384x26.03xI5.77x109
8 fcd
!:l. p =!:l. pm +!:l. pw =2.151+17.721=19.87 mml
Step 2.3: Immediate camber/deflection
8
= M DL = 234.14Xl~6 = 7.93N I mm 2 Zbot 29.53xlO
Noting that ZboFl/Yh thus,
The immediate camber equals: !:l. p+ow =!:l. P +!:l.ow =19.871-8.55-1-=11.33mm 1
M cr = 29.53x106 (0.45$5 + 12.99-7.93)1106 = 228.25 kN.m Wtotal =w DL +W LL = 8.325 + 10 = 18.325 kN 1m'
Step 3: Service load deflection
2
Since the beam is partially prestressed, one should calculate the cracking moment and the effective moment of inertia.
Ma = Wtotal L2 = 18.325x15 =515.39kN.m 8 8
Since Ma>Mcr then calculate Ie
Step 3.1: Calculate cracking moment Mer According the ECP 203 the cracking moment of prestressed beams equals:
Step 3.2: Calculate cracked moment of inertia Ier
Mcr =~(0.45.JjC +fpc, - fcd ) Yt
65_0_ _ _-1.J
J I-•..__-_ _
where /pee is the compressive at the extreme fibers (bottom in this case) due to effective prestressing force only. A
Z
cracked c.g
bot
nAs=4500
The eccentricity at midspan equals 380 mm.
~ :r=- -----------------------~-- --:-------------~~
J40XlOOO _' 213000
.1.
75m 7.5m . x380 =-12.99 Nlmm'" 29.53 X106
695
• leT calculations
It is customary to neglect the area of the non-prestressing steel in deflection calculations. The transformed area of prestressing steel equals:
n Aps=lO x 450 = 4500 mm2
tendon proflle
fpc, -
z=92.87mm
.. _. .. --'-r-'-'-' ._.
120
T
__ P, _ P,xe fpc, -
_!_
~I
d p = Y +e =335.7 +380 = 115.70 mm
Assume that the c.g. is located inside the flange. Taking the first moment of area for the transformed section about the C.G. gives, 696
Step 3.5: Camber due to effective prestressing The service load deflection at mid-span due to the negative end moments only equals:
650x zx~ = 4500 (715.70- z) ·2
325 z 2 + 4500 z
- 3220650 = 0
Cracked moment of inertia
Icr = B Z3 3
+ nAps (d p -
Ie
i
The moment at the supports equals:
Me = Pe Xe = 740x35 = 25900 kN.m
Z)2
Me L2 8EcIe
D. pm
3
cr
L2
8Ec
Pm
z =92.87 mm < 120 rom (inside the flange as assumed)
Solving for z
I
= Me
f1
= 650x92.87 + 4500x(715.7-92.87)2 =1.92x10 9 mrr?
3
25900x(15xlOOOf =8.96mm 8x26.03x3.122x109
Step 3.3: Calculate effective moment of inertia
Ie =Icr +(Ig -IcJ(::
r
,..". -25900 kN n'e-
I =1.92x109 + (15.77 X109 -1.92X109) (228.25) 3= 3.122x109 mm e 515.39
(
.mWeq-908 .
i
~~~ - __ - __
kn/' lll-- _------ --
!lB-n n I I I I ! ==1 ! n JB-~ ) 15.0m
·1
I·
Step 3.4: Deflection due to total load The deflection of simply supported beam subjected to dead loads only equals: f1 DL
5w DL XL4 =---='---384xE xl c
W f1u =~xf1DL
W DL
e
5x(8.325/1000)x(15xlOOO)4 384x26.03x3.122xl09
= 67.5mm J,.
The eccentricity (et)at midspan equals,et
f1
697
·1
4 _ 5 Weq xL _ 5x (9.08 11000) x (15x 1000)4 384xEc xle 384x26.03x3.122x109
pw
15.0m
380-35 = 345mm
2 Weq xL t 8 2 W x15 eq = 740 x 0.345 8 Weq = 9.08 kN 1m' i
WDL=8.325 knlm' & wu=lO knlm'
I·
::::
--'-- = Pe X e
10 I =--x67.5 =81.09 mm..v 8.325
Me=25900
f1p = f1pm + f1pw
= 8.96 i
+73.61 i = 82.57 mm
698
i
= 7361 i . mm
~ r-----------------------------------------------~ c.g. et=34~ mm ~ ::-_'':: '':: :::::-~:-~:::::-___ '_-=:'-:::-::-~:-.: t_'.::'_-=:.,,: :.::::-'::-': ::,::._-= ::: ::::..:-.::-..: ::._
I5.0m
I..
• 1
9 SHEAR AND TORSION IN PRESTRESSED CONCRETE BEAMS
Step 3.6: Immediate deflection The final deflection equals: !ltotal
=(!lDL +!lu) -!lp =(67.507 + 81.09) t -82.57 1= 66.03mm t
Step 4: Long-term deflection The long term factor a=2 !llong-term
= (1 + a) (!l DL +!l p) + !l LL
!llong-tenn
=(1 + 2) (67.S07 t -82.S7 I) + 81.09 t= 3S.90Smm t L
IS00 2S0
< - < - - .... .o.k 2S0
The beam satisfies the limits of the total deflection. However, the live load deflection should be checked as follows •
The beam is in a floor that supports walls that are not likely to be damaged by large deflections. Hence, the limiting live load deflection is given by:
~~~ lSxlOOO
!l LL
360
360
41.67 m
m
Since !lLL (81.09 mm)< !lallowable (41.67 mm) the beam does not meet code requirements for deflections.
699
Photo 9.1 Milwaukee art museum, USA
9.1 Introduction This chapter presents procedures for the design of prestressed concrete sections to resist shear and torsion resulting from externally applied loads. Since the strength of concrete in tension is considerably lower than its strength in compression, design for shear and torsion becomes of major importance in all types of concrete structures. The behavior of prestressed concrete beams in shear or combined shear and torsion is different from their behavior in flexure: they may fail abruptly 700
without sufficient advance warning, and the diagonal cracks that develop are considerably wider than the flexural cracks. Both shear and torsion forces result in shear stress. Such a stress can result in principal tensile stresses at the critical section which can exceed the tensile strength of concrete.
9.2 Shear in prestressed Beams 9.2.1 Inclined Cracking
·9.2.2 Effect of Prestressing. The shear. web cracks in prestressed beams are attributed to the developing of diagonal tension stresses as shown in Fig 9.2. The maximmll web shear qew occurs at the C.G. of the section where the actual diagonal tension cracks develops. Referring to Mohr's circle shown in Fig. 9.2, the principle tensile stress in concrete due to both compression stress/pee and shear stress qewequals:
Cracking in prestressed concrete beams depends on the magnitude of moment and shear as shown in Fig. 9.1. At locations where the moment is large and shear is small, vertical flexural cracks form when the normal tensile strength is exceeded. Two types of inclined cracking occur in prestressed concrete beams; web shear cracking andflexure~shear cracking. These two types of inclined cracking are illustrated in Fig. 9.1. Web-shear cracking begins at the centroidal axis of the cross section when the principal tensile stresses due to shear exceeds the tensile strength of concrete. Web shear cracking occurs in the regions where moment is small and shear is large.
J;
=
J
(/;cc +q~w _(/;c ). .................................. (9.1) tan2B
ifpccqcw·12) ........................................... (9.2)
where /pee is the concrete compressive stress due to effective prestressing at the C.G. leveL However, if the neutral axis falls inside the flange for flanged sections, the $tress is calculated at the intersection of the flange and the web. It is clear from Mohr's circle that the normal compressive stress /pee reduces the
maximum principle tensionj; and the angle e. Therefore if cracking occurs, the inclined crack is flatter and the effectiveness of the stirrups increases.
Flexure-shear cracking is essentially an extension of a vertical flexural cracking. The flexure-shear crack develops when the principal tensile stress due to combined shear and flexural tensile stresses exceed the tensile strength of concrete. It should be mentioned that web-shear .cracks usually occur in thinwalled I-beams near the C.G. where the shear stresses in the web are high while the flexural stresses are low.
/pee 12
applied loads Maximum shear stress
I I
I
Web-
Flexural-Shear
Shear
Flexural and Flexural-Shear
Web-
Shear
~----------~----~.----------------------~--------~
Fig. 9.1 Type of cracking in prestressed concrete beams
701
end support
Normal stress
I I I I I I
/Pee,qeJ/
I I I
I
: - Maximum tensile stress . Maximum compression stress
,It
Fig. 9.2 Principle tensile stresses in prestressed beam 702
Solving Eq. 9.2 for the web shear strength qcw gives:
qcw =it (fi:c
)+1 . . . . . . . . . . . . . . . . . . . .
To ensure that shear failures occur in a ductile manner by yielding of the shear reinforcement; the ECP 203 specifies that the shear stress qu should not exceed the maximum shear stress qu,max given by: (9.3)
qu max .
9.2.3 Shear Strength According to ECP 203 9.2.3.1 Upper Limit for Design Shear Stress
qllmax
The critical section for shear in prestressed reinforced concrete beams is at tl2 from the face of the support. The applied shear stress is given by:
qu
= 0.75 Jfcu J'c
S 4.5N Imm 2 -
...........................
(9.5)
It is clear from Fig. 9.4 that the maximum shear strength qu,max for prestressed members is slightly higher than that for ordinary reinforced concrete members. However, the concrete shear strength qcu of prestressed members is much higher than that of ordinary reinforced concrete members.
=~ ..................................................... (9.4a) bxd p
d p zO.80t ..................................................... (9.4b)
Change cross section dimension
0.75~fcu I J'c qu.max
where b is the width of the section and dp is the distance from the compression fiber, to the centroid of the cables but not less than 0.8 t. For prestressed concrete beams containing grouted ducts with diameter (<\» more than bw 18 (where bw is the width of the web), as shown in Fig. 9.3, the effective width of the web (b) in Eq. 9.4a should be taken as:
for¢ > bw
•••••••••••••••••• (9.4c)
for ¢ s bw 8
•••••••••••••••••
·8
.
(9.4d)
B "
Use minimum shear reinforcement
Grouted tendons ~~~--------~. with diameter <\>
. ,
Fig. 9.3 Effective width for prestressed beams with grouted ducts
703
Prestressed beams
Non-prestressed beams
Fig. 9.4 Shear reinforcement requirements in prestressed and non-prestressed ~eams
704
9.2.3.2 Shear Strength Provided by Concrete qcu
B: Concrete Shear Strength Using Detailed Procedure
The ECP 203 gives two procedures for calculating concrete shear strength qcu of prestressed beams as follows:
Although the use of the simplified method for calcul~ting concrete ~he~ strength is quite easy, it may produce very. conservatlve ~esults. ThI~ IS especially true for I-sections. The shear strength calculated usmg the. det~I~ed procedure can be as high as 150% of that calcul,ated using the sImphfied procedure. Therefore, when the tendon stress is below 0.4 jpu, or when the full concrete shear strength need to be utilized, the shear strength can be evaluated using the detailed procedure. For a thin-walled section (I-beam), with small shear spans, the shear stresses in the web are high while the flexural stresses are low. The principal stresses at the neutral axis may exceed those at the bottom flange causing cracking to start. at the web. This is called web-cracking shear. On the other hand, for beams WIth relatively large shear span, vertical flexural cracks occur first and ~xtend diagonally due stress redistribution. This is called the flexural-shear cracking.
•
Simplified procedure
•
Detailed procedure
A: Concrete Shear Strength Using the Simplified Procedure Several empirical expressions that predict shear strength of concrete have been developeq from experimental studies of prestressed beams. For prestressed members in which the tendons are stressed to at least 40% of their ultimate tensile strength jpu, the nominal concrete shear strength can be conservatively estimated by the following ECP 203 expression:
q cu o
Itc
= 0.045
....E!...
Y
with the following condition
+
3.6xQ xd r. Mup> - 0. 24v)fF{":":"/ cu I fc
............... (9.6)
u
According to the ECP 203, the concrete shear strength qcu is the smaller value of the flexural shear strength qci and the web-cracking shear strength qcw'
~ 0.375.Jfcu / Yc
qci qcu
(Qu;udp ) ~ 1.0
= smaller of {
qcw
where Qu ;md Mu are the values of shear and bending moment, respectively, produced by the ultimate loads at the section under consideration. dp is the distance from the prestressing reinfoI;cement to the outermost compression fibers. The term dp used in the previous equation is the actual cable depth. The previous equation does not give a valid result when either Qu or Mu is small. For simply supported beams subject to uniform loads, the term expressed as:
Qu dpiMucan be
d p (L-2x)
- - ' - - - .................................... (9.7) x (L-x)
where L is the span length and x is the distance from the support to the critical section.
Photo 9.2 Prestressed concrete bridge during construction
705
706
Flexural-Shear Strength
f!ci
The flexural-shear strength is the shear strength of the beam at the time of developing the first flexure-shear crack. Flexure-shear cracking occurs when flexural cracks, which are initially vertical, become inclined under the influence of shear. Because the flexural-shear strength cannot be predicted by calculating the principal stresses in an uncracked beam, equations for estimating flexural shear strength are based on experimental tests. This is attributed to the redistribution of stresses that OCcur at the tip of the flexural crack.
l' L3
IIIIJJ{IIIJJ
i
I
itiC
.
al ,«tin.
Ultimate loads ( factored)
L
Qu
I
The code specifies the following formula to predict the concrete flexural shear strength qei: eu qci =0.045Jf +0.8 (qd +qi Yc
X
Mer M max
)~0.24.Jfcu Iyc
Ultimate shear (factored)
............ (9.8)
Where Qi =Qu -Qd
Ultimate moment ( factored)
Mmax =Mu -Md
Q.
qj
= bX'd
Q q d =dbxd
Wd
qd
is the unfactored shear stress due to dead load only at the critical section.
qi
is factored shear stress at the critical section due to externally applied loads occurring simultaneously with Mmax is the factored moment at the critical section due to the external applied loads (Refer to Fig. 9.5). is the cracking moment. is the depth of the cross section but not less than 0.8t
Mmax
Mer d
In Eq. 9.8, the flexural shear strength is assumed to be the sum of three components:
1. The shear stress required to transform a vertical flexural crack into inclined crack 0.045.J feu I Yc 2. The un-factored shear stress 0.8 qd, and 3. The portion of the remaining factored shear stress that will cause a flexural crack to initially Occur 0.8xql xMer 1M max
1 I'
I iI I
J
I I I II I I I I I
I I
11
Dead loads (unfactored)
.I
L Qd
Shear force (unfactored) I
~--
Moment (unfactored)
Fig. 9.5 Shear and bending moments for calculating qei
707
708
T I
Cracking Moment Mer Concrete beams are assumed to behave elastically as long as the maximum tensile strength of the concrete is not exceeded. A simply supported prestressed beam will crack at the bottom when the tensile strength is exceeded. Thus the tensile stress at the bottom fibers for simply supported beam equals:
Because most of the prestressed beams are designed to remain uncracked during the lifetime of the structure, the cracking moment is normally higher than the applied moment at full service loads. Furthermore, the ECP 203 requires that prestressed should be designed to withstand at least 1.2 Mer.
(
PeXeXY t +MerYt ............................... (9.9) I
I
where
Yt Mer Pe
!ctr
. is the distance from the neutral axis to the tension surface is thecracking.moment is the effective prestressing force is the maximum allowable tension
The term letr = O.4S.JJ: is the tensile strength of concrete for web-shear cracking. Subsisting with this value in the previous equation gives:
M er
=.~(0.45.JJ: + P. Yt
A
Web Shear Strength qew In the Egyptian code, the value of the web concrete shear strength is given by:
+ Pe Xe XYt) ................. (9.10)
r;:- +-+ Pe p.xeXYt) -Md ........... (9.11) Mer =I- ( O.4S..jleu A
q~ =0.24
I
The code specifies that the value of the unfactored dead load moment at the critical section should be subtracted from the cracking moment. Hence,
Yt
Fig. 9.6 Cracking moment calculations
(!;.
~ )+q~ ................................. (9.13)
+f
where
/pee is the concrete stress at the C.G. of the section due to effective prestressing after considering all losses.
p"
I pee =A
I
e
The code rewrites the previous equation in terms of stress as follows:
Mer
! I.
=~(O.4S.JJ: +Ipee -led) Yt
.......................... (9.12)
where /pee is the compression stress in concrete due to prestressing force after considering all losses calculated at the extreme tension fibers as follows:
I pee
= Pe + p"xexYt A
I'
!cd is the concrete stress due to dead loads and any sustained live loads calculated at the extreme tension fibers.
709
qpv is un-factored shear stress due to the vertical component of prestressing Qpv.
Q pv Iyps _ (p. xsinB)/yps qpv = b Xd p' b xd p
Where yps
= LIS.
(Ipe Iyps xAps )xsinB b xd p
Referring to Fig. 9.7, the vertical component of the
prestressing force Qpv at the critical section for straight tendons equals:
Q pv
= Pe sin(B) == Pe tan(B) ........................................ (9.14)
The approximation of using (tan) instead of (sin) is justified because the eccentricity is very small compared to the span. For beams with straight cables, the vertical prestressed component equals:
710
Qpv
_p em-e. e x
-
••••••••••••••••••••••••••••••••••••••••••••••
(9.15)
where em is the eccentricity inside the beam and ee is the eccentricity at the end. If the tendon eccentricity is located above the C.G., a negative value of ee should be used. critical section I
I
III II
i
~
;!
f
k J+1 ............................. "~
0.25 ifeu
"
.3' Pc ~~~t::t:--:-:-:-~--=-~-~-~--~-~-E-~--=-~j~--~-~--=-=-=-= --~-~-=-:--:-:-:--:-:-:-:--:-:-:-:--:-:-~~---Pe
(9.16)
9.2.4 Shear Reinforcement Calculations
I-
. I.
x
L-x
If the applied shear stress qu exceeds concrete shear strengthqcu, web
·1
reinforcement must be used according to the following equation:
Fig. 9.7 Vertical prestressing component Qpv for case of straight tendons In case of using a parabolic tendon, the .angle differentiating the equation of the parabola as follows: y = ax 2 , taking the first derivative gives y' = tan () = sin () = 2ax
e may
be obtained by
and
I."t--I--
1-.- - - ' - - - - -
= area of one branch
Asb
--------f------
U2
·1
Fig. 9.8 Vertical prestressing component Qpv for case of parabolic tendons 711
xfy 1.1.15 bxqsu
...................................... (9.18)
~~4
b s .......................................... (9.19)
.. A" =4A,b
.. UL
Ast
As/,mill =
x
qeu ......................................... (9.17) 2 ·
Where Ast is the area of the stirrups according to the number of branches as shown in Fig. 9.9. The area of the provided stirrups should not be less than:
8e
y
= qu -
Shear reinforcement is obtained in a similar fashion like ordinary reinforced concrete beam. The required vertical stirrups spacing (s) is given by:
tan()=-m- x L2
critical ection
I,
qsu
s=
Where a is the parabola constant and x is the location of the section measured from the center of the parabola as shown in Fig. 9.8. It can be easily shown for the parabola in Fig. 9.8 that the following expressions are valid:
,
by Eq. 9.3, the web shear strength qcw can be obtained by solving the resulting equation as follows:
qcw =0.25.JJ: (
.
I
I
An alternate method for determining the web shear strength qcw is to limit the principal tensile stresses at the e.G. of the rectangular sections or at the intersection of the web and the flange for flanged sections if the neutral axis falls inside the flange. The code states that this limit may be taken as 0.25 .JJ: . Substituting with this value for the diagonal tension stress It given
I·
b
•
•
·1
I·
Fig. 9.9 Stirrups for shear 712
b
·1
Summary of the De~ign for Shear Step 1: Calculate the ultimate shear stresses due to Qu
Where
Qu
qu=b'd p
Mmax =Mu -Md
Where Qu is calculated at tl2 from the support as follows:
. (t column2 Width) Q =Shear at column aXlS -w x "2 +
J.cd
Md y/
=
I
u
u
P. I pee - A
Step 2: Check that section size is adequate The developed shear stresses due tot shear should stratify the following equation:
~
0.75
~I
cu
Ye
~4.5 N Imm
Fexexy/ I
+~-....::....:...
Step 4: Design the web reinforcement If qu
~
qeu ' then provide minimum stirrups. If qu > qeu ' then design shear reinforcement to resists qsu given by: °qsu = qu -0.5qcu
2
The spacing of stirrups needed for shear is obtained from:
If qu < qumax' the concrete dimensions ofthe section are adequate. If the above condition is not satisfied, one has to increase the dimensions.
Step 3: Determine the shear stress carried by concrete Calculate the concrete contribution to the shear resistance, qcu using:
s=
As/ xl y 11.15
b xqsu
Check minimum shear reinforcement °
As/,min
•
004
=J;
b
S
The simplified procedure (in case of I pe ~ 00401 pu)
where Qu and Mu are calculated at the critical section. • . The detailed procedure, qcu is taken as the smaller of the two values: 1. qei
=0.045~Ieu
2. qew =0.24
Ye
+0.8(qd +qj x Mer M max
)~0.24~IcuIYe
(~I;: +Ipee )+qpv Photo 9.3 Multi-span prestressed box-girder bridge 713
714
Example 9.1: Shear design using the simplified procedure
Solution
The cross-~ecti?n of a simply supported beam is shown in Figure Ex 9.1. Using the code-slmphfied method, determine the required shear reinforcement at the critical section knowing that the stirrups diameter is 10 mm ({YsF360 N/mm2 ). Assu~e that the column width is 500 mm. The material properties are fpu=2000 N/mm for normal stress relieved strands,fpe= 1080 N/mm2 and/cu=35 N/mm2. Assume that the applied live load and superimposed dead load are 22 kN/m', 2 kN/m', respectively.
Step 1: Verify the use· of the simplified method Since the effective prestressing stress fpe is greater than 40% of the ultimate 2 tendon strength fpu (1080 > 0.40 x 2000=800 N/mm ), the code simplified expression can be used.
Step 2: Calculate section properties A= 2x500x150+180x600 = 258000 mm W
OJV
=Yc xA
2
= 25x 258~00 = 6.45kN 1m' 10 .
Step 3: Calculate forces at th~ critical section Wu
= 1.4
Wu
=1.4 (6.45 + 2) + 1.6 x 22 = 47 .0~'kN I m'
beam e.g ,
o
Aps=1280 mm
2
T t-
t c 900 500 =_+_=_+_=700mm=0.70m
--i
2
c
2
2
I
I
-~-~- -=-=-=-~~-:bl=-_=_=_b=_~=_=_:::.:g_:__:_:_:_-:-:-:::--:-:-:--:-:-:--=-]- -l
-1=--:-:--:-:-:::--:::-:-:--:-:-:- -:-:-:-
= 47.03 x 18 =423.27 kN
2
u
«')
2
The reaction at the support equals: R = wu xL
8
W LL
The critical section is at t12 from· the face of the support. Since the column width (c) is 500 mm, the critical s~ction is at distance Xc from the centerline of the support. Xc equals: X
500
+ 1.6
i
o \0
W DL
2
The shear at the critical section equals: Qu =Ru -wu ·xx =423.27-47.03(0.70)=390.35 kN
The moment at the critical section for shear equals:
r---------------------18m-----------------------·~1
2
M =R .x _ u
U
c
Wu
.xc
2
2
Fig. Ex. 9.1 Tendon profile for Example 9.1
715
M u = 423.27xO.7
47.03xO.70 = 284.8 kN.m 2
716
wu=47.03 kNlm /
J
J J
p,
=O j70
Ru=wU2 =423.27
Step 4: Check the maximum shear stress
I
'1
The maximum shear strength is given by: q
t-o---r;______1_8_ _ _--:-_ _ _-IaI I I I
~~
qu,max
= 0.75 .Jf~cu = 0.75 ~~ [35 = 3.62 N = 3.62
.
~ 4.5 N
I mm 2
N I mm 2
Mu=284.80 kN.m
Step 5: Calculate concrete shear strength Moment qcu
= 0.045
qcu
.Jfcu 3.6xQu xd p · ~ - + M ~O.24~fcu I yc yc u
• I I I
I
I mTl1,2
Since qu is less than qu,mllX the concrete dimensions of the section are acceptable.
CritiCW=tiotJm= I ~ 423.27
qumax
~ 0.375~fcu I yc
Qu=390.35 kN
I
Qu xd p = 390.35x(757.811000) = 1.03 > 1.0 Mu 284.77 Shear
Qu xd p _ d p (L-2x) or ........ M u - x (L-x)
Use
:I :IJ---f}----u-- ~ij-----u----u---u-ul I·
18 m
,
I
Quxd p
= (757.8/1000)(18.0-2xO.70) =1.03
=1.0
Mu q cU.lIlJ.n. =0.24.J35/1.5 =1.16N Imm 2
qcu,~ = 0.375.J35 11.5 =1.81N Imm 2 q cu =0.045~~ [35 +3.6x1.0=3.82N Imm 2 >qcumin ,
The depth of the prestressing steel at the critical section equals: dp
= 750+ 0.70 x(400-300) =757.8mm 9
qcu=1.81 N/mm
2
dp =757.8 mm > 0.8 t " .o.k . qu
Qu
="bdp
390.35 x 1000 = 2.86 N I m~ 2 180x757.8
717
0.70(18-0.7)
718
Step 6: Calculate shear reinforcement Since qu (2.86) > qcu (1.81), shear reinforcement is required. The shear stress that needs to be carried by web reinforcement equals:
qsu _-qu
qcu _ 2 86 1.81 -2-' -2=1.955 N
Imm
2
Example 9.2: Shear design using the detailed procedure The cross-section of a simply supported beam is shown in Figure Ex 9.2. Using the code-detailed .method, determine the required stirrup spacing ({YsF360 N/mm2) at the critical section. Assume column width of 500 mm. Given that hu=2000 N/mm2 for normal stress relived strands,fp'= 1080 N/mm2 andfcu=35 N/mm2. Assume that the applied live load is 22 kNlm' and the superimposed dead load is 2 kN/m'.
For 10 mm stirrups, the total shear reinforcement area for two branches equals: ASI
=2x78.5=157 mm
2
l
The required spacing is given by: ASI
s
xfy 11.15 b xqsu
t- 500 -1
157x360/L15 180x1.955 = 139.7 mm BbeamC.O.
Take s =125mm
0.4
0.4
2
As1,min =fb xs =-xI80xI25 = 25 mm
Use et> 10
@ 125
mm (8et> 101m')
T t-
500
-\
o
o
et>1O @125mm
II Shear reinforcement details
719
i
«)
beamc.g
I- t===~===~---=---=::---==----:::---::----=---=---=----==1--- -l
~14--------------------18m---------------------·~1 Fig. EX.9.2
720
e = 300 + (400 - 300) x ~ = 307.8 mm
Solution
In the detailed procedure, the concrete shear strength is taken as the smaller of two vales qci (flexural-shear strength) and qcw (web-cracking shear strength).
(18/2)
d = 750+ 0.70 x(400-300) = 757.8mm
cu qci = 0.045Ji
Yc
+ 0.8 (qd +qi x M cr ) M max
P.
~ 0.24~icu 1Yc
Step 1.1: Calculate Mer
=i pe xAps = 1080x 12801 1000 = 1382.4 kN
o
o
3
3
Y
g
1 = 2X[500X150 +500X150X(450-75 ]+ 180x600
12
II" 4)
12
I
O.65~
Since the section is symmetrical, Ytop= Ybot= 450 mm 6 _ -
!
-h·r·---------------------------- -l g I-- --,;- r-----------------~J--{ ~
I =2.46 x 10 10 mm4
- _1_ -- 2.46x10 Z bolYbo/ 450
9
p
Step 1: Calculate qci
~
tendon profile
9m ----~I·-----9m----~·1
54 •7 X 10 6 mm 3 =
i pce
1382.4xI000x307.8 =-13.14N Imm 2 54.7 x 106
1382.4xI000 258000
It should be clear that the absolute value offpce is used. Hence, it is given by: 2
o o
/pce=13.14 Nlmm !cd is the unfactored concrete stress under dead load moment only.
BeamC.G.
\0 2
=6.45+2=8.45 kNlm'
Wd
Aps=1280 mm
Rd=Wd V2=76.05
150
T
The dead load moment at the critical section equals:
/-500-1
Yb
cd
wherefpce is the compressive stresses at the extreme fibers (bottom in this case) due to the prestressing steel only. =- Pe
A
2
Md
_
P. Xe Z
bOI
= Rd ·x c -
f. =
Mcr =!':"'(0.45.JJ: +ipce-icd)
i pee
kN
d _·X-,C,-2.= W_.::..
2
76.05xO.70- 8.45xO.70 = 51.2 kN.m 2
6
Md = 51.2x10 = 0.93N Imm 2 Zbol
54.7 x 106
Noting that ZboFl/Yh thus 6
M cr = 54.7 X106 (0.4555 + 13.14-0.93 )110 = 813.22 kN.m
.
The eccentricity at the critical section equals:
721
..
722
Step 1.2: Calculate qd and qi
Step 2: Calculate qcw
The un factored shear due to dead loads at the critical section equals:
q~ = 0.24 (k +J,a )+q~
Qd = Rd -w d . X e = 76.05 - 8.45 (0.70) = 70.135 kN
=~= 70.135xlOOO =0.514 Nlmm 2
qd
bxd p
Wu
/pee represents the stress at the C.G. of the section after losses. At the C.G. only
180x757.8
normal stress exists as shown the in figure.
-
=1.4xw d +1.6xw u = 1.4x8.45+1.6x22 = 47.03kN 1m'
The factored reaction at the support equals:
R = wu xL = 47.03x18 =423.27 kN u 2 2 The factored shear Qu at the critical section equals: Qu
-wu 'xx =423.27-47.03(0.70)=390.35 kN
=Ru
The factored moment Mu at the critical section equals: 2
M =R u
.X - Wu
u
e
2
,xe = 423.7xO.7- 47.03xO.70 =284.8 kN.m
2
2
The factored shear Qi at the critical section equals: Qi = Qu
-
Qd = 390.35 -70.135 = 320.21 kN
. = ~ = 320.21xlOOO = 2.35 N I mm 2 q, b Xd p 180x757.8
f pee
= Fe ::;: 1382.4xlOOO A 258000
5.36 N Imm 2
qpv represents the stress due to the vertical component of the section. The vertical component was determined previously as:
The factored moment MlIlQX at the critical section equals:
(Fe xsinO)lyps qpv::;: bxd p = bxd p
Mmax =Mu -Md =284.8-51.2=233.6 kN.m
Since 8 is small we can assume that sin 8= tan 8.
I:Ience,
-e. ::;: 1382.4x 400 - 300 ::;: 15.36 kN Q p=vF. x tan(O) = Fe emLI2 18/2xlOOO
f.g
5 ( 0.514+2.35x-813.22) =7.17 N/mm 2 qei =0.045 -+0.8 1.5 233.64
Q pv Iyps
Q pv Iyps = 15.36/1.15xlOOO =0.098 N Imm 2 qpv::;: b xd p 180x757.8
qei,rDm = 0.24.J35/1.5 = 1.16 N Imm 2 qcw = 0.24 (
723
(fpe Iyps xAp )xsinO bxd p
f.g
+5.36)+0.098 = 2.54 N Imm
724
2
r - - - -_ _ _ _ Alternatively
qcw may be taken as the shear stress that produces a principle tension stress of ~ = 1.48N I mm 2 at the centroid of the web. It = 0.25 ",35
F JI
=.~ L(Ipcc)2 + 2 2 qew
qcw =0.25J.J:
!
Step 5: Calculate shear reinforcement
Il
Since qu (2.86) > qcu (2.54), shear reinforcement is required. Assume that the stirrups diameter is 10 mm, thus:
l
Ast = 2x78.5 = 157 mm
I 1
_(Ipcc) 2
I!
t( k ~
·li;?":~:'.f
I J+1 0.25 fleu
I
2
286 - 2.54 - =. - - -159 - . N I mm 2 q su =q u -qcu 2 2 For 10 mm stirrups, the total shear reinforcement area for two branches equals: Ast = 2x78.5 = 157 mm
2
The required spacing is given by:
2
Sincehcc=5.36 N/mm and 0.25Ji: =1.48, the previous equation gives: 5.36) qcw =1.48 ( - +1 1.48
A
There is about 25% difference in the value of the web-cracking shear strength determined from both methods. We shall take the conservative value of qcw = 2.54N/mm2.
Step 3: Calculate
s = As, xl y 11.15 = 157x360/1.15 = 172 mm Use <1>10 @166 mm (61O/m') b xqsu 180x1.59
qcu
. =0.4bxs=0.4x180X166=33.3mm2
sl.nun
It is clear form the previous two examples that the simplified method is very
conservative. The shear strength calculated using the detailed method (2.54 N/mm2) is about 40 percent more than the simplified procedure (1.81 N/mm\ '\
The concrete shear strength is the smaller of the flexural-shear strength (qci=7.17 N/mm2 ) and the web-cracking shear strength qcw=2.54 N/mm 2. Hence, it is given by: 2 qcu = 2.54 N Imm
Step 4: Check the maximum shear stress
qumax
The applied ultimate shear stress at the critical section equals: qu
=~ = b dp
390.35 = 2.86 N I mm 2 180x757.8
The maximum shear strength is given by: qumax
S
0.75~CU Ye
=0.75
{35 =3.62N Imm 2 s4.5N Imm 2
V1.5
qu,max = 3.62 N I mm 2 Photo 9.4 Curved reinforced concrete bridge
Since qu is less than qu,max the concrete dimensions of the section are adequate. 725
"
726
. \
\
9.3 Torsion in Prestressed Concrete 9.3.2 The Design for TCZ-5iui1 in the Egyptian Code
9.3.1 General When subjected to torsion, a cracked prestressed concrete beam as the one shown in Fig. (9.lOa) can be idealized as shown in Fig. (9.10b). The cracked beam resists the applied torsional moment through acting as a space-truss as shown in Fig. 9.10. The space truss consists of: •
Longitudinal reinforcement concentrated at the comers.
• •
Closed stirrups Diagonal concrete compression members between the cracks which spiral around the beam.
The angle of the inclination of the compression diagonals with respect to the beam axis, e, depends on the ratio of the force carried by the longitudinal reinforcement to that carried by the stirrups and also on the value of the prestressing force.
9.3.2.1 Introduction The ECP 203 torsion design procedure for prestressed beams is based on the space truss model with some simplifications. The assumptions are the same as those for ordinary reinforced concrete with minor modifications and can be summarized in the following: •
The angle of inclination of the compression diagonals (which is the angle of inclination of the cracks) is set equal to: 45°
for cases in which f pe S 40% of f
pu
37.5° for cases in which fpc > 40% of f
pu
•
The thickness of the walls of the truss model, te , and the area enclosed by the shear flow, Ao, are calculated using the expressions given in the ECP 203.
•
A limiting value for the allowed shear stresses developed due to torsion is given to ensure prevention of crushing failure of concrete in the struts.
In the ECP 203 torsion design procedure, the following three strength criteria are considered: •
First, a limitation on the shear stress developed due torsion is established such that the stirrups and the longitudinal reinforcement will yield before the crushing of the concrete struts.
•
Second, closed stirrups are provided to resist the applied torsional moment.
•
Third, the longitudinal steel distributed around the perimeter of the stirrups should be adequate to resist the longitudinal force due to torsion.
b) Idealized section of the truss
a) Section of the actual beam
Fig. 9.10 Idealized cross-section for torsion
.. 727
728
9.3.2.2 Calculation of the Shear Stress due to Torsion The ECP 203 adopts a thin-walled section analysis, to predict the shear stress due to torsion in hollow as well as in solid sections. The ultimate shear stress developed due to the ultimate torque M tu is given by:
Consideration of Torsion
According to the Egyptian code ECP 203, torsional moments should be considered in design if the factored torsional stresses calculated from Eq. 9.20 exceed qlumin' given by:
=
M,u . ................................................ (9.20) 2Ao t. For simplicity, the following expressions are suggested by the code to compute the area enclosed by the shear flow path, Ao, and the equivalent thickness of the shear flow zone, te: q/u
9.3.2~3
Ao =0.85Aoh .............................................. (9.21) te =
Aoh/ Ph ............................................. (9.22)
where Aoh is the gross area bounded by the centerline of the outer closed stirrups. Ph is the perimeter of the stirrups.
q
. =0.06/,CU tu mm Yc
1+
fpcc
(9.23)
.............................
0.25 .J.J::
.
Wherehcc is the average normal stress at the e.G.. of the sectIOn ifpcc
p. ).
=A
The previous equation is similar to that of ordinary reinforced concrete except
fa~tor ~1 +f pee /0.25.J.J:: that presents the added
for the magnification
concrete strength due to prestressing as shown in Fig. 9.12. -------_ ...
4.5
4.0
The area Aoh is shown in Fig. 9.11 for cross-sections of various shapes. 2
For hollow sections, the actual thickness of the walls of the section should be used if it is less than te .
b; trl
C"J
3.5
3.0
0
~
'-.,'"
2.5
+
.-<
!
2.0
1.5
1.0
0.5 ---------.. -._--
0.0
-
.. ---_._... _--. - - - - . - - - - . - - - t - - - - . - .
-1-------1-----+----1-----+---------1
o
5
10
hcc(N/mm Fig. 9.11 Definition of AOh
. 729
15
20
2 )
Fig. 9.12 Magnification factor according to the applied prestressing stress and concrete strength 730
25
9.3.2.4 Check the Adequacy of the Concrete Section The concrete compression diagonals carry the diagonal forces necessary for the equilibrium of the space-truss model. Preventing crushing failure of the compression diagonals can be achieved either by limiting the compressive stresses in the concrete struts or by limiting the maximum shear stress. The·ECP 203 limits the shear stress calcutated by Eq. 9.20 to the value given by:
qlumax
=
::; 4.5 N Imm 2 ..................... (9.24)
0.75 f,cu
Yc
If qu > qtu,l1l11X, the concrete dimensions of the cross-section must be increased.
1 1
!i
B-Longitudinal Reinforcement
The area of longitudinal reinforcement required for torsion Asl is given by:
!
AsI = M tu IPh cot. 2 () ............. .<............................. (9 .27) 2A ..L o Y s Substituting the value of M/u from Eq. 9.25, the ar«a of the longitudinal reinforcement can be expressed in temis of A str as follows:
ASI =
9.3.2.5 Design of Torsional Reinforcement A-Closed Stirrups The ECP 203 uses the expression that was derived from the space-truss model with the angle set equal to either 37.5° or 45° depending on the amount of prestressing. Hence, the area of one branch of closed stirrups A str is given by:
e
A
sir
= 2 Ao
Mlu's (fYSI ) cot
Mlu's
sir = 1. 7
fr
(X 1 • Y 1 )
cot
37.5°
0.40jf-Acp
r..c
AsImill =
Iy / Ys
-
.
(Aslr) Ph (IYSI) ................... (9.29) S
Iy
In the previous equation A slr should not be less than
b 6x IY'I
9.3.2.6 Related Code Provisions
pe
::; 40% 01 f pu
for cases in which f
pe
> 40% 01 f
pu
The Egyptian Code sets the following requirements with respect to the arrangements and the detailing of reinforcement for torsion as follows: 1- Stirrups must be closely spaced with maximum spacing (s) such that:
= 0.40 b xs
200 mm
f ys/
s = smaller 01
rr 8
731
(9.28)
The area of the longitudinal reinforcement should not be less than:
e
for cases in which f
A strmin
COe () .....................................
S
where Xl and Yl are the shorter and the longer center-to-center dimensions of closed stirrups. The angle e is taken as
•
Iy
where Acp is the area enclosed by outside perimeter of the section including area of openings.
> ASlr.min .......... (9.26)
()
IYSI
where h and hst are the yield strength of the longitudinal· reinforcement and the yield strength ofthe stirrups, respectively.
,."
In case of rectangular sections, Eq. 9.25 takes the form: A
s
e ................................... (9.25)
Ys
Asli. Ph
.. 732
'2- Only the outer two legs are utilized for torsion plus shear, and the interior legs are utilized for vertical shear only. 3- For box sections, transversal and longitudinal reinforcement arranged along the outside and the inside perimeter of the section may be considered effective in resisting torsion provided that the wall thickness tw is less or equal to b/6 where b is the shorter side length of the section. If the wall thickness is thicker, torsion shall be resisted by reinforcement arranged along the outside perimeter only.
I
I I
I
i~f
.------:1
:-------'1
iJ!
.-------ll
I
4- Stirrups proportioned for torsion must be closed as shown in Fig. 9.13. Fig. 9.14 Effective flange width for torsion
16 bar diameter embedded /
leg with 105 bend ""
-
..
'
,"'
".
7- The spacing of the longitudinal bars should not exceed 300 mm and they should be uniformly distributed along the perimeter as shown in Fig. 9.13. At least one bar must be placed in each corner of the section (Le. in each corner of stirrup). The minimum bar diameter shall be 12 mm or 1115 of the spacing between stirrups whichever is larger.
- - - - - - - - - I--
•
8- Enough anchorage of longitudinal torsional reinforcement should be provided at the face of the supporting columns, where torsional moments are often the maximum.
•
Summary of Torsion Design Fig. 9.13 Torsion stirrup details
Step 1: Determine cross-sectional parameters
5- It is permitted to neglect the effective part of the slab in T- and L- sections when calculating the nominal shear stresses due to torsion. 6- In case of considering the effective part of the slab in T- and Lsections when calculating the nominal shear stresses due to torsion, the following measures are taken refer to Fig. 9.14. •
•
The effective part of t~e slab in T and L sections measured from the outer face of the beam should not be more than 3 times the slab thickness. The effective part of the slab should be provided with web reinforcement.
Aoh = area enclosed by the centerline of the closed stirrups. Ph
=Perimeter of the centerline of the closed stirrups.
Step 2: Calculate the shear stress due to the ultimate torsion M tu
qtu
= 2A t o e
Note: If the actual thickness of the wall of the hollow section is less than Aohl Ph ,then the actual wall thickness should be used.
.. 733
734
9.4 Combined Shear and Torsion 9.4.1 Introduction
Step 3: Check the need for considering torsion
When a hollow section is subjected to a direct shear force and a torsional moment, the shear stresses on one side of the cross section are additive and on the other side are subtractive as shown in Figs. 9.1~a.
- 006!iU . 1+. Ipccr;:Ye 0.25 .Jleu
qtumin - .
If
q tu
< q tu min , one has to consider the shear stresses due to torsion.
When a solid section is subjected to combined shear and torsion, the shear stresses due to shear are resisted by the entire section, while the shear stresses due torsion are resisted by the idealized hollow section as shown in Fig. 9.15b.
Step 4: Check that section size is adequate
. If qtu
qtumax
= 0.75
~ ~ 4.5 N / mm VY:
2
If q tu > q tu max' one has to increase concrete dimensions.
Step 5: Design the closed stirrups The amount of closed stirrups required to resist the torsion is:
A sir =
Shear stress due to torsion
M( tu· s)
2AOh 1;:1
Shear stress due to torsion
Shear stress due to shear
Shear stress due to shear
cot () b) Solid section
a) Hollow section
Check that the provided area is more than A strOUD. = 1 0040 b x S
Fig. 9.15 Addition of torsional and shear stresses
yst
Check that the provided spacing is less than the code requirement.
Step 6: Design longitudinal reinforcement ASl =ASIr (Ph s
)(&-)
9.4.2 Design for Shear and Torsion in ECP 203 9.4.2.1 Consideration of Torsion
coe B
Iyst
Check that the provided longitudinal reinforcement is not less than
As/min
In prestressed members, the Egyptian code ECP 203 requires considering the torsional moments in design if the factored torsional stresses calculated from Eq. 9.20 exceed qtumin' given by: q/umin
In the previous equation ASIr should not be less than __ b_ s 6xlyst
= 0.06/~
Where! pcc
1+
o.:SPk . . . . . . . . . . . . . . . .
P A
=_e
736 735
(9.30)
9.4.2.2 Adequacy of the Concrete Cross-Section
9.4.2.3 Design of Transverse Reinforcement
The shear stresses qu due to direct shear and shear stress qtu due to torsional
For prestressed members under combined she~r and torsion, the Egyptian Code requires adding the transverse steel due to torslOn to that due to shear. Concrete is assumed to contribute to the shear strength of the beal1J.. It does not, however, contribute to the torsional strength of the beam. The transverse reinforcement for combined shear and torsion is obtained according to Table 9.1 ..
moment are given by:
M tu qtu = 2A t
v e
The Egyptian Code concentrates on the side of the hollow section where the shear and torsional stresses are additive. On that side:
q +qt u
u
~ 0.75~fcu ~
Table 9.1: Transverse reinforcement requirements according to ECP 203
'5,4.5Nlmm 2 ...................... (9.31)
Case
qlU <006/i _. Y ~
.
1+
c
In a solid section, the shear stresses due to direct shear are assumed to be uniformly distributed across the width of the section, while the torsional shears only exist in the walls of the assumed thin-walled tube, as shown in Fig. (9.15b). The direct summation of the two terms tends to be conservative and a root=:square summation is used
~(qU)2 + (qtu)2
'5,
0.75~f;:
'5,4.5N Imm
2
qu ~ qcu Provide
qu ) qcu
......... (9.32)
minimum
fpcc 0.25
Jt::
006/i qtu>' -~ Yc
1+ fp"c ,,0.25
Jt::
reinforcement Provide reinforcement to resist
given by Eq. 9.33
qtu' given by Eq. 9.25
Provide reinforcement to resist
Provide reinforcement to resist
qu - qcu/ 2
qu - qcu/ 2 and
qtu
In Table (9.1), qcu is the concrete contribution to the shear strength and is obtained from either •
The simplified procedure
q
•
cu
=
Ii
0.045 ~ + Yc
3.6xQu xd p
Mu
'5, 0.375~fcu / Yc
The detailed procedure, where qcu is taken as the smaller of :
qd ~ 0.045l~ + 0.8 (q, +q,
:
I.
i
2. qcw =0.24 ..jfcu +fpcc +qpv
11
.~/
> 0.24'\f} cu t Yc
(IC
::J:>. O.1A~f. I
X ,:
y<
)
The total amount of stirrups needed for shear and torsion should satisfy the following equation:
Photo 9.5 Beam failure due to combined shear and torsion 737
738
0.40 b
2A str +Asl) nUll. ~
f
S
..................................... (9.33)
Design Summary for Combined Shear and Torsion
YS1
Step 1: Determine cross-sectional parameters
9.4.2.4 Design of Longitudinal Reinforcement.
The cross-sectional parameters for combined shear and torsion design are b, dp ,
The longitudinal steel is not required for shear H . . torsion should be obt . . d . E . . owever, 10ngItudmai steel for aIne usmg q. 9.34.
Aoh and, Ph'
Asl = Astr
(:h )(ff
y
.
)
coe
Step 2: Calculate the ultimate shear stresses due to Qu and Mt
Qu
e ;....................................... (9.34)
yst
qu=-;;-;J
.
p
rye area of the 10ngitudir~~Irei~forcement should not be less th~n: A,'m'.
~
0.40.fi A
f,
;~, ~ ~(A;,) p. [;:' Jh'
d p ~ 0.80t
(9.35)
Note: If the actual thickness of the wall of the hollow section is less than Aohl Ph ' then the actual wall thickness should be used. dp is should not be less 0.8 t.
Step 3: Check the need for considering torsion Calculate the minimum shear stress below which torsion can be neglected.
O qtu min =. .
06 ~f- ~
1
+
Yc
fpcc ~ 0.25 ..Jfcu
If qtu ) qtu min' one has to consider the shear stresses due to torsion
Step 4: Check that section size is adequate The developed shear stresses due to shear and torsions should stratify the following equations For Hollow sections
qu + qtu
~
0.75f,CU Yc
~4.5N Imm
2
For solid sections
~(qu)2 + (qtu)2 ~ 0.75~fcu ~4.5N Imm 2 Yc
Photo 9.6 Curved prestressed box-girder bridge
.. 739
740
,s,'" a:" ~
Check that the chosen area of stirrups satisfies the minimum requirements.
If qtu ( qtu max and qu ( qu max, the concrete dimensions of the section are
adequate. If the above condition is not satisfied, one has to increase the dimensions.
i'
0.40xs xb
'j
~l
(Ast + 2Astr thosen )
Step 5: Calculate the concrete shear strength qcu Calculate the concrete contribution to the shear resistance, qcu using one of the following two procedures: •
~
II'
•
The simplified procedure (use only if ft, e>O.4 /pu)
.
"
• Astr + Ast /4
_ Jf 3.6xQu xd p > ~ qcu - 0.045 - cu + - O.24..Jfcu / Yc Yc Mu ::; 0.375~fcu / Yc I.
•
The detailed procedure, where qcu is taken as the smaller of the flexural shear strength and the web shear strength.
•
•
•
•
Fig. 9.16 Stirrups for shear and torsion
Step 7: Design longitudinal reinforcement 2.
q~ =0.24
(J;,
+/
~ )+q~
A sf
Step 6: Design the closed stirrups
= qsu sl
A
b
S
sir
. = 0.40 s/mm
)(fL) 1 ysl
coe
e
fl: fr:Acp
1 Iys y
(
A slr ) Ph
(I J 2!!...
s
1Y
fysi/Ys
The area of one branch of stirrups needed for torsion is obtained from: A=
S
Check that the provided longitudinal torsional reinforcement is more than the minimum requirement As/,min, where:
If qu ) qcu, calculate the stirrups needed for shear
A
= A sir (Ph
M IU
In the previous equation Astr should not be less than s
S
1. 7Aoh ifYSI / y) cot e
The area of one branch of stirrups needed for resisting shear and torsion
=
A"I Aslr+-
n where n is the number of branches determined from shear calculations as shown in Fig. 9.16. 741
742
b
6x Iyst
Example 9.3: Combined shear and torsion design (1) The cross section of a simply supported prestressed beam is shown in Fig. Ex . 9 . 3. The beam is subjected to a factored shear force of 510 kN, a factored bending moment of 80 kN.m, and a factored torsional moment of 34kN.m at the critical section. Design the required reinforcement to resist the applied shear and torsion. The material properties are hu=1860 N/mm2 for normal stress relieved strands, he = 960 N/mm2, h =360 N/mm2, hst =360 N/mm2 and fcu=40 N/mm
2
•
1 T
Solution Step 1: Calculate section properties To design a T-section for torsion, one has two options: 1- Consider the slab in the calculations and reinforce both the slab and the . --= beam for torsion. 2- Do not consider the slab contribution in torsion design, and provide stirrups and longitudinal reinforcement in the web only (easier and more practical for thin slabs). In this example, the contribution of the slab is considered in the calculations. Note that the flanges must be less than 3 ts as shown in the figure below.
1000mm 0-------1.
1 -. 1 .
(,=250mm
I <3ts
g 00
250mm
350
50mm2
•
100
Assume concrete cover of 40 mm to the centerline of the stirrup.
L I .. Beam cross section
920
.I
170
§
1
Critical section
350
0
C'l
r-
AOh definition Qu=51OkN M u=80kN.m M/u=34 kN.m
Ph = 2x (720 + 920) = 3280 mm
Straining actions at the critical section
AOh
=220x550+170x920 = 277400mm 2
Ao
=0.85Aoh =0.85 x 277400 =235790 mm2
= AOh
t e
Fig. Ex. 9.3
743
A
Ph
= 277400 3280
84.6 mm
= 1000x250+300x550 = 415000 mm 2 744
Step 2: Calculate the ultimate shear stresses due to Qu and Mt 1. Shear stress: The depth of the prestressing steel at the critical section equals
The maximum shear strength qumllX is given by:
d p =800-100 = 700mm qumax
dp =700 mm > 0.8 t ... o.k
:::;
0.75 Jfcu =0.75
Yc
Only the web width is effective in resisting shear force, thus b is taken as 300 mm. Qu 51Ox1000 q =--= =2.429 N Imm 2 b dp 300x700 u
2. Torsional stresses 6
_M/u 34x10 _ 2 q/u - 2xAo xte = 2x235700x84.6 -0.852N Imm
{40 =3.87 Nlmm 2 :::;4.5N Imm 2
Vu
-
qu.max = 3.87 N I mm 2
Since . ~(qu)2 + (q/u)2 ~
qumax'
the concrete dimensions of th~ section are
adequate as shown in the graphical representation below.
Step 3: Check the need for considering torsion qtu,max=3.87
The value of qcu,min equals q/u min = 0.06
Jf
eu
1+
Yc
f .JJ:: pee
0.25
0.75 .J40/1.5 = 3.87
The prestressin~ fo~ce P e is obtained by multiplying the effective prestressing stress after consldenng all losses he by the area of prestressing steel Aps Pe = f pe xAps = 960x850/1000 = 816 kN
-
f pee -
Pe
_
A-
{40
Vu
1+
--I_ _ _ _ _.J.-_--I.._ _ qu (N/mm2)
2.429
816000 2 415000 = 1.97 N I mm
q/u min = 0.06
0.852
\qu,max == 0.75 .J40/1.5 = 3.87
Ko
9 1. = 0.424 N I mm 2 0.25 40
Step 5: Calculate concrete shear strength qcu
Since q/u > q/u min' we have to consider the shear stresses due to torsion.
To simplify the calculation of qcu, the simplified method is used. However, verification needs to be made as shown in step 5.1. '
Step 4: Check that section size is adequate
Step 5.1: Verify the use of the simplified method
For solid sections, the developed shear stresses due to combined shear and torsion should stratify the following equation:
Since the effective prestressing stress he is greater than 40% of the ultimate tendon strength hu (960 > 0.40 x 1860=744 N/mm2 ), the code simplified expression can be used. To use the simplified equation for evaluating concrete shear strength, the term Qu dlMu equals:
745
746
1 .!.'
:1
1':
~1! ~li
Q xd
51Ox(7001l000)
Mu
SO
u p ---'=
i!
I
:'1
use
Quxd p
step 6.3: Stirrups for combined shear and torsion A: Web
= 4046 > 1.0
Area of' one branch for combined shear and torsion = Astr + Asr/2= 23.03 + 69.97 = 93 mm2
= 1.0
Mu
I
Choose $ 12 mm (113 mm2)
I
1.
2.
qcu,min = 0.24Jlcu = 0.24
Yc
{40 = 1.24 N
V'LS
qcu,max = 0.375 Jlcu = 0.375
Yc
Imm 2
(40 = 1.94 N
V'LS
I mm 2
Tota/area chosen = 2 x 113 > As/,mill .......o.k Final design use 12/100 mm
B: Flanges
qcu =0.045Jlcu +3.6X(Qu Xd p ) Yc Mu qcu =
. =. 0040 300xlOO=33.3mm2 Iy bxs = 0040 360 .
Ast,null
The flanges only resists torsion thus the area of one branch=Astr
0.045~+3.6X1.0 = 3.S3 N Imm
2
> qcu,min(l.24) .... o.k
Astr = 23.03 mm2 use 811 00 mm
Step 7 Design of longitudinal reinforcement for torsion
However, since qcu > qcu,max use qcu = qcu,max
qcu =1.94 N/mm2 AI = s
Step 6: Design of stirrups for shear and torsion
AS/rXPh(IYs/] -.- cot 28 = 23.03X32S0(360} co t 2 45 = 755 mm 2 s Iy 100 360
Calculate the minimum area for longitudinal reinforcement As1,min
Step 6.1: Area of stirrups for shear Since the applied shear qu is greater than qcu, shear reinforcement is needed.
0040 rz:Acp _ 2.429 ---=1.459N 1.94 qsu -qu -qcu -Imm 2
2
A
2
sl,min
· a cand'ltion . on thoIS equatIOn . that -A str > b There IS _ -s 6x Iysl
A -- q,u xb Xs = 1.459x300xlOO =139. S mm 2 sl Iy 11.15 360/1.15 Area for one branch of the stirrup equals
Ast/ 2=69.91
mm2
Step 6.2: Area of stirrups for torsion Since/pe (960 N/mm2) is greater than OAO/pu, use 8=45 Using the same stirrup spacing of 100 mm, the area of one branch Astr
= sir
.
M IU Xs
2XAo xl ysl I Ys cot 8
fyc rs
I / y
The spacing of the stirrups should be smaller of phIS (410) mm or 200 mm, try a spacing of 100 mm
A
=
23.03 ~~ .. .o.k 100 6x 360 Acp =300x550+250xlOOO=4l5000mm 2
6
34x10 x 100 = 23.03mm2 2x235790x360/1.15 cot 45° 747
748
0.40 As/,min
=
Example 9.4: Combined shear and torsion design (Boxsection)
(40 x415000
'V360/1.15 1.5
23.03X3280(360) 100 360 = 1983 mm 2
Figure Ex. 9.4 shows a box section that conl'ltitutes the cross-section of the girder of a road-way bridge. Structural analysis of the bridge revealed that the critical section of the girder near the support is l'lubject to the following straining actions:
Since Asl < As1,min ... use Asl,min
Cho~se ~4 $14 (2.155.1 mm ). Note that the maximum spacing between 10ngitudmal bars IS 300 mm 2
Qu= 13000kN M 1u=32000 kN.m M u=60200 kN.m
I[
] ,
~
At this section the girder has been post-tensioned with 32 tendons arranged in 8 2 ducts 60 mm diameter. The total prestressing steel Aps = 17120 mm . The low2 relaxation strand1'i have fpu = 1860 N/mm2 and/pe =1080 N/mm • It is required to carry out a design for the combined shear and torsion for that section. The material properties are as follows: feu= 40 N/mm2 and h = 400 N/mm2
1401>14
V
.\
14000mm
\.
-f------.. _----1-----.. ------.. . ••
Torsional reinforcement details
350
('----J
..
Torsion only stirrup
..
Shear + torsion l'ltirrup
!
I
700 700
350
I-
7000
Fig. EX. 9.4 Cross section of the road-way bridge
Stirrup detail
749
·1
750
Solution Step 1: Calculate section properties Assume a clear concrete cover of 40. mm and the diameter of the bars used is 22 mm as illustrated in the figure shown below
2. Torsional Stresses The torsional stresses in the webs equal:
qtu(web)
6
M tu
= 2xA
xt
o
e
320.0.0. x 10. 2 x (0..85 X 2861290.4) X 70.0.
= 0..94 N
I mm 2
AOh = [4250.- 2x(4o.+ 11) ]X[7o.o.o.- 2x(4o.+ 11)] The top flange is more critical because its thickness is smaller than the bottom one. Thus the torsion stress in the slab (flange) equals:
=4148x6898= 2861290.4 mm 2
Ph =2X(4148+6898}=22o.92mm
6
M tu
qtu(flange)
te = AOh = 2861290.4 = 1295.1mm Ph 220.92 Since the effective thickness (te ) is less than both the web thickness (70.0. mm) and the flange thickness (350. mm), use the actual thickness.
= 2xA() xte
Step 3: Check the need for considering torsion The value of qtu,m;1I equals:
Use te=tactual=35o. mm for flanges
q . = 0..0.6 tu IDm
Use te=tactual=7o.o. mm for webs
320.0.0. x 10. =2.23N Imm 2 2x(o..85x 286129o.4)x35o.
Jfyc
cu
1+
.JJ:
[pee
0..25
The prestressing force Pe is obtained by multiplying the effective prestressing stress after considering all losses he by the area of prestressing steel Aps. Pe =f pe xAps =108o.x1712o./lOo.o. = 18489.6 kN .
•
It can be computed that the total concrete cross sectIOnal area Ac= 13 A m
= p. = 18489.6xlOo.o. =1.38N Imm 2
f pee
6898
Step 2: Calculate the ultimate shear stresses due to Qu and Mt 1. Shear Stress:
Ae
13Ax 106
~
qtumin =0..0.6 -
o.
1.5
1+
1.38 2 r;;: =o.AN Imm 0..25....,40.
Since qtu > qtumin' we have to consider the shear stresses due to torsion.
The applied vertical shear force is resisted by the internal shear stresses developed in each web. From the figure one gets:
d p = 360.0. mm > (o..8t
qu
= 0..80. x 4250. = 340.0. mm )... .ok
=~= 13o.o.o.xlOo.o. =2.58N Imm 2 b xd
(2x 70.0.) x 360.0.
751
752
2
TI
Step 4: Check that section size is adequate
1
The maximum shear strength qU1lUJX is given by:
q
. umax
::::: 0.75 Jf cu =0.75
yc
[40 =3.87 N V15
Imm 2 :::::4.5 N Imm 2
qtu(f1ange)
i1 i
For the flanges (top or bottom flanges) Since
j
= 2.23 N I mm 2 < qu,lnax, the flange thickness is adequate.
For the webs For hollow sections, the developed shear stresses due to combined shear and torsion should stratify the following equation:
qu + qtu ::; qumax qu + qtu =0.94+2.23=3.17 N Imm
Step 5: Calculate concrete shear strength qcu To simplify the calculation of qcu, the simplified method is used. However, verification needs to be made as shown in step 5.1.
Step 5.1: Verify the use of the simplified method Since the effective prestressing stress he is greater than 40% of the ultimate tendon strength hu (1080 > 0.40 x 1860=744 N/mm2 ), the code simplified expression can be used To use the simplified equation for evaluating concrete shear strength, the term Qu dlMu equals:
Qu xd p = 13000 x (3600/1000) = 0.77 < 1.0 .... .ok Mu 60200 •
qcu.min = 0.24Jfcu
•
qcu,max
yc
2
Since , the concrete dimensions of the section are adequate as shown in the graphical representation below.
= 0.24 [40 = 1.24 N I mm 2
=0.375~fcu yc
V15
=0.375
qcu =0.045Jf;: + 3.6 x (Q:ud
. [40
qtu,max=3.87
qcu = 0.045
V15
(40 =1.94N Imm V15
2
p )
..
2
+3.6xO.77 = 3.51 N Imm > qcu,min(l.24) .... o.k
Since qcu > qcu,max use qcu = qcu,max
0.75 ../40/1.5 = 3.87 0.94
Step 6: Design of stirrups for shear and torsion Step 6.1: Area of stirrups for shear
r
--f _ _ _ _J . - I _ _~ _ _ qu (N/mm2 )
2.23 \qu,max
~ 0.75 ../40/1.5 = 3.87
Since the applied shear qu is greater than qeu, shear reinforcement is needed.
q.u =qu - q;
=2.58_1.~4 =1.61N Imm 2
The spacing of the stirrups should be smaller of Ph/8 (2716) mm or 200 mm, try a spacing of 100 mm
A = qsu xb Xs = 1.61x(2x700)x100 st fy 11.15 400/1.15
648 mm2
For one web = 648/2=324 ·mm2 and area of one branch=32412=162 mm2 753
754
I ;1
r,
Step 6.2: Area of stirrups for torsion Since/pe (1080 N/mm2) is greater than 0.40/pu, use 8=45. Using s of 100 mm, the area of one branch Astr , one gets: ==
A
sIr
M,uxs 2xAo xi ySI / Ys cot B
6
32000 x 10 x 100 ==189.1mm 2 2x(0.85x28612904)x400/1.15 cot 45°
Step 7 Design of longitudinal reinforcement for torsion = A slr XPh (/ys,
A sl
sly
Jcoe B = 18if.1x10022092 (400)coe 45 = 41784.mm 2 400_
Calculate the minimum area for longitudinal reinforcement As1,min
For box sections, the code permits the use of reinforcement along the interior and exterior sides of each web if the wall thickness tw is less or equal to the section width/6 . .: t (700) < ~ < 7000
6
W
6
The area of the stirrups for torsion can be divided on the two sides Area of one branch A str =189.112 =94.55 mm2
Step 6.3: Stirrups for combined shear and torsion A: Web Area of one branch for combined shear and torsion 2 = Astr + Astf2= 94.55 + 162 = 256.6 mm Choose 20 mm (314 mm2)
. A b There is a condition on this equation that ~ ~ - - S
6xlysl
7000 b 189 - < thus use - - 100 6x400 6xlys, Acp
=7x4.25 =29.75 m
2
b 0.40 2(&loroneweb) A, . =0.4 s ,mm Iy- xs =--700x100=70mm 400 Total area chosen = 2 X 314 > A sl .min' ..... .o.k
Final design use 181100 mm
B: Flanges The flanges only resists torsion thus the area of one branch=Astr
A str = 94.55 mm2 use 12/100 mm 2A,
sr
+A,) . S
nun
o 0.4 -x29.75x106 A . = 1.5 _( 7000 )X22092X(400)=112237mm2 sl.nun 400/1.15 6x400 400
~
= 0.40 bxs = 0.40 (350)x100=35mm 2 Iy 400 Since Asl < As1,min ... use As1,min 2
As,,chosen = 2x1l3 = 226 mm > 35.2 ..... .ok
Choose 184 28 such that the maximum spacing between longitudinal steel is less than 300 mm
Final design two stirrups +20/100 mm (two branches) in the webs and two stirrups +121100 mm (two branches) in the flanges 755
756
'-
c
~
~
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tU
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r-
10
~ "iii
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'?'
0C\I '§: 0 ~
~
~
E
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'§:
I
CONTINUOUS PRESTRESSED BEAMS
I W/OZ~O~
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<0 C\I
~
:
~ ~
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'§:
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V E
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Photo 10.1 Sohag bridge over the River Nile
10.1 Introduction Continuity is frequently used because of the several benefits that can be achieved. Continuity reduces the bending moments resulting in more economic designs. It also permits tensioning of the tendons over several supports with a great reduction in the number of anchorage and labor cost in the prestressing operation. Finally, the deflection of continuous members is 'greatly reduced when compared to that of the simple span.
757
758
Continuous prestressed concrete beams are widely used in Egypt in the construction of bridges particularly those constructed using post-tensioning technique. The disadvantages of continuity can be summarized in the following: • Higher frictional losses due to the larger number of bends and longer path. • The sections over the interior supports are subjected to combined effect of high bending moments and high shear forces whereas the section at mid-span of a simple beam is subjected to zero shear. • Development of horizontal forces and moments in the supporting columns. These forces are produced by elastic shortening of the beams. •
Formation of secondary stresses due to shrinkage, creep and temperature. • Moment reversal may occur due to alternate loading of spans. • Formation of secondary moment due to induced reactions at the middle supports caused by prestressing force (to be discussed later).
Despite of all these disadvantages, the use of continuous prestressed concrete beams is an attractive solution when compared to other structural systems especially in bridge construction. Most of these factors can be eliminated by following the appropriate design considerations.
anchorage
(a) Beam with constant depth
Post-tensioned cable
~q (b) Beam with variable depth and straight
(c) Beam with overlapping tendons
Fig. 10.1 Tendon profile in continuous post-tensioned beams
10.2 Tendon Profile for Continuous Beams Tendon profiles for continuous beams vary according to the span length, structural integrity, and the construction method. Figure 1O.1a shows how continuity is achieved in a post-tensioned beam. This profile is used extensively in slabs and short span beams. The tendon is located below the C.G. at midspan while it is located above the C.G. at the supports. The major advantage of such a system is the simplicity of formwork. However, high frictional losses due to the length of the cable and the large number of bends are considered as major disadvantage. To overcome this disadvantage, a non-prismatic section is used through varying the depth over the support as shown in Fig. 1O.1b. The added cost of formwork is justified by the use of almost a straight cable that· reduces the frictional losses. The system shown in Fig. 1O.1c has the advantage of small frictional losses due to shorter cable length in addition to the simplicity of the formwork. Additional cost may be incurred due to the use of several anchorages.
Continuity may also be achieved by pre-tensioning some cables in the beam and post-tensioning other cables. In Fig. 10.2, the pre-tensioned precast elements are arranged over the support as simple beams. Then post-tensioning is applied longitudinally to provide continuity over the supports. Concrete is poured over the support between the beams. Example of continuous prestressed box section with various cable profiles is shown in Fig. 10.3. ost-tensioned cable
Pre-tensioned cable
lZig. 10.2 Continuity through pre~tensioning and post-tensioning
759
760
10.3 Elastic Analysis of Continuous Beams 10.3.1 Effects of the Prestress The deformation caused by prestressing in a statically determinate member is free to take place without any restraint from supports. In statically indeterminate members, however, this is not the' case. The intermediate supports impose additional geometric constraint which is zero deflection at the intermediate supports. During the stressing operation, the geometric constrains of zero deflection at the intermediate supports cause additional reactive forces to develop at the locations of the intermediate supports, which in tum change the distribution and magnitude of the moments and shears in the members.
m
-"'--
N.~-~~~4----;~-
(/) X «)-,
!!2
x~
--+4--~--~~
m me:' 0
13 CD (f)
In continuous prestressed concrete beams, the moment induced by prestressing on a particular cross-section in a statically indeterminate structure may be considered to be made of two components: a- The first component is the product of the prestressing force (P) and its eccentricity from the centroidal axis (e). This is the moment that acts on the cross-section when the geometric constraints imposed by the intermediate supports are removed. The moment (P.e) is called the primary moment.
e: o
b-
1a
a;
iTI -§ -------.
__'«"
« -"'--
13CD
The second component is the moment caused by the reactions developed at the intermediate supports. As mentioned before, such reactions are required in order to achieve zero deflection at the intermediate supports due to prestressing. This moment is called secondary moment.
(f)
Elastic analysis of continuous beams can be carried out using one of two methods: • Support displacement method. •
le: o
Equivalent load method.
10.3.2 Support Displacement Method
UCD (f)
10.3.2.1 Background Let us consider a cantilevered beam with a roller support at the end as shown in ". Fig. lOA. If this support is removed, the beam becomes determinate and it will deflect downward. To maintain its previous position, a force R is required. This force causes the secondary· moment. The original (primary) moment due to prestressing equals MJO=P.e (negative in this case). The final moment any point equals:
,....)------..JIYoI.~4_------_;.
~!~
- w oa: -0.
761
,I
Mjillal
=Mprimary + Msecolldary •••••••••••••••••••••..••••• (10.1) 762
BeamC.G.
To detennine the unknown reaction R, the method of consistent defonnation is used. The unknown reaction is replaced by a unit load and the structure becomes detenninate. The deflection ~1 due to this unit load (P =1) can be obtained by integrating the moment Mll over the span as follows:
_. __. . . . . . _.. . . . . . _. . . . . . ._. . . . _._. . . . . . . . ._. . _._. _. . __._. . . . . . _.,l
~--r_--------------------,.-r~--p
t
Cable profile
£\1 =:1
JM 11 xM 11 d x
••••••••••••••••••••••••••••••••
(10.2)
Furthennore, for simple structures, the deflection Oll can be obtained using the expressions given in Appendix A. For example, the deflection of a cantilever beam with concentrated load at the end equals: P L3
L3
3E I
3E I
L
r
~o
~-,
---------- ------
due to the primary moment MJO can be computed by as
£\0 = Ell
JM ll M lO d x
••••••••••••••••••••••••••••••••••
~--r_~------------------,.-T----p :
T
-,
~l
(10.4)
.Since, the deflection at the actual support should equal to zero, the unit load deflection ~ 1 should be equal and opposite to the deflection caused by the primary moment ~o. Hence, compatibility of defonnations gives: ROil
Deflected shape
~.
£\1 = - - = - - ........................................ (10.3) The deflection follows:
1-
~
~I--------~-----------,l kN t T L
= -010 ............................................... (10.5)
I
R is a factor required for consistency of defonnations and is given by:
R= -
010 ....................................................
(10.6) Moment due to unit load (Mll)
011
The secondary moment has the same shape as the unit force moment, but with a modified value given by:
Msec
Removing the support
= RxM u ............................................... (10.7)
L
It should be clear that the secondary moment is added to the primary moment to produce the final moment. Also, the value of the secondary moment is dependent on the prestressing force and the tendon profile.
Fig. 10.4 Application of support displacement method to continuous prestressed beam
763
764
P.e
Applying of the method of consistent deformation to the beam shown in Fig. 10.5, results in the following expressions:
BeamC.G.
P.e
~
P--+---..4...._..........•....•.....•- ..•............•..•._.___............................................
........-t----=-p
)
Cable profile
J
L
1 1 L -P·e· L2 I 8. = - M M d =-(-P·e)·Lx-=---w \0 EI II 10 x EI 2 2EI
P.e
P.e To facilitate the calculations of the above integrals, the integrations of some typical shapes are given in Table 10.1. Thus, R equals:
8.
R =-....JQ. = 011
Primary moment, MJO
-P·e·L2 /2EI 3 L /3EI
L~
The secondary moment at the fixed support equals:
_3P·e L_ 3P . e M sec --R X M 11-2L""X --2-
3
p·Mws==:::==-;;:/
Moment due to unit force (MIl)
Secondary moment, Msec
2L
2
= Mprimary + Msecolldary
The final moment at the fixed support
3 P·e P·e =-P·e+--=+-2 2 The effective eccentricity at the fixed end
=+e/2 (above C.G.)
The Moment at the free end
=Mprimary + Msecondary
2
=-P·e+O=-P·e The effective eccentricity at the free end
=-e
1
(below C.G.)
Figure 10.5 shows the primary, the secondary and the final moments for the beam. The final moment can be represented by an effective cable profile or line of pressure or C-line. The profile is obtained by dividing the final moment by the prestressing force.
I, "
II 765
BeamC.G.
e/2
1 /}--,--i-----+----:...;;::..:..::...........~p L
Fig. 10.5 C-Iine, or pressure line, or effective cable profile 766
Example 10.1 The stress distribution in a statically determinate beam is given by considering the actual cable profile, whereas in a continuous beam, the stress distribution is obtained by using the effective cable profile which gives the effective eccentricity e * or the final moment due to prestressing (P e*). Hence, the stresses at the top and bottom fibers of a section in a continuous beam can be obtained using the following equation: P
P xe*
The figure given below shows a post-tensioned continuous beam. The tendon profile is shown in figure. the effective prestressing force after losses is 1500 leN. Compute the primary, the secondary and the final moments using the support displacement method. Calculate the stresses at section F due to prestressing and self-weight knowing that thecross:.section of the beam is rectangular with dimensions 300 rom x1200 mm.
M
f =--;(+-z-±z······························(lO.8) where M is the applied moment at the critical section.
160
Cable profile
f
Table 10.1 Values of product integral M 11 M 10 dx
~M'
1
I I
M 3
I.
1 .I
~M3
1
L
I
M3~
1
M3~Mt
1<'1
1
L
1
M,
1
L
2L (M, +M 2) M3 2L M , M3
L
(i (M, +2M 2) M3
3 M , M3
L
L
(i (2M, +M 2)M 3 L (iM, (2M 3+M.)+
L
"6M, (M, +2M.)
L "4MJ M 3
L
M,
~
2
I M3
c:t
2
L -M, M3
L (iM, M3
L
I
L
M,
~
1
1
L
1
2L M M
3
'
3
L "4 M ,M3
L -M, M3
L "4MJ M3
L -M J M 3
3
3
L 3L M ,(M,+M -::1M, (M, +M.)
4)
-M2 (M3 +2M.) 6 L
-::I M, (M, +M 2 )
L -M,M3
3
5L M M
12
'
3
1----1 300
Beam section F-F
767
768
1
Solution Step 1: Calculate the secondary moment at support b The primary moment due- to prestressing causes camber at the middle support. By removing the middle support and assuming a unit downward force of 1 kN, the bending moment equals:
4
5. =_1_ fM M dx =~XM xM = 12x12x48 = 2304 J, EI
11
3EL
11
11
11
3 EI
c
12
12
12m
12m
a- Cable profile
I
630kN.m
tl
A
EI
420
b
a
1
The displacement at the middle support c~h 1 due to the unit force equals (refer to Table 10.1): 11
j
fS----~~-~-~-----~
Ii
M 11 = P xL = 1x(24 + 24) = 12 kN.m
4
I
Cable profile
630
~.~ "l(iJY~ 240
b- Primary moment
1
630+240/2=759.
l
750
~
48m
240
c- Simplified primary moment
.
+
iiii
M -12
Moment due to unit force
11-
ih 1
3
48xE I
i
Mll=12
Moment due to 1 kN
=lx(24+24)3 = 2304J, 48xE I EI
5. =_1_ fM M d =~x(24X240X12 750X24X12) = _ 97920 EI
11
0
x
EI
3
The condition at the support is given by R 811 .+ 810
769
3
=0
EI
~
+
+
The displacement due to the original prestressing force can be obtained by applying the method of consistent deformation. Referring to Table 10.1, the deflection at intermediate support equals: 12
ii
can also be determined using the deflection equation as follows:
5. = PL 11
i
510
375
d- Secondary moment
375
A~~~ 750 e- Final moment 770
R =-
<\0 <\1
=
-97920/ EI = 42.5-12304/ EI
Step 3: Concrete stress due to prestressing and self-weight at section f
Thus, the secondary moment at the intennediate support equals:
The effective eccentricity e* at section F equals: e* = eab = 250 mm
Msee = RxM II = 42.5x12 = 51OkN.m
A=300xI200=360000 mm 2
Step 2: Calculate final moment and effective eccentricity The final moment (due to prestressing) at the intennediate support is given by:
Mb +Msec
= 240+51O=}50kN .m
wow
= 25 x 360000 = 9 kN / m' 10 6
The maximum positive bending for a continuous beam with two equal spans and equal loading can be obtained as follows:
The effective eccentricity at the intennediate support equals:
2
Mow -
=primary moment _ M sec
The midspan final moment
Zbot
2
=
11
11
2
2
Ztop
= bxt = 300x1200 = 72xl0 6 mm 3 6 6
The stresses at bottom and top fibers due to prestressing and self-weight equal:
= -630+ 510 = -375 kN.m
2 The effective eccentricity at mid-span equals: e ab
2
_ w ow xL =9X24 =471kN.m
eb -- 750x1000 -_ 500 mm i 1500
P
J;
P xe*
Mow
=-~---+bot A Zbot Zbot
- -375x1000 _ 250 I mm-¥ 1500
-
1500x1000 360000
6
1500x1000x250 + 471.27x10 = -2.83 N / mm 2 6 I 72x10 72xl06
P Pxe* _ Mow flOp =--A + Z Z 500
top
C-Iine (pressure line) hop
=
bot
1500 x 1000 + 1500 x 1000 x 250 360000 72xl0 6
irop = -5.5 Nlmm2
c
/.
12m
12m .I
./
'
Effective cable profile (C-line)
12m
./
6
471.27x10 = -5.5 N / mm 2 72xl0 6
tl
f-..= -2.83 Nlmm'
771
772
Example 10.2
Solution
A continuous pretensioned beam'with two equal spans of 16.0m each is shown in the figure below. It is required to compute the primary, the secondary and the final moments using the support displacement method. The effective prestressing force after losses can be estimated as 1800 kN. Calculate the stresses at the section F due to additional live loads of 32 kN/m'.
Step 1: Calculate section properties A= 2x600xlS0+600x200 = 300000 mm
Since the section is symmetrical;
Ytop
2
= Ybottom= 4S0 mm 3
3
1= 2X(600XlS0 + 600XlS0X(4S0-7S)2)+ 200x600 = 2.92S X1010 mm
,12
IF
200 rom
12
Cable profile Zbol
I =--
2.92S X 1010
----=
4S0
Y bottom Ztop= Zbot=
c
a
8m
4
8m
Wo,w
3
6Sx10 mm
= r xA = 2Sx 300000 = 7.SkN 1m' c
8m
6
6S X 106 mm 3
1000000
Step 2: Calculate the secondary moment at support b The primary moment due to prestressing causes camber at the middle support b. By removing the middle support and applying a unit force of 1 kN, the bending moment equals:
L ISO
1T 8
1-,L'600 ---i I I L..-.,
200-
I-
lx(16+16) =8 kN.m 4 4 The displacement at the middle support ~h 1 due to the unit force equals:
T 1
11
1 L 32 682.667 011 =-fMllMlId =--M 11 xM lI =--x8x8= J,. EI x 3EI 3 EI E I
o o
\0
II I
= PxL
M
0\
ISO
•
I
T
!- 600 ---i Beam cross section
1 kN
A-
I-
1 32m
~
I
~~ Mll=8 kN.m
Bending Moment due to a unit force 773
A
774
280
200
Cable profile
The displacement due to the primary moment (prestressing force) equals:
J. = _1_ fM M d =_1_(32X8X360 _16x684x8 _16X468X8) = _ 6144 EI
10
a b c 8m 8m I 8m I 8m 1 1 I
11·0
x
EI
3
4
The condition at the support is given by R 8 11 + 810
a- Cable profile
4
EI
=0
-61441 EI = 9 J.. 682.6671 EI
Thus, the secondary moment at the intermediate support equals:
Msec 360 b- Primary moment 684
Step 3: Calculate final moment and effective eccentricity 468
~~A 360 c- Simplified primary moment
The final moment (due to prestressing) at the intermediate support is given by:
M b + M sec = 360 + 72 = 432 kN ,m The effective eccentricity at intermediate support equals:
eb
A
The midspan final moment (span a-b)
252
~ ~A ~ A 775
2
= -468xlOOO = 260 mm J, ab
432 e- Final moment
= primary moment _ M sec
The effective eccentricity at left midspan equals: e
468
- 432xlOOO _ 240 t 1800 mm
-
72 =-504+-=-468 kN.m 2
MlJ=8 Moment due to 1 kN
72 d- Secondary moment
= RxM ll =9x8 = 72kN.m
1800
The midspan final moment (span b-c) =primary moment _ M,sec 2 . 72 =-288+-=-252 kN.m 2 The effective eccentricity at the midspan of the right span equals: ebc
_-252XlOOO_ J, 1800 - 140 mm /
776
240
,I·
8m
I·
8m
·1·
10.3.3 Equivalent Load Method
C-line (pressure line)
·1 ~
8m
The equivalent load method is another approach for computing the secondary and the final moments. In this method, the prestressing force is replaced by an equivalent load produced by the primary moments. Solving the continuous beam under the effect of the equivalent loads gives the final moments directly. The secondary moments are obtained by subtracting'the final moment from the primary moments as follows:
8m
·1
Effective cable profile (C-line)
Step 3: Concrete stress due to service loads at section F ,
The effective eccentricity e* at section F equals:
M
Secondary
= M final
-
M
Primtvy ............................
(10.9)
The method of moment distribution is usually used to calculate the indeterminate moments at the supports. The equivalent loads can be computed for both linear and curved tendons. The equivalent loads for straight tendon profiles are concentrated forces while those for parabolic tendon profile are uniform loads.
e * = eab = 260 mm
A-Straight Tendon Profile
The total weight Wtot equals:
The horizontal and the vertical components of the tendon forces shown in Fig. 10.6 can be expressed as functions of the cable slope angle as follows:
Wtot =wow +(W DL +w LL )=7.5+32=39.5kN 1m'
H
The maximum positive bending for a continuous beam with two equal spans and equal loading is given as: ftop =-12.94 Nlmm2
M
W XL2 = --!!to"-.t --
11
P
t bot
=P
cos 8
V
=P
sin 8
For small angles, it can be assumed that cos 9=1 and sin 9 =9. Thus, V =P 8
H =P
2
At points D and D' where the tendon changes direction, a summation of forces indicates the existence of an upward force in the vertical direction. The changes in tendon slope at points D and D "equal:
39.5x16 = 919.27 kN.m 11
P xe*
M
=-----+A Zbot Zbol
ihottom=+O.94 1800 xlOOO 300000
0
1800 xlOOOx260 919.27x106 -----:---+ = +094 . N I mm 2 6 6 65xl0
=
= el +e2 Xl
and 8 2
= e2 +e3
65 X 10
' -- e3 +e4 and 01
Pxe* M t top = -AP - + ---Ztop ZIOP
floP
1
O2
X2
6 1800 x 1000 1800 x 1000 x 260 = -12.94 N Imm 2 - - - - - + - - - - - :6- - - 919.27x10 6 300000 65 x 10 65xl0
~----------------.-----------------------------~
777
"'. 778
••••••••••••••••••••••••••••
(1O.10a)
L-x\
= e~ -es L
-X2
........................ (10. lOb)
The equivalent concentrated loads VPJ and Vn are given by:
j
3 e z+e+e? -l -+ ...................... (10.11) Vpi = p ·/10 = p (e
~
.
L-~
4 , (e +e. e 4 -e Vpz =p·/1o:=P -3 _ +-, - s)
Xz
X2
L'-X2
·1
I·
P
H01
V
2 P
--L
1-1
--+-1·
--L'
..................... (10.12)
-Xz
The equivalent concentrated loads can also be obtained by equating the moment due to prestressing force to the moment caused by the equivalent concentrated loads as follows: V
P BI
L
x\(L"':'x l ) L
:=
Pel ................................ (10.13a) C
xz(L'-xz):=Pe 2 L' C
............................
(10.13b)
where eel and ec 2 are the eccentricities at point of change in slop at spans ab and bc, respectively. The eccentricities of the cable cause concentrated positive moment equals (P.e!) at support A and a concentrated negative moment equals (P.es) at support C.
Fig. 10.6 Calculation of the equivalent loads for straight cable profile Photo 10.2 Prestressed concrete box section 780 779
B-Curved Tendon Profile The equivalent load caused by a curved tendon configuration can be established by considering a simple beam with parabolic tendon profile. The bending moment at any point due to this prestressing force is given by (MJ=P.e). If we assume an equivalent uniform upward load Weq acting on the beam as shown in Fig. 10.7, the maximum moment at mid-span equals:
M2
=
Weq XL2
8
............................................. (10.14)
It should be noted that for eccentric cables, the eccentricity em is measured at mid-span from the cable to the line connecting the two ends as shown in Fig. 10.8.
e'i-~::::tL~~' ~e3~ I·
Since the equation of the bending moment for uniformly loaded simply supported beam is also parabolic, the moments must be equal in the two beams at any point. Thus, Ml
=M
2 ••••••••••••••••••••••••••••••••••••••••••••••••••••••
(10.15)
p·e m
=
2
xL
8
Weq
------I-
= 8P em / L2
,l2 t ttl I-I t f f tit I I 1ft t t f tll
Application of this equation at the mid-span gives: Weq
p(el
L
pe)2
......................-.................... (10.16) Fig. 10.8 Determination of em for cable with eccentricity el and e2
Weq
=
8 P·e
2 m ••••••••••••••••••••••••••••••••••••••••••••••
L
(10.17)
where em is the mid-span deflection.
.\ I· 12 II I I I I I I I I I t II II tit t t;!1. L
Weq
Fig. 10.7 Calculation of the equivalent load for curved tendons
Photo 10.3 Continuous prestressed box-girder bridge
781
782
Solution
Example 10.3 A continuous prestressed beam having a rectangular cross-section (250 nun xllOO mm) is shown in the figure below. Also .shown is the cable profile. The span a-b has linear cables while span B-C has a parabolic curve. Locate the line of pressure. Calculate the final stresses at support b due to the prestressing as well as a uniformly distributed load of 15 kN/m' . (Pe=1200 kN)
200
+l~---- ----~i0z;=;:--r~-~ 12m
,I'
8m,
1 ,10m
,
The equivalent concentrated load acting on the beam equals: V p --P X
«() + () )-1200 x (0.4-0.12 12 + 0.4+0.2):.... 8 -118 leN t 1
2
-
or em \ = (400-120)+(120+ 200)xI2/20 = 472 mm
Cable profile
120 ......------~----2;+-:-t----I-----------,
I'
Step 1: Calculate the secondary moment at b
1
10m
V x\(L-x\)_ P L -P eml
Using Eq. 10.13: V 8x12 = 1200 x 472 p 20 1000
·1 The equivalent uniform load on span b-c equals p. e .
2
m
=
W xL2 --=eq,--_
8
The eccentricity at mid-span em2 = 0.45 + 0;2 = 0.55 m = 8·P ~em2 = 8'1200~0.55 =13.2 kN /m't L 20
Weq
The concentrated moment at point a equals
8....
Ma = P.e = 1200x-o.12 =-144 kN.m
....
*
0.12
H 250
Beam cross section
783
0.2
er ~c-~--e-; ,; ,; ;,I- ; ; . ;. - e-~,~;-f-Tlt>(1!---,e,..;T--,.......;::.......:·:c:::::::::::~-~---~.....;---;.;.:.---;;.-;.;.--,;;,,;;,;;---~
I. ",
-=----------A-----------
tT 0.45
0.4 12
., '
8
.,.
784
20
~
,
em]
400
200
Cable profile
em2
l~'-;-:------ __J-t-___;:z0_ _ --+-1%0-1--~-nnn--l--:-:~-i?i----,.-
c
The beam is once statically indetenninate. We shall use the three-moment equation to calculate the moment at.the middle support. MaL. +2M b (Ll +L2)+Me~ =-6(Rab + Rbe )
In the previous equation, Ma=-144 (negative bending) and Mc=O ,
12m
/.
8m .,.
10m
./.
10m
.1
a- Cable profile 540
~
480
1~·~
'
R be
__
Weq X
L3
-----'-- =
24
-13.2x203 2 = -4400 kN.m 24
The elastic reaction Rab due to concentrated load not in the middle is given by R
_ Pxaxb (L+a) 6L
ab -
b- Primary moment Ma=l44
The elastic reaction Rbc due to unifonn load is given by:
weq=13.2 kNlm'
£"'" t, 11111111 t II t 11
-118x8xI2x(20+12) =-3020.8 kN.m 2 6x20
The reader should be aware that the negative sign is due to upward force direction. P=-118kN
t
Al Il-t-:===~.:~-L=_-=20=·~·'==:=::
c- Equivalent loading
I
a=12 .
363.72
268.46
144~rr:"";',,-'----:--]I'1A
~
8
-
Rab
-144x20+ 2M b(20+20)+0 = -6 (-4400-3020.8) Mb= +592.56 kN.m (positive bending)
592.56
Step 2: Calculate the C-line
d- Final moment
The secondary moment at the support (b) equals: iii
I
+
11111111
+
352.56 e-Secondary moment
Msecondary = Mfinal -Mprimary=592.56-240 =352.56 kN.m Thus, the eccentricity of C-line at the support (b) equals: e = M b = 592.56 = 0.494 m b
Primary, secondary and final moments
p.
1200
t
The negative bending at the cable broken point of beam a-b equals:
", 785
786
Mab,final
=Mab,primary + Mab,secondary = -
12 480 + 352.56 x 20 == -268.46 kN .m
Step 3: Concrete stress due to prestressing at support (b) The effective eccentricity e* equals:
Thus, the eccentricity of C-line at the cable broken point of beam a-b equals:
. _ M ab _ e ab - -P- -
-
268 .64 - 0 224 ,l1200 -. m
e * = eb = 0.494 m A = 250xllOO = 275000 mm 2
The bending moment at mid-span of span b-c equals: Mbe
= 592.56
13.2x202 =-363.72 kN.m
2
The beam self weight is given by:
8
Thus, the eccel:1tricity of C-line at mid-span of span b-c equals:
=
e
Mbe
P
be
wow
=25xO.25xl.l=6.875kN 1m'
W lotal =wow
= -363.72 =0.303in,l1200
+ (w LL
+W DL)
= 6.875 + 15 = 21.875 kN 1m'
The negative moment at support equals: M
=W lolal xL
2 21.875x20 :::;: 1093.8 kN.m 8
2
8 P
P xe*
M
A
ZIOP
ZIOP
!rop = - - - - - + -
I·
12m·
8m .. \.
10m
.\.
10m
·1
flOP
=
1200 xlOOO 275000 P
fbollom
bOI
fbOltOm
M
=- A +-Z---Z-
Effective cable.profile or C-line
787
Pxe*
1200 x 1000 x 494 1093.8x106 _ 55 2 50.416 X 106 + 50.41x106 - + . 8 N Imm
=
lop
1200 x~OOO + 1200 xlOOOx494 275000 50.416 X 106
788
1093.8x106 =-14.30 N Imm2 50.41 X 106
10.4 Linear Transformation and Concordant Profiles
\
P=1200kN
Cable profile (1)
Cable profile (2)
If the original cable profile was selected as the effective cable profile, the secondary moment will be equal to zero and the final moment will be equal to the primary moment. This is called a concordant profile. The concordant profile induces no reactions due to the prestressing at the intermediate supports (secondary moment 0). The choice of a concordant profile or a non-concordant profile is governed by the concrete cover. In addition, any tendon profile can be linearly transformed without affecting the C-line position.
=
When the position of a cable is moved over the interior supports without changing the curvature and the shape of the cable within each individual span, the line is said to be linearly transformed. It is possible to linearly transform any pressure line by rising or lowering the eccentricity at the interior support without altering the exterior eccentricity. The resulting effective cable profile is the same in both cases. However, the amount of the secondary moment and the induced reactions at the middle support is different for each profile, but the sum of the primary and the secondary moment is the same. For example the beam shown in Fig. 10.9 has two tendon profiles, each produce different primary moment. However, the equivalent loads and hence the final moments in both cases are the same.
\.
12m
8m
.\.
.\
, .
,
+
// /
'/240
Moment dIagram 2 / "
y /
480
. 0.2 e m2 = 0.45 + - = 0.55 m 2 For the cable profile 2
b- Primary moment due to prestressing
Ma=144
e~l = (2S0-120) + (120 + 400)x12/20 = 472 mm
<2 = 0.35 + 0.42 = 0.55 m
Vp=llS
w eq=13.2 kN/m'
(~~______~t____~*~I~"~II~I~lI~II~I~11~11~1~11~11~1L c- Equivalenfloading for both moment diagrams
For both profiles
V Sx12 = 1200 x 472 p 20 1000 L2
10m
Moment diagram 1
em1 = (400 -120) + (120+ 200)x12/20 = 472 mm
=s·p ·em2
\.
a- Cable profiles (1),(2)
For the cable profile 1
Weq
10m
.\
Fig. 10.9 Linear transformation of cables
= 8x1200xO.55 =13.2 kN Im't 202
789
790
APPENDIX
Design Charts for Sections Subjected to Flexure
A
Area of Steel Bars in em 2 II>
Weight
Area of Steel Bars in mm 2
(used in Egypt)
Cross sectional area (cm')
II>
Weight
mm
kg/m'
(used in Egypt)
Cross sectional area (mm')
1
2
3
4
5
6
7
mm
kg/m'
1
2
3
4
5
6
7
8
9
10
11
12
6
0.222
0.28
0.57
0.85
1.13
1.41
1.70
1.98
2.26
2.54
2.83
3.11
3.39
6
0.222
28.3
56.5
84.8
113
141
170
198
8
0.395
50.3
101
151
201
251
302
352
• 8
12
9
10
11
226
254
283
311
339
402
452
503
553
603
785
864 .Jl42
8
0.395
0.50
1.01
1.51
2.01
2.51
3.02
3.52
4.02
4.52
5.03
5.53
6.03
10
0.617
0.79
1.57
2.36
3.14
3.93
4.71
5.50
6.28 ·7.07
7.85
8.64
9.42
10
0.617
78.5
157
236
314
393
471
550
628
707
12
0.888
1.13
2.26
3.39
4.52
5.65
6.79
9.05 10.18 11.31 12.44 13.57
12
0.888
113
226
339
452
565
679
792
905
1018 1131. _1244 1357
14
1.208
1.54
3.08
4.62
6.16
7.70
9.24 10.78 12.32 13.85 15.39 16.93 18.47.
14
1.208
154
308
462
616
770'
924
1078 1232 .1385 1539 1693 1847
16
1.578
2.01
4.02
6.03
8.04 10.05 12.06 14.07 16.08 18.10 20.11 22.12 24.13
16
1.578
201
402
603
1.998
254
509
763
1018 1272 1527 1781 2036 2290 2545 2799 3054 1257 1571 1885 2199 2513 2827 3142 3456 3770
7.92
---
-.
804
1005 1206 1407 1608 .1810 2011 -2212 "2413
18
1.998
2.54
5.09
7.63 10.18 12.72 15.27 17.81 20.36 22.90 25.45 27.99 30.54
18
20
2.466
3.14
6.28
9.42 12.57 15.71 18.85 21.99 25.13 28.27 31.42 34.56 37.70
20
2.466
314
628
942
7.60 11.40 15.21 19.01 22.81 26.61 30.41 34.21 38.01 41.81 45.62
22
2.984
380
760
1140 1521
1473 1963 2454 2945 3436 3927 4418 4909 5400 5890
22
2.984
3.80
1901 2281
2661
3041
3421 3801 4181
4562
25
3.853
4.91
9.82 14.73 19.63 24.54 29.45 34.36 39.27 44.18 49.09 54.00 58.90
25
3.853
491
982
28
4.834
6.16 12.32 18.47 24.63 30.79 36.95 43.10 49.26 55.42 61.58 67.73 73.89
28
4.834
616
1232 1847 2463 3079 3695 4310 4926 5542 6158 6773 7389
32
6.313
8.04 16.08 24.13 32.17 40.21 48.25 56.30 64.34 72.38 80.42 88.47 96.51
32
6.313
804
1608 2413 3217 4021
38
8.903 11.34 22.68 34.02 45.36 56.71 68.05 79.39 90.73 102.1 113.4 124.8 136.1
38
8.903
1134 2268 3402 4536 5671
Area of Other Steel Bars in em 2 II>
Weight
mm
kg/m'
2
3
4
5
6
7
8
6805 7939 9073 10207 11341 12475 13609
Area of Other Steel Bars in mm 2
Cross sectional area (cm')
1
4825 5630 6434 7238 8042 8847 9651
9
10
11
12
II>
Weight
mm
kg/m'
Cross sectional area (mm')
1
2 56.5
6
0.222
0.28
0.57
0.85
1.13
1.41
1.70
1.98
2.26
2.54
2.83
3.11
3.39
6
0.222
28.3
8
0.395
0.50
1.01
1.51
2.01
2.51
3.02
3.52
4.02
4.52
5.03
5.53
6.03
8
0.395
50.3 100.5
10
0.617
0.79
1.57
2.36
3.14
3.93
4.71
5.50
6.28
7.07
7.85
8.64
9.42
10
0.617
79
157
13
1.042
1.33
2.65
3.98
5.31
6.64
7.96
9.29 10.62 11.95 13.27 14.60 15.93
13
1.042
133
265
16
1.578
2.01
4.02
6.03
8.04 10.05 12.06 14.07 16.08 18.10 20.11 22.12 24.13
16
1.578
201
402
19
2.226
2.84
5.67
8.51 11.34 14.18 17.01 19.85 22.68 25.52 28.35 31.19 34.02
19
2.226
284
22
2.984
3.80
7.60 11.40 15.21 19.01 22.81 26.61 30.41 34.21 38.01 41.81 45.62
22
2.984
380
3
4
5
6
7
8
9
10
11
12
84.8 113.1 141.4
170
198
226
254
283
311
339
151
302
352
402
452
503
553
603
707
785
864
942
201
251
236
314
393
471
550
628
398
531
664
796
929
1062 1195 1327 1460 1593
603
804
1005 1206 1407 1608 1810 2011 2212 2413
567
851
1134 1418 1701 1985 2268 2552 2835 3119 3402
760
1140 1521 1901 2281
1473 1963 2454 2945 3436 3927 4418 4909 5400 5890
2661
3041 3421 3801
4181
4562
25
3.853
4.91
9.82 14.73 19.63 24.54 29.45 34.36 39.27 44.18 49.09 54.00 58.90
25
3.853
491
982
28
4.834
6.16 12.32 18.47 24.63 30.79 36.95 43.10 49.26 55.42 61.58 67.73 73.89
28
4.834
616
1232 1847 2463 3q79 3695 4310 4926 5542 6158 6773 7389
32
6.313
8.04 16.08 24.13 32.17 40.21 48.25 56.30 64.34 72.38 80.42 88.47 96.5
32
6.313
804
1608 2413 3217
38
8.903 11.34 22.68 34.02 45.36 56.71 68.05 79.39 90.73 102.1 113.4 124.8 136.1
38
8.903
-
..
791
~1)21
1134 2268 3402 4536 5671
792
4825 5630 6434 7238 8042 8847 9651 6805 ni39 9073 10207 11341 12475 13609
G>
DESIGN CHART FOR SECTIONS SUBJECTED TO SIMPLE BENDING
:T
o
::J
§.
(Table 4-1) R1 0.D15 0.020 0.025 0.030 0.035 0.040 0.045 0.050 0.055 0.060 0.065 0.070 0.075 0.080 0.085 0.090 0.095 0.100 0.105 0.110 0.115 0.120 , 0.125 0.129 0.139 0.143
r
-...l 10
L
w
!lO
!!l
;l:: 2:
co 0.D18 0.024 0.030 0.036 0.042 0.048 0.055 0.061 0.068 0.074 0.081 0.088 0.095 0.102 0.109 0.117 0.124 0.132 0.140 0.148 0.156 0.164 R1max 0.173 Jy=400 0.180 '!y"=360 0.198 fy=280 0.206 ~
~f9 !Y:"~~q!'l['!~:2" •...
0.15 ...........13
~.~:
. 0.12
~ -1 ... L..
• .. .. •• ... '" fy:--4QP t~ult1liL ... ••• ........ ... ... ... :;2~
V
.
V-
0.11
V '.
1 z: I
('II
0.09
V
a: 0.08
V"
L
0.06 ' 0.05
~
-. J
. /
II S •
('II
E ~
gj
~
'"
U
. .., ";.
II
I
J.
,
~
o 3l
I
.:
cO' ::J
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a
RI--_u 2 - feu bd
V
~ §-
f. P A =OJ-E...bd±--", ~ ~/~
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Q~ 0.01 0.02
:~
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./
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N
E •
V
0.07
0.04 0.03
.. . .
./
0.10
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"'''''' .. : ... ~ ~~~ m;' ................. '" ........... ;pT
i
(')
g
0.04
0.06
0.08
0.10
0.12
0.14
0.16
0.18
0.20
~
0.22
f
CJ)
~
~<0":""
W C
",
,.,~;~:~~-,~~~·=lt1lO''''''''''~~~~~..:r;~'~-'''''·'''''==-''''=''''~~~"·~~f·"''''''~~'''''''~~~=;~~:-'=~~~~~7r«~'~~~¥~~"'~..1'>1~.~,~~~~~~~)f~~0'f~:",;g:..--=·""",-'01.';~"J·~·.·<~.)i<~r.'t";"fr":";~"'llI·.!"_
o
?
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0.08
>:.
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~
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"~
<::r'
~
p
0.10
II
II
~
I:l..
.;-.; 1;-..
I; -. .'1::1 ~I ~
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0.14 0.16
p co o
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0
p
p
M
~
0.26 0.28 0.30 0.32 0.34
,..---..... s: I.
~IIC :J>
a
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0.36 ,I
0.38
-'-+I I<-
JI ~::~ 0.
0.44
J>:.
ks
0
0.46 0.48 0.50
o
000
~
~
S5
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~
38
~
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C
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a
8' 8' 8' 8' I ............
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0.20
0.24
8
c;;
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o
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0.22
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0.20
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m en S
<:::-lS:: 1:).."
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en
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0.30
5'
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CD
Ilf '\ ~ 1:-' ~~
0.28
i:
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{(
~
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&~
8 g
Z Z 0 "'/I
a.
=-m ? ifII o :::a
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0
=
)t ~'\ I ~ IV'
0.44
l:
.
0
0.18
lf~:::
J>
0
8' 8' 8' 8' ""1 ""1 .., "'1
0.34
{Ie
~
0
f~8~8~8
0.32
~:: c. c: ,I . I.
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0
..,
R;
0.16
0.26
S
OJ
p ~
I'll..
0.24
Ul
en
p
~
0.22
-..J \0
e
p
p ~
"'I
0.14
.;....Iii'"
p
"-
0.12
I:>..
II
OJ
~
0.10
<:::-
.;....Iii'"
.?':.
.?>II e::
0
b
en
m (") -I
~
0 Z
"'If\.
0.46
en
if'\
0.48
~
0.50
~
cO' ::J
g,
~ 0-
:i'
aCD
c.
o
g CD
it
I
~
~
--_ .. -
jI
-..J \0
0\
--.-.-.--~
C1
J
c/d
C",.,/O
2.65 2.69
0.696 0.703
0.500 0.480
fv=240 fv=280
~:~~
g:~g
g:1~g :~~~~g
2.90 2.95 3.00 3.05 3.10 3.15 3.20 3.25 3.30 3.35 3.40 3.45 3.50 3.55 3.60 ~
0.732 0.738 0.743 0.748 0.753 0.757 0.761 0.765 0.768 0.772 0.775 0.778 0.781 0.784 0.787 ~
0.395 FOR 0.379 0.364 0.350 56 0.337 0.324 . 0.312 54 L . . ~ 0.301 .~ d = Cl __u_ B. 0.291 5 2 0.281' cu 0.272 50 0.263 . \ 0.254 4.8 0.246 0.239 4.6 I ~ I '\
3.75 3.80 3.85 3.90 3.95 4.00 4.05 4.10 4.15 4.20 4.25 4.30 4.35 4.40 4.45 4.50 4.55 4.60 4.65 4.70 4.75 4.80 4.85
0.794 0.796 0.798 0.800 0.802 0.804 0.806 0.807 0.809 0.810 0.812 0.813 0.815 0.816 0.817 0.818 0.820 0.821 0.822 0.823 0.824 0.825 0.826
0.218 " 0.212 4.2 +----:'I--+-~"--+----+--__Ir_-/-:;;;"9----+----+----+ 0.75 0.206 , " / 0.200 4.0 , , , , / 0.76 "") 0.194 I './ 0.189 3.8 I.......... 0.77 0.184 36 I .......... / 078 0.179 . I ~ • 0.175 34 / 079 0.170 . I /........... • 0.166 32 V "'" 0 80 0.162 . I / ~ c /d (T ble 4-1) . 0.158 30 V """ rna. 081 0.154 . I 0.150 2.8 ~ 0.82 0.147./' 0 ' O~--s...... 0 0.143 26./ 0 • CO • cO~ 083 0.140 . r I II : .l!: '~: 0.137 2.4 >- .. ~: >- ..<':' 0.84 0.134· 'C 0.131 0.10 '":5 0.15 0.20 0.25 0.30 0.35 0.40 0.45 0.50 0.128 c/d 0.125
~
~
=s-
SIMPLE BENDING (R and T-sections)
3'
1.
«
I
O ::J CD
po
ALL GRADES OF STEEL AND CONCRETE
!!!
.
i:
2:
068
IM P. ija5,t, .. ·A,=-"-±--"-
.
fy /1.15
fy J d
/fa>t ... A _
'
±
M"
' f /1.15 (d-t,
/2)
p"
/'
071
y./'
/' V
,~
/"
f /1.15
y
3' '<
069 . . / 070
A, =
1\
~
G)
DESIGN CHART FOR SECTIONS SUBJECTED TO
.
./
0.72 0.73
J/
~
U
r---...
V
___. 11
(J
.
oCD (JI
cO' ::J
g, ~
~
~
b'::J
~
(/)
2
I
APPENDIX
Design Charts for Calculating Icr and 0Jtc
".
B
Ghoneim & EI-Mihilmy
Cracked Section Moment of Inertia I
cr
0.15
I II
II I
0.14
n:EJEe
n 1 '.... [,-
0.12
II
1.1
0.08
1/
I
0.07
I)
0.06
I
0.05 0.04 0.03 0.02
I
~
!
l
0.09
.j
I ~r
I
0.11 0.10
~11
~
I
II ~I V v~ I
II~ [I i/
lilt V' V ~
~
~
~V
~
)/
~
/V ~
~
VII11IIV ~ II-
V /I II I) Ii
~
1/
~
V
~
1/ ~ '~
I..... V
~
~
~
12y V
~
~
t
18 1 , I;
t ~ i-'"
~
..... .....
b
j VJ 'j V/v /~ V ~ ~, I~ ~ V j ~/ V ~~ V .~ ~ fcu=35
I; V
..... ~
0.8
J
0.7
~
fcu=20
0.6 1
V
0.5
I;
0.4
I
\.I~
0.3
0.2
I 0.010
0.014
0.018 1.1.
0.022
0.026
0.1
0.030
~
0.0 200
rd
300
400
5,)0
~~ V
600
700
800
900 1000 1100 1200 1300 1400 1500
h(mm) Mer: b(mm). Ker
797
r;,
VI rl
1+--->1
0.9
II
j
1.1
Il} I
1
/J
h
1.2
"I1( ~j...oo ~II
~ '/
0.006
I'!.
Uf
/ l/ ~~ '~
0.01 ~ 0.002
1.3
1.0
..... ~
I
I
V
~
1.4
\.
II~
I I
I
Design of Reinforced Concrete Structures
Cracking Moment M cr for rectangular
for Rectangular
Sections with 'Tension Reinforcement only
0.13
Ghoneim & EI-Mihilmy
Design of Reinforced Concrete Structures
".
(k!'l.m)
798
I: i
Design of Reinforced Concrete Structures
Ghoneim & EI-Mihilmy
Wk
f cu=25 N/mm
,
65
f.--
.
60
J
1.
• -.e ••
I
-.
55 50 45
/
40
I
t/d=1.15, smooth bars, n=10
70
/
•J1=O.OO
II
V
/ / /
V
7
V
V
/"""
I
1.003 =0.004
/
II
/
/
~
./
/
[0.005
V
V
:.t 35
30
/
0.006
20
10 5 1---
o 0.0
~
0.2
0.4
0.6
70 65 l 60
0.006
/
50
I V
1.4
1.6
1.8
2.0
2.2
2.4
2.6
2.8
20
I
15
VI
10
77
75
7
//
V
V
V
... ./
V
./
/
/'
- ---
/
/'
0.0
0.2
Iff 0.4
0.6
~I-::::
0.8
1.0
1.2
1.4
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
Values ofSm Bar Diameter
Bar Diameter
0.001 0.002 0.003 0.004 0.005 0.006 0.007 0.008 0.009 0.010 0.011 0.012 0.013 0.014 0.015
/
/
Mlbd2
Values of Sm 10 425 238 175 144 125 113 104 97 92 88 84 81 79
/
/
Mlbd2
11
I
-_."
/
./
25
3.0
7
. ..
/ ' . /V / ' - --./'" ./'" - --/ / / ./ / ' ../V' / / V V / V V V l.,....---" ~ _.---II V V V V V V V t::-: [::::::: ~ - _.~ ~ t:::---:: ~ 1/ ~ ~ ~ ~ ~ ~ ~ ~ ~~~ ~~ ~~
I /
o 1.2
l7
V
55
30
._.
I
t.•••••
5
1.0
2
:.t 35
~
0.8
.
f cu =25 N/mm , t/d=1.05, smooth bars, n=10
40
0.015
15
factor for sections subjected to bending only
0.007
'0.009 0.010
25
Wk
Design of Reinforced Concrete Structures
45
/ ' /" /'" / I / / V / ' /' / ' . /V ./'" / / / V ./ . /V -"V V ~ ~1!~:~12 II V V V V V ~ ~ ~ ~ ~ j/V. ~ ? ~ ~ ~ ~ ~§:::~ /1 ~ ~ 0 ~~~~ ~ ::;,:::
/
Ghoneim & EI-Mihilmy
1 I
factor for sections subjected to bending only 2
I!
12 500 275 200 163 140 125 114 106 100 95 91 88 85 82 80
14 575 313 225 181 155 138 125 116 108 103 98 94 90 88 85
16 650 350 250 200 170 150 136 125 117 110 105 100 96 93 90
18 725 388 275 219 ·185 163 146 134 125 118 111 106 102 98 95
799
20 800 425 300 238 200 175 157 144 133 125 118 113 108 104 100
22 875 463 325 256 215 188 168 153 142 133 125 119 113 109 105
25 987 519 363 284 238 206 184 167 154 144 135 128 122 117 113
28 1100 575 400 313 260 225 200 181 167 . 155 145 138 131 125 120
32 1250 650 450 350 290 250 221 200 183 170 159 150 142 136 130
...I!c
0.001 0.002 0.003 0.004 0.005 0.006 0.007 0.008 0.009 0.010 0.011 0.012 0.013 0.014 0.D15
10 175 113 92 81 75 71 68 66 64
63 61 60
60 59 58.
12 200 125 100 88 80 75 71 69 67 65 64 63 62 61 60
14 225 138 108 94 85 79 75 72 69 68 66 65 63 63 62
16 250 150 117 100 90 83 79 75 72 70 68 67 65 64 63
18 275 163 125 106 95 88 82 78 75 73 70 69 67 66 65
800
20 300 175 133 113 100 92 86 81 78 75 73 71 69 68 67
22 325 188 142 119 105 96 89 84 81 78 75 73 71 70 68
25 363 206 154 128 113 102 95 89 85 81 78 76 74 72 71
28 400 225 167 138 ~20
108 100 94 89 85 82 79 77
75 73
32 450 250 183 150 130 11-7 107 100 94 90 86 83 81 79 77
Ghoneim & EI-Mihilmy
Design of Reinforced Concrete Structures
Ghoneim & EI-Mihilmy
factor for sections subjected to bending only
Wk
Wk
I
65 +
60
I
V
L
h;. •• ·t
/
/
50
.
V
/ V
40
35
I
30
/
/
/
/
/
/
/
55
/'
./
V
V / ' ,.v V
./
/'
/' ---
/'" ./
40
..-
::.t 35
----
/'"
25 20 15 10 5
o 0.2
V /
fM
0.4
0.6
0.8
/'
V
'"
./
~
/
30
I
V y
/
v
/"
V
V
/'
./" / v V / ' /" / V /'
/
-
/'
- ---
- ------
20
./'
..
./
- A'_
15 10
Pr~
1.2
1.4
1.6
1.8
2.0
2.2
2.4
2.6
2.8
0.0
3.0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
2.2
2.4
2.6
2.8
Mlbd2
2
Values ofSm Bar Diameter
0.001 0.002 0.003 0.004 0.005 0.006 0.007 0.008 0.009 0.010 0.011 0.012 0.Q13 0.014 0.Q15
V
V
..
./
o
1.0
ValuesofSm 10 425 238 175 144 125 113 104 97 92 88 84 81 79 77 75
/
'/
~
/
V . / . /V [.../V ./"'"~ --__.I / / V / v-:V ::::::k ::::::~ ::;:::::: J / V 0- ~ ~ ~ ~ ~ ~ §:::: I. ~ ~ ~ ~ ~ ~ ~ ~/
25
5
Mlbd
11
/ V
/
/
L
/
/
45
----
/
/
/
50
/v
/
II
- ---
. ..
/
J
1,;. ••••
60
V / ' [.../ ~ ~ I / / / / ' / V ::::::::e:::::: ~ ~ --.-_.. 1/ /v/ ~ ~ ~ ~ ~ ~ ~ r~~ ~ LV~ ~ ~ ~ ~ ~ ~ V
0.0
/
..
65
/
/
2
70
----
L
/V
J
45
i/
/
/
55
"""~
'1"
factor for sections subjected to bending only f cu =25 N/mm , t/d=1.05, ribbed bars, n=10
f cu =25 N/mm2, t/d=1.15, ribbed bars, n=10 70
Design of Reinforced Concrete Structures
12 500 275 200 163 140 125 114 106 100 95 91 88 85 82 80
14 575 313 225 181 155 138 125 116 108 103 98 94 90 88 85
16 650 350 250 200 170 150 136 125 117 110 105 100 96 93 90
18 725 388 275 219 185 163 146 134 125 118 111 106 102 98 95
801
20 800 425 300 238 200 175 157 144 133 125 118 113 108 104 100
Bar Diameter
22 875 463 325 256 215 188 168 153 142 133 125 119 113 109 105
25 987 519 363 284 238 206 184 167 154 144 135 128 122 117 113
28 1100 575 400 313 260 225 200 181 167 155 145 138 131 125 120
32 1250 650 450 350 290 250 221 200 183 170 159 150 142 136 130
)1.
0.001 0.002 0.003 0.004 0.005 0.006 0.007 0.008 0.009 0.010 0.011 0.012 0.013 0.014 0.Q15
10 175 113 92 81 75 71 68 66 64 63 61 60 60 59 58
12 200 125 100 88 80 75 71 69 67 65 64 63 62 61 60
14 225 138 108 94 85 79 75 72
69 68 66 65 63 63 62
16 250 150 117 100 90 83 79 75 72 70 68 67 65 64 63
18 275 163 125 106 95 88 82 78 75 73 70 69 67 66 65
802
20 300 175 133 113 100 92 86 81 78 75 73 71 69 68 67
22 325 188 142 119 105 96 89 84 81 78 75 73 71 70 68
25 363 206 154 128 113 102 95 89 85 81 78 76 74 72 71
28 400 225 167 138 120 108 100 94 89 85 82 79 77
75 73
32 450 250 183 150 130 117 107 100 94 90 86 83 81 79 77
3.0
Ghoneim & EI-Mihilmy
Wk
Design of Reinforced Concrete Structures
factor for sections subjected to bending only fcu=30 N/mm
2
65 I - -
.
60
v
t.
--
._!.
V
55
v
I
50
V
45
I
40
1/
V
L
V
/
v
V
V
25 20
---
45
---
40
./ ---
V
0.4
0.6
0.8
1.0
/
10
1.2
1.4
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
Mlbd2
10 425 238 175 144 125 113 104 97 92 88
/
/
/
_.-
/
/
1/ 1/ V
/'
V ---
V
/
/ v
L
o 0.0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
Values of Sm Bar Diameter
11
_..
Mlbd2
Values ofSm
0.001 0.002 0.003 0.004 .0.005 0.006 0.007 0.008 0.009 0.010 0.011 0.012 0.013 0.014 0.015
._ .
~~
5
o 0.2
20
lL
/
/
V
V . / --I / V /' / 'V V v L V / _./ V ./ .....-' / V ~ ~ ~ I ~ L / iVV V V V ~ ~ ~ !:-::::: II / '/ ~ ~ ~ l:2 ~ ~ ~ §::: ~ r~ ~ ~~ ~ ~ ~ ~ J
35
15
~~
5
II
25
_._
V
j
30
i/.t
10
~
/
)
IL
./
w
15
II
50
V L . .V .,/ V . / II / / /'"V ...-V .,./"~ ~ ~ _.-_.J / / .// ~ ~ ~ ~ ::::::: ~ ~ f V/ V ~ ~ ~ ~ ~ !-~~~ ~~ ~~ ~~~
/
30
.
55
... -
./
J
~ I- - _. •-
60
/
L
...
65
/
/
/
L
70
/
/
factor for sections subjected to bending only
-_.
/
1/
Design of Reinforced Concrete Structures
fcu=30 N/mm2 , t/d=1~05, ribbed bars, n=10 ....
/
I
.~
I- -
Wk
t/d=1.15, ribbed bars, n=10
,
70
0.0
Ghoneim & EI-Mihilmy
84
12 500 275 200 163 140 125 114 106 100 95 91
81 79 77 75
85 82 80
88
14 575 313 225 181 155 138 125 116 108 103 98 94 90 88 85
16 650 350 250 200 170 150 136 125 117 110 105 100 96 93 90
18 725 388 275 219 185 163 146 134 125 118 111 Hi6 102 98 95
803
20 800 425 300 238 200 175 157 144 133 125 118 113 108 104 100
22 875 463 325 256 215 188 168 153 142 133 125 119 113 109 105
25 987 519 363 284 238 206 184 167 154 144 135 128 122 117 113
28 1100 575 400 313 260 225 200 181 167 155 145 138 131 125 120
32 1250 650 450 350 290 250 221 200 183 170 159 150 142 136 130
Bar Diameter
u 0.001 0.002 0.003 0.004 0.005 0.006 0.007 0.008 0.009 0.010 0.011 0.012 0.Q13 0.014 0.015
10 175 113 92 81 75 71 68 66 64
63 61 60 60 59 58
12 200 125 100 88 80 75 71 69 (;7· 65 64 63 62 61 60
14 225 138 108 94 85 79 75 72 69 68 66 65 63 63 62
16 250 150 117 100 90 83 79 75 72 70 68 67 65 64 63
18 275 163 125 106 95 88 82 78 75 73 70 69 67 66 65
804
20 300 175 133 113 100 92 86 81 78 75 73 71 69 68 67
22 325 188 142 119 105 96 89 84 81 78 75 73 71 70 68
25 363 206 154 128 113 102 95 89 85 81 78 76 74 72 71
28 400 225 167 138 120 108 100 94 803
85 82 79 77 75 73
32 450 250 183 150 130 117 107 100 94 90 86 83 81 79 77
Ghoneim & EI-Mihilmy
Ghoneim & EI-Mihilmy
Design of Reinforced Concrete Structures
Wk
factor for sections subjected to bending only
Wk
fcu=50 N/mm 70
2
,
.
65
_L
60
"" ..
V
V I-
I- •
• •• II
50
/
/
45
V
40
/
.:.!; 35
V
'"
V
./
---
20 15
J
VV
---- ---
17
I II
40
./
:.< 35 30
~
./
5
o 0.0
0.2
0.4
~
20
- _.15
0.6
0.8
1.0
1.2
5
o
1.4
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
0.2
0.4
~ 0.6
0.8
1.0
12 500 275 200 163 140 125 114 106 100 \ 95 91 88 " 85
10 425 238 175 144 125 113 104 97 92 88 84 81 79
n
82
75 m
V
/v
/
/
V
/
V
V
/
-.--
./ L
- .--
V
/
1.2
1.4
1.6
1.8
2.0
2.2
2.4
2.6
2.8
3.0
Bar Diameter
Bar Diameter
k
/
...
/v
/ /
/
ValuesofSm
Values ofSm
w . =S
/
[7
I V
V
Mlbd 2
Mlbd
0.001 0.002 0.003 0.004 0.005 0.006 0.007 0.008 0.009 0.010 0.011 0.012 0.Q13 0.014 0.Q15
/
~
2
u
V
~
10
0.0
/
- _0-
7
.
./
25
_ ..
.-
V / 'VV V . / --j / L / V V V ./'" V" ~ -_ .. v - .. / / L v/ ~ ~ t:::: t::::: t:;:: ~ I 1//v/ ~ ~ ~ ~ ~ ~ ~ ~ 1/ ~ ~ ~ ~ ~ ~ ~ J
---
./
V
II
••
~
10
/
•
I.
45
~ ~V / II V V . . . ~ ~ l-:::: ~ ~ ~ "/~ ~ ~ ~ ~ ~ ~ ~ ~ f V~ ~ ~ ~ ~ ~ ~
25
V
\I
J
t/d=1.05, ribbed bars, n=10
50
V
vV'
/
",V'" /" V /V 1/ /" V V
,
55
V
V
.
I- •
/V
2
I
60
~
1/ /
65
. ...
V V .I
/ / II /
30
70
- --
/
55
factor for sections subjected to bending only fcu=50 N/mm
t/d=1.15, ribbed bars, n=10
I
Design of Reinforced Concrete Structures
80
14 575 313 225 181 155 138 125 116 108 103 98 94 90 88 85
16 650 350 250 200 170 150 136 125 117 110 105 100 96 93 90
18 725 388 275 219 185 163 146 134 125 118 111 106 102 98 95
20 800 425 300 238 200 175 157 144 133 125 118 113 108 104 100
22 875 463 325 256 215 188 168 153 142 133 125 119 113 109 105
25 987 519 363 284 238 206 184 167 154 144 135 128 122 117 113
28 1100 575 400 313 260 225 200 181 167 155 145 138 131 125 120
32 1250 650 450 350 290 250 221 200 183 170 159 150 142 136 130
u
0.001 0.002 0.003 0.004 0.005 0.006 0.007 0.008 0.009 0.010 0.011 0.012 0.013 0.014 0_015 W k
xk Xl0- 4
10 175 113 92 81 75 71 68 66 64
63 61 60 60 59 58
12 200 125 100 88 80 75 71 69 67 65 64 63 62 61 60
=Sm xkr xl0-
14 225 138 108 94 85 79 75 72 69 68 66 65 63 63 62
16 250 150 117 100 90 83 79 75 72 70 68 67 65 64 63
18 275 163 125 106 95 88 82 78 75 73 70 69 67 66 65
4
'l,
r
805
806
20 300 175 133 113 100 92 86 81 78 75 73 71 69 68 67
22 325 188 142 119 105 96 89 84 81 78 75 73 71 70 68
25 363 206 154 128 113 102 95 89 85 81 78 76 74 72 71
28 400 225 167 138 120 108 100 94 89 85 82 79
n
75 73
32 450 250 183 150 130 117. 107 100 94 90 86 83 81 79
n
APPENDIX
Slope and Deflection Equations
C
2
APPENDIXC
~
) wbx y=--(3L+3a-2x 12 EI
w
!""
t- a _ol-I-
'!
b----l
O~x~a
wa 2 b 12EI
wabL B=-A 2EI
!:1A =--(3L+a)
Deflections and Slopes of Beams
B =~(iJ-a3) B 6EI . P x2 ' y=-(3L-x) 6 EI P L2 B =B 2EI
A-DEFLECTION AND SLOPES OF CANTILEVER BEAMS
y= deflection at any point !:1=deflection at certain point 6= slope at certain point EI =constant
~ w
t- a
2
W X
2
P x2 y=--(3a-x) 6EI
r
P a2 y=--(3x-a) 6El
b----l
2)
y=--(6L -4Lx+x 24EI 3 . wL4 B = wL !:1 = - B 8 El B 6 El
a~x~L
Pa 3
Pa 2 B =-A 2EI
Pa 2 6 El
Pa 2 B =-B 2El
!:1 = - A 3 El !:1 =--(3L-a) B
O~x~a
M x2 y = 2°El 2
WX
2
y=--(6a -4ax+x 24EI
~
w
I I I
I---a
2)
O~x~a
~
M.~
M L2 2El
!:1 = - " B
3
wa y=--(4x-a) 24El
II 01
b-l
a~x~L
wa 4 11 = - A 8 EI
B = wa A 6El
wa 3 24EI
B = wa B 6EI
!:1 =--(4L-a) D
3
3
!:1 = w" L4 B
807
".
30EI
808
B =Mo L D El
y= Pbx (iJ_b2_X2) 6L£1 8 =Pab(L+b) A 6LEI
Pi d = 11 WO L4 8 120£1
() = 8
Wo
IJ
.e
£#,_---...:'1\:....-1A"""
8£1
j--a
b--j
ifa~b, de
=
B
Pab(L+a) 6LEI
P b (3iJ -4b 2) 48£ I
B-DEFLECTION AND SLOPES OF SIMPLE BEAMS
W
I I
!1i
Pi 4
d =d c
. max
e
= 5 wL 384 £ 1
A
3
wL =8 = - 8 24EI
P X 2 -X 2) y=--(3aL-3a 6EI
Pi
P a
A"--J~--"'L-IA-" . I-a
a-j
2
2
y=--(3Lx-3x -a) 6E 1 P a (L-a) 8 A =8B = 2EI Pa 2 d =d . =--(3L -4a 2) c max 24 E 1
wx
,,, 'I
y=--(9i! -24Lx2 + 16x3 ) 384 £ 1
w
l-:-U2
_.
IA
U2-j
Mo 5wL4 d=-c 768 EI
3w L3 8=-A 128 El
7w L3 8=-B 384 EI
~ \J\------"""
A
;(;$.,
M x 2 y=_0_(2L -3Lx+x 2)' 6LEI ML 8 _MoL 8 __ 0_ A - 3EI n- 6EI Xl
PX 48£ 1
2
Mo
2
y=--(3L -4x)
,A
i
I
IA
l-:- U2-f-U2-j
d =d e
max
P L3 =-48 E 1
A
8 =8 = P L2 A 8 16 El
I
IA
l-:-U2-f-- U2 - j
". 809
Ci)
=L(1-
~)
and
d max =
M X 2 -4x 2) y=-O-(L 24LE 1
8 _MoL A - 24EI
810
8 =_MoL B 24EI
ML2 d =_0_ c 16EI
/jj~1
y=M o x(L_x) 2EI
e A
=(J =MoL B 2EI
11 =11 c
max
A
W
l-L e A
= 7
Wo
.I}
360 EI
W
W L2 -2 2 11 =--(5L -12a ) c 384 EI
B
,J;!!!!II,Z}!lo
M L2 =_0_ SEI
I
11 =~{a2 (4L+3a)-I}} o 24 EI
a~
-PL MA =Mn =-S-
L3
(J =_0_ B 45 EI
L4
PL
M =c .8
L4 11 =~,Xl =0.5193L and 11m.. =0.00652-c 76SEI EI 5
y = Pa X (L2 _ x 2) 6LEI
WO
pI} 11 = - c 192 E I
O:S; x:S; L
y = P(x-L) [(x-L)2-a (3x-L)] 6EI
w
I I
L:S;x:S; L+a
1---- L
Pa 2
I~ ----I
110 =--(L+a) 3EI
2 L2 11=~ c IS.,fj EI
wa3
110 =--(4L+3a) 24EI
811
".
812
REFERE·NCES
10.
.
References Commit~~e
318,. "Building Code Requirements for Reinforced Concrete . (AC! 318-02) ,Amencan Concrete Institute, Detroit, 2002. ACI
ACI-ASCE Committee 423.3R, "Recommendations for Concrete Members Prestressed with Unbonded Tendons", ACI Journal Proceedings, Vol. 86 No.3, 1989, pp. 301-318. ' ACI Committee 224, "Control of Cracking in Concrete Structures", Concrete International: Design and Construction, Vol. No. 10, October 1980, pp. 35-76. ACI-ASCE Committee 445, "Recent Approaches to Shear Design of Structural Concrete", State-of-the -Art - Report by ACI-ASCE Committee 445 on Shear and Torsion. ASCE Journal of Structural Engineering V. 124, No. 12, 1998, pp. 1375-1417.
CSA Committee A23.3, "Design of Concrete Structures for Buildings," CAN3A23.3-M94 Canadian Standards Association, Rexdale, Canada, 1994, 199 pp. ECP Committee 203, "The Egyptian Code for Design and Construction of Concrete Structures", Housing and Building Research Center, Giza, Egypt. EI-Mihilmy, M., "Tendon Stress at Ultimate For Partially-Prestressed Concrete Flexure Members" Engineering Research Journal, University of Helwan, Vol.96 , pp. C63-C82, 2005. EI-Mihilmy, M., Tedesco, J., "Deflection Of Reinforced Concrete Beams Strengthened With FRP Plates", ACI, Structural Journal, Vol. 97, No.5, September-October 2000, pp. 679-688 Eurocode 2, "Design of Concrete Structures-Part 1: General Rules and Rules for Buildings (EC-2)" European Prestandard ENV 1992-1-1:1991, Comte European de Normalisation, Brussels, 253 pp. Ghali, A and Favre, R., "Concrete Structures: Stresses and Deformations", Chapman & Hall, New York, 1986,348 pp.
Am~rican
Concrete Institute, Special publication 208, "Examples for the Deslgn of Structural Concrete with Strut-and- Tie Models" Farmington ' Hills, 2002, 242 pp.
Arthur H. Nilson, "Design of Concrete Structures" Twelfth Edition McGraw " Hill, 1997, 780 pp. Branson, Dan E., "Deformation of Concrete Structures", McGraw-Hill Book Co., New York, 1977,546 pp. Branson, Dan E. "Compression Steel Effect on Long-Time Deflections" ACI Journal, Proceedings V. 68, No.8, Aug. 1971, pp. 555-559. ' Bowles, Joseph E., "Foundation Analysis and Design" 4th Edition McGrawHill, Singapore, 1988, 1004 pp. " Collins, M.P. and Mitchell, D., "Shear and Torsion Design of Prestressed and Non-Prestressed Concrete Beams," PCI Journal, V. 25, No.2, Sept. - Oct. 1980, pp. 32-100. Collins, M.P. and Michell, D., "Prestressed Concrete Structures" Prentice Hall Inc., Englewood Cliffs, 1991, 766.
Ghali; A. and Tadros; M.K., "Partially Prestressed Concrete Structures", ASCE Journal of Structural Engineering V. 111, No.8, 1995, pp. 1846-1865. Ghoneim, M., "Shear Strength of High-Strength Concrete Deep Beams", Journal of Engineering and Applied Science, Faculty of Engineering, Cairo University, Vol. 48, No.4, Aug. 2001, PP. 675-693. Ghoneim M. and MacGregor, J. G., "Evaluation of Design Procedures for Torsion in Reinforced and Prestressed Concrete", Structural Engineering Report No. 184, Department of Civil Engineering, University of Alberta, Edmonton, Canada, Feb. 1993,231 pp. Ghoneim, M., "Design for Shear and Torsion - Background and Evaluation of the Egyptian Code Provisions", The Eighth Arab Structural Engineering Conference, Cairo, Egypt, Oct. 2000, pp. 659-674. Gilbert, R. and Mickleborough, N., "Design of Prestressed Concrete", Unwin Hyman Ltd, London, 1990, 504 pp. Hilal, M., "Design of Reinforced Concrete Halls", Marcou & Co, 1987,364 pp.
814 813
Hsu, T. T. C., "ACI Torsion Provisions for Prestressed Hollow Gi~ders", ACI Structural Journal, V. 94, No.6, Nov.-Dec. 1997, pp. 787-799. Hsu, T. T. c., "Unified Theory of Reinforced Concrete", CRC Press, Boca Raton, 1993, pp 193-255.
Jaco~, S. Gross~~n, "Siml!lified Computations for Effective Moment of Inertza Ie and ~mlmum Thlckness to Avoid Deflection Computations", ACI Journal Proceedings, Vol. 78, No.6, Nov.- Dec. 1981, pp. 423-440. Leet, K. and Bernal, D., "Reinforced Concrete Design", McGraw Hill, New York, 1997,544 pp. Libby, J.R., "Modern Prestressed Concrete", 4th ed., Van Nostrand Reinhold,'New York, 1990,859 pp.
M~ttock, Alan H., Chen K. and Soongswang, K. " The Behavior of Remforced Concrete Corbels," Journal, Prestressed Concrete Institute, V. 21 No.2, Mar. Apr. 1976, pp. 52-77. MacGregor, J. G. and Ghoneim, M. G. "Design for Torsion", ACI Structural Journal, V. 92, No.2, March-April 1995, pp. 211-218.
and Naaman, A. E., "Partially Prestressed Concrete: Review Recommendations", Journal of the Prestressed Concrete Institute 30 (1985): 3071. Park, R. and Paulay T., " Reinforced Concrete Structures''; A Wiley-Interscience Publication, Wiley, New York, 1975,769 pp. PCA, "Notes on ACI 318-95: Building Code Requirements For Structural Concrete With Design Applications", Skokie, lllinois, 1996,818 pp. PCI Committee on Prestress Losses, "Recommendations for Estimating Prestress Losses", Journal, Prestressed Concrete Institute, V. 20 No.4, JulyAug. 1975, pp. 43-75. Rogowsky, D. M. And MacGregor, J. G., " Design of Reinforced Concrete Deep Beams", Concrete International: Design and Construction, V.8, No.8, Aug. 1986, pp. 46-58. Schlaich, 1., Schafer, K. and Jennewein, M., "Toward a Consistent Design of Structural Concrete", Journal of the Prestressed Concrete Institute, V. 32, No. 3, May-June 1987, pp 74-150.
MacGregor, J. G. "Reinforced Concrete - Mechanics & Design", Prentice Hall, Englewood Cliffs, New Jersey, Second edition, 1992.
Siao, W.B., "Strut-and-Tie Model for Shear Behavior in Deep Beams and Pile Caps Failing in Diagonal Tension", ACI Structural Journal, V. 90, No.4, 1993, pp. 356-363.
MacGregor, J.G., "Derivation of Strut-and-Tie Models for the 2002 ACI CodeExamples for the Design of Structural Concrete with Strut-and-Tie Models" Special publication 208 of ACI, American Concrete Institute, Farmington Hills: 2002, pp. 7-40.
Zia, Paul; Preston, H. Kent; Scott, Norman L.; and Workman, Edwin B., "Estimating Prestress Losses", Concrete International: Design and Construction, V.1, No.6, June 1979, pp. 32-38.
Mattock, A., Kirz, B. and Hognestad, E. "Rectangular Stress Distribution in Ultimate Strength Design", ACI Journal, V. 57, No.1, July 1960, pp.I-28.
Vecchio, F. J. and Collins, M. P., "The Modified Compression Field Theory for Reinforced Concrete Elements Subjected to Shear", ACI Journal, V. 83, No.2, March-April 1986, pp. 219-231.
Marti, P. "Basic Tools of Reinforced Concrete Beam Design" ACI Journal, ' Proceedings, V. 82, No.1, Jan.-Feb. 1985, pp. 46-56.
Mit~hell, D. and Collins M. P. "Diagonal Compression Field Theory _ A Ratzonal Model for Structural Concrete in Pure Torsion", ACI Journal, V. 71, August 1974, pp. 396-408. .
Vecchio, F. J. and Collins, M. P., "The Response of Reinforced Concrete to In-plane Shear and Normal Stresses", Puhlication No. 82-03, Department'of Civil Engineering, ~niversity of Toronto, 1982.
Il,
815
816
Units Conversion Table
To transform from SI':'units /
To French -units
Multiply by factor
kg kg ton
0.1 100 0.1
tim'
0.1
tlm:t kg/m:t kg/m:t
0.1 0.1 100
kg/cm:t kg/cm:t tonlm:t
10 0.01 0.1
kg/mJ j tonlm kg/mJ
0.1 0.1 100
ton.m kg.cm
0.1 0.01
cm:t cm:t
10000 0.01
Concentrated loads IN 1 kN 1 kN
\
Linear Loads 1m' 1 kN/m'
Uniform Loads 1m2 kN/m:t N/m:t kN/m:t Stres~
N/mm:t (=1 MPa) kN/m:t kN/m:t
Density
J N/m kN/mJ kN/mJ
Moment kN.m N.mm
Area m:t 2
mm
817
"'.
.
" • • "\/, 0.. "\ "\/\ :~~I y:iS.l1 )~ tl~'il ~j
u:aA y'-,Jl14 ~ b..)1.cl ..,l
W±lJi ..,l U"1..p91 ~ .~yJl U:.~ "'..,hll ~ ~ .<~II ~I " "I~I tiJ..b 4...u "till 4..k.L......J.l1.....l5.J . _II •4..;....)-""'" ~ <..EJ -""'" ~ y " ..r-
..,l J.-j..i..,l
~ b..)L..cJ
~I
y'~1 s:-I~ G......jts ~-'
..,l
..,l t4-.Jiu.'X1
~~ yt6.l1 b..)t... ulfol
t.j4 yt6.l1 s:-1J;>.1
..,l
~ j~ 'X
<.y> s:-J;>.
.~yJl <.y> ~bS u~l U-,..) ~-,ys.l)'1 ~I
~j~IJ y!..:lIJ ~L:k1l t~1 ;is'?
t.j14Y
..,l t.jy'y.dlll
". • "\ ~ :~-,'iI~1 " •• V ~ :~~I ~l
~yJl ~ ~j~
s:-4- t... ~ ~~-' ~6.lfl4 b~~ ~J ~t6.l1 u-lJ s:-lyJl uUlyJl .JC~ :~t:J1 ~-,ys.l~1 ~y,ll
Jc 4.1...lyJl L~ <.y> ,~.m-, yt6.l4
Rconcrete@ link.net
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Features • Reflec1s the very latest Egyptian Code provisions (ECP 203- 2007) and includes all major changes and additions. • Numerous illustrations and figures for each topic. • Good theoretical background for each topic with code provisions. • Extensive examples in each chapter utilizing SI units. • All examples are worked out step-by-step ranging from simple to advanced. • Full reinforcement details for every example. • Numerous design charts.
Volume 3 covers the following topics: . • Reinforced Concrete Frames, Arches and Arched Slabs • Design of Deep Beams and Corbels • Deflections of Reinforced Concrete Members • Crack Control of Reinforced Concrete Members • Design of Shallow Foundations and Pile Caps • Design of Raft Foundations • Strut-and-Tie Model for Reinforced Concrete Members • Fundamentals of Prestressed Concrete • Flexural Design of Prestressed Concrete Members • Shear and Torsion in Prestressed Concrete • Analysis of Continuous Prestressed Beams