Post Tension Slabs

POST TENSIONED FLOORS

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POST TENSIONED FLOORS ■ History of PrePre-stressed Concrete

1886 First Patent for Prestressed Concrete (P.H. Jackson of San Francisco)

1928 Modern Development of Prestressed Concrete (E. Freyssinet of France )

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POST TENSIONED FLOORS ■ Idea of PrePre-stressed Concrete

POST TENSIONED FLOORS ■ Idea of PrePre-stressed Concrete

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POST TENSIONED FLOORS ■ Idea of PrePre-stressed Concrete

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POST TENSIONED FLOORS ■ Types of Prestressed Concrete

POST TENSIONED FLOORS ■ PRE TENSIONING

Steel tendons are stressed prior to concrete placement, usually at a precast plant remote from the construction site

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POST TENSIONED FLOORS ■ POST TENSIONING

Steel tendons are stressed after the concrete has been placed and gained sufficient strength at the construction site

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POST TENSIONED FLOORS ■ STRANDS / TENDONS

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POST TENSIONED FLOORS ■ BONDED TENDONS Can be more costly due to duct placement & grouting Force transmitted by anchors and bond to concrete Greater total force can be applied Strain compatibility with concrete Openings less difficult Minimizes need for nonnon-prestressed reinforcement More complex stressing equipment required

POST TENSIONED FLOORS ■ UNBONDED TENDONS Economical Greater layout flexibility Force transmitted solely by the anchors Total force limited by anchor spacing Replaceable Simple stressing equipment

POST TENSIONED FLOORS ■ Main Applications of Prestressed Concrete

POST TENSIONED FLOORS ■ Main Applications of Prestressed Concrete

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POST TENSIONED FLOORS ■ Main Applications of Prestressed Concrete

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POST TENSIONED FLOORS ■ Main Advantages of Post Tension Floors ■ Functional Large Cantilevers Long economical spans Flexibility in Column Layout Effective use of high strength materials P/T slab is typically 30% 30% thinner

POST TENSIONED FLOORS ■ Main Advantages of Post Tension Floors ■ Economical Effective use of high strength materials P/T slab is typically 30% 30% thinner Forms are removed in 2-3 days not in 21 to 28 day as for rebar Concrete Significantly reduces amount of reinforcement Typically need about 50% 50% of crew

POST TENSIONED FLOORS ■ Main Advantages of Post Tension Floors ■ Technical Deflection and vibration control Long--term creep problems are virtually Long eliminated by load balancing Moment of inertia approaches Igross Crack control and waterwater-tightness

POST TENSIONED FLOORS ■ PT Slab Vs RC Slab ■ Slab Thickness Typical Span/Depth Floor System P/T

RC

One way slabs

48

21-28

Two-way slabs

45

33

Two-way slabs with drop panels

50

36

(minimum drop panel L/6 each way)

POST TENSIONED FLOORS ■ PT Slab Vs RC Slab ■ Span – Cost Relation

POST TENSIONED FLOORS ■ PT Slab Vs RC Slab ■Cost Breakdown

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POST TENSIONED FLOORS ■ Common Systems of PT Slabs Solid Slab

One Way Slabs Two Way Slabs

Flat Slabs

Flat Plates Flat Slab With Drop

Waffle Slabs

One Way Joists Two Way Waffle Slab

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POST TENSIONED FLOORS ■ One Way Systems

POST TENSIONED FLOORS ■ Two Way Systems

POST TENSIONED FLOORS ■ Banded & Waffle Slabs

POST TENSIONED FLOORS ■ Construction of PT Slabs ■ Shuttering

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POST TENSIONED FLOORS ■ Construction of PT Slabs ■ Laying of Bottom Reinforcement

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POST TENSIONED FLOORS ■ Construction of PT Slabs ■ Laying of Tendons & Laying of Top Reinforcement

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POST TENSIONED FLOORS ■ Construction of PT Slabs ■ Concrete Casting

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POST TENSIONED FLOORS ■ Construction of PT Slabs ■ Stressing of Strands

POST TENSIONED FLOORS ■ Construction of PT Slabs ■ Stressing of Strands INITIAL

FINAL

At 25 25% % of Concrete Strength

At 70 70% % of Concrete Strength

About 24 hours from casting

About 72 hours from casting

Shutter is removed and props are installed

Anchors are finished and shutter can be removed

POST TENSIONED FLOORS ■ Construction of PT Slabs ■ Measurement of Elongation

POST TENSIONED FLOORS ■ Construction of PT Slabs ■ Stressing Report Measured elongation needs to be within 7% of calculated value Per code, for tendons outside the 7%, the EOR shall ascertain and correct the “problem”. “problem”. What to do? DeDe-Tension / Re Re--Tension? Elongation records shall be sent to the engineer by next working day after stressing Elongations shall be approved or rejected within three working days after stressing

POST TENSIONED FLOORS ■ Construction of PT Slabs ■ Finishing of Tendon Ends

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POST TENSIONED FLOORS ■ Outlines of Design Procedure Selection of Initial Slab Thickness

Determination of the Amount of PrePre-Stressing Serviceability Calculations (Deflection, Vibration) Limit State Calculations (Stresses) Calculation of bonded reinforcement 12/10/2009

POST TENSIONED FLOORS ■ Selection of Initial Thickness

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POST TENSIONED FLOORS ■ Amount of Prestressing Minimum P/A =0.9

ACI

Maximum spacing of tendons is six times the slab thickness.

Prestressing always provide an uplift to overcome 6060-90 percent of dead loads

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POST TENSIONED FLOORS ■ Amount of Prestressing

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wb L2 P= 8h

POST TENSIONED FLOORS ■ Amount of Prestressing

wbx =

Ly

αLx + Ly 4

wbx Lx Px = 8hx

Py =

wbx Lx y

8hy

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2

2

4

4 4

wb

Lx wby = wb 4 4 αLy + Lx

POST TENSIONED FLOORS ■ Amount of Prestressing

α =1.0 for 4 edges continuous or discontinuous =1.0 for 2 adjacent edges discontinuous =2.0 for 1 long edge discontinuous =0.5 for 1 short edge discontinuous =2.5 for 2 long and 1 short edges discontinuous =0.4 for 2 short and 1 long edges discontinuous =5.0 for 2 long edges discontinuous =0.2 for 2 short edges discontinuous