IRREGULAR FLAT RC SLABS DESIGNED ACCORDING TO STRUCTURAL MEMBRANE APPROACH.pdf
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DESIGN OF SLABS
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Steel StairFull description
RC Flat slab design
Ribbed slabs are used for long spans with relatively light loads. They are constructed in one of the following ways as described in clause 30 of IS: 456-2000 1. As a series of concrete ribs with t...
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ANALYSIS & DESIGN OF STAIR CASE
RC stair case design in accordance with BS 8110
Stair Climbing Training
DT126/3
Third Year Civil Technician Diploma- Reinforced Concrete Design
RC Stair Slabs Types: There are two types of stair flights, classified on the direction of span: 1. Transverse: The steps may be supported on both sides, or may be cantilevered from an adjacent wall, for example. 2. Longitudinal: The stair flight spans onto landings or beams at either end of the stair flight. Design of Transverse Stairs: Design of these sections are based on the average effective depth of the section. These flights may cantilever from a wall or span from a wall to a stringer beam, for example. Design of Longitudinal Stairs: The design of these stairs is more complicated. The additional factors to consider are: 1. Geometry: Given the rise, going and the number of steps, the span and overall height rise can be determined: Span = (No. Steps – 1) × going Height = No. Steps × rise
Slope Length = √(Span + Height ) 2
2
SPAN 8 7 6 5 T H G I E H
GOING
4 3
2 RISE
1 WAIST
EFFECTIVE SPAN 1
When the flight is built monolithically into members spanning at right angles to its span, the effective span is given by: la = 0.5(lb1 + lb2) where la = clear horizontal distance between supporting members lb1 = Breadth of supporting member at end 1 but ≤ 1.8 m lb2 = Breadth of supporting member at end 2 but ≤ 1.8 m Lecturer: Colin Caprani
DT126/3
Third Year Civil Technician Diploma- Reinforced Concrete Design
Otherwise the effective span should be taken as the distance between the centrelines of support, or the clear distance between support faces plus the effective depth, whichever is less. If a flight is built into a wall (which is running in the same direction as the span) by at least 110 mm, 150 mm can be taken off the loaded width of the stair flight. The thickness of the waist is taken as the slab thickness. 2. Loading: The dead load is based on the slope length of the stair flight. The average thickness of the stair slab is used to calculate the dead load: 2 2 h = 0.5 × rise × going / √(rise + going ) + waist + finishes
Finishes are included as they are generally assumed to have a density equal to that of concrete. The live load is based on the plan area of the stairs and is to be taken as the same to the floor which the stairs give access, but ≥ 3 kN/m2 and ≤ 5 kN/m2. If two stair flights, at right angles, share a landing, the landing loads may be assumed to be divided equally between the spans. As part of the landing may be considered as part of the stair flight, the loading on the landing must be taken into account in the shear check. 3. Design: Flights with significant end restraint, such as those that are continuous with their supporting slabs or beams may be designed for mid-span design moment of 2 wl /10 and hogging moment at the supports of the same value. Where there is not 2 sufficient end restraint the stair slab is to be designed for wl /8.
The maximum shear should be ascertained from a simply-supported model of the stair slab. Shear should not be critical in a stair flight. When the stair flight (on plan) occupies at least 60% of the effective span, the permissible span/d ratio may be increased by 15%.
Lecturer: Colin Caprani
DT126/3
Third Year Civil Technician Diploma- Reinforced Concrete Design
CRANKED BARS FOR CONTINUITY WITH LANDING
LANDING U-BAR
MAIN STEEL
4. Detailing: The reinforcement arrangement in stair flights follows a standard pattern. Deviation from this is not recommended unless a specific need arises. Longitudinal steel is the main reinforcement and in the transverse direction the minimum percentage of steel is provided as “distribution steel” to help prevent cracking.
Strength requirements are not always critical for stair slabs. essential that the other limit states are checked: a. Deflection b. Cracking c. Min % As