Any construction building design as per the below step. In this article, we design only slab and next article next steps calculation.
- Slab Design
- Slab Beam Design
- Lintel Beam Design
- Column Design
- Plinth Beam Design
- Footing Design
Some Important Point for Slab Design
Important Point
Type of Slab
A slab is a plate element having a depth (D), Very small as compared to its length and width slab is used as floor or roof in building, carry uniformly distributed load.
Slab may be
- Simply Supported
- Continuos
- Cantilever
Also, Read: What Is a Waffle Slab
Type of Slab Based on Support Conditions Are:
1). One Way Spanning Slab
2). Two Way Spanning Slab
3). Flat Slab Resting Directly on Columns Without Beams
4). Grid Slabs or Waffle Slabs
5). Circular Slab and Other Shapes
One Way Spanning Slab
If the slab is supported on two opposite sides. it is called a one-way spanning slab. In this type of slab, lads are transferred on two opposite supports as shown below figure.
One Way Slab
If the slab is supported on four sides, and if ly/lx ≥ 3 one way spaning slab.
For any slab, if ly = lx, the slab has a tendency to bend in both the directions Which increase is provided along lx (Short Span)
Two Way Spanning Slab
It the slab is supported on all four edges and if ly / lx < 2,
The tendency of the slab is to bend in both directions. Such slabs are called a two-way slab. ( as shown below figure.)
In a two-way slab, the main reinforcement is provided along with lx as well as ly direction.
Flat Slab
When the slab is directly supported on columns, without beams, it is known as a flat slab.
Flat slabs are provided to increased the floor height and to permitted a large amount of light which might be obstructed by the depth of beams.
Grid Slabs
When the slab is required on beams with columns only on the periphery of the hall, the slab is called grid slab
Sometimes, in a large hall, public places, marriage halls, auditoriums, etc. a large column-free area is required. In these cases, large deep beams may be permitted but the columns are permitted only on the periphery
Also Read: Floor Slab
One Way Simply Support Slab Calculation /Design
One Way Simply Support slab Below Point Calculation Required
1. Effective Depth (d)
2. Effective Span
3. Reinforcement Requirements
4. Check for Cracking
5. Check for Deflection
6. Check for Development Length (Ld)
Effective Depth (d)
For deflection control
L/d = 20 X M.F
- M.F. Modifiction factor from— IS: 456, p.38.Fig-4
- Assume % steel 0.3 to 0.6%
Fs = 0.58 Fy X (Ast requierd / Ast Provied)
Initially assume that Ast reqierd = Ast Provided
Fy = 250 N/ Sq.mm —– Fs = 0.58 X 250 = 145 N/ sq.mm.
Fy = 415 N/ Sq.mm —– Fs = 0.58 X 415 = 240 N/ sq.mm.
Fy = 500 N/ Sq.mm —– Fs = 0.58 X 500 = 290 N/ sq.mm.
Effective Span
Clear Span + d
c/c of Supports
Whichever is smaller ——– as per IS 456-2000 P. 34, CI 22.2.a
Reinforcement Requirements
Minimum reinforcement
For Fe-250 Pt = 0.15 % of total C/s area (d x D)
For Fe-415 Pt = 0.12 % of total C/s area (d x D)
For Fe-500 Pt = 0.12 % of total C/s area (d x D) ——– as per IS 456-2000 P. 48, CI 26.5.2.1
Maximum diameter (Sp 34)
For minbar:
- Plain bars———–10 mm Ø min dia
Deformed bars—–8 mm Ø min dia
For Distribution bars:
- Plain bars———–6 mm Ø min dia
Deformed bars—–6 mm Ø min dia
Check for Cracking
For Min Steel:
3d ——— Where. d = Effective depth
300 mm
Spacing should not exceed smaller these two values.
For Distribution steel:
5 d
450 mm
Spacing should not exceed smaller these two values. ——- IS: 456-2000, P.46
Check for Deflection
Allowable L/d = 20 X M.F.
- M.F is Obtained from IS:456-200 P-38 Fig 4
Find actual, L/d
If Actual L/d < allowable L/d ———- Ok
Check for Development Length (Ld)
IS 456-2000,P.44, Cl. 26.2.3.3 C
Ld should be ≤ 1.3 (M1/V) + L0
Where
Ld = (Ø.σs / 4 τ bd )—————–σs = 0.87 fy As per IS 456-200, P.42
50 % of steel is bent up near support. Therefore find M.R for 50 % of steel only
M1 = M.R. for 50% steel support
V = Shear force at the support
L0 = Sum of anchorage beyond the center of support
d
12 Ø
Take L0 as the smaller of two values.
One Way Simply Support SlabCalculation /Design- Example
Sum Point Consider As below
Slab Size 3.2m X 9.2 m
The slab is resting on 300mm thick wall
Find One Way Slab or Two Way Slab
ly/lx = 9.2 / 3.2 = 2.875 > 2
As per the type of slab
Here this one-way slab, So we design the slab as one-way simply supported slab
Effective Depth (d)
Here Consider shorter span as l,
l = 3200 mm = 3.2 m
l/d = 20 x M.F
fy – 415 N/sq.mm, fs = 240 N / Sq.mm
M.F = 1.15 | As per IS Code 456, Fig.4
l/d = 20 x 1.15
3200/d = 20 x 1.115
d = 139.13 mm
Here, d = 150 mm , Assume 10 mm Ø bars
Overall Depth, D = 150 + (Ø / 2 ) + Clear Cover
D = 175 mm
Effective Span
1). 3200 + 150 = 3350 mm
2). c/c of Supports = 3200 + 300 = 3500 mm | IS: 456-2000,P-34, CI. 22.2.a
Whichever is smaller
Effective Span = l = 3350 mm = 3.35 m.
Reinforcement Requirements
Load Calculations
Dead load | 4.375 | Kn/m |
Floor Finsh | 1 | Kn/m |
Live Load | 2.5 | Kn/m |
Total Load | 7.875 | Kn/m |
Factored Load = 1.5 x 7.875
w = 11.82 kn/m.
Bending Moment
Mu = (w. l2) / 8 = (11.82 / 3.352)
Mu = 16.58 Kn.m.
Main Steel
Pt = 50 (fck/fy) [1 – √ ( 1 -{(4.6 Mu)/ (fck x bd2)})]
Pt = 50 x (0.482) x (0.0945)
Pt = 0.215 %
Ast = ( pt / 100) x 1000 x 150
Ast = 322.5 mm2
For Spacing
Sapcing = ({[π/4] x d2}/Ast ) x 1000 mm
Sapcing = ( 78.53 / 322.5 ) x 1000 = 243.50 mm
Distrbution Steel
Provide a minimum of 0.120% of Total C/s Area | As per IS 456-200 P 48, CI. 26.5.2.1
Ast = (0.12/100) x 1000 x 175 = 210 Sq.mm
Check for Cracking
For Main Steel
1). 3 d = 3 x 150 = 450 mm
2). 300 mm | IS 456-2000 P-46
240 mm provided < 300 mm …………….. o.k.
For Distribution Steel
1). 5 d = 5 x 150 = 750 mm
2). 450 mm
130 mm provided < 450 mm …………….. o.k.
Check for Deflection
Allowable (l/d) = 20 x M.F.
% pt Provided = 100 Ast / bd = (100 x 327) / (1000 x 150) = 0.218% | IS Code 456-2000 P.38, Fig 4
M.F = 1.6
Allowable l/d = 20 x 1.6 = 3350 / 150 = 22.33
22.33 < 32 …………….. o.k.
Check for Development Length (Ld)
1). d = 150 mm
2). 12 Ø = 12 x 10 = 120 mm
Taking larger of two values L0 = 150 mm
S.F. at support = 50% of East at mid-span = 327 / 2 = 163.5 Sq.mm
M1 = 0.87 x 415 x 163.5 x 150 x [1-(415 x 163.5) / (20 x 1000 x 150)]
M1 = 8.65 x 106 N.mm = 8.65 kN.m.
1.3 [ M1/V] + L0 = 1.3 x (8.65 x 106 ) / (18.91 x 103 ) + 150
M1 = 744.65 mm
for M 20 , fy = 415 N/mm2
10 mm Ø. bar, tension
Ld = 470 mm
470 mm < 744.65 mm …………….. o.k.
Also, Read: Structural Audit of Building
Reinforcment Details
One Way Simply Support Slab Calculation /Design Excel Sheet – Download
Video tutorial for better understanding:
Design of a Building
Building design refers to the broadly based architectural, engineering and technical applications to the design of buildings. All building projects require the services of a building designer, typically a licensed architect.
Building Structure Design
The process of building structure design involves project planning, site investigation, structural system selection, load calculation, structural analysis, structural design, foundation design, structural detailing, compliance with building codes, collaboration and coordination, construction documentation, and construction administration.
Structural Design Examples
Structural Design. Structural Engineering is the branch which involves analysis and design of mainly steel, concrete, or timber framed structures such as Tall Buildings, Bridges, Dams, Towers, Offshore Platforms, Stadiums, Retaining Walls and Foundation.
House Slab Design
House slab design involves determining the appropriate slab type, thickness, reinforcement, control joints, vapor barrier, slope, drainage, and compliance with building codes. It is important to consult a qualified professional for an accurate and safe design.
Structural Design of Building
Structural design is the methodical investigation of the stability, strength and rigidity of structures. The basic objective in structural analysis and design is to produce a structure capable of resisting all applied loads without failure during its intended life.
Beam Design for House
In beam design for a house, you need to calculate the loads, determine the span length, choose the appropriate beam type, size the beam to support the loads, consider reinforcement for concrete beams, analyze shear and moment diagrams, control deflection, ensure fire resistance, design connections, and comply with building codes. Consult a qualified professional for accurate and safe beam design.
Structural Building Design
Structural building design involves calculating loads, selecting a suitable structural system, analyzing the structure, designing structural elements, considering foundation design, complying with building codes, collaborating with other professionals, preparing construction documents, and providing construction administration. Consult a qualified structural engineer for accurate and safe design.
Home Slab Design
- Soil Investigation
- Load Calculation
- Slab Type
- Slab Thickness
- Reinforcement
- Slope and Drainage
- Compliance and Quality Control
How to Design a Building Structure?
There are mainly 5 essential steps to be followed for the design of any structure. (1) modelling, (2) load analysis, (3) structural analysis, (4) structural design and (5) detailing.
Structural Design of Building Plan
A structural drawing, a type of engineering drawing, is a plan or set of plans and details for how a building or other structure will be built. Structural drawings are generally prepared by registered professional engineers, and based on information provided by architectural drawings.
How to Design Building Structure?
- Project Planning
- Site Investigation
- Structural System Selection
- Load Calculation
- Structural Analysis
- Structural Design
Plinth Beam Design
According to the rules, the bottom of the plinth beam has two reinforcing steel bars with a minimum diameter of 12mm. On the top are two more steel bars for reinforcement with a diameter of at least 10 mm. The reinforcement bars must have a concrete cover of at least 25mm thickness.
How to Design Structure of House?
To design the structure of a house:
- Determine requirements and desired layout.
- Calculate loads on the structure.
- Select a suitable structural system.
- Analyze the structure for stability and strength.
- Design structural elements like beams, columns, slabs, and walls.
- Design an appropriate foundation system.
- Ensure compliance with building codes.
- Coordinate with other professionals involved in the design.
- Prepare detailed construction documents.
- Provide construction administration support.
Design of Structures
- Plan the project and define requirements.
- Calculate the loads the structure will experience.
- Select an appropriate structural system.
- Analyze the structure for stability and strength.
- Design structural elements and connections.
- Design a suitable foundation system.
- Ensure compliance with building codes.
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Suggested Read –
- Building Layout
- Steel Calculation for Slab
- Structural Load Calculation Example
- The Cantilever Footing Is Used to Support a Wall near Its Edge
- How to Structural Design a Building/House Step by Step Part-1 (One Way Simply Support Slab)
- How to Structural Design a Building/House Step by Step Part-2 (Two Way Simply Support Slab)
- How to Structural Design a Building/House Step by Step Part-3 (Slab Beam Design)
- How to Structural Design a Building/House Step by Step Part-4 (Column Design)
Originally posted 2023-06-15 11:09:39.
Md Nuruzzaman says
very good post. i am a civil engineer at bangladesh. need more post like that. if one end continius on end discontinuous .
Krunal Rajput says
Thanks, Dear
Emmanuel Kwabdins says
Hy I am Emmanuel Kwabdins from Nigeria, please can I have this as a PDF?
Krunal Rajput says
Thanks for comment
How to get easy pdf
Go to Print or ctrl + p button press,
Then select print PDF,
After select print then click ok to print for get your PDF file
nabil zayer says
good prog.
Md Moynuddin says
You have added lots of information about Structural design of building, I appreciate the post
Krunal Rajput says
Thanks