Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE) PDF Download

Chapter 6  

Footings

Isolated Footing Footings are structural elements that transfer loads from the building or individual columns to the earth. If these loads are to be properly transmitted, foundations must be and to provide adequate safety against sliding and overturning.
Theoretically speaking isolated footings must be designed for both axial load and moment but practically isolated footings are designed only for axial load.

Foundation may be broadly classfied under two heads: shallow foundation and deep foundation. According to Terzaghi, a foundation and deep foundation. According to Terzaghi, a foundation is shallow if its depth is equal to or less than it width. In the case of deep foundation, the depth is greater than the width. Apart from deep strip, rectangular or square foundations are; pier foundation, pile foundation and well foundation. The shallow foundation are of the following types: Spread footing, strap footing, combined footing and mat or raft footing.

Spread footing: A spread footing or simply footing, is a type of shallow foundation used to transmit the load of an isolated column, or that of a wall, on the subsoil. In the case of wall, the footing is continuous while in the case of column, is a isolated.

Combined footings: A spread footing which supports two or more columns is termed as a combined footing. Such a footing is provided when the individual footings are either very near to each other, or overlap. Combined footings may either be rectangular or trapezoidal.

Strap or Cantilever footings:  A strap footing consists of spread footing of two columns connected by a strap beam. The strap beamdoes not remain in contact with soil, and thus does not transfer any pressure to the soil.

Mat or Raft foundation: A mat or raft is a combined footing that covers the entire area beneath a structure and supports all the walls and columns. When the available soil pressure is low or the building loads are heavy, the use of spread footing would cover more than one-half of the area and it may prove more economical to use mat or raft foundation.

Pile foundation : Pile foundation is a deep foundation used where the top soil is relatively weak. Piles transfer the load to a lower stratum of greater bearing capcity, by the way of end bearing, or to the intermediate soil through skin friction. This is more common type of deep foundation generally used for building where a group of piles transfer the load of the super-structure to the sub soil.

Design of Isolated Footing

Rectangular footing

Given values 1. Load = P or Pu 2. Bearing capacity of soil = qu 3. Size of column 4. Grade of concrete and steel

Design Steps (i) Size of foundation Load from column = P Increase 10% of the total load Add weight of foundation (PF) = 0.1 P Total load PT = 1.1P (even for limit state method use unfactored load for calculation of area) Area of footing,

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

Choose L and B such taht A = L × B Net soil pressure

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

Net soil pressure over foundation

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

For LSM Net soil pressure (wu) =

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

(ii) Check for bending moment Critical section for bending moment is at the face of the column

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

Consider 1 m strip of foundation Bending moment about X1 X1

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)
Maximum bending moment =Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

Similarly moment about Y1Y1

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

Maximum BM

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

Note: Use w = w m= 1.5 w for Limit State Method.
(iii) Depth required

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

where B = 1000 mm For  LSM
Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

(iv) Check for single shear (one-way shear) Critical section for one-way shear is at 'd' distance from the face of the column

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

Shear at X2X2
Overhang,
Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE) 

Shear force, Vx = w.1 × Oy

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

Similarly Shear force at Y2Y2 overhang, Ox =

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

Vy = w.1 × Ox = w

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

Find out maximum of Vx and Vy Nominal shear stress

Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE) 

where, tc is permissible design shear strength of concrete in N/mm2 as given in IS : 456 Footing should be always safe in shear. No shear reiforcement is provided.

(v) Check for two-way (Punching Shear)

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

Critical section for punching shear also called two-way shear is at (d/2) distance from face of the column all around.
Pnet = P – w(a+d) (b+d)
Punching shear stress developed =

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

Cross section area = permiter × depth Now perimeter = 2[(a+d) + (b+d)] Depth = d

Punching shear stress

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

Above developed stress should be less than the permissible punching shear stress Permissible punching shear stress
ζcp = ks × 0.16Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE) (working stress method)
= ks × 0.25 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE) (Limit state method)
ks = (0.5 + βc ) but not greater than 1, βc being the ratio of short side to long side of the column

 (vi) Area of steel for the longer span The area of steel Ast of long bars parallel to direction L is calculated as under.
For My moment

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

(Working stress method)

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

(Limit state method) This reinforcement is equally distributed over entire width B.

 Note: Area of steel calculated above is for 1 m, width, Calculate this area for width B and distribute uniformly over entire width For B m, total area of steel = B × Ast

(vii) Area of steel for shorter span The area of steel Ast of short bars parallel to direction B is calculated as under

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

for 1 m For L m, total area of steel = L × Ast This area is provided in two distinct band widths: 

  • the centre band B of width B, and  the end bands A, each of width
    Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)
    The reinforcement in central band width

Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE) total reinforcement in short direction.

Where,β = ratio of long side to the short side of the footing The remainder or reinforcement shall be uniformly distributed in outer portions of the footing.

 Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

 

The document Footings | Civil Engineering SSC JE (Technical) - Civil Engineering (CE) is a part of the Civil Engineering (CE) Course Civil Engineering SSC JE (Technical).
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FAQs on Footings - Civil Engineering SSC JE (Technical) - Civil Engineering (CE)

1. What are footings in construction?
Footings are structural elements that are used to support and distribute the load of a building or other structure to the soil or foundation below. They are typically made of concrete and are placed below ground level to provide stability and prevent settling or movement of the structure.
2. Why are footings important in construction?
Footings are essential in construction because they help to transfer the load of the building to the ground in a stable and safe manner. By spreading the weight of the structure over a larger area, footings prevent excessive settlement or sinking of the building and ensure its long-term stability.
3. What are the different types of footings used in construction?
There are several types of footings used in construction, depending on the specific requirements of the building and the soil conditions. Some common types include spread footings, which distribute the load over a wide area, and deep or pile footings, which are used when the soil is not able to support the load on its own.
4. How are footings designed and constructed?
The design and construction of footings involve several factors, such as the type of soil, the load of the structure, and the local building codes and regulations. Typically, a structural engineer will analyze these factors and determine the appropriate size, depth, and reinforcement of the footings to ensure the stability and safety of the building.
5. Can footings be added or modified after the construction of a building?
In some cases, footings can be added or modified after the construction of a building, depending on the specific situation and structural requirements. However, this process can be complex and may require the expertise of a structural engineer to assess the feasibility and safety of such modifications. It is always recommended to consult with professionals before making any changes to the footings of a building.
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