DESIGN OF AXIALLY LOADED STEPPED FOOTING DATA :- SBC of soil =200 KN /m 2 Concrete Mix =M20 Steel Grade = Fe 415 Clear cover of bottom slab =50 mm

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Elizabeth Flowers
6 years ago
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1 STEPPED FOOTING The construction of sloped footing is sometimes difficult and when the slope of the top face of footing is more, say more than 1 vertically to 3 horizontally, it may be difficult to finish the top without having concrete slump too much. In such cases, stepped footing is an alternative. The stepped footing give least steel quantity, while the slopped footing give least concrete quantity. Stepped footings are little cumbersome in construction, while the slopped footings are easier in execution. For stepped footings, additional checks for moment and beam shear(one way shear) are required to be made for the portion of the footing of depth D3 (at edge depth). Normally D o (depth at each edge) is kept as 0.30D to 0.50D in stepped footing. Check for one way shear is checked to be safe by using first principle. The design is first done at the section X1-X1 passing through face of the column. The depth d is determined both on the basis of bending moment and shear. The depth so found is checked both for one way shear(beam shear) as well as for two way shear(punching shear). The area of steel reinforcement is provided as usual. Let the size of footing at its top, at the next step be B x B and its depth d. The critical section for design will be at section X-X. The critical depth d should be safe in compression, tension, shear and development length. The bending moment at X-X will be the moment of the total pressure acting on the rectangular area to one side of the

2 section. The resisting width will be B. From compression point of view, d= Mu/(0.138fckx B) where Mu is the ultimate B.M. at X-X. From tension point of view, providing the same reinforcement Ast as at X1-X1. Ast = Mu 0.87fyxjxAst The greater of the two values of d is selected. This value of d is checked both for beam shear (at a section distant d from X-X) and for punching shear(at perimeter section distant d/ from the face of the step) Similarly, depth d3 at section X3-X3 is determined. DESIGN OF AXIALLY LOADED STEPPED FOOTING DATA :- Load on column = 800 KN Column size =350 x 350 mm SBC of soil =00 KN /m Concrete Mix =M0 Steel Grade = Fe 415 Clear cover of bottom slab =50 mm DESIGN :- 1. SIZE OF FOOTING : Load on column P =800 KN Self weight of footing 10% = 80 KN

3 Total load on soil P1 = 880 KN SBC of soil = 00 KN/m Area of footing required = 880 / 00 =4.4 m Provide.10 x.10 m square footing. Area provided =4.41 m > 4.40 m. NET UPWARD SOIL PRESSURE : Load from column =800 KN Area of footing =4.41 m Net upward soil pressure p =800 / 4.41 = KN/m 3. BENDING MOMENT : < 00 KN/m (SBC) O.K.

4 let us give first step at 75 mm from column face and second step at 575 mm from face of column. B1= b+ x first offset = x 75 =900 mm. B = b + x second offset distance = x 575 = 1500 mm. Cantilever projection from X1 X1=( ) /= 875 mm Bending X1-X1 passing through face of column = x.10 x = KN.m Ultimate B.M. Mu1 =1.5 x = KN.m The top width of footing at the column base = B1=900mm effective depth d1 required = (18.76 x 10 6 ) / (0.138x0x900) =96.76 mm Approximate depth D required = 100/4.5 = 467 mm

5 For stepped footing increase depth by 0% = 1.0x467 =560.4 mm say 600 mm. Provide overall depth D =600 mm & d1= =53 mm 4. Check for one way shear : SF at a distance d =53 mm from column face which lies after the step where thick d is yet to be found. For two way shear, the critical plane lies at a distance of d1 = 53 = 67 mm from the face of column where b o =(350 +x 67) =884 mm Hence perimeter or punching shear zone = 4 x 884=3536mm Punching shear = x [ ] = KN Factored Shear Vu = 1.5 x = KN ζv = x 10 3 = 0.53 N/mm 3536 x 53 Permissible shear stress ζc= Ks x ζc where Ks = (0.5 +1) =1.5 > 1. Take Ks =1 Ks ζc = 1 x = 1.1 N/mm > 0.53 N/mm Hence safe. 5. REINFORCEMENT: K= Mu/b d = x x 53 =0.86

6 100 Pt from Table of Design Aid =0.51 Ast = 0.51 x 900 x 53 = 10 mm 100 Provide 1 Nos. 1 Φ RTS on both direction. (Ast =1356 mm > 10 mm ) 6. CHECK FOR CRACKING : Clear distance between bars = =173.7 mm < 180 mm for Fe CHECK FOR DEVELOPMENT LENGTH : Development length = 45 Φ =45 x 1 = 540 mm Available length of anchorage =875 50=85 mm> Ld O.K. 8. Design of section after first step: Let the effective depth be d mm Width of footing at top = B = 1500 mm Cantilever X-X = = 600 mm Bending moment M just at the face of step = x.10 x 0.60 = KN.m Factored B.M. =1.50 x = KN.m

7 From compression point of view, if the same reinforcement as provided at the column face is to be kept d = (10.86 x 10 6 )/(0.138 x 0 x 1500) = mm From Tension point of view, if the same reinforcement as provided at the column face is to be kept d = Mu/ 0.87 fy Ast j = x x415x1356x0.904 =3.41 mm Check for one way shear : Pt = 1356 x 100 = 0.8 % 100x 3.41 Permissible shear stress ζc = N/mm from Table 61 of Design Aid. One way Shear force = x.10 x ( ) = KN Factored SF Vu d = Vu B x ζc = 1.50 x = KN = x 10 3 = mm 1500 x For punching shear, taking d=448.9 mm (max. of the above three values ) b o = B1+ d/ = / = mm Shear force = x [ ] = KN

8 Factored SF Vu =1.50 x =856.5 KN ζv = Vu / 4 x b o x d = x x x d Permissible shear stress ζc = 1.1 N/mm d required = x 10 3 = mm 4 x x 1.1 Max. value of d = mm 9. Design of section after second step: Let the effective depth be d3. This is provided up to the edge of the footing. Cantilever projection at X3-X3 = = 300 mm The B.M. M3 just at the face of second steps M3= x.10 x 0.30 =17.14 KN.m Factored B.M. = 1.5 x =5.71 KN.m From compression point of view d3= (5.71x10 6 )/(0.138x0x100) =66.60mm From Tension point of view, using same steel d3= 5.71 x x415x0.904x1356 =58.09 mm From one way shear point of view d3= Vu/ B x ζc

9 Take d3= mm Shear force for one way shear = x.10 x( ) = 9.16 KN Vu = 1.50 x 9.16 =138.4 KN For Pt = 0.8%, ζc = 0.374N/mm d3= x 10 3 = mm 100 x For punching shear, taking d3 = mm (Max. of the above three values ) b o = = mm Shear force = x [ ] =34.55 KN Factored SF Vu = 1.5 x = KN d3 = x x x 1.1 = 7.3 mm Max. value of d3 = mm 10. Total Thickness : At the section before first step, d1 = 53 mm. Hence effective depth in other section = = 544 mm. D1 = = 594 mm.

10 Provide D1 = 650 mm. At the section after second step, d = mm. Hence effective depth d in the other direction = = mm D = = mm. Provide D = 515 mm. For the other edge d3= mm for one direction and = mm for the other direction. Hence D3 = =38.01 mm. Provide D3= 40 mm

11 11.SKETCH:

Formation level = m. Foundation level = m. Height of the wall above the Ground Level = 7.42 m

Formation level = m. Foundation level = m. Height of the wall above the Ground Level = 7.42 m DESIGN OF RETAINING WALL INTRODUCTION: This wall is designed for active earth pressure and live load surcharge pressure The loads for the purpose of design are calculated per meter length of wall. BASIC