Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 Design and drawing of RC Structures CV61 Dr. G.S.Suresh Civil Engineering Department The National Institute of Engineering Mysore-570 008 Mob: 9342188467.

Similar presentations


Presentation on theme: "1 Design and drawing of RC Structures CV61 Dr. G.S.Suresh Civil Engineering Department The National Institute of Engineering Mysore-570 008 Mob: 9342188467."— Presentation transcript:

1 1 Design and drawing of RC Structures CV61 Dr. G.S.Suresh Civil Engineering Department The National Institute of Engineering Mysore-570 008 Mob: 9342188467 Email: gss_nie@yahoo.com

2 2 WATER TANKS

3 3 Learning out Come REVIEW DESIGN OF CIRCULAR WATER TANK RESTING ON GROUND WITH RIGID BASE

4 4 When the joints at base are flexible, hydrostatic pressure induces maximum increase in diameter at base and no increase in diameter at top When the joint at base is rigid, the base does not move

5 5 Tank with flexible base Tank with rigid base

6 6 Design of Circular Tanks resting on ground with Rigid base

7 7 Due to fixity at base of wall, the upper part of the wall will have hoop tension and lower part bend like cantilever. For shallow tanks with large diameter, hoop stresses are very small and the wall act more like cantilever For deep tanks of small diameter the cantilever action due to fixity at the base is small and the hoop action is predominant

8 8 The exact analysis of the tank to determine the portion of wall in which hoop tension is predominant and the other portion in which cantilever action is predominant, is difficult Simplified methods of analysis are 1.Reissner’s method 2.Carpenter’s simplified method 3.Approximate method 4.IS code method

9 9 IS code method Tables 9,10 and 11 of IS 3370 part IV gives coefficients for computing hoop tension, moment and shear for various values of H 2 /Dt Hoop tension, moment and shear is computed as T= coefficient (  w HD/2) M= coefficient (  w H 3 ) V= coefficient (  w H 2 )

10 10 Thickness of wall required is computed from BM consideration where, Q= ½  cbc jk j=1-(k/3) b = 1000mm

11 11 IS code method Over all thickness is then computed as t = d+cover. Area of reinforcement in the form of vertical bars on water face is computed as Area of hoop steel in the form of rings is computed as

12 12 IS code method Distribution steel and vertical steel for outer face of wall is computed from minimum steel consideration Tensile stress computed from the following equation should be less than the permissible stress for safe design the permissible stress is 0.27  fck

13 13 IS code method Base slab thickness generally varies from 150mm to 250 mm and minimum steel is distributed to top and bottom of slab.

14 14 Design Problem No.1 on Circular Tanks resting on ground with Rigid base

15 15 A cylindrical tank of capacity 7,00,000 liters is resting on good unyielding ground. The depth of tank is limited to 5m. A free board of 300 mm may be provided. The wall and the base slab are cast integrally. Design the tank using M20 concrete and Fe415 grade steel. Draw the following Plan at base Cross section through centre of tank.

16 16 Step 1: Dimension of tank H= 5-0.3 = 4.7 and volume V = 700 m 3 A=700/4.7 = 148.94 m 2 D=  (4 x 148.94/  ) = 13.77  14 m

17 17 Step 2: Analysis for hoop tension and bending moment One meter width of the wall is considered and the thickness of the wall is estimated as t=30H+50 = 191 mm. The thickness of wall is assumed as 200 mm. Referring to table 9 of IS3370 (part IV), the maximum coefficient for hoop tension = 0.575

18 18 Step 2: Analysis for hoop tension and bending moment (Contd.) Tmax=0.575 x 10 x 4.7 x 7 =189.175 kN Referring to table 10 of IS3370 (part IV), the maximum coefficient for bending moment = -0.0146 (produces tension on water side) Mmax= 0.0146 x 10 x 4.73=15.15 kN-m

19 19 Step 3: Design of section: For M20 concrete  cbc=7, For Fe415 steel  st=150 MPa and m=13.33 for M20 concrete and Fe415 steel The design constants are: j=1-(k/3)=0.87 Q= ½  cbcjk = 1.19 Effective depth is calculated as

20 20 Step 3: Design of section: (Contd.) Let over all thickness be 200 mm with effective cover 33 mm d provided =167 mm Spacing of 16 mm diameter bar = (Max spacing 3d=501mm) Provide #16@275 c/c as vertical reinforcement on water face

21 21 Step 3: Design of section: (Contd.) Hoop steel: Spacing of 12 mm diameter bar = Provide #12@80 c/c as hoop reinforcement on water face Actual area of steel provided

22 22 Step 4: Check for tensile stress: Permissible stress = 0.27  fck=1.2 N/mm2 >  c Safe

23 23 Step 5: Distribution Steel: Minimum area of steel is 0.24% of concrete area Ast=(0.24/100) x1000 x 200 = 480 mm 2 Spacing of 8 mm diameter bar = Provide #8 @ 100 c/c as vertical and horizontal distribution on the outer face.

24 24 Step 5: Base slab: The thickness of base slab shall be 150 mm. The base slab rests on firm ground, hence only minimum reinforcement is provided. Ast=(0.24/100) x1000 x 150 = 360 mm 2 Reinforcement for each face = 180 mm 2 Spacing of 8 mm diameter bar = Provide #8 @ 250 c/c as vertical and horizontal distribution on the outer face.

25 25

26 26 Design Problem No.2 on Circular Tanks resting on ground with Rigid base

27 27 Design a circular water tank to hold 5,50,000 liters of water. Assume rigid joints between the wall and base slab. Adopt M20 concrete and Fe 415 steel. Sketch details of reinforcements.

28 28 Step 1: Dimension of tank Volume of tank V=550 m 3 Assume H= 4.5 A=550/4.5 = 122.22 m 2 D=  (4 x 122.22/  ) = 12.47  12.5 m

29 29 Step 2: Analysis for hoop tension and bending moment One meter width of the wall is considered and the thickness of the wall is estimated as t=30H+50 = 185 mm. The thickness of wall is assumed as 200 mm. Referring to table 9 of IS3370 (part IV), the maximum coefficient for hoop tension = 0.575

30 30 Step 2: Analysis for hoop tension and bending moment (Contd.) Tmax=0.575 x 10 x 4.5 x 6.25 =161.72 kN Referring to table 10 of IS3370 (part IV), the maximum coefficient for bending moment = -0.0146 (produces tension on water side) Mmax= 0.0146 x 10 x 4.53=13.3 kN-m

31 31 Step 3: Design of section: For M20 concrete  cbc=7, For Fe415 steel  st=150 MPa and m=13.33 for M20 concrete and Fe415 steel The design constants are: j=1-(k/3)=0.87 Q= ½  cbcjk = 1.19 Effective depth is calculated as

32 32 Step 3: Design of section: (Contd.) Let over all thickness be 200 mm with effective cover 33 mm d provided =167 mm Spacing of 16 mm diameter bar = (Max spacing 3d=501mm) Provide #16@300 c/c as vertical reinforcement on water face

33 33 Step 3: Design of section: (Contd.) Hoop steel: Spacing of 12 mm diameter bar = Provide #12@100 c/c as hoop reinforcement on water face Actual area of steel provided

34 34 Step 4: Check for tensile stress: Permissible stress = 0.27  fck=1.2 N/mm2 >  c Safe

35 35 Step 5: Distribution Steel: Minimum area of steel is 0.24% of concrete area Ast=(0.24/100) x1000 x 200 = 480 mm 2 Spacing of 8 mm diameter bar = Provide #8 @ 100 c/c as vertical and horizontal distribution on the outer face.

36 36 Step 5: Base slab: The thickness of base slab shall be 150 mm. The base slab rests on firm ground, hence only minimum reinforcement is provided. Ast=(0.24/100) x1000 x 150 = 360 mm 2 Reinforcement for each face = 180 mm 2 Spacing of 8 mm diameter bar = Provide #8 @ 250 c/c as vertical and horizontal distribution on the outer face.

37 37

38 38 A TYPICAL DRAWING

39 39

40 40 Dr. G.S.Suresh Civil Engineering Department The National Institute of Engineering Mysore-570 008 Mob: 9342188467 Email: gss_nie@yahoo.com


Download ppt "1 Design and drawing of RC Structures CV61 Dr. G.S.Suresh Civil Engineering Department The National Institute of Engineering Mysore-570 008 Mob: 9342188467."

Similar presentations


Ads by Google