Summary Sheet

1
Summary Sheet
Session Number
5

Date

09.04.2007

Subject Expert
Dr. M.C. Nataraja Professor Department of Civil
Engineering, Sri Jayachamarajendra College of
Engineering, Mysore 570 006.
Phone0821-2343521, 9880447742 E-mail
nataraja96_at_yahoo.com
2
Design and Detailing of Counterfort Retaining wall

• Dr. M.C. NATARAJA

3
Counterfort Retaining wall

• When H exceeds about 6m,
• Stem and heel thickness is more
• More bending and more steel
• Cantilever-T type-Uneconomical
• Counterforts-Trapezoidal section
• 1.5m -3m c/c

4
Parts of CRW

• Same as that of Cantilever Retaining wall Plus
  Counterfort

Cross section
Plan
5
Design of Stem

• The stem acts as a continuous slab
• Soil pressure acts as the load on the slab.
• Earth pressure varies linearly over the height
• The slab deflects away from the earth face
  between the counterforts
• The bending moment in the stem is maximum at the
  base and reduces towards top.
• But the thickness of the wall is kept constant
  and only the area of steel is reduced.

6
Maximum Bending moments for stem

• Maximum ve B.M pl2/16
• (occurring mid-way between counterforts)
• and
• Maximum -ve B.M pl2/12
• (occurring at inner face of counterforts)
• Where l is the clear distance between the
  counterforts
• and p is the intensity of soil pressure

7
Design of Toe Slab

• The base widthb 0.6 H to 0.7 H
• The projection1/3 to 1/4 of base width.
• The toe slab is subjected to an upward soil
  reaction and is designed as a cantilever slab
  fixed at the front face of the stem.
• Reinforcement is provided on earth face along the
  length of the toe slab.
• In case the toe slab projection is large i.e. gt
  b/3, front counterforts are provided above the
  toe slab and the slab is designed as a continuous
  horizontal slab spanning between the front
  counterforts.

8
Design of Heel Slab

• The heel slab is designed as a continuous slab
  spanning over the counterforts and is subjected
  to downward forces due to weight of soil plus
  self weight of slab and an upward force due to
  soil reaction.
• Maximum ve B.M pl2/16
• (mid-way between counterforts)
• And
• Maximum -ve B.M pl2/12
• (occurring at counterforts)

9
Design of Counterforts

• The counterforts are subjected to outward
  reaction from the stem.
• This produces tension along the outer sloping
  face of the counterforts.
• The inner face supporting the stem is in
  compression. Thus counterforts are designed as a
  T-beam of varying depth.
• The main steel provided along the sloping face
  shall be anchored properly at both ends.
• The depth of the counterfort is measured
  perpendicular to the sloping side.

10
Behaviour of Counterfort RW

• Important points
• Loads on Wall
• Deflected shape
• Nature of BMs
• Position of steel
• Counterfort details

11
PROBLEM-Counterfort Retaining Wall

• A R.C.C. retaining wall with counterforts is
  required to support earth to a height of 7 m
  above the ground level. The top surface of the
  backfill is horizontal. The trial pit taken at
  the site indicates that soil of bearing capacity
  220 kN/m2 is available at a depth of 1.25 m below
  the ground level. The weight of earth is 18 kN/m3
  and angle of repose is 30. The coefficient of
  friction between concrete and soil is 0.58. Use
  concrete M20 and steel grade Fe 415. Design the
  retaining wall.

12

• Draw the following
• Cross section of wall near the counterfort
• Cross section of wall between the counterforts
• L/s of stem at the base cutting the counterforts
• Given
• fck 20 N/mm2, fy 415N/mm2, H 7 m above
  G.L, Depth of footing below G.L. 1.25 m, ?
  18 kN/m3,
• µ 0.58, fb SBC 220 kN/m2

13
a. Proportioning of Wall Components

• Coefficient of active pressure ka 1/3
• Coefficient of passive pressure kp 3
• The height of the wall above the base
• H 7 1.25 8.25 m.
• Base width 0.6 H to 0.7 H
• (4.95 m to 5.78 m), Say b 5.5 m
• Toe projection b/4 5.5/4 say 1 .2 m
• Assume thickness of vertical wall 250 mm
• Thickness of base slab 450 mm

14

• Spacing of counterforts
• l 3.5 (H/?)0.25 3.5 (8.25/18)0.25 2.88 m
• c/c spacing 2.88 0.40 3.28 m say 3 m
• ? Provide counterforts at 3 m c/c.
• Assume width of counterfort 400 mm
• ? clear spacing provided l 3 - 0.4 2.6 m

15
Details of wall
16
b. Check Stability of Wall
17
(No Transcript)
18
Stability of walls

• Horizontal earth pressure on full height of wall
• Ph ka?H2 /2 18 x 8.252/(3 x 2) 204.19 kN
• Overturning moment M0
• Ph x H/3 204.19 x 8.25/3 561.52 kN.m.
• Factor of safety against overturning
• ? M / M0 2210.71/561.52 3.94 gt 1.55
• ? safe.

19

• Check for sliding
• Total horizontal force tending to slide the wall
• Ph 204.19 kN
• Resisting force ?µ.W 0.58 x 679.25
• 393.97 kN
• ?Factor of safety against sliding
• ?µ.W / Ph 393.97/204.19
• 1.93 gt 1.55 ... safe.

20

• Check for pressure distribution at base
• Let x be the distance of R from toe (T),
• ? x ? M / ? W 2210.71 -561.52 /679.25 2.43
  m
• Eccentricitye b/2 - x 5.5/2 - 2.43 0.32 lt
  b/6 (0.91m)
• ?Whole base is under compression.
• Maximum pressure at toe
• pA ?W / b ( 16e/b) 679.25/5.5 ( 1
  60.32/5.5)
• 166.61 kN/m2 lt f b (i.e. SBC 220 kN/m2)
• Minimum pressure at heel
• pD 80.39 kN/m2 compression.

21

• Intensity of pressure at junction of stem with
  toe i.e. under B
• pB 80.39 (166.61 - 80.39) x 4.3/5.5
  147.8kN/m2
• Intensity of pressure at junction of stem with
  heel i.e. under C
• Pc 80.39 (166.61 - 80.39) x 4.05/5.5 143.9
  kN/m2

22
(No Transcript)
23
b) Design of Toe slab

• Max. BMB psf x (moment due to soil pressure -
  moment due to wt. of slab TB
• 1.5 147.8 x 1.22/2 (166.61 - 147.8) x 1.2
  (2/3 x 1.2)
• -(25x 1.2 x 0.45 x 1.2/2) 174.57 kN-m.
• Mu/bd2 1.14 lt 2.76, URS

24
b) Design of Toe slab- Contd.,

• To find steel
• pt0.34 lt0.96, A st 1326 mm2, 16 _at_150
• However, provide 16 _at_110 from shear
  considerations.
• Area provided 1827 mm2 , pt0.47
• Development length 47 x 16750 mm
• Distribution steel 0.12 x 1000 x 450/100 540
  mm2
• Provide 12 mm at 200 mm c/c.
• Area provided 565 mm2

25
Check for Shear

• Critical section for shear At distance d ( 390
  mm) from the face of the toe
• pE 80.39 (166.61 - 80.39) (4.3 0.39)/5.5
• 153.9kN/m2
• Net vertical shear
• (166.61 153.9) x 0.81/2 - (25 x 0.45 x 0.81)
  120.7 kN.
• Net ultimate shear Vu.max 1.5 x 120.7 181.05
  kN.
• ?v 181.05x 1000/1000x390 0.46 MPa
• pt 100 x 1827/ (1000 x 390) 0.47
• ?uc 0.36 (0.48 - 0.36) x 0.22/0.25
• 0.47N/mm2 gt ?vsafe

d
26
(c) Design of Heel Slab

• Continuous slab.
• ? Consider 1 m wide strip near the outer edge D
• The forces acting near the edge are
• Downward wt. of soil18x7.8xl 140.4 kN/m
• Downward wt. of heel slab 25 x 0.45 x 1 11.25
  kN/m
• Upward soil pressure 80.39 kN/m2 80.39 x 1
  80.39 kN/m
• ? Net down force at D 140.4 11.25 - 80.39
  71.26 kN/m
• Also net down force at C 140.4 11.25 - 143.9
  7.75 kN/m
• Mu (psf) pl2 /12 1.5 x 71.26 x 2.62/12 60.2
  kN-m (Near junction of CF)

27
Forces on heel slab
28

• To find steel
• Mu/bd260.2x106/(1000x3902) 0.39 lt 2.76, URS
• To find steel
• pt0.114 lt0.12GA (Min.), lt0.96,
• Provide 0.12 of GA
• Ast 0.12x1000x450/100 540 mm2
• Provide 12 mm _at_ 200 mm c/c,
• Area provided 565 mm2
• pt 100 x 565/ (1000 x 390) 0.14

29
Check for shear (Heel slab)

• Maximum shear Vu,max 1.5 x 71.26 x 2.6/2
  139 kN
• For Pt, 0.14 and M20 concrete, ?uc 0.28
  N/mm2
• ?v Vumax/bd 0.36 N/mm2 , Shear steel is needed
  
• Using 8 mm 2-legged stirrups,
• Spacing0.87x415x100/(0.36-0.28)x1000
• 452 mm lt (0.75 x 390 290 mm or 300 mm )
• Provide 8 mm 2-legged stirrups at 290 mm c/c.
• Provide for 1m x 1m area as shown in figure

30
(No Transcript)
31

• Area of steel for ve moment
• (Heel slab)
• Maximum ve ultimate moment psf x pl2/16
• 3/4 Mu 0.75 x 60.2 45.15 kN-m.
• Mu/bd2Very small and hence provide minimum
  steel.
• Ast,min 540 mm2
• Provide 12 mm bars at 200 mm c/c.
• Area provided 565 mm2 gt 540 mm2

32

• Check the force at junction of heel slab with
  stem
• The intensity of downward force decreases due to
  increases in upward soil reaction. Consider m
  width of the slab at C
• Net downward force 18 x 7.8 25 x 0.45 - 143.9
  7.75 kN/m. ? Provide only minimum reinforcement.
• Distribution steel
• Ast 0.12 x 1000 x 450/100 540 mm2
• Using 12 mm bars, spacing 1000 x 113/468
  241 mm.
• Provide 12 mm at 200 mm c/c.
• Area provided 565 mm2

33
(d) Design of Stem (Vertical Slab).

• Continuous slab spanning between the counterforts
  and subjected to earth pressure.
• The intensity of earth pressure
• ph ka ?h 18 x 7.8/346.8 kN/m2
• Area of steel on earth side near counterforts
• Maximum -ve ultimate moment,
• Mu 1.5 x ph 12/12 1.5 x 46.8 x 2.62/12
  39.54 kN.m.
• Required d v (39.54 x 106/(2.76 x 1000)) 119
  mm
• However provide total depth 250 mm
• Mu/bd2 39.54x106/1000x39021.1 lt 2.76, URS

34

• To find steel Pt0.34 lt0.96,
• Ast646 mm2, 12 mm _at_ 170 mm c/c,
• However provide 12 mm _at_ 110 mm c/c,
• Area provided 1027.27 mm2,Pt 0.54 .
• As the earth pressure decreases towards the top,
  the spacing of the bars is increased with
  decrease in height.
• Max.ult. shear Vumax 1.5 x 46.8 x 2.6/2
  91.26 kN
• For Pt, 0.54 and M20 concrete ?uc 0.5 N/mm2
  
• ?v Vumax/bd 91.28 x1000/(100X190)0.48 N/mm2,
• Shear steel is not needed and hence safe.

35
(e) Design of Counterfort

• At any section at any depth h below the top,
  the total horizontal earth pressure acting on
  the counterfort
• 1/2 kay h2x c/c distance between counterfort
• 18 x h2 x 3 x 1/6 9 h2
• ?B.M. at any depth h 9h2xh/3 3h3
• B.M. at the base at C 3 x 7.83 1423.7 kN.m.
• Ultimate moment Mu 1.5 x 1423.7 2135.60
  kN.m.
• Counterfort acts as a T-beam.
• Even assuming rectangular section,
• d v(2135.6 x 106(2.76 x 400)) 1390 mm

36
The effective depth is taken at right angle to
the reinforcement. tan ? 7.8/4.05 1.93, ?
62.5, ? d 4050 sin ? - eff. cover 3535 mm
gt gt 1390 mm Mu/bd22135.6x106/(400x35352) 0.427,
pt0.12, Ast1696mm2 Check for minimum steel
37

• Ast.min 0.85 bd/fy 0.85 x 400 x 3535/415
  2896 mm2
• Provided 4- 22 mm 4 - 22 mm,
• Area provided 3041 mm2
• pt 100 x 3041/(400 x 3535) 0.21
• The height h where half of the reinforcement can
  be curtailed is approximately equal to vH
  v7.82.79 m
• Curtail 4 bars at 2.79-Ldt from top i.e,
  2.79-1.03 1.77m from top.

38
Design of Horizontal Ties

• The direct pull by the wall on counterfort for 1
  m height at base
• ka?h x c/c distance 1/3x18 x 7.8 x 3 140.4
  kN
• Area of steel required to resist the direct pull
• 1.5 x 140.4 x 103/(0.87 x 415) 583 mm2 per m
  height.
• Using 8 mm 2-legged stirrups, Ast 100 mm2
• spacing 1000 x 100/583 170 mm c/c.
• ? Provide 8 at 170 mm c/c.
• Since the horizontal pressure decreases with h,
  the spacing of stirrups can be increased from 170
  mm c/c to 450 mm c/c towards the top.

39
Design of Vertical Ties

• The maximum pull will be exerted at the end of
  heel slab where the net downward force 71.26
  kN/m.
• Total downward force at D
• 71.26 x c/c distance bet. CFs 71.28 x 3
  213.78 kN.
• Required Ast 1.5 x 213.78 x 103/(0.87 x 415)
  888 mm2
• Using 8 mm 2-legged stirrups , Ast 100 mm2
• spacing 1000 x 100/888 110 mm c/c.
• ?Provide 8 mm 2-legged stirrups at 110 mm c/c.
• Increase the spacing of vertical stirrups from
  110 mm c/c to 450 mm c/c towards the end C

40
Cross section between counterforts
41
Cross section through counterforts
42
(No Transcript)
43
Backfill
Backfill
Cross section of heel slab
44
Thank you very much Good day Dr. M. C. Nataraja