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Concrete Retaining Wall to AS4678

Verified by the CalcTree engineering team on September 27, 2024.

This calculator designs a concrete retaining wall to ensure it can withstand earth pressures, surcharge loads and environmental factors. It determines the design capacities of the retaining wall to meet stability, bearing, and structural design requirements.
This calculation has been written in accordance with AS4678:2002.
Design checks for a retaining wall are not explicitly stated in AS4678. The design methods presented below are based on Advanced Soil Mechanics by Braja M. Das and Module 6: Earthquake resistant retaining wall design published by the New Zealand Geotechnical Society.

Summary 
Design Check
Parameter
Utilisation
Status
Sliding
Sliding Force= 189.061759 kilonewton
0.60
🟢
Overturning
Overturning Moment= 519.659623 kilonewton * meter
1.37
🔴
Bearing Pressure
Bearing pressure= 85.698726 kilopascal
0.34
🟢

Calculation

Technical notes

1. Properties

1.1 Classifications

1.1.1 Risk Classification



Risk Class
:B


Table 1.1

1.1.2 Backfill Soil Condition



Soil Condition
:Controlled fill class I


Cl 1.4.3

1.1.3 Design Factors



Φn
:1.00


Table 5.2


Φs
:0.80


Appendix J3


1.2 Materials

1.2.1 Soil

Retained soil:


gamma1
:18.0 kN / m^3



phi1
:30.0 degrees


Backfill soil:


Consider Passive Pressure
:No



gamma2
:18.0 kN / m^3



phi2
:30.0 degrees


Ground base:


sigma_adm
:150.0 kPa



friction_coefficient
:0.548



1.2.2 Concrete



f'c
:40MPa



concrete density
:25.0 kN / m^3



1.3 Geometry

Stem wall:


hw
:3.00 m



t1
:200 mm



t2
:200 mm



B
:1.00 m

Base:


Lheel
:0.90 m



Ltoe
:2.80 m



hf
:400 mm

Key:


Use key
:Yes



hk
:300 mm



Lk
:300 mm



Xk
:2.00 m

Soil:


beta
:0.0 degrees



hs
:40.00 cm

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2. Loads

2.1 Dead Loads

2.1.1 Soil Loads

Lateral forces:


Consider Passive Pressure
:No



Φuφ
:0.95


Table 5.1(A)


φ*1
:28.74 degrees



φ*2
:0.50 rad




Eq. 5.2(2)


Ka
:0.351






Kp
:2.853






pa
:21.45 kPa





Fa
:36.47 kN






pp
:56.49 kPa






Fp
:0.00 N




Vertical forces:


Retained soil area
:2.70 m^2



Ws1
:48.60 kN






Backfill soil area
:1.12 m^2



Ws2
:20.16 kN






2.1.2 Concrete Loads

To calculate the dead loads, the entire structure of the concrete retaining wall was considered, including the stem wall, toe slab, heel slab, and key. The total volume of concrete was determined by multiplying the cross-sectional area of the wall's profile by its width.


Retaining wall area
:2.25 m^2



Wc
:56.25 kN




2.2 External Loads

2.2.1 Surcharge

The active pressure from external (surcharge) loads is determined as an equivalent pressure with a uniform distribution along the height of the soil.
The equivalent active pressure

due to surcharge, and the equivalent force applied at

from the top of the retained soil is given by:

pa=KaSFa=paH1p_a = K_aS \hspace{1cm} F_a = p_aH_1
Where:
  1. 
    
    : Active pressure coefficient due to retained soil
  1. 
    
    : Surcharge load
  2. 
    
    : Total height of wall, including base thickness
Surcharge loads and the pressure distribution on a retaining wall



DL
:0.0 kPa



LL
:3.0 kPa




LL_min
:5.0 kPa


Table 4.1
Lateral forces:


pa_DL
:0.00 kPa






pa_LL
:1.75 kPa






Fa_DL
:0.00 kN






Fa_LL
:5.96 kN




Vertical forces:


W_DL
:0.00 kN






W_LL
:4.50 kN






3. Design Checks

The below design checks follow the procedures outlined in Advanced Soil Mechanics by Braja M. Das.

3.1 Sliding Check

The sliding check is described in AS4678 as "Limit Mode U1" and refers to sliding failure within or at the base of the retaining structure. This occurs when the sliding forces on the wall exceed the resisting lateral forces, causing the wall to slide horizontally.
Sliding forces are caused by:
  1. active soil pressure due to retained soil
  2. active pressure from surcharge loads at top of the wall
Resisting (lateral) forces are caused by:
  1. passive resistance from the passive soil pressure of backfill soil, which can be enhanced by the addition of a key
  2. frictional resistance from the friction between the base of the wall and the founding soil
Sliding of a cantilevered wall

The design action for limit mode U1 (sliding)

is given by:

SU1=1.25Fa+1.25Fa,DL+1.5Fa,LLSU_1 = 1.25F_a + 1.25F_{a, DL}+ 1.5F_{a,LL}
Where:
  1. 
    
    : Active soil pressure force due to retained soil
  1. 
    
    : Active surcharge force due to additional dead and live loads, respectively
The design resistance for limit mode U1 (sliding)

is given by:

RU1=μV+FpRU_1 = \mu V + F_p
Where:
  1. 
    
    : Friction coefficient of base soil material
  2. 
    
    : Sum of vertical Forces, including the surcharge loads
    
    , self-weight of wall
    
    , self-weight of retained soil
    
    and self-weight of backfill soil
    
    
  3. 
    
    : Passive soil pressure force due to backfill soil, where the addition of a key on the retaining wall increases this resisting passive soil force
Sliding forces:


SU1
:54.53 kN




Resisting (lateral) forces:


V
:129.51 kN






RU1
:75.47 kN






Sliding check
:ϕSU1 > RU1 🟢 Ok






3.2 Rotation Check

The rotation check is described in AS4678 as "Limit Mode U2" and refers to the rotation of the retaining structure, where the wall tends to overturn around its toe due to lateral forces. This occurs when the overturning moments on the wall, exceed the restoring moments.
Overturning moments are caused by:
  1. active soil pressure due to retained soil
  2. active pressure from surcharge loads at top of the wall
  3. self-weight of backfill soil on the wall's toe
Restoring moments are provided by:
  1. self-weight of the wall
  1. self-weight of retained soil on the wall's heel
  1. passive soil pressure due to backfill soil
  2. vertical component of surcharge loads at top of the wall
Rotation of a cantilevered wall about it's base

The design action for limit mode U2 (rotation)

is given by:

SU2=1.25Ms,a+1.25Ms2,SW+1.25Ma,DL+1.5Ma,LL\small SU_2 = 1.25M_{s,a} + 1.25M_{s_2,SW} + 1.25M_{a,DL} + 1.5M_{a,LL}
Where:
  1. 
    
    : Overturning moment
    
    
  1. 
    
    : Active soil pressure moment from the retained soil, with a lever arm of
    
    from base of footing
  2. 
    
    : Active surcharge moment due to additional dead and live loads, respectively, with a lever arm of
    
    from base of footing
  1. 
    
    : Moment from the self-weight of the backfill soil, with a lever arm of
    
    from base of footing
The design resistance for limit mode U2 (rotation)

is given by:

RU2=Ms1,SW+MDL+MLL+Mp+Mw,SW\small RU_2 = M_{s_1,SW} + M_{DL} + M_{LL} + M_p + M_{w, SW}
Where:
  1. 
    
    : Restoring moment
    
    
  1. 
    
    : Moment from the self-weight of the retained soil, with a lever arm of
    
    from base of footing
  1. 
    
    : Moment from vertical component of surcharge loads, due to additional dead and live loads, respectively, with a lever arm of
    
    from base of footing
  1. 
    
    : Passive soil pressure moment from the backfill soil, with a lever arm of
    
    from base of footing
  1. 
    
    : Moment from the self-weight of the retaining wall, including the stem, toe and heel. The lever arm is calculated automatically using Python's library Shapely
Overturning moments:


Ms,a
:41.33 kN m






Ms2,SW
:50.40 kN m






Ma,DL
:0.00 kN m






Ma,LL
:10.13 kN m






SU2
:127.33 kN m




Restoring moments:


Ms1,SW
:167.67 kN m






M,DL
:0.00 kN m






M,LL
:15.53 kN m






Ms,p
:0.00 kN m






Mw,SW
:124.39 kN m






RU2
:307.58 kN m






Overturning check
:ϕSU2 > RU2 🟢 Ok






3.3 Settlement Check

The settlement check is described in AS4678 as "Limit Mode S3" and refers to the settlement of the structure, where the retaining wall sinks into the founding soil. This occurs when the vertical loads from the wall, backfill, and surcharge exceed the allowable bearing capacity of the foundation soil. When the applied pressure surpasses the soil's ability to support the load, the soil compresses, leading to differential or uniform settlement.
In Limit Mode S3, no reduction coefficient is applied for stability and resistance actions since it pertains to a serviceability check.
Settlement of a cantilevered wall

The design action for limit mode S3 (settlement) is given by the pressure applied to the soil beneath a retaining wall

due to serviceability actions:

SS3=σu=VAf+McISS3=\sigma_u = \dfrac{V}{A_f} + \dfrac{Mc}{I}
Where:
  1. 
    
    : Vertical serviceability actions
  2. 
    
    : Footing Area
  3. 
    
    : Flexural Moment due to serviceability actions
  4. 
    
    : Distance from the neutral axis to the most distanced fibre in compression/tension
  5. 
    
    : Footing inertia
Note,

accounts for the combined effect of the vertical forces and the pressure induced by the resultant flexural moment.
The design resistance for limit mode S3 (settlement) is given by:

RS3=σadmRS3 = \sigma_{adm}
Where:
  1. 
    
    : Allowable bearing pressure for supporting soil base which is a soil property defined in section 1.2 of this calculator


V
:129.51 kN






Af
:3.90 m^2






M
:205.72 kN m






c
:1.95 m






I
:4.94 m^4






SS3
:114.36 kPa






RS3
:150.00 kPa






Settlement check
:SS3 > RS3 🟢 Ok







Related Resources

  1. Concrete Slab-on-grade Designer to AS3600
  2. Rectangular Footing Design to AS3600
  3. Concrete Shear Wall to AS3600