I need complete answer so plz make it perfect and easy to understand for me A cantilever sheet pile wall is required to support a temporary excavation, as shown inthe accompanying Figure. Using the available information, determine the depth ofpenetration of the wall into the stiff clay layer, and the anchor force per unit length ofthe wall (i.e. normal to the plane of the Figure). Assume the soil above the groundsurface to be fully saturated. In carrying out your calculations, consider two differentapproaches: (A) Apply a factor of safety FS on the overall passive resistance, which isusually taken at around 1.5 while using the nominal values for the strength parametersshown in the Figure. (B) Apply a mobilization factor Fo to the friction angle so thatthe design value is obtained from the nominal value as o 'design = p'er / Fo where themobilization factor is about 1.5. Likewise, in the second method the design undrainedshear strength is obtained from the corresponding nominal value as (Su), design= Su / Fuwhere the mobilization factor Fu is about 1.75. Compare the results between the twoapproaches. Also, discuss the most critical loading condition i.e., undrained (short-term) conditions using total stresses and c = Su , 9 = 0, or drained (long term)conditions using effective stresses and o = per', c=0. Justify your answers.1 mAnchor0,5 mSoft clay:6 mY= 18.8 kN/m³, o', = 30°, s, = 25 kPa,8 = 0°Stiff clayY =19.2 kN/m³, o', = 28°, s, = 100 kPa, 8= 0°Figure: design considered.

A cantilever sheet pile wall is required to support a temporary excavation, as shown in the accompanying Figure. Using the available information, determine the depth of penetration of the wall into the stiff clay layer, and the anchor force per unit length of the wall (i.e. normal to the plane of the Figure). Assume the soil above the ground surface to be fully saturated. In carrying out your calculations, consider two different approaches: (A) Apply a factor of safety FS on the overall passive resistance, which is usually taken at around 1.5 while using the nominal values for the strength parameters shown in the Figure. (B) Apply a mobilization factor F, to the friction angle so that the design value is obtained from the nominal value as o'design = 9'er / F, where the mobilization factor is about 1.5. Likewise, in the second method the design undrained shear strength is obtained from the corresponding nominal value as (Su), design = Su / Fu where the mobilization factor Fu is about 1.75. Compare the results between the two approaches. Also, discuss the most critical loading condition i.e., undrained (short- term) conditions using total stresses andc = Su , 9 = 0, or drained (long term) %3D

A cantilever sheet pile wall is required to support a temporary excavation, as shown in the accompanying Figure. Using the available information, determine the depth of penetration of the wall into the stiff clay layer, and the anchor force per unit length of the wall (i.e. normal to the plane of the Figure). Assume the soil above the ground surface to be fully saturated. In carrying out your calculations, consider two different approaches: (A) Apply a factor of safety FS on the overall passive resistance, which is usually taken at around 1.5 while using the nominal values for the strength parameters shown in the Figure. (B) Apply a mobilization factor F, to the friction angle so that the design value is obtained from the nominal value as o'design = 9'er / F, where the mobilization factor is about 1.5. Likewise, in the second method the design undrained shear strength is obtained from the corresponding nominal value as (Su), design = Su / Fu where the mobilization factor Fu is about 1.75. Compare the results between the two approaches. Also, discuss the most critical loading condition i.e., undrained (short- term) conditions using total stresses andc = Su , 9 = 0, or drained (long term) %3D

Principles of Foundation Engineering (MindTap Course List)

9th Edition

ISBN:9781337705028

Author:Braja M. Das, Nagaratnam Sivakugan

Publisher:Braja M. Das, Nagaratnam Sivakugan

Chapter18: Sheet-pile Walls

Section: Chapter Questions

Problem 18.5P: In Problem 18.4, find the maximum bending moment in the sheet pile and determine the required...

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