Concept explainers
For the following cases, determine the allowable gross vertical load-bearing capacity of the foundation. Use Terzaghi’s equation and assume general shear failure in soil. Use FS = 4.
Parameters for Problem 6.1
a)
Find the allowable gross vertical load-bearing capacity of the continuous foundation.
Answer to Problem 6.1P
The allowable gross vertical load-bearing capacity of the continuous foundation is
Explanation of Solution
Given information;
The width (B) of the foundation is 3 ft.
The depth
The angle of friction
The cohesion
The specific weight
The factor of safety is (FS) is 4.0.
Calculation:
Refer Table (6.1), “Terzaghi’s bearing capacity factors” in the text book.
For
Take the value of
Take the value of
Take the value of
Determine the ultimate load bearing capacity
Determine the allowable gross vertical load-bearing capacity
Hence, the allowable gross vertical load-bearing capacity
b)
Find the allowable gross vertical load-bearing capacity of the continuous foundation.
Answer to Problem 6.1P
The allowable gross vertical load-bearing capacity of the continuous foundation is
Explanation of Solution
Given information;
The width (B) of the foundation is 1.5 m.
The depth
The angle of friction
The cohesion
The specific weight
The factor of safety is (FS) is 4.0.
Calculation:
Refer Table (6.1), “Terzaghi’s bearing capacity factors” in the text book.
For
Take the value of
Take the value of
Take the value of
Determine the ultimate load bearing capacity
Determine the allowable gross vertical load-bearing capacity
Hence, the allowable gross vertical load-bearing capacity
c)
Find the allowable gross vertical load-bearing capacity of the square foundation.
Answer to Problem 6.1P
The allowable gross vertical load-bearing capacity of the square foundation is
Explanation of Solution
Given information;
The width (B) of the foundation is 3.0 m.
The depth
The angle of friction
The cohesion
The specific weight
The factor of safety is (FS) is 4.0.
Calculation:
Refer Table (6.1), “Terzaghi’s bearing capacity factors” in the text book.
For
Take the value of
Take the value of
Take the value of
Determine the ultimate load bearing capacity
Determine the allowable gross vertical load-bearing capacity
Hence, the allowable gross vertical load-bearing capacity
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Chapter 6 Solutions
Principles of Foundation Engineering (MindTap Course List)
- 2 ft 2 ft 24 ft 24 ft 24 ft Problem 4 B D E F G | 3 ft DL=100 kip DL=180 kip LL = 60 kịp LL = 120 kip DL=190 kip DL=110 ki • The plan of a mat foundation with column loads is shown in Figure 2. Use the rigid method to calculate the soil pressures at point A, B, C, D, E, F, G, H, , J, K, L, M and N. The size of the mat is 76 ft x 96 ft, all columns are 24 in x 24 in in section, and qlnet = 1.5 kip/ft². Verify that the soil pressures are less than the net allowable bearing capacity. LL = 120 kip LL = 70 ki 30 ft DL=180 kip DL=400 kip DL=200 kip LL = 250 kip LL = 120 kip DL=360 kip LL = 120 kip LL = 200 kip ex 30 ft DL-190 kip DL=500 kip LL = 130'kip LL = 240 kip DL=T10 kip DL=200 kip LL =300 kip LL =120 kip 30 ft DL=180 kip DL=120 kip LL =120 kip L =70 kip x' 3 ft IDL=120 kip DL=180 kip ILL =70 kip LL =120 kip J Figure 2: Plan of a Mat Foundation M L K Harrow_forwardFor the following cases, determine the allowable gross vertical load-bearing capacity of the foundation. Use Terzaghi’s equation and assume general shear failure in soil. Use FS = 4.arrow_forwardA square shallow foundation (B × B) is planned to be constructed on a normality consolidated (NC) clay soil as shown in the below figure. The maximum acceptable settlement for the foundation is equal to 2.0 inches (5 cm), and the safety factor against bearing capacity is FS = 4. Determine the size of foundation. (Note: To simplify the calculations, ignore both the elastic settlement and secondary compression settlement. Also consider Ao'ave = 4o'm) Q = 500 kN Ysat = 19.24 kN/m³ eo = 0.8 C. = 0.25 p'= 0 c' = 25 kPa FS again Bearing Capacity = 4 Acceptable settlement = 2.0 inches 2 m В ХВ 10 marrow_forward
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