Principles Of Foundation Engineering 9e
9th Edition
ISBN: 9781337705035
Author: Das, Braja M.
Publisher: Cengage,
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Question
Chapter 6, Problem 6.15P
(a)
To determine
Find the eccentricity and inclination of the load for foundation of case (a).
(b)
To determine
Find the eccentricity and inclination of the load for foundation of case (b).
(c)
To determine
Find the eccentricity and inclination of the load for foundation of case (c).
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An eccentrically loaded foundation is shown in Figure P3.9. Use FS of 4 and
determine the maximum allowable load that the foundation can carry. Use
Meyerhof's effective area method and the bearing capacity, shape, and depth
factors given in Section 3.6.
FIGURE P6.14
à.15
Three continuous foundations are shown in Figure P6.15.
For each of them, what values would you use for their
eccentricity and inclination in the bearing capacity
calculations?
ving:
500 kN/m
50 kN m/m
600 kN/m
500 mm
GL
300 mm
30 mm
500 mm
1500 mm
2000 mm
(b)
(a)
).
600 kN/m
5.11.
at
hod.
80 kN m/m
50 kN/m –
0.5 m
GL
0.5 m
1.0 m
0.5 m
1.0 m
(c)
FIGURE P6.15
Determine the increase in vertical stress at a depth of 5 mbelow the centroid of the foundation shown in Figure P7.21.
Chapter 6 Solutions
Principles Of Foundation Engineering 9e
Ch. 6 - For the following cases, determine the allowable...Ch. 6 - A 5.0 ft wide square footing is placed at 3.0 ft...Ch. 6 - Prob. 6.3PCh. 6 - Redo Problem 6.2 using the general bearing...Ch. 6 - The applied load on a shallow square foundation...Ch. 6 - A 2.0 m wide continuous foundation carries a wall...Ch. 6 - Determine the maximum column load that can be...Ch. 6 - A 2.0 m wide strip foundation is placed in sand at...Ch. 6 - A column foundation (Figure P6.9) is 3 m × 2 m in...Ch. 6 - For the design of a shallow foundation, given the...
Ch. 6 - An eccentrically loaded foundation is shown in...Ch. 6 - Prob. 6.12PCh. 6 - For an eccentrically loaded continuous foundation...Ch. 6 - A 2 m 3 m spread footing placed at a depth of 2 m...Ch. 6 - Prob. 6.15PCh. 6 - A tall cylindrical silo carrying flour is to be...Ch. 6 - A 2.0 m 2.0 m square pad footing will be placed...Ch. 6 - An eccentrically loaded continuous foundation is...Ch. 6 - A square foundation is shown in Figure P6.19. Use...Ch. 6 - The shallow foundation shown in Figure 6.25...Ch. 6 - Consider a continuous foundation of width B = 1.4...
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- Refer to Figure P5.5. Using the procedure outlined in Section 5.5, determine the average stress increase in the clay layer below the center of the foundation due to the net foundation load of 900 kNarrow_forwardAn eccentrically loaded continuous foundation is shown in Figure P6.18. Determine the ultimate load Qu per unit length that the foundation can carry. Use the reduction factor method [Eq. (6.67)]. 4 ft 2 ft Figure P6.18 Qu 2 ft → -5 ft Y = 105 lb/ft³ Groundwater table Ysat 118 lb/ft³ c' = 0 $' = 35° =arrow_forward5.8 An eccentrically loaded foundation is shown in Figure P5.8. Use FS of 4 and determine the maximum allowable load that the foundation can carry. Use Meyerhof's effective area method. 1.0 m (Eccentricity in one direction only) e = 0.15 m Call 1.5 m X 1.5 m Centerline Figure P 5.8 y = 17 kN/m³ c' = 0 o'= 36°arrow_forward
- A short rectangular post supports a compressive load of P = 210 kN as shown. A top view of the post showing the location where load P is applied to the top of the post is also shown. Determine the vertical normal stress at corner d of the post. -9.14 MPa -15.12 MPa -11.20 MPa -12.06 MPa -14.02 MPaarrow_forwardO A rectangular foundation 4 m × 6 m (Figure P7.20) trans- mits a stress of 100 kPa on the surface of a soil deposit. Plot the distribution of increases of vertical stresses with depth under points A, B, and C up to a depth of 20 m. At what depth is the increase in vertical stress below A less than 10% of the surface stress? B 6 m -2 m- A 2 m -4 m FIGURE P7.20arrow_forwardProblem 2: A rectangular foundation of 4m × 6m (as shown in Figure P2) transmits a stress of 150 kPa on the surface of a soil deposit. Plot the distribution of induced vertical stresses with depth under points A (the centre of the rectangle), B and C up to a depth of 20 m. 6m 4m A Figure P2 B 2m с 2marrow_forward
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- 1) (30 points) Find the stress beneath Point B of the 40 ft by 80 ft. L-Shaped flexible mat foundation at depth (Z) = 20 ft. deep. Mat load is 200 psf. 80' 20 200 psf 1401 20 60arrow_forwardA short rectangular post supports a compressive load of P = 175 kN as shown. A top view of the post showing the location where load P is applied to the top of the post is also shown. Determine the vertical normal stress at corner d of the post.arrow_forwardA 4.5m square foundation exerts uniform pressure of 200kn/m^2 on a soil . Determine 1:the vertical stress increment due to the foundation load to adepth of 10 m below its centre 2: the vertical stress increment at apoint 3m below the foundation and 4m from its centre along one of the axes of symmetryarrow_forward
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