Principles of Foundation Engineering (MindTap Course List)
9th Edition
ISBN: 9781337705028
Author: Braja M. Das, Nagaratnam Sivakugan
Publisher: Cengage Learning
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Question
Chapter 17, Problem 17.6P
(a)
To determine
Find the factor of safety with respect to sliding and overturning of the gravity retaining wall.
(b)
To determine
Find the factor of safety with respect to sliding and overturning of the gravity retaining wall.
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Students have asked these similar questions
It was found that the backfill against a retaining wall (6 meters in height as shown in
Figure 3) has specify weight y= 16 kN/m³ when its water content w= 5 %, S = 0.12, its
internal friction angle was measured as 30° (take G,= 2.7 and xw = 10 kN/m³).
a. Predict distribution of lateral stress on this retaining wall along its depth in its “at
rest" state, and its resultant force.
b. Rain leads the backfill water content increase to 10% in its upper half, and
saturated in its lower half, find and plot its lateral stress and pore pressures along
its depth in an active state.
Problem 10
The backfill and foundation sand have unit weight of
y = 135 pcf and Ø = 38. The backfill has a slope of
17 degrees and resultant force Ra acts parallel to the
backfill slope as shown below. The friction angle
between the base of the wall and the foundation sand
is 8-2/30. The factor of safety against sliding and
overturning, respectively, are most nearly (neglect
passive pressure):
W=5,531 lb/ft
17°
Ra=2576 lb/ft
9.0
12.0'
17
5.54
2.5 1.5
A. 1.1 and 2.8
B. 1.3 and 3.8
C.
1.3 and 2.8
1.1 and 3.8
ABCD
5.0
1.5
4.0
Question 1:
You are designing a retaining wall at the construction site. The friction angle of sand backfill is 28". Define the active lateral earth pressure coefficient based on
Rankine's theory. Show your work and select the closest value:
a) 0.30
b) 0.35
c) 0.40
d) 0.50
Chapter 17 Solutions
Principles of Foundation Engineering (MindTap Course List)
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- 17.6 It is required to design a cantilever retaining wall to retain a 5.0 m high sandy backfill. The consultant suggests the dimensions and soil properties shown in Figure P17.6 and requires that the wall be checked for stability with respect to sliding and overturning based on the active earth pressures determined using 5.0 m 1.0 m FIGURE P17.6 1.5 m 0.5 m 1.0 m 1.0 m * 10° Sand y = 18.5 kN/m³ $' = 36° 10.5 marrow_forwardPlease solve 17.6 question in figurearrow_forwardA cantilever retaining wall of 8 meter height retains sand. The properties of sand are; e= 0.4, phi = 30 degree, G = 2.65, gamma_{w} = 9.8kN / (m^3) Using Rankine's theory, the active earth pressure at the base when the back fill is dry is?arrow_forward
- Given data: Depth of Clay layer =4Depth of Sand layer=2unit weight of clay kN/m3=23unit weight of sand kN/m3 =21Ø in both layers=30C´= 0arrow_forwardU The soil conditions adjacent to a rigid frictionless retaining wall are shown in the figure below. A surcharge pressure of 50 kN/m² is applied on the surface of the backfill. For Soil A above the water table, c' = 20 kN/m², '= 28°, y = 18 kN/m³ For Soil B below the water table, c' = 0, ' = 38°, y = 20 kN/m³ Calculate the maximum Rankine active earth pressure behind the wall and the resultant active force per unit length of the wall. Also determine the location of the resultant force. q = 50 kN/m² ↓↓↓↓ 后 Soil A Soil B 4 6 m 3 m GWT 12:04 PMarrow_forwardI need the answer as soon as possiblearrow_forward
- Determine the stability of the cantilever gravity retaining wall shown in figure below. The existing soil is a clay and the backfill is a coarse-grained soil. The base of the wall will rest on a 50-mm-thick, compacted layer of the backfill. The interface friction between the base and the compacted layer of backfill is 25.0°. Groundwater level is 8 m below the base. 1.0 m Batter 1:20 0.4 m 1.8 m 9, = 20 kPa 8⁰ Ysat = 18 kN/m³ cs = 25° 8 = 15⁰ Backfill Drainage blanket Y = 23.5 kN/m³ 3 m Existing soil 6.1 m 0.9 mi Ysat = 19 kN/m³ = 35° % = 25°arrow_forwardSoil with an internal angle of friction of 40° and a cohesion of 10 kPa is excavated to a depth of 6 m prior to the placement of a retaining wall. The stability of a trial wedge with a horizontal angle of 25° is being investigated. The soil above the wedge weighs 12 kN/m of wall. 12 kN/m 6 m as=25° What is most nearly the available shearing resistance along the indicated slip plane? O A. 70 kN/m B. 140 kN/m O C. 150 kN/m OD. 180 kN/marrow_forwardQuestion 2 For the gravity retaining wall (concrete) shown in figure below; if the angle B has changed to be 80°, Ø1= 29°; and a = 5° use Coulomb's theory to calculate the horizontal and vertical components of the active earth pressure. %! Y-18.5 kN/m :-32 5.7 m 5m 283 m P. 75 2.167 m 1.5 m 1.53 m 0.8 m 0.22 m - 18 KN/m 0.3 m 0,8 m :-24 3.5 m 30 KN/m?arrow_forward
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