3.9: Additional problems

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George Kouretzis
The University of Newcastle, Australia via Council of Australian University Librarians Initiative

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3.9.1

You are called to verify Saint-Venant’s principle on the difference between the effects of two dissimilar yet statically equivalent loadings becoming negligible at sufficiently large distances from the loading. For that, you should calculate the vertical stress increment Δσ_z below the axis of an infinite strip pressure of magnitude q_ext= 100 kPa and width B = 2 m, and compare it with the corresponding value of Δσ_z due to a statically equivalent line load, Q_ext. Try the comparison at depths z = 1 m, z = 3 m and z= 9 m from the ground surface.

Diagram showing an external pressure q_ext=100 kPa, and a line load Q_ext acting on the surface of an elastic half-space. Three different points at depth z= 1m, 3m, and 9m underneath the axis of the line load are identified. — Additional problem 3.9.1. Problem description and input parameters.

Answer

Additional problem 3.9.1 Answers
z (m)	Δσ_z (strip pressure, kPa)	Δσ_z (line load, kPa)	Difference (Δσ_z_,line-Δσ_z_,strip)/Δσ_z_,line (%)
1.00	81.83	127.32	55.59
3.00	39.58	42.44	7.22
9.00	14.03	14.15	0.82

3.9.2

A line load of magnitude Q_ext = 100 kN/m is applied at 2 m from the crest of a 4 m-deep excavation, which is supported by a flexible retaining wall e.g., a sheet pile wall. Calculate the horizontal stress Δσ_x due to the external load acting on the wall at z = 1 m and z = 3 m from the top of the wall. Calculate the stresses again, considering this time a rigid retaining wall e.g., a basement reinforced concrete wall.

Additional problem 3.9.2. Problem description and input parameters.

Answer

Additional problem 3.9.2 Answers
z(m)	Δσ_x (flexible wall, kPa)	Δσ_x (rigid wall, kPa)
1.00	10.19	20.38
3.00	4.52	9.04

3.9.3

Two alternative routes are examined for a sewage pipeline, passing below locations A and B. You are the designers of the pipeline. Which one would you prefer, and why? Justify your answer.

Schematic showing a pipe underneath a circular pressure 200 kPa (left) and a strip pressure 200 KPa (right). The depth of the pipe is 16 m in both cases. — Additional problem 3.9.3. Problem description and input parameters.

Answer: Location A.

3.9.4

Calculate the vertical stress below the axis of the embankment shown below, at a depth z = 10 m.

Schematic illustrating a well-compacted fill of trapezoidal section with height 9m and crest with 10m. The inclination of the slopes is 2 horiz : 1 vert. A soil element is identified at the middle of the embankment, at depth 10m from the ground surface, and the additional vertical stress Δσ_z at that element is requested. — Additional problem 3.9.4. Problem description and input parameters.

Answer: Δσ_z= 136 kPa

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