11. As shown in the figure below, a rectangular beam is subjected to two concentrated forces. Calculate the maximal normal stress and maximal shear stress at point Q in the cross section cut at C using Mohr's circle. Q5² 1₂b with S mx (o= = y, and t = A 0.5m 400N C = 0.5m bh² -² (1-2)) 400N D 0.5m B 30 ↑h Q 50 150

11. As shown in the figure below, a rectangular beam is subjected to two concentrated forces. Calculate the maximal normal stress and maximal shear stress at point Q in the cross section cut at C using Mohr's circle. Q5² 1₂b with S mx (o= = y, and t = A 0.5m 400N C = 0.5m bh² -² (1-2)) 400N D 0.5m B 30 ↑h Q 50 150

Structural Analysis

6th Edition

ISBN:9781337630931

Author:KASSIMALI, Aslam.

Publisher:KASSIMALI, Aslam.

Chapter2: Loads On Structures

Section: Chapter Questions

Problem 1P

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Concept explainers

Methods to Determine Vertical Stress

The load applied to the soil is transferred to the underground. The presence of water at soil pores and solid grains above the soil are the primary components that are responsible for the effective load transfer. Due to the load acting, the internal component of the soil or the underground formations undergoes deformations or a tectonic shift. The amount of deformation depends upon the amount of load acting on the soil surface, which indeed, depends on the weight of everything present above the soil. Due to this, the underground soil element develops internal stresses which try to resist the tectonic changes.

Question

11. As shown in the figure below, a rectangular beam is subjected to two concentrated
forces. Calculate the maximal normal stress and maximal shear stress at point Q in the
cross section cut at C using Mohr's circle.
Q5%
with S=b² (1-4)
(0 =
==
mx
Iz
y, and t =
0.5m
400N
C
0.5m
400N
D
0.5m
B
30
Q
50
150

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