A simply supported beam AB = 11 m has a hollow rectangular cross-section with 11 cm as width, 28 cm as depth and inner thickness as 1 cm is subjected to a point load of 5 N & 6 N acting at C and D respectively and a uniformly distributed load (UDL) of 9 N/m starts from mid-span and ends at the right support of the beam. Determine the maximum bending stress and the bending stress at 1 cm from the top. Take AC = 1 m & CD = 1 m. iv) Maximum Bending Moment (Please write the Maximum bending moment valve in "Nm") = v) Moment of Inertia, I = vi) Maximum bending stress = vii) Bending stress at 1 cm from the top =

A simply supported beam AB = 11 m has a hollow rectangular cross-section with 11 cm as width, 28 cm as depth and inner thickness as 1 cm is subjected to a point load of 5 N & 6 N acting at C and D respectively and a uniformly distributed load (UDL) of 9 N/m starts from mid-span and ends at the right support of the beam. Determine the maximum bending stress and the bending stress at 1 cm from the top. Take AC = 1 m & CD = 1 m. iv) Maximum Bending Moment (Please write the Maximum bending moment valve in "Nm") = v) Moment of Inertia, I = vi) Maximum bending stress = vii) Bending stress at 1 cm from the top =

Mechanics of Materials (MindTap Course List)

9th Edition

ISBN:9781337093347

Author:Barry J. Goodno, James M. Gere

Publisher:Barry J. Goodno, James M. Gere

Chapter5: Stresses In Beams (basic Topics)

Section: Chapter Questions

Problem 5.5.17P: A simple beam A B of a span length L = 24 ft is subjected to two wheel loads acting at a distance d...

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A simply supported beam AB = 11 m has a hollow rectangular cross-section with 11 cm as width, 28 cm as depth and inner thickness as 1 cm is subjected to a point load of 5 N & 6 N acting at C and D respectively and a uniformly distributed load (UDL) of 9 N/m starts from mid-span and ends at the right support of the beam. Determine the maximum bending stress and the bending stress at 1 cm from the top. Take AC = 1 m & CD = 1 m.

iv) Maximum Bending Moment (Please write the Maximum bending moment valve in "Nm") =

v) Moment of Inertia, I =

vi) Maximum bending stress =

vii) Bending stress at 1 cm from the top =

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