The beam shown below is made of an alloy of titanium that has a stress-strain diagram that can in part be approximated by two straight lines. If the material behaviour is the same in both tension and compression, determine the bending moment that can be applied to the beam that will cause the material at the top and bottom of the beam to be subjected to a strain of 0.050 mm/mm 3 cm M 2 cm σ (MPa) 1330 1050 σ = 105(10¹) € σ= 7000€ + 980 0.010 0.050 -€ (mm/mm)

The beam shown below is made of an alloy of titanium that has a stress-strain diagram that can in part be approximated by two straight lines. If the material behaviour is the same in both tension and compression, determine the bending moment that can be applied to the beam that will cause the material at the top and bottom of the beam to be subjected to a strain of 0.050 mm/mm 3 cm M 2 cm σ (MPa) 1330 1050 σ = 105(10¹) € σ= 7000€ + 980 0.010 0.050 -€ (mm/mm)

Materials Science And Engineering Properties

1st Edition

ISBN:9781111988609

Author:Charles Gilmore

Publisher:Charles Gilmore

Chapter6: Introduction To Mechanical Properties

Section: Chapter Questions

Problem 36CQ

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Concept explainers

Bars

In civil engineering, bars refer to steel reinforcement bars or rebars. These are structural members primarily used for reinforcement purposes in masonry works. A bar is characterized by its cross-sectional area, which is negligible compared to its length. Bars are usually manufactured by steel which is uniform throughout the length, or by meshing multiple steel wires. Other materials of the bar include carbon steel, glass fiber, carbon fiber, and basalt fiber. The reinforcing bars are coated with epoxy resins and other materials to enhance some of their properties including corrosion resistance.

Question

Q4 The beam shown below is made of an alloy of titanium that has a stress-strain diagram that can in part
be approximated by two straight lines. If the material behaviour is the same in both tension and
compression, determine the bending moment that can be applied to the beam that will cause the
material at the top and bottom of the beam to be subjected to a strain of 0.050 mm/mm
3 cm
2 cm
σ(MPa)
1330
1050
σ = 105(10¹) €
σ= 7000€ +980
0.010
gaizu
201
0.050
€ (mm/mm)

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