FL b FL What is the change in length (L) of the titanium bar (E = 16.5E6 psi) given: L = 36 in., b = 3 in., h = 0.25 in, and F = 3 kips Answer to above question is 8.72E-3 in, the shear modulus for the bar is 6.145E6 psi, poisons ratio is 0.343. My question is what is the strain (in macrostrain) in the bar in a direction perpendicular to the direction of the applied force? (Answer is 82.8, I need to understand how to reach this answer.)
FL b FL What is the change in length (L) of the titanium bar (E = 16.5E6 psi) given: L = 36 in., b = 3 in., h = 0.25 in, and F = 3 kips Answer to above question is 8.72E-3 in, the shear modulus for the bar is 6.145E6 psi, poisons ratio is 0.343. My question is what is the strain (in macrostrain) in the bar in a direction perpendicular to the direction of the applied force? (Answer is 82.8, I need to understand how to reach this answer.)
Materials Science And Engineering Properties
1st Edition
ISBN:9781111988609
Author:Charles Gilmore
Publisher:Charles Gilmore
Chapter6: Introduction To Mechanical Properties
Section: Chapter Questions
Problem 6.2P
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Question
![L
b
F
What is the change in length (L) of the titanium bar (E = 16.5E6 psi) given:
L = 36 in., b = 3 in., h = 0.25 in, and F = 3 kips
Answer to above question is 8.72E-3 in, the shear modulus for the bar is 6.145E6 psi, poisons ratio is
0.343. My question is what is the strain (in macrostrain) in the bar in a direction perpendicular to the
direction of the applied force? (Answer is 82.8, I need to understand how to reach this answer.)](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2F9c895505-6d42-4185-883d-7c5b94979691%2F3d36e8ef-66ab-4282-a270-38ee312270a8%2F4fjmrrm_processed.jpeg&w=3840&q=75)
Transcribed Image Text:L
b
F
What is the change in length (L) of the titanium bar (E = 16.5E6 psi) given:
L = 36 in., b = 3 in., h = 0.25 in, and F = 3 kips
Answer to above question is 8.72E-3 in, the shear modulus for the bar is 6.145E6 psi, poisons ratio is
0.343. My question is what is the strain (in macrostrain) in the bar in a direction perpendicular to the
direction of the applied force? (Answer is 82.8, I need to understand how to reach this answer.)
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