Two concentric springs are constructed with squared and ground ends from oil-hardened steel.The ultimate strength for the steel is 204,000 lbf/in². The steel's yield strength is to be estimated as75% of the ultimate strength. The shear modulus for the steel is 11.5 x 106 lbf/in². The springssupport a static force of 150 lbf. The spring dimensions andproperties are as follows:Inner springWire diameter: 0.177 inMean coil diameter: 1.5 inTotal number of coils: 12.75Free length: 4.5 inOuter springMean coil diameter: 2.0 inWire diameter: 0.2253 inFree length: 3.75 inTotal number of coils: 10.251. The deflection of the inner spring is most nearlyA. 2.0 inB. 2.4 inC. 2.9 inD. 3.1 in2.The maximum force exerted by the inner spring is most nearlyA. 57 lbfB. 67 lbfC. 79 lbfD. 86 lbf3. The maximum shear stress in the inner spring is most nearlyA. 47 kips/in²B. 52 kips/in²C. 57 kips/in² D. 64 kips/in²4. The factor of safety in shear for the inner spring is most nearlyA. 1.2B. 1.5C. 1.8D. 2.2Determine:

Given: The ultimate strength, Sut = 204,000 lbf/in^2 The yield strength of steel, Syt = 0.75Sut The…

Two concentric springs are constructed with squared and ground ends from oil-hardened steel. The ultimate strength for the steel is 204,000 lbf/in². The steel's yield strength is to be estimated as 75% of the ultimate strength. The shear modulus for the steel is 11.5 x 106 lbf/in². The springs support a static force of 150 lbf. The spring dimensions and properties are as follows: Inner spring Wire diameter: 0.177 in Mean coil diameter: 1.5 in Total number of coils: 12.75 Free length: 4.5 in Outer spring Wire diameter: 0.2253 in Free length: 3.75 in Mean coil diameter: 2.0 in Total number of coils: 10.25 1. The deflection of the inner spring is A. 2.0 in B. 2.4 in most nearly C. 2.9 in D. 3.1 in 2.The maximum force exerted by the inner spring is most nearly A. 57 lbf B. 67 lbf C. 79 lbf D. 86 lbf 3. The maximum shear stress in the inner spring is most nearly A. 47 kips/in² B. 52 kips/in² C. 57 kips/in² D. 64 kips/in² 4. The factor of safety in shear for the inner spring is most nearly A. 1.2 B. 1.5 C. 1.8 D.2.2 Determine:

Two concentric springs are constructed with squared and ground ends from oil-hardened steel. The ultimate strength for the steel is 204,000 lbf/in². The steel's yield strength is to be estimated as 75% of the ultimate strength. The shear modulus for the steel is 11.5 x 106 lbf/in². The springs support a static force of 150 lbf. The spring dimensions and properties are as follows: Inner spring Wire diameter: 0.177 in Mean coil diameter: 1.5 in Total number of coils: 12.75 Free length: 4.5 in Outer spring Wire diameter: 0.2253 in Free length: 3.75 in Mean coil diameter: 2.0 in Total number of coils: 10.25 1. The deflection of the inner spring is A. 2.0 in B. 2.4 in most nearly C. 2.9 in D. 3.1 in 2.The maximum force exerted by the inner spring is most nearly A. 57 lbf B. 67 lbf C. 79 lbf D. 86 lbf 3. The maximum shear stress in the inner spring is most nearly A. 47 kips/in² B. 52 kips/in² C. 57 kips/in² D. 64 kips/in² 4. The factor of safety in shear for the inner spring is most nearly A. 1.2 B. 1.5 C. 1.8 D.2.2 Determine:

Mechanics of Materials (MindTap Course List)

9th Edition

ISBN:9781337093347

Author:Barry J. Goodno, James M. Gere

Publisher:Barry J. Goodno, James M. Gere

Chapter2: Axially Loaded Members

Section: Chapter Questions

Problem 2.5.29P: A polyethylene tube (length L) has a cap that when installed compresses a spring (with under-formed...

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