Problem 4. The 16 × 22 x 100-mm rubber blocks (E = 54.76 MPa and v = 0.48)shown in the figure are used in a double U shear mount to isolatethe vibration of a machine from its support. An applied load P causesthe upper frame to deflect.16 mm14. If the allowable deflection is 4 mm and the allowable shear stress is5.85 MPa determine the maximum load P that can be supported by22 mmthe rubber blocks.c. 20350.0 Nd. 10763.6 Na. 25437.5 Nb. 12870.0 N

Given: Length of the rubber block→L=100 mm Height of the rubber block→H=22 mm Allowable shear…

Problem 4. The 16 × 22 × 100-mm rubber blocks (E = 54.76 MPa and v = 0.48) shown in the figure are used in a double U shear mount to isolate the vibration of a machine from its support. An applied load P causes the upper frame to deflect. mm 14. If the allowable deflection is 4 mm and the allowable shear stress is 5.85 MPa determine the maximum load P that can be supported by 22 mm the rubber blocks. a. 25437.5 N c. 20350.0 N b. 12870.0 N d. 10763.6 N

Problem 4. The 16 × 22 × 100-mm rubber blocks (E = 54.76 MPa and v = 0.48) shown in the figure are used in a double U shear mount to isolate the vibration of a machine from its support. An applied load P causes the upper frame to deflect. mm 14. If the allowable deflection is 4 mm and the allowable shear stress is 5.85 MPa determine the maximum load P that can be supported by 22 mm the rubber blocks. a. 25437.5 N c. 20350.0 N b. 12870.0 N d. 10763.6 N

Mechanics of Materials (MindTap Course List)

9th Edition

ISBN:9781337093347

Author:Barry J. Goodno, James M. Gere

Publisher:Barry J. Goodno, James M. Gere

Chapter1: Tension, Compression, And Shear

Section: Chapter Questions

Problem 1.10.9P: A square steel tube of a length L = 20 ft and width b2= 10.0 in. is hoisted by a crane (see figure)....

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