The 3/4" bolts holding the steel plates together below can withstand a maximum shear stress of 36 ksi (kips/in^2). What is the maximum load, P, that can be applied to the plates before the bolts will fail? 1) Find the area of one bolt. 2) Find the total area of the bolts that resist the shear. This can be increased by the number of bolts and the number of cutting planes. 3) Rearrange the shear stress equation so you are solving for Load instead of stress. 4) Use the rearranged equation, the total area you found, and the provided allowable shear stress to find the maximum load. 5) Compare your answer: 31.81 kips or 31,807 Ibs Sheared surface - P (a) Joint (b) Sheared bolts

The 3/4" bolts holding the steel plates together below can withstand a maximum shear stress of 36 ksi (kips/in^2). What is the maximum load, P, that can be applied to the plates before the bolts will fail? 1) Find the area of one bolt. 2) Find the total area of the bolts that resist the shear. This can be increased by the number of bolts and the number of cutting planes. 3) Rearrange the shear stress equation so you are solving for Load instead of stress. 4) Use the rearranged equation, the total area you found, and the provided allowable shear stress to find the maximum load. 5) Compare your answer: 31.81 kips or 31,807 Ibs Sheared surface - P (a) Joint (b) Sheared bolts

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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