(a) Explanation Given information: The value of yield stress is 145 MPa. The value of modulus of rigidity is 77.2 GPa . The torque applied to the shaft is 600 N ⋅ m . Calculation: The expression for maximum shear stress ( τ max ) in the shaft is shown below: τ max = T c J (1) Here, T is the maximum elastic torque, c is the radius of the shaft, and J is the polar moment of inertia of the shaft. The radius value of the shaft is 15 mm. The polar moment of inertia of a shaft with radius c is, J = π 2 c 4 = π 2 ( 15 mm ) 4 = 7.9522 × 10 4 mm 4 = 7.9522 × 10 − 8 m 4 Substitute 600 N ⋅ m for T , 15 mm for c , and 7.9522 × 10 − 8 m 4 for J in Equation (1). τ max = ( 600 N ⋅ m ) ( 15 mm ) 7 (b) To determine The maximum shearing stress in the shaft. The radius of the elastic core.

7th Edition

ISBN: 9780073398235

Author: Ferdinand P. Beer, E. Russell Johnston Jr., John T. DeWolf, David F. Mazurek

Publisher: McGraw-Hill Education

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Any functioning component, such as machine parts, structural members, pressure vessels, and so on, are all under the influence of more than one force. When anybody is under the influence of more than one force such as shear forces, bending moments, axial…

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Chapter 3.8, Problem 95P

(a)

To determine

The maximum shearing stress in the shaft.

The radius of the elastic core.

(b)

To determine

The maximum shearing stress in the shaft.

The radius of the elastic core.

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Chapter 3.8, Problem 94P

Chapter 3.8, Problem 96P

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Chapter 3 Solutions

Mechanics of Materials, 7th Edition

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The maximum shearing stress in the shaft. The radius of the elastic core.

Solution Summary: The author calculates the maximum shear stress in the shaft. The radius of the elastic core is underset_15mm.

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The maximum shearing stress in the shaft. The radius of the elastic core.

The maximum shearing stress in the shaft. The radius of the elastic core.

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Chapter 3 Solutions

The maximum shearing stress in the shaft.

The radius of the elastic core.

The maximum shearing stress in the shaft.

The radius of the elastic core.