Explanation Given information: The length of the shaft is 1.2 m. The diameter of the shaft is 18 mm. The yield shear stress is 145 MPa. The modulus of rigidity is 77.2 GPa . The Torque applied to the shaft is 200 N ⋅ m . Calculation: The radius value of the shaft is 9 mm. The polar moment of inertia of a shaft with radius c is, J = π 2 c 4 = π 2 ( 9 mm ) 4 = 1.0306 × 10 4 mm 4 = 1.0306 × 10 − 8 m 4 The expression for yield stress ( τ Y ) in the shaft is shown below: τ Y = T Y c J (1) Here, T Y is the maximum elastic torque and c is the radius of the shaft. Substitute 145 MPa for τ Y , 9 mm for c , and 1.0306 × 10 − 8 m 4 for J in Equation (1). 145 MPa = T Y ( 9 mm ) 1.0306 × 10 − 8 m 4 145 MPa × 10 6 Pa 1 MPa = T Y ( 9 mm × 10 − 3 m 1 mm ) 1.0306 × 10 − 8 m 4 T Y = 166.04 N ⋅ m The value of torque applied to the shaft is greater than the yield torque T ( 200 N ⋅ m ) > T Y ( 166.04 N ⋅ m ) . Therefore, the shaft contains a plastic zone. Thus the maximum shear stress is equal to the yield shear stress. Hence, the maximum shearing stress in the shaft is 145 MPa _ . The angle of twist at yield ( ϕ Y ) of the shaft is expressed as follows: ϕ Y = T Y L G J (2) Here, L is the length of the shaft and G is the modulus of rigidity

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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Torsion

In mechanical engineering, torque, torsion, and twisting moment are three of the most important concepts which have different meanings. Torque is the consequence of a moment of a force that produces an angular acceleration in a body or induces rotational…

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Chapter 3.8, Problem 102P

To determine

The maximum shearing stress in the shaft.

The angle of twist of the shaft.

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Chapter 3.8, Problem 101P

Chapter 3.8, Problem 103P

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Chapter 3 Solutions

Mechanics of Materials, 7th Edition

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The maximum shearing stress in the shaft. The angle of twist of the shaft.

Solution Summary: The author calculates the maximum shearing stress in the shaft, the angle of twist, and the polar moment of inertia.