Explanation The effective length of the steel rod is L e = 0.9 m . The diameter of the steel rod is d = 60 mm . The allowable yield stress is σ Y = 250 MPa . The modulus of elasticity of the steel rod is E = 200 GPa . The eccentricity of the load is e = 40 mm . Find the cross sectional area of the steel rod ( A ) using the equation. A = π d 2 4 Here, the diameter of the steel rod is d . Substitute 60 mm for d . A = π × 60 2 4 = 2 , 827.433 mm 2 Find the moment of inertia of the steel rod ( I ) using the equation. I = π d 4 64 Substitute 60 mm for d . I = π × 60 4 64 = 636 , 172.5124 mm 4 Find the minimum radius of gyration ( r ) using the relation. r = I A Substitute 636 , 172.5124 mm 4 for I and 2 , 827.433 mm 2 for A . r = 636 , 172.5124 2 , 827.433 = 15 mm Find the distance between the neutral axis to the extreme fibre ( c ) using the relation. c = d 2 Substitute 60 mm for d . c = 60 2 = 30 mm Find the slenderness ratio L r using the equation. L r = 4.71 E σ Y Here, the modulus of elasticity of the material is E and the allowable yield strength is σ Y Substitute 200 GPa for E and 250 MPa for σ Y L r = 4.71 200 GPa × 1,000 MPa 1 GPa 250 = 133.22 Find the ratio of the effective length to the minimum radius of gyration. L e r = 0.9 m × 1,000 mm 1 m 15 = 60 < L r = 133.22 Find the effective stress ( σ e ) using the equation. σ e = π 2 E ( L e / r y ) 2 Substitute 200 GPa for E and 60 for L e / r y

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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Axial Load

When a bar of the uniform cross-section is acted by a load, such that the load acts along the longitudinal axis of the bar, such kinds of loadings are known as axial loadings. In general terms, a load is an external force acting on a component. An axial …

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Chapter 10.4, Problem 90P

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Find the allowable load P.

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Chapter 10.4, Problem 89P

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Chapter 10 Solutions

Mechanics of Materials, 7th Edition

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Solution Summary: The author calculates the allowable load P and the cross sectional area of the steel rod ( A ) using the equation.

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