Explanation Given information: The magnitude of the eccentric load is P = 48 kN . The diameter of the rod is d = 50 mm . The allowable stress in bending is ( σ all ) bending = 180 MPa . The eccentricity of the load in the member is e = 20 mm . Calculation: The effective length ( L e ) is equal to the length of the rod ( L ). L e = L Find the cross sectional area ( A ) of the rod using the equation. A = π d 2 4 Here, the diameter of the rod is d . Substitute 50 mm for d . A = π × 50 2 4 = 1 , 963.495 mm 2 Find the minimum moment of inertia ( I ) of the rod using the equation. I = π d 4 64 Substitute 50 mm for d . I = π × 50 4 64 = 306 , 796.1576 mm 4 Find the minimum radius of gyration ( r ) using the relation. r = I A Substitute 306 , 796.1576 mm 4 for I and 1 , 963.495 mm 2 for A . r = 306 , 796.1576 1 , 963.495 = 12.5 mm Find the ratio of the effective length to the minimum radius of gyration ( L e r ) ; L e r = L m × 1,000 mm 1 m 12.5 = 80 L For 2014 − T 6 aluminum alloy; For the ratio of L r ≥ 55 ; Calculate the allowable stress ( σ all ) centric due to centric load using the relation. ( σ all ) centric = 382 × 10 3 ( L e r ) 2 Substitute 80 L for L e r

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Author: BEER

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Chapter 10.4, Problem 102P

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Find the largest allowable effective length L.

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Chapter 10.4, Problem 101P

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Chapter 10 Solutions

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Solution Summary: The author calculates the largest allowable effective length L, which is equal to the length of the rod.

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