Explanation Calculation: Refer to sample problem 6.6 in the text book. Combined stress along the vertical leg, τ e = 3 P ( a − y ) ( a + 5 y ) 4 t a 3 . Combined stress along the horizontal leg, τ f = 3 P ( a − z ) ( a − 3 z ) 4 t a 3 . Calculate the value of ∫ q d z along the horizontal leg of the angle as shown below. ∫ q d z = ∫ 0 a τ f t d z Substitute 3 P ( a − z ) ( a − 3 z ) 4 t a 3 for τ f . ∫ q d z = ∫ 0 a 3 P ( a − z ) ( a − 3 z ) 4 t a 3 × t d z = 3 P 4 a 3 ∫ 0 a ( a 2 − a z − 3 a z + 3 z 2 ) d z = 3 P 4 a 3 ∫ 0 a ( a 2 − 4 a z + 3 z 2 ) d z = 3 P 4 a 3 ( a 2 z − 4 a z 2 2 + 3 z 3 3 ) 0 a = 3 P 4 a 3 ( a 3 − 2 a 3 + a 3 − 0 ) = 0 Hence, ∫ q d z = 0 along the horizontal leg of the angle is proved

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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Combined Loading

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 6.6, Problem 79P

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Show that ∫q dz=0 along the horizontal leg of the angle and ∫q dy=P along its vertical leg.

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Chapter 6.6, Problem 78P

Chapter 6.6, Problem 80P

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Chapter 6 Solutions

Mechanics of Materials, 7th Edition

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Show that ∫ q d z = 0 along the horizontal leg of the angle and ∫ q d y = P along its vertical leg.

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Show that ∫q dz=0 along the horizontal leg of the angle and ∫q dy=P along its vertical leg.

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Chapter 6 Solutions