Explanation Given information : The given beam has a rocker at point A and a pin support at B . It has an inclined member and the inclined angle ( θ ) is 30 ° . The length ( L 1 ) of inclined member is 3 meter and the length ( L 2 ) of straight member is 4 meter. A uniformly distributed load is acting throughout the span of 4 meters. Show the free body diagram of the beam as in Figure (1). Using Figure (1). Determine the normal reaction ( N A ) at A by taking moment about point B . ∑ M B = 0 w × L 2 × L 2 2 − N A sin θ ( L 1 sin θ ) − N A cos θ ( L 1 cos θ + L 2 ) = 0 (I) Determine reactions at point B using the equation of equilibrium. Apply the equation of equilibrium along the horizontal direction: ∑ F x = 0 N A sin θ − B x = 0 (II) Apply the equation of equilibrium along the vertical direction: ∑ F y = 0 B y + N A cos θ − w ( L 2 ) = 0 (III) Check for maximum intensity of load : Determine the resultant load F B . F B = ( B x ) 2 + ( B y ) 2 (IV) Show the calculation maximum load as follows. Conclusion: Substitute 4 m for L 2 , 30 ° for θ , and 3m for L 1 in Equation (I). w × 4.0 × 4.0 2 − N A sin ( 30 ° ) ( 3.0 sin 30 ° ) − N A cos 30 ° ( 3.0 cos 30 ° + 4.0 ) = 0 8 w − 0.75 N A − 5.71 N A = 0 8 w = 6

Engineering Mechanics: Statics & Dynamics (14th Edition)

14th Edition

ISBN: 9780133915426

Author: Russell C. Hibbeler

Publisher: PEARSON

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Chapter 5.4, Problem 23P

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The maximum intensity of the distributed load (w).

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Chapter 5.4, Problem 22P

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Chapter 5 Solutions

Engineering Mechanics: Statics & Dynamics (14th Edition)

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The maximum intensity of the distributed load ( w ).

Solution Summary: The author shows the free body diagram of the beam as in Figure (1). Determine reactions at point B using the equation of equilibrium.

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Chapter 5 Solutions