Explanation Given information: The beam will fail when the maximum moment is M max = 30 kip-ft or the maximum shear is V max = 8 kip . Assumption: If a concentrated force acts upward in the beam, the shear will jump upward by the same amount. The change in the shear between the two points is equal to the area under the distributed loading curve between the points. Consider the force indicating the right side as positive and left side as negative in horizontal components of forces. Consider the force indicating upward is taken as positive and downward as negative in vertical components of forces. If a clockwise moment acts in the beam, the moment diagram will jump upward by the amount of the moment. Consider the distance x from the left end of the beam. Determine the reactions: Entire beam: Show the free body diagram of the entire beam as in Figure (1). Using Figure (1), Moment about the point A : Determine vertical reaction at point B by taking moment about point A . ∑ M A = 0 B y ( 6 ) + 1 2 × w × 6 × 1 3 × 6 − w × 6 × 6 2 = 0 (I) Along the vertical direction: Determine the vertical reaction at point A by resolving the vertical component of forces. ∑ F y = 0 A y + B y − 1 2 × w × 6 − w × 6 = 0 (II) Along the horizontal direction: Determine the horizontal reaction at point B by resolving the horizontal component of forces. ∑ F x = 0 B x = 0 Conclusion: Solve Equation (I). 6 B y + 6 w − 18 w = 0 6 B y = 12 w B y = 2 w Substitute 2 w for B y in Equation (II). A y + 2 w − 3 w − 6 w = 0 A y = 7 w Determine the shear force and moment: The substitution of reaction values and moment included in the calculation steps. Show the calculation of the shear force and bending moment as follows: Shear force: Shear force at x = 0 : V | x = 0 ( Just left ) = 0 V | x = 0 ( Just Right ) = 0 Shear force at x = 6 ft : V | x = 6 ft ( Just left ) = − 1 2 × w × 6 = − 3 w V | x = 6 ft ( Just right ) = − 3 w + A y = − 3 w + 7 w = 4 w Shear force at x = 10 ft : V | x = 10 ft ( Just left ) = 4 w − w × 4 = 0 V | x = 10 ft ( Just r

13th Edition

ISBN: 9780132915540

Author: Russell C. Hibbeler

Publisher: Prentice Hall

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Question

Chapter 7.3, Problem 83P

To determine

The largest distributed load w the beam will support.

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Chapter 7.3, Problem 82P

Chapter 7.3, Problem 84P

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