Explanation Assumption: The self-weight of the cable is ignored. The cable is perfectly flexible and inextensible. The tensile force acting in the cable is always tangent to the cable at points along its length. Being inextensible, the cable has a constant length both before and after the load is applied. The cable or a segment of the cable can be treated as a rigid body. Method of joints is used to determine the force in the cable. Consider the state of the member as tension where the force is pulling the member as compression where the force is pushing the member. 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. Consider clockwise moment as negative and anti-clock wise moment as positive wherever applicable. Apply Equation of equilibrium wherever applicable. Assume maximum tension in the cable is at BD . Segment ACD : Show the free-b0dy diagram of the segment ACD as in Figure (1). Using Figure (1), Determine the value of θ using the relation: tan θ = Opposite side Adjacent side (I) Moment about point A : Determine the tension in the BD by taking moment about point A . ∑ M A = 0 T B D cos θ 1 ( 3 ) + T B D sin θ 1 ( 7 ) − 50 ( 7 ) − P ( 3 ) = 0 (II) Along the vertical direction: Determine the vertical reaction at point A by resolving the vertical component of forces. ∑ F y = 0 T B D sin θ 1 − 50 − P + A y = 0 (III) Along the horizontal direction: Determine the horizontal reaction at point A by resolving the horizontal component of forces. ∑ F x = 0 T B D cos θ 1 − A x = 0 (IV) Conclusion: Substitute 5 ft for opposite side and 3 ft for adjacent side in Equation (I). tan θ 1 = 5 3 θ 1 = 59.04 ° Substitute 59.04 ° for θ 1 and 75 lb for T B D in Equation (II). 75 cos 59.04 ° ( 3 ) + 75 sin 59.04 ° ( 7 ) − 350 − P ( 3 ) = 0 115.75 + 450.20 − 350 − 3 P = 0 3 P = 215.95 P = 71.98 lb Substitute 75 lb for T B D , 59.04 ° for θ 1 , and 71.98 lb for P in Equation (III). 75 sin 59.04 ° − 50 − 71.98 + A y = 0 A y = 57.67 lb Substitute 75 lb for T B D and 59.04 ° for θ 1 in Equation (IV). 75 cos 59.04 ° − A x = 0 A x = 38.58 lb Joint A : Show the free-body diagram of the joint A as in Figure (2). Using Figure (2), Along the vertical direction: Determine the tension in the cable AC and the angle θ 2 by resolving the vertical component of forces. ∑ F y = 0 A y − T A C sin θ 2 = 0 (V) Along the horizontal direction: Determine the tension in the cable AC and the angle θ 2 by resolving the horizontal component of forces. ∑ F x = 0 T A C cos θ 2 − A x = 0 (VI) Conclusion: Substitute 57

Engineering Mechanics: Statics and Study Pack (13th Edition)

13th Edition

ISBN: 9780133027990

Author: Russell C. Hibbeler

Publisher: Prentice Hall

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Question

Chapter 7.4, Problem 95P

To determine

The tension in each segment of the cable and the cable’s total length.

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Chapter 7.4, Problem 94P

Chapter 7.4, Problem 96P

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Chapter 7 Solutions

Engineering Mechanics: Statics and Study Pack (13th Edition)

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