(a) Explanation Refer Fig P7.100. The figure below shows the free body diagram of the entire cable. Since the system is in equilibrium the total force in the vertical direction will be zero. Refer the above free body diagram and write the equation for the total vertical force. R y − 1 kip − 1 kip − 2 kip=0 (I) Here R y is the vertical component of the reaction at point A . The total moment about the point A is zero. Refer the free body diagram of the entire cable and write the equation for the moment about point A . R E ( 12 ft ) − ( 1 kip ) ( 6 ft ) − ( 1 kip ) ( 12 ft ) − ( 2 kip ) ( 21 ft ) = 0 (II) Here R E is the reaction force at point E . Since the system is in equilibrium the total horizontal force is zero. Refer the free body diagram write the equation for the horizontal force. − R x + 5 kip=0 (III) Here R x is the horizontal component of the reaction at point A . The figure below is the free body diagram of the portion ABC . The total moment about the point C is zero. Refer the free body diagram and write an equation for the total moment about C . R x d C − R y ( 12 ft ) + ( 1 kips ) ( 6 ft ) = 0 (IV) Here d C is the distance of the point C from the horizontal line passing through point A . Conclusion: Calculate R y from the equation (I) (b) To determine The distances d C when the portion BC of the cable is horizontal.

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Chapter 7.4, Problem 7.100P

(a)

To determine

The distances dC when the portion BC of the cable is horizontal.

(b)

To determine

The distances dC when the portion BC of the cable is horizontal.

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Chapter 7.4, Problem 7.99P

Chapter 7.4, Problem 7.101P

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The distances d C when the portion BC of the cable is horizontal.

Solution Summary: The figure below shows the free body diagram of the entire cable. Since the system is in equilibrium the total force in the vertical direction will be zero.

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The distances dC when the portion BC of the cable is horizontal.

The distances dC when the portion BC of the cable is horizontal.

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