a) Explanation Apply the principle of work-energy relation to the system. T 1 + V 1 + U 1 − 2 = T 2 + V 2 (I) Here, initial and final kinetic energies of the system are T 1 and T 2 respectively, initial and final potential energies of the system are V 1 and V 2 respectively and work done on the system is U 1 − 2 . Conclusion: The initial kinetic energy of the system is zero since the rod is released from rest. T 1 = 0 Calculate the initial potential energy of the system. V 1 = − W A L A sin θ + W B L B sin θ (II) Here, weights of the particles are W A and W B respectively, distance between the mass A and center O is L A , distance between the mass B and center O is L B and angle made by the bar with the horizontal is θ . Substitute 10 lb for W A , 12 in . for L A , 8 lb for W B , 18 in . for L B and 30 ° for θ in Equation (II). V 1 = − ( 10 lb ) ( 12 in . ) sin 30 ° + ( 8 lb ) ( 18 in . ) sin 30 ° = 12 lb ⋅ in . = 12 lb ⋅ in . ( 1 lb ⋅ ft 12 lb ⋅ in . ) = 1 lb ⋅ ft The work done during the processes is zero. U 1 − 2 = 0 Calculate the final kinetic energy of the system. T 2 = 1 2 m A v A 2 + 1 2 m B v B 2 = 1 2 ( W A g ) v A 2 + 1 2 ( W B g ) v B 2 = 1 2 ( W A g ) ( L A θ ˙ ) 2 + 1 2 ( W B g ) ( L B θ ˙ ) 2 (III) Here, masses of the particles are m A and m B respectively, acceleration due to gravity is g , angular velocity of the rod is θ ˙ and final velocities of the particles are v A and v B respectively. Substitute 10 lb for W A , 12 in . for L A , 8 lb for W B , 18 in . for L B and 32.2 ft / s 2 for g in Equation (III). T 2 = 1 2 ( 10 lb 32.2 ft / s 2 ) ( ( 12 in . ) θ ˙ ) 2 + 1 2 ( 8 lb 32.2 ft / s 2 ) ( ( 8 in b) To determine The maximum compression of the spring.

8th Edition

ISBN: 9781118885840

Author: James L. Meriam, L. G. Kraige, J. N. Bolton

Publisher: WILEY

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Chapter 3.7, Problem 147P

To determine

The velocity of the 8 lb particle just before it hits the spring.

To determine

The maximum compression of the spring.

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Chapter 3.7, Problem 146P

Chapter 3.7, Problem 148P

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