Explanation Given information: Velocity V 0 = ( 1.25 f t / s ) i Relative velocity V ' = 2.5 f t / s Distance a = 0.433 f t Length of string l = 0.25 f t Applying conservation of linear momentum: When the circles in ring: L 0 = ( 3 m ) V 0 L 0 = ( 3 m ) 1.25 L 0 = m ( 3.75 f t / s ) i __________________ (1) After break: L = m v A j − m v B j + m v C i __________________ (2) Hence, L = L 0 From equation (1) and (2): m ( v A − v B ) j + m v C i = m ( 3.75 f t / s ) i m v C i = m ( 3.75 f t / s ) i o r , m ( v A − v B ) j = 0 Therefore, v C = 3.75 f t / s o r , v A = v B Now, applying principle of conservation of angular momentum: When the circles in ring: ( H o ) 0 = 3 m l v ' ( H o ) 0 = 3 m ( 0.25 ) ( 2.5 ) ( H o ) 0 = 1.875 m After break: H 0 = − m v A x A + m v A ( x A + 0.433 ) + m v C d H 0 = − m v A x A + m v A ( x A + 0.433 ) + m v C d H 0 = − m v A x A + m v A x A + 0.433 m v A + m v C d H 0 = 0.433 m v A + m v C d Hence, ( H 0 ) o = H 0 Therefore, 1 To determine (b) The distance (d).

12th Edition

ISBN: 9781259977305

Author: BEER, Ferdinand P. (ferdinand Pierre), Johnston, E. Russell (elwood Russell), Cornwell, Phillip J., SELF, Brian P.

Publisher: Mcgraw-hill Education,

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Chapter 14.2, Problem 14.56P

To determine

(a)

The velocity of each identical sphere A, B and C.

To determine

(b)

The distance (d).

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Chapter 14.2, Problem 14.55P

Chapter 14.3, Problem 14.57P

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Vector Mechanics For Engineers

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(a) The velocity of each identical sphere A, B and C.

Solution Summary: The author analyzes the velocity of each identical sphere A, B, and C.