Explanation Given information: The mass of the each rod is m , the length of the rod is d and the corresponding impulse is F Δ t . The figure below shows the effective kinetic diagram of the system. Figure-(1) Write the expression for the moment of inertia of the system about the centre of mass of the system G with respect to x- axis. I x = ( I B S ) x + ( I Q R ) x + ( I A P ) x ...... (I) Here, the moment of inertia of the rod B S with respect to x- axis is ( I B S ) x , the moment of inertia of the rod Q R with respect to x- axis is ( I Q R ) x and the moment of inertia of the rod A P with respect to x- axis is ( I A P ) x . Write the expression for the moment of the rod B S with respect to x- axis. ( I B S ) x = 1 12 m d 2 Here, the diameter of the rod is d and the mass of the rod is m . Write the expression the moment of inertia of the rod Q R with respect to x- axis. ( I Q R ) x = 0 Write the expression for the moment of the rod A P with respect to x- axis. ( I A P ) x = 1 12 m d 2 Substitute 1 12 m d 2 for ( I B S ) x , 1 12 m d 2 for ( I A P ) x and 0 for ( I Q R ) x in Equation (I). I x = 1 12 m d 2 + 0 + 1 12 m d 2 = 1 12 m d 2 + 1 12 m d 2 = 1 6 m d 2 ...... (II) Write the expression for the moment of inertia of the system about the centre of mass of the system G with respect to y- axis. I y = ( I B S ) y + ( I Q R ) y + ( I A P ) y ...... (III) Here, the moment of inertia of the rod B S with respect to y- axis is ( I B S ) y , the moment of inertia of the rod Q R with respect to y- axis is ( I Q R ) y and the moment of inertia of the rod A P with respect to y- axis is ( I A P ) y . Write the expression for the moment of the rod B S with respect to y- axis. ( I B S ) y = m ( d 2 ) 2 Here, the diameter of the rod is d and the mass of the rod is m . Write the expression the moment of inertia of the rod Q R with respect to y- axis. ( I Q R ) y = 1 12 m d 2 Write the expression for the moment of the of the rod A P with respect to y- axis. ( I A P ) y = 1 12 m d 2 + m ( d 2 ) 2 Substitute m ( d 2 ) 2 for ( I B S ) y , 1 12 m d 2 + m ( d 2 ) 2 for ( I A P ) y and 1 12 m d 2 for ( I Q R ) y in Equation (III). I y = ( m ( d 2 ) 2 ) + ( 1 12 m d 2 ) + ( 1 12 m d 2 + m ( d 2 ) 2 ) = ( m ( d 2 4 ) ) + ( 1 12 m d 2 ) + ( 1 12 m d 2 + m ( d 2 4 ) ) = m ( d 2 2 ) + 1 6 m d 2 = 2 3 m d 2 ...... (IV) Write the expression for the moment of inertia of the system about the centre of mass of the system G with respect to z- axis. I z = ( I B S ) z + ( I Q R ) z + ( I A P ) z ...... (V) Here, the moment of inertia of the rod B S with respect to z- axis is ( I B S ) z , the moment of inertia of the rod Q R with respect to z- axis is ( I Q R ) z and the moment of inertia of the rod A P with respect to z- axis is ( I A P ) z To determine (b) The angular velocity of the assembly.

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 18.1, Problem 18.26P

To determine

(a)

The velocity of the mass centre G.

To determine

(b)

The angular velocity of the assembly.

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Chapter 18.1, Problem 18.25P

Chapter 18.1, Problem 18.27P

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