Explanation Consider the points A 1 and A 2 on the links C E and O D respectively, coinciding with point A . The triangle O A C is an equilateral triangle. Thus, A O = 6 in . Write the expression for the velocity of the point A 2 . v A 2 = ω OD ( A O ) (I) Here, the angular velocity of the link O D is ω OD and the distance between the points A and O is A O . Write the expression for the vector representation of velocity of point A 2 . v A 2 = v A 2 ( cos 30 ° i + sin30 ° j ) (II) Write the expression for the vector representation of velocity of point A 1 . v A 1 = v A 1 ( cos 30 ° i − sin30 ° j ) (III) Write the expression for the normal acceleration of the point A 1 . ( a A 1 ) n = v A 1 2 ρ ( − cos 60 ° i − sin60 ° j ) (IV) Write the expression for the tangential acceleration of the point A 1 . ( a A 1 ) t = ( a A ) t ( cos 30 ° i − sin30 ° j ) The figure below represents the velocity polygon of points A and B . Figure-(1) Write the expression for the acceleration of point A . a A 1 = a 0 + ω ˙ × r + ω × ( ω × r ) + 2 ω × v A 1 /A 2 + a rel (V) Here, the relative acceleration is a rel . . Write the expression for the net acceleration of the point A . a A 1 = ( a A 1 ) n + ( a A 1 ) t Write the expression for the angular acceleration of the link E C . ( A C ) × α EC = ( a A ) t (VI) Here, the angular acceleration is α EC and the acceleration is ( a A ) t . Conclusion: Substitute 6 in for A O and 2 rad/sec for ω OD in Equation (I). v A 2 = ( 2 rad/sec ) ( 6 in ) = ( 2 × 6 ) in / sec = 12 in / sec Substitute 12 in / sec for v A 2 in Equation (II). v A 2 = ( 12 in / sec ) ( cos 30 ° i + sin30 ° j ) = ( 12 in / sec ) cos 30 ° i + ( 12 in / sec ) sin30 ° j = ( 10.39 i + 6 j ) in / sec Apply the sine rule in the velocity polygon. v A 1 /A 2 sin 60 ° = v A 2 sin 30 ° v A 1 /A 2 = v A 2 sin 60 ° sin 30 ° (VIII) Substitute 12 in / sec for v A 2 in Equation (VIII). v A 1 /A 2 = ( 12 in / sec ) ( sin 60 ° sin 30 ° ) = ( 12 × 3 2 × 2 ) in / sec = 12 3 in / sec Apply the sine rule in the velocity polygon. v A 1 sin 90 ° = v A 2 sin 30 ° v A 1 = v A 2 sin 90 ° sin 30 ° (IX) Substitute 12 in / sec for v A 2 in Equation (IX)

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Chapter 5.7, Problem 183P

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The angular acceleration of the link EC.

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Chapter 5 Solutions

EBK ENGINEERING MECHANICS: DYNAMICS, SI

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