To determine The velocity of the pin at C in the horizontal guide for the instant when θ = 50 ° . Explanation Write the expression for the velocity of the pin at C in the horizontal guide. v C = x ˙ = d d t ( x ) Here, velocity of the pin at C in the horizontal guide is v C , first derivative of distance between the points O and C is x ˙ and distance between the points O and C is x . Conclusion: Let the length of all the links be equal to b . Let the link distance between the pins O and A be equal to s . Show the schematic diagram of the system as in Figure (1). From Figure (1), consider the triangle Δ O B E . Calculate the value of sin θ . sin θ = B E ¯ O B ¯ (I) Here, angle made by the link OB with horizontal is θ , distance between the point B and E is B E ¯ and distance between the point O and B is O B ¯ . Substitute s / 2 for B E ¯ and b for O B ¯ in Equation (I). sin θ = ( s / 2 ) b s = 2 b sin θ (II) Differentiate Equation (II) with respect to time. d d t ( s ) = d d t ( 2 b sin θ ) d s d t = 2 b cos θ d d t ( θ ) s ˙ = 2 b cos θ θ ˙ (III) Here, angular velocity of the link OB is θ ˙ and moment rate of the hydraulic cylinder is s ˙ . From Figure (1), consider the triangle Δ O B E . Calculate the value of cos θ . cos θ = O E ¯ O B ¯ (IV) Here, distance between the point O and E is O E ¯

8th Edition

ISBN: 9781118885840

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

Publisher: WILEY

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Chapter 5.3, Problem 33P

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The velocity of the pin at C in the horizontal guide for the instant when θ=50°.

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Chapter 5.3, Problem 32P

Chapter 5.3, Problem 34P

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Engineering Mechanics: Dynamics

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