To determine The expression for number of revolutions Explanation Draw the freee body diagram of the coin in the slider is shown in Figure (1). Here, the force acting on the coin in the radial direction is F n and the force acting on the coin in the tangential direction is F t . Apply the dynamic equilibirum condition along tangential direction using Figure (1). ∑ F t = m a t F t = m a t (I) Here, mass of the coin is m and tangential accelration is a t . Substitute r α for a t in Equation (I). F t = m r α (II) Here, radial distance is r and angular acceleration is α . Apply the dynamic equilibirum condition along normal direction using Figure (1). ∑ F n = m a n F n = m a n (III) Here, radial accelration is a n . Substitute r ω 2 for a t in Equation (III). F n = m r ω 2 (IV) Here, angular velocity is ω . Write the expression to determine the maximum resultant force ( F max ) . F max = ( F n ) 2 + ( F t ) 2 (V) Substitute m r ω 2 for F n , m r α for F t , and μ s m g for F max in Equation (V)

8th Edition

ISBN: 9781118885840

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

Publisher: WILEY

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Chapter 3.5, Problem 85P

To determine

The expression for number of revolutions

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Chapter 3.5, Problem 84P

Chapter 3.5, Problem 86P

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Engineering Mechanics: Dynamics

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