Explanation Given: Cart has mass m 1 . Box on the top of the cart has mass m 2 . Coefficient of friction between cart and box is μ s . ramp is inclined by angle θ with horizontal. Acceleration is a . T is tension in the string. g is gravitational acceleration. Formula used: Newton’s second law of motion: F = m a Frictional force: F μ = μ N Calculation: Using above free body diagram, apply Newton’s second law along x and yaxis as follows: ∑ F x = T − ( m 1 + m 2 ) g sin θ = ( m 1 + m 2 ) a ∴ a = T − ( m 1 + m 2 ) g sin θ ( m 1 + m 2 ) Similarly, along y -axis ∑ F y = N − m g cos θ = 0 ∴ N = m g cos θ Force of friction is given as, F μ = μ N ∴ F μ = μ m 2 g cos θ Now, as cart accelerates uphill with force T, equal and opposite force will act on box and it will try to slide it down

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ISBN: 9781429281843

Author: Tipler

Publisher: MAC HIGHER

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Newton's Second Law

Newton’s laws of motion describe the relationship between the motion of an object and forces acting on it. Newton’s law of motion has two types as follows:

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Chapter 5, Problem 126P

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Maximum tension that can be applied without causing load to slip.

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Chapter 5, Problem 125P

Chapter 5, Problem 127P

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Maximum tension that can be applied without causing load to slip.

Solution Summary: The author explains how Newton's second law of motion is applied along x and yaxis.

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Maximum tension that can be applied without causing load to slip.