Explanation Given info : The coefficient of static friction is 0.50 ,angle of the cable with the rod is 37 ° and the force of friction is 0.40 T . The frictional force at point A is f = ( f s ) max = μ s n but the sum of horizontal forces on the rod at equilibrium condition is ∑ F x = 0 = n − T cos θ . By using these two expressions, the force of friction is calculated. At equilibrium condition, the vertical components of forces on the rod is defined as ∑ F y = 0 = f + T sin θ − 2 w . The sum of torques about the point A is ∑ τ = 0 = − x min w − ( l / 2 ) w + l ( T sin θ ) = 0 . The formula for the force of friction is, f = μ s T cos θ μ s is coefficient of static friction. T is force of tension in the cable. θ is the angle of the cable with the rod. Substitute 0.50 for μ s and 37 ° for θ to find f . f = ( 0.50 ) ( cos 37 ° ) T = 0.40 T Thus, the force of friction the surfaces of the wall and the end of the rod is 0.40 T

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ISBN: 9781337514637

Author: Vuille

Publisher: CENGAGE LEARNING - CONSIGNMENT

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Center of Gravity of a system

The centre of gravity is a property that is based on the geometry of a rigid body or any particle. It is described as an equilibrium point or a hypothetical location where the total weight of the body is concentrated.

Question

Chapter 8, Problem 36P

To determine

The minimum distance from a point A at which an additional weight w can be hung without causing the rod to slip at point A.

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Chapter 8 Solutions

EBK COLLEGE PHYSICS, VOLUME 1

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The minimum distance from a point A at which an additional weight w can be hung without causing the rod to slip at point A .

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The minimum distance from a point A at which an additional weight w can be hung without causing the rod to slip at point A.

Chapter 8 Solutions