A block of mass m= 13.5 kg rest on inclined plane with the coefficient of static friction of us= 0.12 between the block in the plane. The inclined plane is L= 6.3 m long and it has a height of h= 3.8 m at its tallest point. What angle, Θ in degrees, does the plane make with respect to the horizontal? What is the magnitude of the normal force, Fn in Newton’s, that acts on the block? What is the component of the force of gravity along the plane, Fgx in Newton’s? Will the block slide?

A block of mass m= 13.5 kg rest on inclined plane with the coefficient of static friction of us= 0.12 between the block in the plane. The inclined plane is L= 6.3 m long and it has a height of h= 3.8 m at its tallest point. What angle, Θ in degrees, does the plane make with respect to the horizontal? What is the magnitude of the normal force, Fn in Newton’s, that acts on the block? What is the component of the force of gravity along the plane, Fgx in Newton’s? Will the block slide?

Name: A block of mass m= 13.5 kg rest on inclined plane with the coefficient
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Description: A block of mass m= 13.5 kg rest on inclined plane with the coefficient of static friction of us= 0.12 between the block in the plane. The inclined plane is L= 6.3 m long and it has a height of h= 3.8 m at its tallest point. What angle, Θ in degrees

Principles of Physics: A Calculus-Based Text

5th Edition

ISBN:9781133104261

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter5: More Applications Of Newton’s Laws

Section: Chapter Questions

Problem 61P

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