A solid sphere starts from rest at a height of 2.5 meters.rolls down a ramp without slipping, so no friction.The mass of the sphere is 2 kg.ItThe radius of the sphere is 0.02 mThe moment of Inertia of a sphere is: I = (2/5)mr²) Compute the change in gravitational potential energywhen the ball rolls from the top to the bottom of the ramp.Use conservation of energy to compute the angularvelocity, oo, in radians/s and the linear velocity in m/s at theend of the ramp.h1

The height is h1=2.5 m The mass of the sphere is m=2 kg The radius of the sphere is r=0.02 m The…

solid sphere starts from rest at a height of 2.5 meters. rolls down a ramp without slipping, so no friction. The mass of the sphere is 2 kg. The radius of the sphere is 0.02 m The moment of Inertia of a sphere is: I = (2/5)mr² A It ) Compute the change in gravitational potential energy when the ball rolls from the top to the bottom of the ramp. Use conservation of energy to compute the angular velocity, o, in radians/s and the linear velocity in m/s at the end of the ramp. h1

solid sphere starts from rest at a height of 2.5 meters. rolls down a ramp without slipping, so no friction. The mass of the sphere is 2 kg. The radius of the sphere is 0.02 m The moment of Inertia of a sphere is: I = (2/5)mr² A It ) Compute the change in gravitational potential energy when the ball rolls from the top to the bottom of the ramp. Use conservation of energy to compute the angular velocity, o, in radians/s and the linear velocity in m/s at the end of the ramp. h1

International Edition---engineering Mechanics: Statics, 4th Edition

4th Edition

ISBN:9781305501607

Author:Andrew Pytel And Jaan Kiusalaas

Publisher:Andrew Pytel And Jaan Kiusalaas

Chapter1: Introduction To Statics

Section: Chapter Questions

Problem 1.19P: Plot the earths gravitational acceleration g(m/s2) against the height h (km) above the surface of...

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