Please help solve for Fn A certain amusement park ride consists of a large rotatingcylinder of radius R = 3.15 m. As the cylinder spins, ridersinside feel themselves pressed against the wall. If thecylinder rotates fast enough, the frictional force between theriders and the wall can be great enough to hold the riders inplace as the floor drops out from under them.RIf the cylinder makes f = 0.510 rotations/s, what is themagnitude of the normal force FN between a rider and thewall, expressed in terms of the rider's weight W?FN3.23WIncorrectWhat is the minimum coefficient of static friction usrequired between the rider and the wall in order for the riderto be held in place without sliding down?

The free body diagram shows the force acting on the riders.

A certain amusement park ride consists of a large rotating cylinder of radius R = 3.15 m. As the cylinder spins, riders inside feel themselves pressed against the wall. If the cylinder rotates fast enough, the frictional force between the riders and the wall can be great enough to hold the riders in place as the floor drops out from under them. If the cylinder makes f = 0.510 rotations/s, what is the magnitude of the normal force FN between a rider and the wall, expressed in terms of the rider's weight W? FN = 3.23 W Incorrect

A certain amusement park ride consists of a large rotating cylinder of radius R = 3.15 m. As the cylinder spins, riders inside feel themselves pressed against the wall. If the cylinder rotates fast enough, the frictional force between the riders and the wall can be great enough to hold the riders in place as the floor drops out from under them. If the cylinder makes f = 0.510 rotations/s, what is the magnitude of the normal force FN between a rider and the wall, expressed in terms of the rider's weight W? FN = 3.23 W Incorrect

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

Chapter10: Rotational Motion

Section: Chapter Questions

Problem 10P: A wheel 2.00 m in diameter lies in a vertical plane and rotates about its central axis with a...

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