Problem 2: Two identical masses are hung from two different flywheels that are initially stationary. Flywheel B is a uniform disc. Flywheel A has less mass than flywheel B and its mass is distributed in a uniform ring that is attached to the center by spokes of negligible mass. Refer to the figure. The masses are released from rest and allowed to fall from the same height above the floor. A Which is the correct statement about the flywheel's angular accelerations? The angular accelerations of the two flywheels are equal. The angular acceleration of flywheel B is greater. The angular acceleration of flywheel A is greater. The angular acceleration of the two flywheels is different but it is impossible to tell which is greater. There's not enough information to determine which angular acceleration is greater. m m B

Problem 2: Two identical masses are hung from two different flywheels that are initially stationary. Flywheel B is a uniform disc. Flywheel A has less mass than flywheel B and its mass is distributed in a uniform ring that is attached to the center by spokes of negligible mass. Refer to the figure. The masses are released from rest and allowed to fall from the same height above the floor. A Which is the correct statement about the flywheel's angular accelerations? The angular accelerations of the two flywheels are equal. The angular acceleration of flywheel B is greater. The angular acceleration of flywheel A is greater. The angular acceleration of the two flywheels is different but it is impossible to tell which is greater. There's not enough information to determine which angular acceleration is greater. m m B

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

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A bicycle wheel of mass M (all at the edges) and radius r is fixed about an axis through its center and is initially at rest. You wrap the wheel with a cord and attach a hanging weight of mass m to the cord. You release the weight and allow it to fall a distance d. The weight falls smoothly, and the cord does not slip over the wheel as it unwinds. a. (Write an expression for the angular acceleration α of the wheel in terms of the tension T of the cord.b. Write an expression for the linear acceleration a of the weight in terms of the tension T of the cord.c. (Using parts (a) and (b) find the linear acceleration in terms of M, m, and g.d. Write an expression for the linear speed v of the weight after it falls a distance d.e. For M = 7.5 kg, r = 33 cm, m = 250 g, and d = 1.5 m, what is the rotational kinetic energy of the wheel afterthe weight has fallen?
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Case 1: A DJ starts up her phonograph player. The turntable accelerates uniformly from rest, and takes t1 = 11.6 seconds to get up to its full speed of f1 = 78 revolutions per minute. Case 2: The DJ then changes the speed of the turntable from f1 = 78 to f2 = 120 revolutions per minute. She notices that the turntable rotates exactly n2= 12 times while accelerating uniformly. a. Calculate the magnitude of the angular acceleration of the turntable (in radians/second2) while increasing to 120 RPM (Case 2). b. How long (in seconds) does it take for the turntable to go from f1 = 78 to f2 = 120 RPM?
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rod of length L = .9 m and mass mod = .1 kg connects two small balls of mass m = .2 kg each. The rod rotates about its midpoint with an axis perpendicular to the rod. The initial angular velocity is w, = 3 rad/s in the counterclockwise direction. A tangential force F = 9 N is applied to one of the spheres for 2 s causing the system to Rotation accelerate. a. What is the moment of inertia of the rod and ball m system? b. What is the torque acting on the system? Magnitude and direction? c. What is the angular acceleration of the system? d. What is the final angular velocity of the rod? e. What is the final speed v of one of the masses?
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