Block A rests on a horizontal tabletop. A light horizontal rope isattached to it and passes over a pulley, and block B is suspendedfrom the free end of the rope. The light rope that connects the twoblocks does not slip over the surface of thè pulley (radius 0.080 m)because the pulley rotates on a frictionless axle. The horizontalsurface on which block A (mass 3.70 kg) moves is frictionless. Thesystem is released from rest, and block B (mass 6.00 kg) movesdownward 1.80 m in 2.00 s.Part BWhat is the tension force that the rope exerts on block A?Express your answer with the appropriate units.µATA=ValueUnitsSubmitRequest AnswerPart CWhat is the moment of inertia of the pulley for rotation about the axle on which it is mounted?Express your answer with the appropriate units.µA台新I =ValueUnits|| Block A rests on a horizontal tabletop. A light horizontal rope isattached to it and passes over a pulley, and block B is suspendedfrom the free end of the rope. The light rope that connects the twoblocks does not slip over the surface of thè pulley (radius 0.080 m)because the pulley rotates on a frictionless axle. The horizontalsurface on which block A (mass 3.70 kg) moves is frictionless. Thesystem is released from rest, and block B (mass 6.00 kg) movesPart AWhat is the tension force that the rope exerts on block B?downward 1.80 m in 2.00 s.Express your answer with the appropriate units.HÁTB =ValueUnitsSubmitRequest AnswerPart BWhat is the tension force that the rope exerts on block A?Express your answer with the appropriate units.HẢ王新TA=ValueUnits

Given, Mass of block A, mA=3.70 kg, and Mass of block B, mB=6.0 kg,

Block A rests on a honzontal ltabletop. A light horizontal rope is attached to it and passes over a pulley, and block B is suspended from the free end of the rope. The light rope that connects the two blocks does not slip over the surface of the pulley (radius 0.080 m) because the pulley rotates on a frictionless axle, The horizontal surface on which block A (mass 3.70 kg) moves is frictionless. The system is released from rest, and block B (mass 6.00 kg) moves downward 1.80 m in 2.00 . Part B What is the tension force that the rope exerts on block A? Express your answer with the appropriate units. HA TA = Value Units Submit Request Answer Part C What is the moment of inertia of the pulley for rotation about the axle on which it is mounted?

Block A rests on a honzontal ltabletop. A light horizontal rope is attached to it and passes over a pulley, and block B is suspended from the free end of the rope. The light rope that connects the two blocks does not slip over the surface of the pulley (radius 0.080 m) because the pulley rotates on a frictionless axle, The horizontal surface on which block A (mass 3.70 kg) moves is frictionless. The system is released from rest, and block B (mass 6.00 kg) moves downward 1.80 m in 2.00 . Part B What is the tension force that the rope exerts on block A? Express your answer with the appropriate units. HA TA = Value Units Submit Request Answer Part C What is the moment of inertia of the pulley for rotation about the axle on which it is mounted?

University Physics Volume 1

18th Edition

ISBN:9781938168277

Author:William Moebs, Samuel J. Ling, Jeff Sanny

Publisher:William Moebs, Samuel J. Ling, Jeff Sanny

Chapter11: Angular Momentum

Section: Chapter Questions

Problem 89AP: A solid cylinder of mass 2.0 kg and radius 20 cm is rotating counterclockwise around a vertical axis...

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