Block B, in the figure below, weighs 100 kg. The coefficient of friction (1) between Block B and the floor is 0.4. Pulley A has a radius of gyration (k) of0.5m, it has a mass of 300 k ((-mk") and a diameter of 1.5m. The system starts from rest. Neglect the weight of the cable. A constant force (P) of 1000 N is applied. Using the inertia method of Chapter 13 determine a) the angular acceleration of Pulley A. b) the tension in the cable, 100 kg B. 30 300 kg k-0.5 m Dia 1.5 m

Block B, in the figure below, weighs 100 kg. The coefficient of friction (1) between Block B and the floor is 0.4. Pulley A has a radius of gyration (k) of0.5m, it has a mass of 300 k ((-mk") and a diameter of 1.5m. The system starts from rest. Neglect the weight of the cable. A constant force (P) of 1000 N is applied. Using the inertia method of Chapter 13 determine a) the angular acceleration of Pulley A. b) the tension in the cable, 100 kg B. 30 300 kg k-0.5 m Dia 1.5 m

University Physics Volume 1

18th Edition

ISBN:9781938168277

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

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

Chapter12: Static Equilibrium And Elasticity

Section: Chapter Questions

Problem 24P: When tightening a bolt, you push perpendicularly on a wrench with a force of 165N at a distance of...

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