6/177 The grooved pulley of mass m is acted on by a con-stant force F through a cable which is wrappedsecurely around the exterior of the pulley. Thepulley supports a cylinder of mass M which isattached to the end of a cable which is wrappedsecurely around an inner hub. If the system is sta-tionary when the force F is first applied, determinethe upward velocity of the supported mass after40 kg, M = 10 kg, r.150 mm, ko = 160 mm, and F = 75 N.Assume no mechanical interference for the indi-cated time frame and neglect friction in the bear-ing at O. What is the time-averaged value of theforce in the cable which supports the 10-kg mass?3 seconds. Use the values m =225 mm, ridl IVI adgiov daidwwode noitiaog Ininosim, ko u sdT E8rabasTOsd banMFProblem 6/177

Answered: Image /qna-images/answer/53182daa-728b-4323-8b82-bf7956fee73d.jpg

The grooved pulley of mass m is acted on by a con- stant force F through a cable which is wrapped securely around the exterior of the pulley. The pulley supports a cylinder of mass M which is attached to the end of a cable which is wrapped securely around an inner hub. If the system is sta- tionary when the force F is first applied, determine the upward velocity of the supported mass after 3 seconds. Use the values m = 40 kg, M = 10 kg, r, = 225 mm, ri %3D %3D and F = 75 N. 150 mm, ko = 160 mm, Assume no mechanical interference for the indi- cated time frame and neglect friction in the bear- ing at O. What is the time-averaged value of the force in the cable which supports the 10-kg mass? %3D %3D otin odT E8re TI adgiow daidw ade noitisog Inin т, kо ती To lo an bana M Problem 6/177

The grooved pulley of mass m is acted on by a con- stant force F through a cable which is wrapped securely around the exterior of the pulley. The pulley supports a cylinder of mass M which is attached to the end of a cable which is wrapped securely around an inner hub. If the system is sta- tionary when the force F is first applied, determine the upward velocity of the supported mass after 3 seconds. Use the values m = 40 kg, M = 10 kg, r, = 225 mm, ri %3D %3D and F = 75 N. 150 mm, ko = 160 mm, Assume no mechanical interference for the indi- cated time frame and neglect friction in the bear- ing at O. What is the time-averaged value of the force in the cable which supports the 10-kg mass? %3D %3D otin odT E8re TI adgiow daidw ade noitisog Inin т, kо ती To lo an bana M Problem 6/177

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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