You pull on a string with a horizontal force of magnitude Fyb = 43 N that is attached to a block of mass m = 7.5 kg, then to the axle of a solid cylinder of mass me = 5 kg and radius r = 0.4 m, then to aspring of spring constant k = 135 N/m. This is all done on an inclined plane where there is friction (μs = 0.62 and μ = 0.39), and the incline angle is 0 = 27 degrees. Everything starts at rest, and the springis unstretched. The block slides down the plane, the cylinder rolls down the plane (without slipping), and the spring stretches.kbelllllllb016ybSpeedFirst, what is the speed of the block and cylinder after you have pulled the block and cylinder 64 cm down the plane?v=2.18193489018 m/s

Name: You pull on a string with a horizontal force of magnitude Fyb = 43 N
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Description: You pull on a string with a horizontal force of magnitude Fyb = 43 N that is attached to a block of mass m = 7.5 kg, then to the axle of a solid cylinder of mass me = 5 kg and radius r = 0.4 m, then to aspring of spring constant k = 135 N/m. This is

Given data: Horizontal force Fyb = 43 N Block's mass mb = 7.5 kg Cylinder mass mc = 5 kg Radius r =…

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You pull on a string with a horizontal force of magnitude Fyb = 43 N that is attached to a block of mass mp = 7.5 kg. then to the axle of a solid cylinder of mass me = 5 kg and radius r = 0.4 m, then to a spring of spring constant k = 135 N/m. This is all done on an inclined plane where there is friction (s = 0.62 and μ = 0.39), and the incline angle is = 27 degrees. Everything starts at rest, and the spring is unstretched. The block slides down the plane, the cylinder rolls down the plane (without slipping), and the spring stretches. k belllllll Speed b 0 yb First, what is the speed of the block and cylinder after you have pulled the block and cylinder 64 cm down the plane? U2.18193489018 m/s

You pull on a string with a horizontal force of magnitude Fyb = 43 N that is attached to a block of mass mp = 7.5 kg. then to the axle of a solid cylinder of mass me = 5 kg and radius r = 0.4 m, then to a spring of spring constant k = 135 N/m. This is all done on an inclined plane where there is friction (s = 0.62 and μ = 0.39), and the incline angle is = 27 degrees. Everything starts at rest, and the spring is unstretched. The block slides down the plane, the cylinder rolls down the plane (without slipping), and the spring stretches. k belllllll Speed b 0 yb First, what is the speed of the block and cylinder after you have pulled the block and cylinder 64 cm down the plane? U2.18193489018 m/s

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

Chapter7: Conservation Of Energy

Section: Chapter Questions

Problem 15P: A block of mass m = 2.00 kg is attached to a spring of force constant k = 500 N/m as shown in Figure...

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