A. A block of mass M rests on an inclined plane with a smooth surface forming a angle of 37 with the horizontal. This block is attached to a second mass of 4.5kg. Initially, the system is kept at rest with the mass of 4.5 kg suspended 2 meters above the ground. The system is released and the mass of 4.5 kg hits the ground 1.5 s later. Determine the magnitude of the mass M and the tension of the string when the masses are in motion. At the beginning, draw a force diagram on the sketch. (hint: you have to find the acceleration of the block m with the kinematics equations) m = 4,5 kg h= 2 m M h 37° At-1,5 s

A. A block of mass M rests on an inclined plane with a smooth surface forming a angle of 37 with the horizontal. This block is attached to a second mass of 4.5kg. Initially, the system is kept at rest with the mass of 4.5 kg suspended 2 meters above the ground. The system is released and the mass of 4.5 kg hits the ground 1.5 s later. Determine the magnitude of the mass M and the tension of the string when the masses are in motion. At the beginning, draw a force diagram on the sketch. (hint: you have to find the acceleration of the block m with the kinematics equations) m = 4,5 kg h= 2 m M h 37° At-1,5 s

Name: Explain this well detailed please, and readable on a sheet. A. A block
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Description: Explain this well detailed please, and readable on a sheet. A. A block of mass M rests on an inclined plane with a smooth surface forming aangle of 37 with the horizontal. This block is attached to a second mass of 4.5kg. Initially,the system is kept

Physics for Scientists and Engineers

10th Edition

ISBN:9781337553278

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter5: The Laws Of Motion

Section: Chapter Questions

Problem 5P: Two forces, F1=(6.00i4.00j)N and F2=(3.00i+7.00j)N, act on a particle of mass 2.00 kg that is...

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