A package of mass m2.00 kg is released on a 53.1°incline, a distance D=500 m from a long spring withforce constant 1.30 x 102 N/m that is attached at thebottom of the incline (Eigure 1). The coefficients of frictionbetween the package and incline are = 0.400 and-0.200. The mass of the spring is negligible. (a) Whatis the maximum compression of the spring? (b) Thepackage rebounds up the incline. When it stops again,how close does it get to its original position? (c) What isthe change in the internal energy of the package andincline from the point at which the package is releaseduntil it rebounds to its maximum height?Figuremwww.< 1 of 1 >▾SubmitPart HCalculate the instant net force exerted on the package at its lowest point Will the package remain there?Express your answer with the appropriate units. Recall that down the incline is the +x direction and up the incline isthe-x direction.F-SubmitPart 1Request AnswerSubmitμAPart JValueAD= Value•Request AnswerUsing the general energy equation for the motion of the package between the lowest and the final points, find how close thepackage is to its original position.Express your answer with the appropriate units.+→Request AnswerÒUnitsA Ć?Units?

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A package of mass m-200 kg is released on a 53.1" incline, a distance D=500 m from a long spring with force constant 1.30 x 102 N/m that is attached at the bottom of the incline (Eigure 1). The coefficients of friction between the package and incline are 4 = 0.400 and 140.200. The mass of the spring is negligible. (e) What is the maximum compression of the spring? (b) The package rebounds up the incline. When it stops again, how close does it get to its original position? (c) What is the change in the internal energy of the package and incline from the point at which the package is released until it rebounds to its maximum height? Figure m < 1 of 1 Submit Request Answer Part H Calculate the instant net force exerted on the package at its lowest point Will the package remain there? Express your answer with the appropriate units. Recall that down the incline is the +x direction and up the incline is the-x direction. Submit Request Answer Part 1 Value AD= Value Using the general energy equation for the motion of the package between the lowest and the final points, find how close the package is to its original position Express your answer with the appropriate units. Submit Part J Units Request Answer ? Units ?

A package of mass m-200 kg is released on a 53.1" incline, a distance D=500 m from a long spring with force constant 1.30 x 102 N/m that is attached at the bottom of the incline (Eigure 1). The coefficients of friction between the package and incline are 4 = 0.400 and 140.200. The mass of the spring is negligible. (e) What is the maximum compression of the spring? (b) The package rebounds up the incline. When it stops again, how close does it get to its original position? (c) What is the change in the internal energy of the package and incline from the point at which the package is released until it rebounds to its maximum height? Figure m < 1 of 1 Submit Request Answer Part H Calculate the instant net force exerted on the package at its lowest point Will the package remain there? Express your answer with the appropriate units. Recall that down the incline is the +x direction and up the incline is the-x direction. Submit Request Answer Part 1 Value AD= Value Using the general energy equation for the motion of the package between the lowest and the final points, find how close the package is to its original position Express your answer with the appropriate units. Submit Part J Units Request Answer ? Units ?

University Physics Volume 1

18th Edition

ISBN:9781938168277

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

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

Chapter8: Potential Energy And Conservation Of Energy

Section: Chapter Questions

Problem 8.11CYU: Check Your Understanding Find x(t) for the mass-spring system in Example 8.11 ii the particle starts...

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