11th Edition

ISBN: 9781323575208

Author: YOUNG

Publisher: PEARSON C

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The potential energy is the energy possessed by a body by virtue of its position or the energy held by the object due to its position relative to other objects, its force like stresses, charge, and other factors affecting the particles of the body. The p…

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Chapter 6, Problem 6.93CP

CALC A Spring with Mass. We usually ignore the kinetic energy of the moving coils of a spring, but let’s try to get a reasonable approximation to this. Consider a spring of mass M. equilibrium length L₀, and force constant k. The work done to stretch or compress the spring by a distance L is 1 2 k X 2 , where X = L − L₀. Consider a spring, as described above, that has one end fixed and the other end moving with speed υ. Assume that the speed of points along the length of the spring varies linearly with distance l from the fixed end. Assume also that the mass M of the spring is distributed uniformly along the length of the spring. (a) Calculate the kinetic energy of the spring in terms of M and υ. (Hint: Divide the spring into pieces of length dl; find the speed of each piece in terms of l, υ, and L; find the mass of each piece in terms of dl, M, and L; and integrate from 0 to L. The result is not 1 2 m υ 2 , since not all of the spring moves with the same speed.) In a spring gun, a spring of mass 0.243 kg and force constant 3200 N/m is compressed 2.50 cm from its unstretched length. When the trigger is pulled, the spring pushes horizontally on a 0.053-kg ball. The work done by friction is negligible. Calculate the ball’s speed when the spring reaches its uncompressed length (b) ignoring the mass of the spring and (c) including, using the results of part (a), the mass of the spring, (d) In part (c), what is the final kinetic energy of the ball and of the spring?

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Chapter 6, Problem 6.92P

Chapter 6, Problem 6.94CP

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We will now determine how the 1/3 rule comes about. Consider a spring of mass ms which is attached to a wall and oscillates on a frictionless surface as shown below. The spring’s mass is uniformly distributed along the length of the spring. We will start with the infinitesimal form of kinetic energy, i.e. dKE = ½ (dms )v2. This formula will apply to an infinitesimal segment of the spring of length dx and mass dms as indicated below. For any point on the spring, the velocity of oscillation will be given by v = (ve/L)x where ve is the velocity of the spring at its end where the mass m is attached, and L is the stretched length of the spring at that instant. Thus, when x = 0 then v = 0, and when x = L/2 then v = ½ ve. Hint: Figure out how to relate dms to dx and then integrate both sides of the infinitesimal kinetic energy equation to get an equation for the kinetic energy of the spring that includes ms/3.

I need help with finding the last part. A moving 1.70 kg block collides with a horizontal spring whose spring constant is 303 N/m. The block compresses the spring a maximum distance of 14.50 cm from its rest position. The coefficient of kinetic friction between the block and the horizontal surface is 0.120. What is the work done by the spring in bringing the block to rest? How much mechanical energy is being dissipated by the force of friction while the block is being brought to rest by the spring? What is the speed of the block when it hits the spring?

Chapter 6 Solutions

UNIVERSITY PHYSICS UCI PKG

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