The coin in the investigation is a good example of work and conservation of energy. You applied a force to the ruler to bend it a certain distance. This was the work done on the ruler to add energy. After that, the ruler had elastic potential energy. When you released the ruler, that energy was transferred to the coin as the ruler applied a force to the coin over a certain distance. The coin now had kinetic energy. It traveled up in the air and the kinetic energy became gravitational potential energy as the coin rose. At its peak, the coin stopped momentarily. It now had no kinetic energy, but did have gravitational potential energy. As the coin began to fall, it gained kinetic energy as it lost gravitational potential energy. At all points during the rise and fall, the sum of the kinetic energy and gravitational energy of the coin

The coin in the investigation is a good example of work and conservation of energy. You applied a force to the ruler to bend it a certain distance. This was the work done on the ruler to add energy. After that, the ruler had elastic potential energy. When you released the ruler, that energy was transferred to the coin as the ruler applied a force to the coin over a certain distance. The coin now had kinetic energy. It traveled up in the air and the kinetic energy became gravitational potential energy as the coin rose. At its peak, the coin stopped momentarily. It now had no kinetic energy, but did have gravitational potential energy. As the coin began to fall, it gained kinetic energy as it lost gravitational potential energy. At all points during the rise and fall, the sum of the kinetic energy and gravitational energy of the coin

Name: From where does the penny that is launched into the air get its energy
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Description: From where does the penny that is launched into the air get its energy Conservation of Energy in the Pole VaultThe coin in the investigation is a good example of work and conservationof energy. You applied a force to the ruler to bend it a certain di

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 6CQ: Two people observe a leaf falling from a tree. One person is standing on a ladder and the other is...

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Spiderman, whose mass is 80.0 kg, is dangling on the free end of a 12.0-m-long rope, the other end of which is fixed to a tree limb above. By repeatedly bending at the waist, he is able to get the rope in motion, eventually getting it to swing enough that he can reach a ledge when the rope makes a 60.0 angle with the vertical. How much work was done by the gravitational force on Spiderman in this maneuver?
Give an example of something think of as work in everyday circumstances that is not work in the scientific sense. Is energy transferred or changed in form in your example? If so, explain how this without doing work.
Review. You can think of the workkinetic energy theorem as a second theory of motion, parallel to Newtons laws in describing how outside influences affect the motion of an object. In this problem, solve parts (a), (b), and (c) separately from parts (d) and (e) so you can compare the predictions of the two theories. A 15.0-g bullet is accelerated from rest to a speed of 780 m/s in a rifle barrel of length 72.0 cm. (a) Find the kinetic energy of the bullet as it leaves the barrel. (b) Use the workkinetic energy theorem to find the net work that is done on the bullet. (c) Use your result to part (b) to find the magnitude of the average net force that acted on the bullet while it was in the barrel. (d) Now model the bullet as a particle under constant acceleration. Find the constant acceleration of a bullet that starts from rest and gains a speed of 780 m/s over a distance of 72.0 cm. (e) Modeling the bullet as a particle under a net force, find the net force that acted on it during its acceleration. (f) What conclusion can you draw from comparing your results of parts (c) and (e)?
Two people observe a leaf falling from a tree. One person is standing on a ladder and the other is on the ground. If each person were to compare the energy of the leaf observed, would each person find the following to be the same or different for the leaf, from the point where it falls off the tree to when it hits the ground: (a) the kinetic energy of the leaf; (b) the change in gravitational potential energy; (c) the final gravitational potential energy?
Give an example of a situation in which there is a force and a displacement, but the force does no work. Explain why it does no work.
What does work on a shuffleboard puck as it slides to rest? Why is the board dusted, and how does this affect work?
Integrated Concepts (a) Calculate the force the woman in Figure 7.46 exerts to do a push-up at constant speed, taking all data to be known to three digits. (b) How much work does she do if her center of mass rises 0.240 m? (c) What is her useful power output if she does 25 push-ups in 1 min? (Should work done lowering her body be included? See the discussion of useful work in Work, Energy, and Power in Humans. Figure 7.46 Forces involved in doing push-ups. The woman's weight acts as a force exerted downward on her center of gravity (CG).
A hummingbird is able to hover because, as the wings move downward, they exert a downward force on the air. Newtons third law tells us that the air exerts an equal and opposite force (upward) on the wings. The average of this force must be equal to the weight of the bird when it hovers. If the wings move through a distance of 3.5 cm with each stroke, and the wings beat 80 times per second, determine the work performed by the wings on the air in 1 m if the mass of the hummingbird is 3.0 g.
Give an example of a situation in which there is a force and a displacement, but the force does no work. Explain why it does no work.
At hokey puck of mass 0.17 kg is shot across a rough floor with the roughness different at different places, which can be described by a position-dependent coefficient of kinetic friction. For a puck moving along the x-axis, the coefficient of kinetic friction is the following function of x, where x is in m: (x)=0.1+0.05x . Find the work done by the kinetic frictional forte on the hockey puck when it h moved (a) from x=0 to x=2 m, and (b) from x=2 m to x=4 m.
Give an example of something we think of as work in everyday circumstances that is not work in the scientific sense. Is energy transferred or changed in form in your example? If so, explain how this is accomplished without doing work.
Consider the following scenario. A car for which friction is not negligible accelerates from rest down a hill, running out of gasoline after a short distance (see below). The driver lets the car coast farther down the hill, then up and over a small crest. He then coasts down that hill into a gas station, where he brakes to a stop and fills that tank with gasoline. Identify the forms of energy the car has, and how they are changed and transferred in this series of events.