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Chapter 7: Q7.2-5 CQ (page 258)

Work done on a system puts energy into it. Work done by a system removes energy from it. Give an example for each statement.

Short Answer

Expert verified

When a person pushes the lawn mower it increases the energy system and the mower starts moving with constant velocity. Once the lawn mower starts moving due to friction, it starts losing energy in the form of heat, and finally its stops.

Step by step solution

01

Definition of Concept

Work energy theorem:According to the work-energy theorem, the change in kinetic energy of the body equals the work done on the body.

In other words, when the kinetic energy of the body increases, the work is done on the system and when the kinetic energy of the system decreases, the work is done by the system.

02

Work on a system that adds energy to it.

When the work is done on the system, the final kinetic energy of the system will be greater than the initial kinetic energy of the system before the application of force on the system.

Assuming a lawn mower is initially at rest. A gardener pushes the lawn mower (work is done on the mower), so the gardener increases the energy of the mower and it starts to move.

Therefore, Work performed on a system adds energy to it.

03

A system's work depletes its energy.

When the work is done by the system, the final kinetic energy of the system will be smaller than the initial kinetic energy of the system before the application of force on the system.

Assuming a lawn mower is moving. There is a frictional force acting between the lawn mower and the lawn. To overcome this friction the mower has to do work against it (work is done by the system), so the friction decreases the energy of the mower and finally it stops.

Therefore, the work done by a system removes energy from it.

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Most popular questions from this chapter

Jogging on hard surfaces with insufficiently padded shoes produces large forces in the feet and legs.

(a) Calculate the magnitude of the force needed to stop the downward motion of a joggerโ€™s leg, if his leg has a mass of 13.0 kg, a speed of 6.00 m/s, and stops in a distance of 1.50 cm. (Be certain to include the weight of the 75.0-kg joggerโ€™s body.)

(b) Compare this force with the weight of the jogger.

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. 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 the tank with gasoline. Identify the forms of energy the car has, and how they are changed and transferred in this series of events. (See Figure 7.34.)

Figure 7.34 A car experiencing non-negligible friction coasts down a hill, over a small crest, then downhill again, and comes to a stop at a gas station.

Using energy considerations and assuming negligible air resistance, show that a rock thrown from a bridge 20.0 m above water with an initial speed of 15.0 m/s strikes the water with a speed of 24.8 m/s independent of the direction thrown.

Question: (a) Calculate the energy in kJ used by a 55.0-kg woman who does 50 deep knee bends in which her center of mass is lowered and raised 0.400 m. (She does work in both directions.) You may assume her efficiency is 20%.

(b) What is the average power consumption rate in watts if she does this in 3.00 min?

Calculate the power output in watts and horsepower of a shot-putter who takes\(1.20{\rm{ s}}\)to accelerate the\(7.27 - {\rm{kg}}\)shot from rest to\(14.0{\rm{ m}}/{\rm{s}}\), while raising it\(0.800{\rm{ m}}\). (Do not include the power produced to accelerate his body.)
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