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Chapter 13 Work and Energy

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Presentation on theme: "Chapter 13 Work and Energy"— Presentation transcript:

1 Chapter 13 Work and Energy

2 Work, Power, and Machines
Is done only when force is applied to an object and the object moves in the same direction as the applied force Is calculated by multiplying the force by the distance over which the force is applied Work = force x distance W = F x d Work is 0 when an object is not moving

3 Work, Power, and Machines
Work is measured in Joules Because work is calculated as force times distance, it is expressed in newtons times meters (N x m) 1 Nm = 1 J = 1 Kg x m2/s2 Because all of these units are equivalent, when solving a particular problem, you can choose which unit to use Substituting equivalent units will often help you cancel out other units in a problem

4 Work, Power, and Machines
In order to lift the barbell above his head the weight lifter need to apply a force which opposes the downward acting force of gravity on the mass of the barbell. The distance from the floor to above the lifters head is 2 meters.

5 Work, Power, and Machines
Mass of barbell = = 50kg Weight of barbell = mass x acceleration due to gravity F = m x g F = 50Kg x 9.8m/s2 = 490 Newtons Work done = force x distance Work done = 490Kgm/s2 x 2m = 980Kgm2/s2 = 980 Joules

6 Work, Power, and Machines
In the example above the work done by the weight lifter in lifting the weights was 980 joules. In order to do this work energy had to be transferred. 980 joules of chemical energy from food eaten by the weight lifter was transferred to 980 joules of gravitational potential energy to the barbell. Thus the amount of work done is equal to the energy transferred from one form to another.

7 Work, Power, and Machines
Is any work being done?

8 Work, Power, and Machines

9 Work, Power, and Machines
Power: is the rate at which work is done, or how much work is done in a given amount of time Power = work / time P = W / t Power is measured in watts One watt is the amount of power needed to do 1 joule of work in 1 second Do not confuse the symbol for work (W) which is italic, with the symbol for watt, W

10 Work, Power, and Machines

11 Work, Power, and Machines
When doing a chin-up, a physics student lifts her 42.0-kg body a distance of 0.25 meters in 2 seconds. What is the power delivered by the student's biceps?

12 Work, Power, and Machines
To raise her body upward at a constant speed, the student must apply a force which is equal to her weight (m•g). The work done to lift her body is W = F * d = (411.6 N) * (0.250 m) W = J The power is the work/time ratio which is (102.9 J) / (2 seconds) = 51.5 Watts (rounded)

13 Work, Power, and Machines
Your household's monthly electric bill is often expressed in kilowatt-hours. One kilowatt-hour is the amount of energy delivered by the flow of l kilowatt of electricity for one hour. Use conversion factors to show how many joules of energy you get when you buy 1 kilowatt-hour of electricity.

14 Work, Power, and Machines
Using conversion factors, it can be shown that 1 kilo-watt*hour is equivalent to 3.6 x 106 Joules. First, convert 1 kW-hr to 1000 Watt-hours. Then convert 1000 Watt-hours to 3.6 x 106 Watt-seconds. Since a Watt-second is equivalent to a Joule, you have found your answer.

15 Work, Power, and Machines
Machines help do work by changing the size of an input force, the direction of the force, or both

16 Work, Power, and Machines
Mechanical advantage: Is the ratio between the output force and the input force Also, it is equal to the ratio between the input distance and the output distance If friction is ignored

17 Work, Power, and Machines
Mechanical advantage = Output force / input force = input distance / output distance Machine with a mechanical advantage greater than 1 Multiplies the input force Helps you move or lift a heavy object Machine with a mechanical advantage less than 1 does not multiply force but increases distance and speed

18 Simple Machines Machines are either modifications of simple machines or combinations of several simple machines Six types of simple machines: Simple lever Pulley Wheel and axle Simple inclined plane Wedge Screw

19 Simple Machines First-class lever: fulcrum located between the points of application of the input and output forces Second-class lever: fulcrum is at end of the arm, and the input force is applied to the other end Third-class lever: multiplies distance rather force. Mechanical advantage of less then 1

20 Simple Machines

21 Simple Machines

22 Simple Machines

23 Simple Machines

24 Simple Machines

25 Simple Machines

26 Simple Machines Pulleys are modified levers
Point in the middle of a pulley is like the fulcrum of a lever

27 Simple Machines

28 Simple Machines A wheel and axle is a lever connected to a shaft

29 Simple Machines

30 Simple Machines Inclined plane: pushing an object up an inclined plane requires less input force than lifting the same object does.

31 Simple Machines

32 Simple Machines

33 Simple Machines Wedge: formed when two inclined planes are placed back to back Like pushing a ramp instead of pushing something up a ramp Turns a single downward force into two forces directed out to the sides

34 Simple Machines

35 Simple Machines Screw is an inclined plane wrapped around a cylinder
The threads on a screw are inclined planes Gentle sloping threads requires a small force to act over a long distance Steeper slopes requires more force over less distance Drill bits Jar lids

36 Simple Machines Compound machines
Many devices that you use everyday are made of more than one single machine Machine that combines two or more simple machines Example: a pair of scissors uses two 1st class levers joined at a common fulcrum Each lever arm has a wedge that cuts into the paper

37 What is Energy? Energy: Ability to do work
Whenever work is done, energy is transformed or is transferred from one system to another system Measured in Joules (same as in Work)

38 What is Energy? Potential Energy (PE):
Energy of position because it results from the relative positions of objects in a system

39 What is Energy? Gravitational potential energy depends on both mass and height PE = mass x free-fall acceleration x height PE = mgh Note: mg is the weight of the object in Newtons

40 What is Energy?

41 What is Energy?

42 What is Energy?

43 What is Energy? Kinetic Energy: energy of motion
Depends on both the mass and speed of an object KE = ½ x mass x speed squared KE = ½mv2 = ½ kg x m2/s2 Why are car crashes more dangerous at high speeds? Depends on speed more than it depends on mass Speed is squared, so a small change in speed causes a large change in KE

44 What is Energy?

45 What is Energy? Mechanical energy: sum of the kinetic energy and potential energy in a system Mechanical engineering Design machines Chemistry: chemical potential energy Photosynthesis: energy from the sun

46 Conservation of Energy
The total amount of energy in the universe never changes, although energy may change from one form to another Energy cannot be created or destroyed Potential becomes kinetic Kinetic becomes potential

47 Conservation of Energy
Efficiency of machines: Not all work done by a machine is useful work Friction generates heat Measured as a percentage: ratio of useful work output to work input Efficiency = useful work output/work input

48 Conservation of Energy
A diesel engine with an efficiency of 0.39 requires 750 J of work to be done on its pistons. How much useful work is done by the diesel engine? 1. List the given and unknown values. Given: efficiency = 0.39 work done on the machine (input) = 750 J Unknown: useful work done by the machine (output) = ? J

49 Conservation of Energy
2. Use the efficiency equation, and rearrange it to solve for useful work done by the machine (output). Efficiency = useful work done by the machine output / work done on the machine input efficiency × work done by the machine (input)= × useful work done by the machine output/work done on the machine input x work done on the machine input = useful work done by the machine (output)

50 Conservation of Energy
3. Substitute the values for the work done on the machine and the efficiency into the equation, and solve. useful work done by the machine (output) = (0.39) × (750 J) useful work done by the machine (output) = 290 J

51 Conservation of Energy


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