1. Energy, Work and Power

2. Energy
Energy: the currency of the universe. Just like money, it comes in many forms!
Everything that is accomplished has to be “paid for” with some form of energy.
Energy can’t be created or destroyed, but it can be transformed from one kind into another and it can be transferred from one object to another.

3. Work = Force x displacement
Doing WORK is one way to transfer energy from one object to another.
Work = Force x displacement
W = Fd
Unit for work is Newton x meter. One Newton-meter is also called a Joule, J.

4. Work- the transfer of energy

5. Work = Force x displacement
Work is not done unless there is a displacement.
If you hold an object a long time, you may get tired, but NO work was done.
If you push against a solid wall for hours, there is still NO work done.

6. For work to be done, the displacement of the object must be along the same direction as the applied force. They must be parallel.
If the force and the displacement are perpendicular to each other, NO work is done by the force.

7. But since they are in opposite directions, now it is NEGATIVE work. d
For example, in lifting a book, the force exerted by your hands is upward and the displacement is upward- work is done.
Similarly, in lowering a book, the force exerted by your hands is still upward, and the displacement is downward.
The force and the displacement are STILL parallel, so work is still done.
But since they are in opposite directions, now it is NEGATIVE work. F d F d

8. Therefore, NO work is done by your hands.
On the other hand, while carrying a book down the hallway, the force from your hands is vertical, and the displacement of the book is horizontal.
Therefore, NO work is done by your hands.
Since the book is obviously moving, what force IS doing work???
The static friction force between your hands and the book is acting parallel to the displacement and IS doing work! F d

9. Work = Force x distance

10. So,….while climbing stairs or walking up an incline, only the vertical component of the displacement is used to calculate the work done in moving the object from the bottom to the top.
Your Force
Vertical component of d
Horizontal component of d

11. Example
How much work is done to carry a 5 kg cat to the top of a ramp that is 7 meters long and 3 meters tall?
W = Force x displacement
Force = weight of the cat
Which is parallel to the weight- the length of the ramp or the height?
d = height NOT length
W = mg x h
W = 5 x 10 x 3
W = 150 J
7 m
3 m

12. How much work do you do to carry a 30 kg cat from one side of the room to the other if the room is 10 meters long?
ZERO, because your Force is vertical, but the displacement is horizontal.

13. Example
Displacement = 20 m
A boy pushes a lawnmower 20 meters across the yard. If he pushed with a force of 200 N and the angle between the handle and the ground was 50 degrees, how much work did he do?
F cos q q F
W = (F cos q )d
W = (200 cos 50) 20
W = 2571 J

14. Does the gravitational force do any work?
A 5.0 kg box is pulled 6m across a rough horizontal floor (m = 0.4) with a force of 80N at an angle of 35 degrees above the horizontal. What is the work done by EACH force exerted on it? What is the NET work done?
Does the gravitational force do any work?
NO! It is perpendicular to the displacement.
Does the Normal force do any work?
No! It is perpendicular to the displacement.
Does the applied Force do any work?
Yes, but ONLY its horizontal component!
WF = Fcosq x d = 80cos 35 x 6 = J
Does friction do any work?
Yes, but first, what is the normal force? It’s NOT mg!
Normal = mg – Fsinq
Wf = -f x d = -mNd = -m(mg – Fsinq)d = J
What is the NET work done?
J – J = J
Normal FA f q mg

15. Watch for those “key words”
NOTE: If while pushing an object, it is moving at a constant velocity,
the NET force must be zero.
So….. Your applied force must be exactly equal to any resistant forces like friction.

16. Energy and Work have no direction associated with them and are therefore scalar quantities, not vectors.
YEAH!!

18. Power is the rate at which work is done- how fast you do work.
Power = work / time
P = W / t
You may be able to do a lot of work, but if it takes you a long time, you are not very powerful.
The faster you can do work, the more powerful you are.

19. The unit for power is Joule / seconds which is also called a Watt, W
(just like the rating for light bulbs)
In the US, we usually measure power developed in motors in “horsepower”
1 hp = 746 W

20. Example
A power lifter picks up a 80 kg barbell above his head a distance of 2 meters in 0.5 seconds. How powerful was he?
P = W / t
W = Fd
W = mg x h
W = 80 kg x 10 m/s2 x 2 m = 1600 J
P = 1600 J / 0.5 s
P = 3200 W

21. Power = Force x velocity
Another way of looking at Power:
Power = Force x velocity

23. Kinds of Energy

24. Kinetic Energy
the energy of motion
K = ½ mv2

25. Potential Energy Stored energy
It is called potential energy because it has the potential to do work.

26. Different kinds of Potential (stored) Energy
Example 1: Spring potential energy, SPE, in the stretched string of a bow or spring or rubber band. SPE = ½ kx2
Example 2: Chemical potential energy in fuels- gasoline, propane, batteries, food!
Example 3: Gravitational potential energy, GPE- stored in an object due to its position from a chosen reference point.

27. Gravitational potential energy
GPE = weight x height
GPE = mgh
Since you can measure height from more than one reference point, it is important to specify the location from which you are measuring.

28. The GPE may be negative. For example, if your reference point is the top of a cliff and the object is at its base, its “height” would be negative, so mgh would also be negative.
The GPE only depends on the weight and the height, not on the path that it took to get to that height.

29. Many different forms of Energy…
Thermal Energy Solar Energy Atomic Energy Sound Energy Electromagnetic Energy Nuclear Energy Electrical Energy E = mc2

31. Work = Force x distance = change in energy
Work and Energy
Often, some force must do work to give an object potential or kinetic energy.
“Work” is the transfer of energy!!
You push a wagon and it starts moving kinetic energy. You stretch a spring and you transform your work energy  spring potential energy.
Or, you lift an object to a certain height- you transfer your work energy into the object in the form of gravitational potential energy.
Work = Force x distance = change in energy

32. Example of Work = change in energy
How much more distance is required to stop if a car is going twice as fast (all other things remaining the same)?
The work done by the forces stopping the car = the change in the kinetic energy
Fd = D½ mv2
With TWICE the speed, the car has
FOUR times the kinetic energy.
Therefore it takes FOUR times the stopping distance.
(What FORCE is doing the work??)

33. The Work-Kinetic Energy Theorem
NET Work done by all forces = D Kinetic Energy
Wnet = ½ mv2f – ½ mv2o

34. Example, W = Fd = DK A 500kg car moving at 15m/s skids 20m to a stop.
How much kinetic energy did the car lose?
DK = ½ mvf2 – ½ mvo2 (but vf = 0!)
DK = -½ (500 kg)(15 m/s) 2
DK = J
What force was applied to stop the car?
F·d = DK
F = DK / d
F = J / 20 m
F = N

35. Example W = Fd = DK A 500kg car moving at 15 m/s slows to 10m/s.
How much kinetic energy did the car lose?
DK = ½ mvf2 – ½ mvo2
DK = ½ (500 kg)(10 m/s)2 - ½ (500 kg)(15 m/s)2
DK = J
What force was applied to slow the car if the distance moved was 12 m?
F·d = DK
F = DK / d
F = J / 12 m
F = N

36. Example W = Fd = DK
A 500 kg car moving on a flat road at 15 m/s skids to a stop.
How much kinetic energy did the car lose?
DK = ½ mvf2 – ½ mvo2
DK = -½ (500 kg)(15 m/s)2
DK = J
How far did the car skid if the effective coefficient of friction was m = 0.6?
Stopping force = friction = mN = mmg
F·d = DK
-(mmg)·d = DK
d = DK / (mmg) *be careful to group in the denominator!
d = J / (0.6 · 500 kg · 9.8 m/s2) = m

37. Since Power = Work / time and
Back to Power…
Since Power = Work / time and
Net work = DK…
Power = DK / time
In fact, Power can be calculated in many ways since Power = Energy / time, and there are MANY forms of energy!

39. Conservation of Mechanical Energy
Draw a sketch and choose a reference point for height.
Look at the first position of your object. If it is moving, it has Kinetic energy. If it has some height above or below your reference point, it has Potential energy.
Repeat for the second location.
If there is no friction or air resistance, set the mechanical energies at each location equal.
E = E2
mgh1 + ½mv12 = mgh2 + ½ mv22
5. If there is friction or air resistance, use E1 – E2 to find the energy lost.

40. Graphing Force vs. postion
If you graph the applied force vs. the position, you can find how much work was done by the force.
Work = Fd = “area under the curve”.
Total Work = 2 N x 2 m + 3N x 4m = 16 J
Area UNDER the x-axis is NEGATIVE work = - 1N x 2m
Force, N
Position, m F
Net work = 16 J – 2 J = 14 J d

41. Back to the Work-Kinetic Energy Theorem…
According to that theorem,
net work done = the change in the kinetic energy
Wnet = DK
But, if the work can be found by taking the “area under the curve”, then it is also true that
Area under the curve = DK = ½ mvf2 – ½ mvo2
Therefore, the area can be used to predict the final velocity of an object given its initial velocity and its mass.

42. 14 J = ½(3 kg)vf 2 – ½(3 kg)(4 m/s)2
For example…
Suppose from the previous graph
(Area = Wnet = 14 J), the object upon which the forces were exerted had a mass of 3 kg and an initial velocity of 4 m/s. What would be its final velocity?
Area under the curve = ½ mvf2 – ½ mvo2
14 J = ½(3 kg)vf 2 – ½(3 kg)(4 m/s)2
vf = 5.0 m/s

43. The Spring Force
If you hang an object from a spring, the gravitational force pulls down on the object and the spring force pulls up.

44. which describes how stiff the spring is
The Spring Force
The spring force is given by
Fspring = kx
Where x is the amount that the spring stretched and k is the “spring constant”
which describes how stiff the spring is

45. (this is called “Hooke’s Law)
The Spring Force
If the mass is hanging at rest, then
Fspring = mg Or
kx = mg
(this is called “Hooke’s Law)
The easiest way to determine the spring constant k is to hang a known mass from the spring and measure how far the spring stretches!
k = mg / x

46. Graphing the Spring Force
Suppose a certain spring had a spring constant
k = 30 N/m.
Graphing spring force vs. displacement:
On horizontal axis- the displacement of the spring: x
On vertical axis- the spring force = kx = 30x
What would the graph look like?
Fs = kx
In “function” language: f(x) = 30x

47. Spring Force vs. Displacement
Fs = 30x Fs x1 x2
How could you use the graph
To determine the work done by
The spring from some x1 to x2?
Take the AREA under the curve! x

48. where x is the distance the spring is stretched or compressed
Analytically…
The work done by the spring is given by
Ws = ½ kxf2 – ½ kxo2
where x is the distance the spring is stretched or compressed
(Which would yield the same result as taking the area under the curve!)

49. I love mrs. BRown

50. Mechanical Energy E = ½ mv2 + mgh
Mechanical Energy = Kinetic Energy + Potential Energy
E = ½ mv mgh

51. “Conservative” forces - mechanical energy is conserved if these are the only forces acting on an object.
The two main conservative forces are: Gravity, spring forces
“Non-conservative” forces - mechanical energy is NOT conserved if these forces are acting on an object.
Forces like kinetic friction, air resistance

52. Conservation of Mechanical Energy
If there is no kinetic friction or air resistance, then the total mechanical energy of an object remains the same.
If the object loses kinetic energy, it gains potential energy.
If it loses potential energy, it gains kinetic energy.
For example: tossing a ball upward

53. Conservation of Mechanical Energy
The ball starts with kinetic energy…
Which changes to potential energy….
Which changes back to kinetic energy
PE = mgh
What about the energy when it is not at the top or bottom?
E = ½ mv2 + mgh
Energybottom = Energytop
½ mvb2 = mght
K = ½ mv2
K = ½ mv2

54. Examples dropping an object box sliding down an incline
tossing a ball upwards
a pendulum swinging back and forth
A block attached to a spring oscillating back and forth
First, let’s look at examples where there is NO friction and NO air resistance…..

55. Example of Conservation of Mechanical Energy
Rapunzel dropped her hairbrush from the top of the castle where she was held captive. If the window was 80 m high, how fast was the brush moving just before it hit the ground? (g = 10 m/s2) mgh = ½ mv2 gh = ½ v2 2gh = v2 Don’t forget to take the square root! Enter your answer on #1

56. Now… do one on your own
#2 An apple falls from a tree that is 1.8 m tall. How fast is it moving just before it hits the ground? (g = 10 m/s2) mgh = ½ mv2

57. And another one…
#3 A woman throws a ball straight up with an initial velocity of 12 m/s. How high above the release point will the ball rise? g = 10 m/s2 mgh = ½ mv2 h = ½ v2 / g

58. And another one…
#4 Mario, the pizza man, tosses the dough upward at 8 m/s. How high above the release point will the dough rise? g = 10 m/s2 mgh = ½ mv2

59. Conservation of Mechanical Energy- another look
A skater has a kinetic energy of 57 J at position 1, the bottom of the ramp (and NO potential energy)
At his very highest position, 3, he comes to a stop for just a moment so that he has 57 J of potential energy (and NO kinetic energy)
Mechanical energy = KE + PE
#5 What is his kinetic energy at position 2, if his potential energy at position 2 is 25.7 J?
E = 57 J
PE = 25.7 J
KE = ??
E = 57 J

60. Conservation of Mechanical Energy… more difficult
A stork, at a height of 80 m flying at 18 m/s, releases his “package”. How fast will the baby be moving just before he hits the ground? Energyoriginal = Energyfinal mgh + ½ mvo2 = ½ mvf2
Vf = 43.5 m/s

61. #5 Now you do one …
The car on a roller coaster starts from rest at the top of a hill that is 60 m high. How fast will the car be moving at a height of 10 m? (use g = 9.8 m/s2) Energyoriginal = Energyfinal mgho = ½ mv2 + mghf # 5 Enter your answer with ONE decimal place.

62. Mechanical energy will be lost in the form of heat energy.
If there is kinetic friction or air resistance, mechanical energy will not be conserved.
Mechanical energy will be lost in the form of heat energy.
The DIFFERENCE between the
original energy and the final energy
is the amount of mechanical energy lost due to heat.
Final energy – original energy = energy loss

63. Let’s try one…
#6 A 2 kg cannonball is shot straight up from the ground at 18 m/s. It reaches a highest point of 14 m. How much mechanical energy was lost due to the air resistance? g = 10 m/s2 Final energy – original energy = Energy loss mgh – ½ mv2 = Heat loss 2 kg(10 m/s2)(14 m) – ½ (2 kg)(18 m/s)2 = ??

64. And one more…
#7 A 1 kg flying squirrel drops from the top of a tree 5 m tall. Just before he hits the ground, his speed is 9 m/s. How much mechanical energy was lost due to the air resistance? g = 10 m/s2 Final energy – original energy = Energy loss

65. Don’t even think about it…
Sometimes, mechanical energy is actually INCREASED!
For example: A bomb sitting on the floor explodes.
Initially:
Kinetic energy = 0 Potential energy = 0
Mechanical Energy = 0
After the explosion, there’s lots of kinetic and gravitational potential energy!!
Did we break the laws of the universe and create energy???
Of course not! NO ONE, NO ONE, NO ONE can break the laws!
The mechanical energy that now appears came from the chemical potential energy stored within the bomb itself!

66. Law of Conservation of Energy energy cannot be created or destroyed.
According to the
Law of Conservation of Energy
energy cannot be created or destroyed.
The total amount of mechanical energy in a system remains constant when there are no NONCONSERVATIVE forces doing work.
But one form of energy may be transformed into another as conditions change.

68. Physics 1: 1. Get a Clicker and sign in to A240 2
Physics 1: 1. Get a Clicker and sign in to A You need a calculator 3. You need your notes

69. Simple Machines and Efficiency
Machine: A device that HELPS do work.
A machine cannot produce more WORK ENERGY than the energy you put into it- that would break the Law of Conservation of Energy-
but it can make your work easier to do.

70. Work energy in = work energy out
Some common “simple machines” include levers, pulleys, wheels and axles, and inclined planes
Ideally, with no friction, the work energy you get out of a machine equals the work energy you put into it.
Ideally:
Work energy in = work energy out

71. Effort Work = Resistance Work
Work = Force x distance
The work you put into a machine is called EFFORT work.
The work you get out of the machine- is called RESISTANCE work, so ideally
Effort Work = Resistance Work
Feffortdeffort = Fresistancedresistance
(if there’s no NON-conservative forces!)

72. Effort Work = Resistance Work
Try one…
# 1. Hercules pushes a 500 kg boulder up a hill a distance of 25 m using a force of 6000 N. How much work did Hercules do?
Effort Work = Resistance Work
Feffortdeffort = Fresistancedresistance

73. Levers The RESISTANCE force is the weight of the load being lifted.
A B C
Effort force
The RESISTANCE force is the weight of the load being lifted.
#2 Which arrangement will require the least EFFORT force?

74. Levers How do you “pay” for a small effort force? You push harder
You push just the same
You push a smaller distance
You push a greater distance

75. Inclined Planes
A B C
Weight =
Resistance Force
Effort Force
Height = Resistance Distance
Effort Distance
#4. Which arrangement will require the least EFFORT force?
How do you “pay” for a smaller effort force?

76. A motor is attached to one of the pulleys so that as it turns, the belt causes the second pulley to turn.
To have the least effort force, the effort distance must be the greatest. In this case the effort distance is the number of turns around – the ROTATIONS!
Which pulley will have to go around more times? This is the pulley that the motor should be attached to for the least effort force.
# 5 Which pulley should the motor be attached to so that it requires the least effort force from the motor?
Two pulleys with a belt
A B

77. Efficiency
No machine is perfect. That is reflected in the “efficiency” of the machine. In the real world, the efficiency will always be less that 100%. It is found by

78. Some practice…
#6 While using a simple machine, you put in 4500 J of work energy. The machine puts out 3690 J of energy. What was the percent efficiency of the machine?

79. #9 What is the percent efficiency of the incline?
A man pushes a 48 kg box up a 12 m long incline that is 4.2 meters high by applying a force of 240 N. (g = 10 m/s2)
What is the effort (input) work?
Weffort = Feffortdeffort
#7 We = ?
What is the resistance (output) work?
Wresistance = Frdr
W = mg x h
#8 Wr = ?
#9 What is the percent efficiency of the incline?