1. General Science Chapter 13
Work & Energy
Chapter 13
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General Science Chapter 13

2. General Science Chapter 13
Work
Everyday concept of work.
Scientific definition: Work is the transfer of energy through motion.
A force applied, in which the object moves, to an object in the direction that the object moves.
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General Science Chapter 13

3. General Science Chapter 13
Work
In order for work to take place, a force must be exerted through a distance.
In order for work to be done, there has to be motion, and the motion has to be in the direction of the applied force.
If there is no motion, no work will be done
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4. General Science Chapter 13
Recall “work” lab
Did you do more work lifting the books to shoulder level or over your head?
Greater distance means more work
Did you do more work lifting 2 books or 4 books?
Greater force means more work
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5. General Science Chapter 13
Work Equation
Work, like energy, is measured in joules. 1 J = 1 N ∙ m.
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6. General Science Chapter 13
Work and Energy
Work is the transfer of energy through motion.
When 1 J of work is done on an object, 1 J of energy has been transferred to the object.
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7. General Science Chapter 13
Example
A student’s backpack weighs 10 N. She lifts it from the floor to a shelf 1.5 m high. How much work is done on the backpack?
Force, F = 10 N
Distance, d = 1.5 m
Work = (Force)(Distance)
Work = (10 N)(1.5 m)
Work = 15 N ∙m = 15 J
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8. General Science Chapter 13
Example #2
A dancer lifts a 400-N ballerina overhead a distance of 1.4 m and holds her there for several seconds. How much work is done on the ballerina?
Work = (400 N)(1.4 m)
Work = 560 J
Note that the time was not important for us to determine the work done.
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9. General Science Chapter 13
Example #3
A carpenter lifts a 45-kg beam 1.2 m high. How much work is done on the beam?
Remember that weight equals mass times acceleration due to gravity.
Weight = (45 kg)(9.8 m/s2) = 441 N
Work = (441 N)(1.2 m)
Work = J
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10. General Science Chapter 13
Power
The rate at which work is done.
How much work is done in a given amount of time
The ratio of work to time
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11. General Science Chapter 13
Watts
Power is measured in Watts, named after James Watt, who helped develop the steam engine.
1 W = 1 J/s
Very small unit, so we often use kW.
745.6 Watts = 1 horsepower
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12. General Science Chapter 13
Example
A figure skater lifts his partner, who weighs 450 N, 1 meter in 3 seconds. How much power is required?
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13. General Science Chapter 13
You try
A N elevator rises 30.0 m in 60.0 s. How much power is required? Express your answer in kW.
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14. General Science Chapter 13
Making Connections
4.184 Joules = 1 calorie
Joules are units for energy and work
1 Calorie = 1000 calories
A Calorie is used for foods, so if a candy bar has 250 Calories it is the same as calories.
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15. General Science Chapter 13
Example #1
Tommy eats a candy bar that has 230 Calories. How many Joules is that?
1 Calorie = 1000 calories
1 calorie = Joules so
1 Cal = 4184 Joules therefore
230 Calories = Joules
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16. General Science Chapter 13
Example #1 continued
How much Power can be produced with the 230 Calorie candy bar in 1 hour?
230 Cal = Joules
Use the equation below
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17. General Science Chapter 13
Example #1 continued
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18. General Science Chapter 13
Discussion #1
Define work and what are the SI units?
What units are used to measure Power?
Why is the unit kW used more often than W?
What is the conversion factor for horsepower to Watts?
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19. General Science Chapter 13
Machine
A device that makes work easier
By using a machine you DO NOT DO LESS work.
It just makes it seems easier to do the work.
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20. General Science Chapter 13
Work and machines
Work is made easier by doing 1 of 3 things
Changes the size of the input force
Changes the direction of the force
Changes both the size and the direction of the force
Opening a paint can with a screwdriver
Changes size – you can use less force
Changes direction
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21. General Science Chapter 13
Forces and machines
Effort force (Fe) – applied to the machine
The force you exert
Also called input force
Resistance force (Fr) – applied by the machine to overcome gravity or friction
The force the machine exerts
Also called output force
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22. General Science Chapter 13
Work and machines
Work input (Win) – work done on the machine
Effort force times distance it moves
Win = Fe X de
Work output (Wout) – work done by the machine
Resistance force times distance it moves
Wout = Fr X dr
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23. General Science Chapter 13
Mechanical advantage
The number of times a machine multiplies the effort force
The ratio of output to input. (usually a force)
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24. General Science Chapter 13
Mechanical advantage
Can be greater than 1
Opening paint can
Can be equal to 1
Raising blinds
Can be less than 1
Hitting a baseball
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25. General Science Chapter 13
Example
A worker applies an effort force of 10 N to pry open a window that has a resistance of 500 N. What is the mechanical advantage of the crowbar?
Fr = 500 N Fe = 10 N
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26. General Science Chapter 13
You try
A jack is used to lift a 2000-N rock. The effort force is 200 N. Find the mechanical advantage.
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27. General Science Chapter 13
Discuss #2
A _____________ is a device that makes work easier.
What are the 3 ways a machine can make work easier?
What do we call the force applied to a machine?
What do we call the force applied by a machine?
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28. General Science Chapter 13
Discussion #2
What is mechanical advantage?
What does it mean when the MA value is equal to 1?
How do we calculate MA?
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29. General Science Chapter 13
Simple machine
A device that does work with only one movement
There are six types
Levers Inclined Plane
Pulley Wedge
Wheel & Axle Screw
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30. Ideal Mechanical Advantage
The ratio of output to input (usually a force) disregarding friction and gravity.
When the output work = the input work.
Machine would be 100% efficient, which is impossible.
4/14/2017
General Science Chapter 13

31. General Science Chapter 13
Levers
Examples
Crowbars
Seesaws
Baseball bat
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32. General Science Chapter 13
Definitions
A lever is a bar that is free to pivot, or turn, about a fixed point.
A fulcrum is the fixed point of a lever.
The effort arm is the part of the lever on which the force is applied.
The resistance arm is the part of the lever that exerts the resistance.
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33. General Science Chapter 13
Lever
Effort force
Resistance force
Resistance arm
Effort arm
fulcrum
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34. General Science Chapter 13
Mechanical advantage
Review, we learned that
We can also use for levers
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35. General Science Chapter 13
You try
You use a crowbar 160 cm long as a lever to lift a large rock. The rock is 20 cm from the fulcrum. You push down on the other end of the crowbar.
What is the length of the effort arm?
The resistance arm?
What is the IMA of the lever?
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36. General Science Chapter 13
First class levers
The fulcrum is in the middle
Seesaw
crowbar
Effort force
Resistance arm
Effort arm
fulcrum
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37. General Science Chapter 13
Second class levers
The resistance is in the middle
wheelbarrow
nutcracker
Effort force
Effort arm
Resistance arm
fulcrum
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38. General Science Chapter 13
Third class levers
The effort is in the middle
Baseball bat
broom
Effort force
Effort arm
Resistance arm
fulcrum
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39. General Science Chapter 13
Discuss #3
What is a lever?
What is a fulcrum?
What is the effort arm?
What is the resistance arm?
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40. General Science Chapter 13
Discussion #3
What are the 3 types of levers?
What is an example of each type of lever?
Which type usually has a IMA value < 1?
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41. General Science Chapter 13
Pulleys
Pulley – grooved wheel with a rope or chain running along the groove
Acts like a lever
The two ends of the rope are the effort arm and the resistance arm
The wheel acts like the fulcrum
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42. General Science Chapter 13
Fixed pulley
Attached to something that doesn’t move
Change the direction of a force
IMA of 1 Le Lr Fr Fe
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43. General Science Chapter 13
Movable pulley
Attached to the object being moved
IMA greater than 1
Effort distance must be greater than resistance distance Le Lr Fr Fe
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44. General Science Chapter 13
Block and tackle
System of fixed and movable pulleys
Has IMA equal to the number of ropes that support the resistance weight
Count every rope coming off the movable pulleys that supports or moves the resistance force.
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45. Examples of Block & Tackle
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46. Example of Block & Tackle #2
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47. General Science Chapter 13
Wheel and axle
Consists of two wheels of different sizes that rotate together
The effort force is usually applied to the large wheel
The small wheel, or axle, exerts the resistance force
Examples: doorknob, water faucet, gears, pencil sharpener
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48. General Science Chapter 13
Wheel and axle
Can be thought of as a lever attached to a shaft
Radius of wheel is effort arm
Radius of axle is resistance arm
Center of axle is fulcrum
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49. General Science Chapter 13
Inclined plane
A ramp
Lifting something along an inclined plane means you cover more distance than lifting it straight up, but you get to use a smaller force
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50. General Science Chapter 13
Screw
An inclined plane wrapped in a spiral around a cylindrical post.
As you drive in a screw, the inclined plane slides through the wood.
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51. General Science Chapter 13
Wedge
An inclined plane with one or two sloping sides
Examples
Chisels
Knives
Axe blades
The material stays in place while the wedge moves through it.
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52. General Science Chapter 13
Wedge
 Thickness, T
 Side, S
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53. General Science Chapter 13
Variations
All six kinds of simple machines are variations of two basic machines
The lever
The inclined plane
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54. General Science Chapter 13
Compound Machine
A machine that is made up of 2 or more simple machines.
Examples of compound machines
Fishing rod, pencil sharpener, an axe
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55. General Science Chapter 13
Discuss #4
What kind of simple machine is a ramp?
What is an inclined plane wrapped in a spiral around a cylindrical post?
What kind of simple machine are chisels, knives, and axes?
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56. General Science Chapter 13
Discussion #4
What type of pulleys have a MA = 1?
What is the difference between a fixed pulley and a movable pulley?
What is a block and tackle?
What two groups can simple machines be broken into?
What is a compound machine?
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57. General Science Chapter 13
Energy
Scientific definition: Energy is the ability to cause change.
Ability to do work
Any sample of matter has energy if it can produce a change in itself or in its surroundings.
Energy comes in many forms and will be classified as either Kinetic or Potential.
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58. General Science Chapter 13
Energy continued
Kinetic Forms
Radiant (solar), thermal, electrical, wind, sound
Potential Forms
Gravitational, mechanical, chemical, and nuclear
Energy is measured in joules (J).
Named after a British scientist.
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59. General Science Chapter 13
Kinetic energy
Energy in the form of motion
Amount depends on the mass and velocity of the object.
Greater mass at the same velocity OR greater velocity with the same mass will have greater kinetic energy
KE = ½mv2
5 Types (STEWS or SHEWS)
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60. Solar Energy (Radiant)
Electromagnetic energy that travels in transverse waves.
Energy from the sun
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61. General Science Chapter 13
Thermal Energy
Heat energy, the internal energy in a substance.
Caused by the vibration and movement of atoms/molecules within substances.
Geothermal energy is a good example of this type of energy.
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62. General Science Chapter 13
Electrical Energy
Energy produced by the movement of electrons.
Lightning and electricity are good examples of this form of energy.
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63. General Science Chapter 13
Wind Energy (Motion)
Energy produced from the movement of objects from one place to another.
Do not need to see this movement, we just know there is a change in position.
Wind and some forms of hydropower are good examples of this form of energy.
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64. General Science Chapter 13
Sound Energy
Movement of energy through substances using longitudinal or compressional waves.
Obviously this is how we hear “things”
A compressional wave is like the movement of an inch worm or an accordion.
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65. General Science Chapter 13
Potential energy
Stored energy
Depends on its position/condition/height, mass and gravity
4 Types (GECN)
PE = mgh
m = mass, g = gravity, h = height
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66. Gravitational Energy (Hydro)
Potential energy of an object due to height above the earth’s surface.
The higher the object is, the more potential energy it has.
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67. Elastic Potential Energy (Stored)
Energy stored in a spring or rubber band or anything else that stretches.
The farther it is stretched, the greater its potential energy.
Energy based on the position
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68. General Science Chapter 13
Chemical Energy
The energy stored in foods, fuels, and batteries.
There must be a chemical reaction to get the energy out.
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69. General Science Chapter 13
Nuclear Energy
Energy stored in the nucleus of an atom.
Fusion and Fission are two examples
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70. General Science Chapter 13
Mechanical Energy
The sum of potential and kinetic energy in a system is called mechanical energy.
Think about a roller coaster or bungee jumping.
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71. Discuss #5 Energy Review
Define energy
What units are used to describe energy
What are the 2 main forms of energy
List 3 of the 4 subsets of stored energy
List 3 of the 5 subsets of moving energy
What is Mechanical energy?
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72. General Science Chapter 13
Discussion #5
Why is the first hill of a roller coaster ride the highest?
Where would a roller coaster be moving fastest?
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73. General Science Chapter 13
Discussion #5b
Why can you not travel in a circular loop when on a roller coaster?
Is it possible for the second hill to be taller than the first hill? Explain why?
When does a coaster have the most PE?
When does a coaster have the most KE?
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74. Conservation of Energy
Energy cannot be created or destroyed but it can change from one form to another.
Example – Swing
Why does it stop?
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75. Conservation of energy
You can never get more work out than you put in
If force increases, distance must decrease.
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76. General Science Chapter 13
Internal energy
The total energy of all the particles that make up a sample of matter.
Includes both kinetic and potential energy of the particles.
The more mass a material has, the more internal energy it has.
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77. General Science Chapter 13
Internal energy
Different materials have different internal energies even when they have the same mass and temperature.
This is because the particles in the materials are arranged differently.
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78. General Science Chapter 13
Separate energies
Internal energy of a material depends on the total energy of its particles.
Mechanical energy (kinetic and potential) of the material itself has no effect on internal energy.
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General Science Chapter 13

79. 1st Law of Thermodynamics
The net change in energy equals the energy transferred as work and heat.
Q = Heat
W = Work
ΔU = Internal energy
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80. General Science Chapter 13
Efficiency
Measure of how much of the work put into a machine is changed to useful work put out by the machine.
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81. General Science Chapter 13
Efficiency
Can it ever be more than 100%?
How can we increase efficiency?
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82. General Science Chapter 13
example
A worker pushes a 1500 N chair up an inclined plane that is 4.0 m long and 1.0 m high. The worker exerts a force of 500 N. What is the efficiency of the inclined plane?
4 m
1 m
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83. General Science Chapter 13
You try
Using a fixed pulley, you pull the rope down 1.0 m with a force of 72 N. A 65-N object is raised 1.0 m. What is the efficiency of the pulley?
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