1. Work, Energy, and Simple Machine
Physics Chapter 10
Work, Energy, and Simple Machine

2. Next Generation Science Standards
HS-PS3-1.
Create a computational model to calculate the change in the energy of one component in a system when the change in energy of the other component(s) and energy flows in and out of the system are known.
HS-PS3-2.
Develop and use models to illustrate that energy at the macroscopic scale can be accounted for as either motions of particles or energy stored in fields.

3. Physics Turn in Chapter 9 homework, worksheet, and Lab Report Lecture
Q&A

4. Work, W
Work: the product of the force exerted on an object and the distance (displacement) the object moves in the direction of the force.
Valid only when F and d are in the same direction.
F: force
d: displacement, more exactly, d
Unit:
[W] =
[F] · [d] =
N · m =
Joule = J

5. Example: Pg261pp2 Together, two students exert a force of 825 N in pushing a car a distance of 35 m. a) How much work is done? b) If the force was doubled, how much work would they do pushing the car the same distance?

6. Practice: Pg261pp3 A rock climber wears a 7
Practice: Pg261pp3 A rock climber wears a 7.5-kg backpack while scaling a cliff. After 30.0 min, the climber is 8.2 m above the starting point. a) How much work does the climber do on the backpack? b) If the climber weighs 645 N, how much work does she do lifting herself and the backpack?

7. Practice What work is done by a forklift raising a 583-kg box 1.2 m?

8. Practice:
If you push twice as hard against a stationary brick wall, the amount of work you do
doubles.
is cut in half.
remains constant but non-zero.
remains constant at zero.

9. What if F and d are not in the same direction? F: force
d: displacement (more accurately, d)
: angle between F and d

10. Positive and Negative Work
Work is a scalar—it has no direction.
Negative sign does not indicate direction.
A positive work is always larger than a negative work.
 < 90o  W ____ 0
>
 = 90o  W ____ 0 =
 > 90o  W ____ 0
<
F = 0
d = 0
 = 90o
 W = 0

11. Example: Pg262pp5 Two people lift a heavy box a distance of 15 m
Example: Pg262pp5 Two people lift a heavy box a distance of 15 m. They use ropes, each of which makes an angle of 15o with the vertical. Each person exerts a force of 225 N. How much work do they do? d F 

12. Practice: Pg262pp7 A rope is used to pull a metal box 15
Practice: Pg262pp7 A rope is used to pull a metal box 15.0 m across the floor. The rope is held at an angle of 46.0o with the floor and a force of 628 N is applied to the rope. How much work does the force on the rope do? F
46.0o

13. Practice:
If you walk 5.0 m horizontally forward at a constant velocity carrying a 10-N book, the amount of work you do is
more than 50 J.
equal to 50 J.
less than 50 J, but more than 0 J.
zero.

14. Work Done by Weight (Gravity)
When an object goes up or down, the work done by weight (gravity) is given by
where
m: mass of object
g = 9.8 m/s2
Δh: change in height of object
Δh > 0 when going up  W ____ 0
<
Δh < 0 when going down  W ____ 0
>
Δh = 0 when going horizontally  W ____ 0 =

15. How much work does the rider do on the bike?
Practice: Pg262-8
A bicycle rider pushes a bicycle that has a mass of 13 kg up a steep hill. The incline is 25o and the road is 275 m long, as shown in Figure The rider pushes the bike parallel to the road with a force of 25 N.
How much work does the rider do on the bike?
How much work is done by the force of gravity on the bike?
d = 275 m 
F = 25 N
gd h Fg 

16. Practice:
You lift a 10-N physics book up in the air a distance of 1.0 m, at a constant velocity of 0.50 m/s. What is the work done by the weight of the book?
10J
-10 J
5.0 J
-5.0 J

17. Power, P
Power: (time) rate of doing work, or (time) rate of energy transfer
Average power:
W: Work done
t: time, duration, for the work done (more exactly, Δt)
Unit:
1 horse power = 1 hp = 746 W

18. Instantaneous Power
F: force
v: velocity
: angle between F and v

19. Example: Pg264pp9 A box that weighs 575 N is lifted a distance of 20
Example: Pg264pp9 A box that weighs 575 N is lifted a distance of 20.0 m straight up by a rope. The job is done in 10.0 s. What power is developed in watts and kilowatts?
Solution: Pg264pp9
F = 575N, d = 20.0m, t = 10.0s, P = ?

20. Practice:
Does the centripetal force acting on an object do work on the object?
Yes, since a force acts and the object moves, and work is force times distance.
Yes, since it takes energy to turn an object.
No, because the object has constant speed.
No, because the force and the velocity of the object are perpendicular.

21. Practice: Pg264pp12 An electric motor develops 65 kW of power as it lifts a loaded elevator 17.5 m in 35.0 s. How much force does the motor exert?
P = 65kW = W, d = 17.5 m, t = 35.0 s
F = ?

22. Kinetic Energy, KE Energy or ability to do work because of motion.
m: mass
v: velocity
Unit:

23. Practice:
Car J moves twice as fast as car K, and car J has half the mass of car K. The kinetic energy of car J, compared to car K is
The same.
2 to 1.
4 to 1.
1 to 2.

24. Work-Kinetic Energy Theorem
Work and energy are related by
Wnet: total work done on an object
KE: kinetic energy of that object

25. Example You push a 10-kg desk, initially at rest, with a force of 100 N a distance of 8.5 m across the classroom. What is the final speed of the desk?

26. Practice: A rock of mass 2
Practice: A rock of mass 2.0 kg is thrown with a speed of 10 m/s at an angle of 40o above the horizontal at the edge of a 30-m high cliff. With what speed does it hit the ground?

27. Practice:
If the net work done on an object is positive, then the object’s kinetic energy
decreases.
remains the same.
increases.
is zero.

28. Practice:
An arrow of mass kg is shot horizontally into a bale of hay, striking the hay with a velocity of 60 m/s. It penetrates a depth of 0.20 m before stopping. What is the average stopping force acting on the arrow?
45 N
90 N
180 N
360 N

29. Lever,
inclined plane,
and screw
wedge,
wheel-and-axle,
Simple Machine
Simple Machine: anything that can change the force (magnitude or direction) to accomplish a task
Does not change the amount of work done.
(Then why use a machine?)
pulley,
Example:

30. Mechanical Advantage, MA
Fi or Fe: input force or effort force
Force you actually exert on a machine
Force you actually exert when using a machine
Fo or Fr: output force or resistance force
Force exerted by the machine on the load.
Force you need to exert if not using a machine.
MA has no unit.
MA has a unit of 1, or MA is dimensionless.
MA > 1: machine increases your force

31. Input and Output Work
Wi: input work, work done by you when using machine
Fi: input (effort) force
di: input (effort) displacement, displacement of your hand
Wo: output work, work given out by machine. (Work you need to do if not using the machine.)
Fo: output (resistance) force
do: output (resistance) displacement, displacement caused by machine, displacement when not using machine

32. Ideal Machine Ideal Machine: Ideal Mechanical Advantage:
is valid for ideal and non-ideal.
is valid only for ideal machine.

33. Efficiency, eff
Efficiency: ratio of the work done by the machine to the work put into the machine; how much of the input work converted into output work by the machine
Also
Efficiency has no unit.

34. Example: Pg272pp25 A sledge hammer is used to drive a wedge into a log to split it. When the wedge is driven 0.20 m into the log, the log is separated a distance of 5.0 cm. A force of 1.7  104 N is needed to split the log, and the sledge exerts a force of 1.1  104 N . a) What is the IMA of the wedge? b) Find the MA of the wedge. c) Calculate the efficiency of the wedge as a machine.
di = 0.20m, do = 5.0cm = 0.05m, Fo = 1.7  104 N, Fi = 1.1  104 N

35. Practice: Pg272pp26 A worker uses a pulley system to raise a 24
Practice: Pg272pp26 A worker uses a pulley system to raise a 24.0-kg carton 16.5 m. A force of 129 N is exerted and the rope is pulled 33.0 m. a) What is the MA of the pulley system? b) What is the efficiency of the system?

36. Inclined Plane  h d