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Chapter 5 Work and Energy

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Chapter 5 Work and Energy
Chapter 5
Work and Energy
Forms of Energy
 Mechanical
o Kinetic, gravitational
 Thermal
o Microscopic mechanical
 Electromagnetic
 Nuclear
Energy is conserved!
Work
 Relates force to change in energy
 

W  F  ( x f  xi )
 Fx cos 
 Scalar quantity
 Independent of time
Units of Work and Energy
W  Fx
SI unit = Joule
1 J = 1 Nm = 1 kgm2/s2
Work can be positive or negative
 Man does positive work
lifting box
 Man does negative work
lowering box
 Gravity does positive
work when box lowers
 Gravity does negative
work when box is raised
Kinetic Energy
1 2
KE  mv
2
Same units as work
Remember the Eq. of motion
2
vf
2
 vi
 2ax
Multiply both sides by m/2,
1 2 1 2
mv f  mvi  max
2
2
KE f  KEi  Fx
Example 5.1
A skater of mass 60 kg has an initial velocity of 12
m/s. He slides on ice where the frictional force is 36
N. How far will the skater slide before he stops?
120 m
Potential Energy
If force depends on distance,
PE   Fx
For gravity (near Earth’s surface)
PE  mgh
Mysterious Rolling Demo
Conservation of Energy
PE f  KE f  PEi  KEi
KE  PE
Conservative forces:
• Gravity, electrical, QCD…
Non-conservative forces:
• Friction, air resistance…
Non-conservative forces still conserve energy!
Energy just transfers to thermal energy
Example 5.2
A diver of mass m drops from
a board 10.0 m above the
water surface, as in the
Figure. Find his speed 5.00 m
above the water surface.
Neglect air resistance.
9.9 m/s
Example 5.3
A skier slides down the frictionless slope as shown.
What is the skier’s speed at the bottom?
start
H=40 m
finish
L=250 m
28.0 m/s
Example 5.4
Two blocks, A and B (mA=50 kg and mB=100 kg), are
connected by a string as shown. If the blocks begin
at rest, what will their speeds be after A has slid
a distance s = 0.25 m? Assume the pulley and
incline are frictionless.
1.51 m/s
s
Example 5.5
Three identical balls are
thrown from the top of a
building, all with the same
initial speed. The first ball
is thrown horizontally, the
second at some angle above
the horizontal, and the third
at some angle below the
horizontal as in the figure
below. Neglecting air
resistance, rank the speeds
of the balls as they reach
the ground.
All 3 have same speed!
Springs (Hooke’s Law)
F  kx
Proportional to
displacement from
equilibrium
Potential Energy of Spring
1
 PE  (kx) x
2
1 2
PE  kx
2
PE=-Fx
F
x
Example 5.6
A 0.50-kg block rests on a horizontal, frictionless
surface as in the figure; it is pressed against a light
spring having a spring constant of k = 800 N/m, with
an initial compression of 2.0 cm.
x
a) After the block is released, find the speed of
the block at the bottom of the incline, position (B).
b) Find the maximum distance d the block travels up
the frictionless incline if the incline angle θ is 25°.
a) 0.8 m/s
b) 7.7 cm
Example 5.7
A spring-loaded toy gun shoots a 20-g
cork 40 m into the air after the
spring is compressed by a distance of
1.5 cm.
a) What is the spring constant?
b) What is the maximum acceleration
experienced by the cork?
a) 69,760 N/m
b) 52,320 m/s2
Graphical connection between F and PE
PE   Fx
F
x1
x
x2
x
PE2  PE1  Area under curve
Graphical connection between F and PE
PE
PE   Fx
PE
F 
x
F = -slope, points down hill
x
Graphs of F and PE for spring
PE=(1/2)kx2
F=-kx
x
x
Force pushes you to bottom of potential well
PE (J)
Example 5.8
60
Etot
50
40
30
20
10
0
0
1.0
2.0
3.0
4.0
A particle of mass m = 0.5 kg is at a position
x (m)
x = 1.0 m and has a velocity of -10.0 m/s.
What is the furthest points to the left and right
it will reach as it oscillates back and forth?
0.125 and 3.75 m
Power
 Power is rate of energy transfer
W
P
t

SI units are Watts (W)
2
m
1 W  1 J / s  1 kg 3
s
 US Customary units are hp (horse power)
1 hp  550 ft  lb/s  746 W
Example 5.9
An elevator of mass 550 kg and a counterweight
of 700 kg lifts 23 drunken 80-kg students to
the 7th floor of a dormitory 30 meters off the
ground in 12 seconds. What is the power
required? (in both W and hp)
41 kW =55.6 hp
Example 5.10
A 1967 Corvette has a weight of 3020 lbs. The 427
cu-in engine was rated at 435 hp at 5400 rpm.
a) If the engine used all 435 hp at 100% efficiency
during acceleration, what speed would the car attain
after 6 seconds?
b) What is the average acceleration? (in “g”s)
a) 119 mph
b) 0.91g
Power: Force and velocity
KE Fx
P

t
t
P  Fv
For the same force, power is higher for higher v
Example 5.11
Consider the Corvette (w=3020 lbs) having constant
acceleration of a=0.91g
a) What is the power when v=10 mph?
b) What is the power output when v=100 mph?
a) 73.1 hp
b) 732 hp
(in real world a is larger at low v)
Example 5.12
A physics professor bicycles through air at a speed of
v=30 km/hr. The density of air is 1.29 kg/m3. The
professor has cross section of 0.35 m2. Assume all of
the air the professor comes in contact with is
accelerated to v.
a) What is the mass of the air swept out by the
professor in one second?
b) What is the power required to accelerate this air?
a) 10.75 kg
b) 373 W = 0.5 hp
Example 5.13
Find the dimensions of the drag coefficient c in
the equation
P
c
2
Av
3
c is dimensionless
If c=0.4, and the professor’s conversion of food to work
is 20% efficient, how many kilocalories must the professor
burn to cycle for 3 hours?
(=1.29 kg/m3, A= 0.35 m2, v=30 km/hr, 1 kcal=4186 J)
673 kcal
When we discuss diets cal.s actually refer to kcal!
Example 5.14
If a professor burns 75 W
bicycling at 30 km/hr, how
much power would burn
bicycling at Lance
Armstrong’s speed of 45
km/hr?
253 W
Ergometer Demo
Example 5.15
A dam wishes to produce 50 MW of power. If the
height of the dam is 75 m, what flow of water is
required? (in m3/s)
68.9 m3/s = 1.80x104 gallons/s
2001 cost of electricity
Example 5.16
How much money does it cost to run a 100-W light
bulb for one year if the cost of electricity is 8.0
cents/kWhr?
$ 70.08
Some energy facts
http://css.snre.umich.edu
 US consumes 24% of Worlds energy (5% of population)
 Each day, each of us consumes:
o 3 gallons of oil
o 20 lbs of coal
o 221 cubic feet of natural gas
 In 2000 the US consumed 9.9x1016 BTUs
1 BTU is energy required to raise 1 lb of H20 1 degree F
1BTU = 1055 J
Einstein...
“Rest” energy
2
E  mc
c is velocity of light
For small velocities,
1 2
E  mc  mv
2
2
For any v,
E  mc
2
2
v
1 2
c
Example
Suppose one had a supply of anti-matter which
one could mix with matter to produce energy. What
mass of antimatter would be required to satisfy the
U.S. energy consumption in 2000? (9.9x1016 BTUs)
574 kg
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