chapter 5 work, energy, and power. work w = f x this equation applies when the force is in the same...
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![Page 1: Chapter 5 Work, Energy, and Power. Work W = F x This equation applies when the force is in the same direction as the displacement are in the same direction](https://reader035.vdocuments.mx/reader035/viewer/2022062314/56649e8a5503460f94b8f724/html5/thumbnails/1.jpg)
Chapter 5
Work, Energy, and Power
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Work W = F x
This equation applies when the force is in the same direction as the displacement
are in the same direction
and F x
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A linebacker pushes against the blocker but the blocker does not move. The work is:
Positive
Negative
Zero
Not e
nough in
fo
0% 0%0%0%
1. Positive2. Negative3. Zero4. Not enough info
Answer Now
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When doing a bench press, you gradually lower the bar down to your chest. The work done by you is:
Positive
Negative
Zero
Not e
nough in
fo
0% 0%0%0%
1. Positive2. Negative3. Zero4. Not enough info
Answer Now
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When doing a bench press, you gradually lower the bar down to your chest. The work done by gravity is:
Positive
Negative
Zero
Not e
nough in
fo
0% 0%0%0%
1. Positive2. Negative3. Zero4. Not enough info
Answer Now
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When doing a curl, you exert a force to raise the dumbbell to your shoulder. The work done by you is:
Positive
Negative
Zero
Not e
nough in
fo
0% 0%0%0%
1. Positive2. Negative3. Zero4. Not enough info
Answer Now
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Because your two-year old cousin refuses to move, you pull him along the ground while tugging at an angle. The work done is:
Positive
Negative
Zero
Not e
nough in
fo
0% 0%0%0%
1. Positive2. Negative3. Zero4. Not enough info
Answer Now
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If there exists a force on an object an the object moves, work must have been done.
True
False
0%0%
1. True2. False
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Work Can Be Positive or Negative Work is positive
when lifting the box
Work would be negative if lowering the box The force would
still be upward, but the displacement would be downward
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When Work is Zero Displacement is
horizontal Force is vertical cos 90° = 0
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Units of Work SI
Newton • meter = Joule N • m = J J = kg • m2 / s2
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Work W = (F cos )x
q is the angle between
If = 0, cos = 1, and W = F Δx
If = 90o, cos = 0, and W = 0
and F x
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More About Work The work done by a force is zero
when the force is perpendicular to the displacement cos 90° = 0
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Limitations of Work This gives no information about:
the time it took for the displacement to occur
-or- the velocity or acceleration of the
object
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Work is a Scalar Even though the sign matters (like
vectors), the sign does not indicate the direction if travel.
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Let’s try some practice problems:
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Kinetic Energy Energy associated with the motion
of an object Scalar quantity measured in Joules
2mv2
1KE
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Work-Kinetic Energy Theorem
The net work done on an object is equal to the change in the object’s kinetic energy
Speed will increase if work is positive Speed will decrease if work is negative
net fiW KE KE KE
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Gravitational Potential Energy Gravitational potential energy is
associated with the vertical position of the object
PEgrav = mgy y = vertical position (relative to a
reference point – usually ground) g = acceleration due to gravity
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Conservation of Mechanical Energy Total mechanical energy is the sum
of the kinetic and potential energies in the system and is stays constant (if closed system)
ffii
fi
PEKEPEKE
EE
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On which track does the marble have the largest initial potential energy?
Gre
en
Yellow
Red Blue
All the sa
me
0% 0% 0%0%0%
1. Green2. Yellow3. Red4. Blue5. All the same
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On which track will the marble have the largest final velocity?
Gre
en
Yellow
Red Blue
All the sa
me
0% 0% 0%0%0%
1. Green2. Yellow3. Red4. Blue5. All the same
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On which track does the marble have the largest total mechanical energy at the beginning?
Gre
en
Yellow
Red Blue
All the sa
me
0% 0% 0%0%0%
1. Green2. Yellow3. Red4. Blue5. All the same
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If a steel marble is released down the green track and a plastic marble goes down the blue track, which will have the greater velocity at the end of the track?
Steel
Plastic
Same
0% 0%0%
1. Steel2. Plastic3. Same
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If a steel marble is released down the green track and a plastic marble goes down the blue track, which will have the greater kinetic energy at the end of the track?
Steel
Plastic
Same
0% 0%0%
1. Steel2. Plastic3. Same
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On which track did the marble have the largest average velocity?
Gre
en
Yellow
Red Blue
All the sa
me
0% 0% 0%0%0%
1. Green2. Yellow3. Red4. Blue5. All the same
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On which track did the marble have the second largest average velocity?
Gre
en
Yellow
Red Blue
All the sa
me
0% 0% 0%0%0%
1. Green2. Yellow3. Red4. Blue5. All the same
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Notes About Conservation of Energy We can neither create nor destroy
energy Another way of saying energy is
conserved If the total energy of the system does
not remain constant, the energy must have crossed the boundary by some mechanism (friction, heat, sound, …)
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When graphing F vs. –x, what was the relationship?
Linear
Quadratic
Power Functi
on
Inverse
No re
lationshi...
0% 0% 0%0%0%0%
10%
20%
30%
40%
50%
60%
70%
80%
90%
100%
1. Linear2. Quadratic3. Power Function4. Inverse5. No relationship
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Springs – Hooke’s Law
One of the simplest type of simple harmonic motion is called Hooke's Law. This is primarily in reference to SPRINGS.
kxorkxF
k
k
xF
s
s
N/m):nitConstant(U Spring
alityProportion ofConstant
The negative sign only tells us that “F” is what is called a RESTORING FORCE, in that it works in the OPPOSITE direction of the displacement.
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Hooke’s Law
Felas = -kx
Felas = Elastic force of the spring (force points back to equilibrium position.) (N)
k = Spring constant (N/m)x = displacement from equilibrium (m)
(note:opposite to direction of the elastic force)
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Hooke’s Law from a Graphical Point of View
x(m) Force(N)
0 0
0.1 12
0.2 24
0.3 36
0.4 48
0.5 60
0.6 72
graph x vs.F a of Slope
kx
Fk
kxF
s
sSuppose we had the following data:
Force vs. Displacement y = 120x + 1E-14
R2 = 1
0
10
20
30
40
50
60
70
80
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7
Displacement(Meters)
Fo
rce(
New
ton
s) k =120 N/m
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We have seen F vs. x Before!!!!
Force vs. Displacement y = 120x + 1E-14
R2 = 1
0
10
20
30
40
50
60
70
80
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7
Displacement(Meters)
Fo
rce(
New
ton
s)
Work or ENERGY = FDx
Since WORK or ENERGY is the AREA, we must get some type of energy when we compress or elongate the spring. This energy is the AREA under the line!
Area = ELASTIC POTENTIAL ENERGY
Since we STORE energy when the spring is compressed and elongated it classifies itself as a “type” of POTENTIAL ENERGY, Us. In this case, it is called ELASTIC POTENTIAL ENERGY.
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Elastic Potential Energy
The graph of F vs.x for a spring that is IDEAL in nature will always produce a line with a positive linear slope. Thus the area under the line will always be represented as a triangle.
NOTE: Keep in mind that this can be applied to WORK or can be conserved with any other type of energy.
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Elastic potential energy
20
2
00
21|
2|
)(
)()(
kxUWx
kW
dxxkdxkxW
dxkxdxxFW
springxx
x
x
x
x
Elastic “potential” energy is a fitting term as springs STORE energy when there are elongated or compressed.
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Conservation of Energy in Springs
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Strain PE vs. Gravitational PE
The area under the curve on the left equals the energy stored in a linear spring, or the amount of work required to deform the spring.
The area under the curve on the right equals the potential energy due to the constant force of gravity (mg), or the work required to lift an object x m.
Note that one area is square and the other triangular.
Force (N)
x (m)0
Strain
Force (N)“mg”
x (m) “h”
0Gravitational
½Fx Fxor
mgh
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Power Often also interested in the rate at
which the energy transfer takes place Power is defined as this rate of energy
transfer
SI units are Watts (W)
WFv
t
2
2
J kg mW
s s
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Power, cont. US Customary units are generally hp
Need a conversion factor
W746s
lbft550hp1
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Work is done when
the disp
lacement is
not ...
the disp
lacement is
zero
.
the fo
rce is
zero
.
the fo
rce and disp
laceme..
0% 0%0%0%
1. the displacement is not zero.
2. the displacement is zero.
3. the force is zero.4. the force and
displacement are perpendicular.
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If both the mass and the velocity of a ball are tripled, the kinetic energy of the ball is increased by a factor of
3. 6. 9.27.
0% 0%0%0%
1. 3.2. 6.3. 9.4. 27.
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Of the following examples, the one that represents work as defined by a scientist is:
lifting a
book from your..
.
leaning o
n a sh
ovel w
hil...
pushing hard
against
a w...
carry
ing a heavy
box on...
0% 0%0%0%
1. lifting a book from your desk.
2. leaning on a shovel while others labor.
3. pushing hard against a wall for an hour.
4. carrying a heavy box on your head.
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The ability to do work is defined as:
force
and measu
red in
j...
energy a
nd measu
red in
...
power and m
easured in
...
energy a
nd measu
red in
...
0% 0%0%0%
1. force and measured in joules.
2. energy and measured in watts.
3. power and measured in watts.
4. energy and measured in joules.
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A rolling wagon has 50 joules of kinetic energy. If the wagon’s velocity is doubled, the kinetic energy of the wagon:
is re
duced to
25 joules.
is in
creas
ed to 100 jo
ules.
is in
creas
ed to 200 jo
ules.
remains t
he same.
0% 0%0%0%
1. is reduced to 25 joules.
2. is increased to 100 joules.
3. is increased to 200 joules.
4. remains the same.