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Transcript of Work, Energy, and Power Samar Hathout KDTH 101. Work is the transfer of energy through motion. In...
![Page 1: Work, Energy, and Power Samar Hathout KDTH 101. Work is the transfer of energy through motion. In order for work to take place, a force must be exerted.](https://reader036.fdocuments.in/reader036/viewer/2022081519/56649cbb5503460f94983afc/html5/thumbnails/1.jpg)
Work, Energy, and PowerWork, Energy, and Power
Samar Hathout
KDTH 101
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Work is the transfer of energy through motion. In order for work to take place, a force must be exerted through a distance. The amount of work done depends on two things: the amount of force exerted and the distance over which the force is applied. There are two factors to keep in mind when deciding when work is being done: something has to move and the motion must be in the direction of the applied force. Work can be calculated by using the following formula: Work=force x distance
WorkWork
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Work is done on the books when they are being lifted, but no work is done on them when they are being held or carried horizontally.
WorkWork
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Work can be positive Work can be positive or negativeor 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
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Work done by a constant ForceWork done by a constant Force
Ekin = Wnet
• W = F s = |F| |s| cos = Fs s
|F| : magnitude of force |s| = s : magnitude of displacement Fs = magnitude of force in direction of displacement :
Fs = |F| cos
: angle between displacement and force vectors• Kinetic energy : Ekin= 1/2 m v2
• Work-Kinetic Energy Theorem:
F
s
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Work Done by GravityWork Done by Gravity
Example 1: Drop ball
Yi = h
Yf = hf
Wg = (mg)(S)
S = h0-hf
Wg = mg(h0-hf)
= mg(h0-hf)
= Epot,initial – Epot,final
mgS
y
x
Yi = h0
mgS
y
x
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Work Done by GravityWork Done by Gravity
Example 2: Toss ball up
Wg = (mg)(S)
S = h0-hf
Wg =-mg(h0-hf)
= Epot,initial – Epot,final
Yi = h0
Yf = hf
mgS
y
x
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Work Done by GravityWork Done by Gravity
Example 3: Slide block down incline
Wg = (mg)(S)cos
S = h/cos
Wg = mg(h/cos)cos
Wg = mgh
with h= h0-hf
h
mgS
Work done by gravity is independent of path
taken between h0 and hf
=> The gravitational force is a conservative force.
h0
hf
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Work done by a Variable ForceWork done by a Variable Force
The magnitude of the force now depends on the
displacement: Fs(s)
Then the work done by this force is equal to the
area under the graph of Fs versus s, which can be
approximated as follows:
W = Wi Fs(si) s = (Fs(s1)+Fs(s2)+…) s
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Concept QuestionConcept Question
Imagine that you are comparing three different ways of having a ball move down through the same height. In which case does the ball reach the bottom with the highest speed?
1. Dropping2. Slide on ramp (no friction)3. Swinging down4. All the same
In all three experiments, the balls fall from the same height and therefore the same amount of their gravitational potential energy is converted to kinetic energy. If their kinetic energies are all the same, and their masses are the same, the balls must all have the same speed at the end.
1 2 3correct
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Kinetic Energy Potential Energy
Types of Energy
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Radiant ElectricalChemical
Thermal Nuclear
Magnetic
Sound
Mechanical
Forms of Energy
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Mechanical energy is the movement of machine parts. Mechanical energy is also the total amount of kinetic and potential energy in a system. Wind-up toys, grandfather clocks, and pogo sticks are examples of mechanical energy. Wind power uses mechanical energy to help create electricity.
Potential energy + Kinetic energy = Mechanical energy
Mechanical EnergyMechanical Energy
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Potential energy + Kinetic energy = Mechanical energy
Example of energy changes in a swing or pendulum.
Mechanical EnergyMechanical Energy
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Conservation of Mechanical EnergyConservation of Mechanical Energy
Total mechanical energy of an object remains constant provided the net work done by non-conservative
forces is zero: Etot = Ekin + Epot = constantor
Ekin,f+Epot,f = Ekin,0+Epot,0
Otherwise, in the presence of net work done bynon-conservative forces (e.g. friction):
Wnc = Ekin,f – Ekin,0 + Epot,f-Epot,i
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Example ProblemExample Problem
Suppose the initial kinetic and potential energies of a system are 75J and 250J respectively, and that the final kinetic and potential energies of the same system are 300J and -25J respectively. How much work was done on the system by non-conservative forces? 1. 0J 2. 50J 3. -50J 4. 225J 5. -225J
correct
Work done by non-conservative forces equals the difference between final and initial kinetic energies plus the difference between the final and initial gravitational potential energies.
W = (300-75) + ((-25) - 250) = 225 - 275 = -50J.
Samar HathoutSamar Hathout
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Kinetic EnergyKinetic Energy
Same units as work
Remember the Eq. of motion
Multiply both sides by m,
1
2mv f
2 1
2mvi
2 max
KE f KEi Fx
v f2
2vi2
2ax
KE 1
2mv2
Samar Hathout
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ExampleExample
Samar Hathout
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Potential EnergyPotential Energy
Potential energy exists whenever an object which has mass has a position within a force field (gravitational, magnetic, electrical).We will focus primarily on
gravitational potential energy (energy an object has because of its height above the Earth)
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Potential EnergyPotential Energy
If force depends on distance,
For gravity (near Earth’s surface)
PE Fx
PE mgh
Samar Hathout
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Conservation of EnergyConservation of Energy
Conservative forces:• Gravity, electrical, QCD…Non-conservative forces:• Friction, air resistance…Non-conservative forces still conserve energy!Energy just transfers to thermal energy
PE f KE f PEi KEiKE PE
Samar Hathout
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ExampleExample
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
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ExampleExample
A skier slides down the frictionless slope as shown. What is the skier’s speed at the bottom?
H=40 m
L=250 m
start
finish
28.0 m/s
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Example Example
Three identical balls are thrown from the top of a building with the same initial speed. Initially, Ball 1 moves horizontally. Ball 2 moves upward. Ball 3 moves downward.
Neglecting air resistance, which ball has the fastest speed when it hits the ground?A) Ball 1
B) Ball 2C) Ball 3D) All have the same speed.
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Springs (Hooke’s Law)Springs (Hooke’s Law)
Proportional to displacement from equilibrium
F kx
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Potential Energy of Potential Energy of SpringSpring
PE=-Fx
x
F
PE 1
2(kx)x
PE 1
2kx2
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x
Example Example
b) To what height h does the block rise when moving up the incline?
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.
3.2 cm
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Power Power
Average power is the average rate at which a net force
does work:
Pav = Wnet / tSI unit: [P] = J/s = watt (W)
Or Pav = Fnet s /t = Fnet vav
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Example Example
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) 120 mph b) 0.91g
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Example Example
Consider the Corvette (w=3020 lbs) having constantacceleration of a=0.91ga) 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)