Aim: More conservation of Energy
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Transcript of Aim: More conservation of Energy
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Aim: More conservation of Energy
Do Now:A 2 kg mass is dropped from a height of 10 m. What is the KE as it strikes the ground?ΔKE = ΔPEΔKE = mgΔhΔKE = (2 kg)(9.8 m/s2)(10 m)ΔKE = 196 J
HW #10Answer Key
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1. A ball thrown vertically downward strikes a horizontal surface with a speed of 15 meters per second. It then bounces, and reaches a maximum height of 5 meters. Neglect air resistance on the ball.
a. What is the speed of the ball immediately after it rebounds from the surface?
b. What fraction of the ball's initial kinetic energy is apparently lost during the bounce?
ghv
ghv
mghmv
2
2/1
2/1
0
20
20
smv
msmv
/9.9
)5)(/8.9(2
0
20
2
22
2/1
2/12/1
i
fi
i
i
mv
mvmv
K
K
lostenergyK
K
56.0
)/15(2/1
)/9.9(2/1)/15(2/12
22
i
i
K
K
sm
smsm
K
K
Calculator
**5 minutes**
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2. A 0.10-kilogram solid rubber ball is attached to the end of an 0.80-meter length of light thread. The ball is swung in a vertical circle, as shown in the diagram above. Point P, the lowest point of the circle, is 0.20 meter above the floor. The speed of the ball at the top of the circle is 6.0 meters per second, and the total energy of the ball is kept constant.
Calculator
**15 minutes**
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a.Determine the total energy of the ball, using the floor as the zero point for gravitational potential energy.
ET = U + KET = mgh + ½ mv2
ET = (0.1 kg)(9.8 m/s2)(1.8 m) + ½ (0.1 kg)(6 m/s)2
ET = 3.6 J
![Page 5: Aim: More conservation of Energy](https://reader030.fdocuments.us/reader030/viewer/2022013112/568130f1550346895d971496/html5/thumbnails/5.jpg)
b. Determine the speed of the ball at point P, the lowest point of the circle.
smv
msmkgJkg
v
mghEm
v
mghEmv
UEK
tpoinlowestatKUE
T
T
T
T
/2.8
)2.0)(/8.9)(1.0(6.31.0
2
2
2/1
)(
2
2
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c. Determine the tension in the thread ati. the top of the circle
NT
smkgm
smkgT
mgr
mvT
r
mvmgT
r
mvF
maF
c
cc
5.3
)/8.9)(1.0(8.0
)/6)(1.0( 22
2
2
2
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ii. the bottom of the circle.
NT
smkgm
smkgT
mgr
mvT
r
mvmgT
r
mvF
maF
c
cc
.5.9
)/8.9)(1.0(8.0
)/2.8)(1.0( 22
2
2
2
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The ball only reaches the top of the circle once before the thread breaks when the ball is at the lowest point of the circle.
d. Determine the horizontal distance that the ball travels before hitting the floor.
y = vot + ½ at2
y = ½ gt2
t2 = 2y/gt2 = 2(0.2 m)/9.8 m/s2
t2 = 0.04 s2
t = 0.2 s
vx = x/tx = vxtx = (8.2 m/s)(0.2 s)x = 1.6 m
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P
Calculator
**17 minutes**3.
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ii. Calculate the value vmax of this maximum speed
smv
msmv
ghv
mghmv
UK
A
A
/42
)90)(/8.9(2
2
2/1
max
2max
max
2max
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b. Calculate the speed vB of the car at point B.
smv
vkgmsmkgJ
mvmghE
JE
msmkgE
mghE
B
B
BBT
T
T
AT
/28
)700(2/1)50)(/8.9)(700(400,617
2/1
400,617
)90)(/8.9)(700(
22
2
2
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Fg N
Fg = mg
Fg = (700 kg)(9.8 m/s2)
Fg = 6860 N
NN
Nm
smkgN
mgr
mvN
r
mvmgN
r
mvF
B
c
580,20
686020
)/28)(700( 2
2
2
2
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Flatten out the track on either side of the loop so the bottom of the loop is on the ground, thus lowering point B. The work done by friction will reduce the total mechanical energy available at point B, so if the kinetic energy at point B is to remain the same, the potential energy at that point must be reduced.