http://jgerton/2210.html mechanics lecture 10, slide 1 announcements quiz 4 on friday covers unit 7...
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Mechanics Lecture 10, Slide 1
Announcements Quiz 4 on Friday
Covers Unit 7 (Work and Energy) and Unit 8 (Potential Energy)
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Mechanics Lecture 10, Slide 2
Lecture 10: Center of Mass
Today’s Concept:Center of mass Finding it Using it
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Mechanics Lecture 10, Slide 3
Center of Mass
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Mechanics Lecture 10, Slide 4
Cube Example
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Mechanics Lecture 10, Slide 5
Cube Example: Using Volume Mass Density
ρ = mass density(mass/volume)
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Mechanics Lecture 10, Slide 6
Cube Example: CM Calculation
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Mechanics Lecture 10, Slide 7
x = Lx = 0
ExerciseShow mathematically that the center of mass of a uniform stick of length L and mass M is at x = L/2.
dm
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Mechanics Lecture 10, Slide 8
x = Lx = 0
ExerciseShow mathematically that the center of mass of a uniform stick of length L and mass M is at x = L/2.
dm
L
dxMdm dx
L
M
xdmM
xcm
1
Ldx
L
Mx
M 0
1 L
xdxL 0
1
L
xL 0
2
2
11
22 0
2
11 L
L 2
L
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Mechanics Lecture 10, Slide 9
Center of Mass for System of Objects
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Mechanics Lecture 10, Slide 10
The disk shown in Case 1 clearly has its CM at the center. Suppose the disk is cut in half and the pieces arranged as shown in Case 2
In which case is the center of mass highest?
ACT: Disk vs. 2 half-disks
Case 1 Case 2
xCM
x
A) Case 1 B) Case 2 C) same
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Mechanics Lecture 10, Slide 11
The disk shown in Case 1 clearly has its CM at the center. Suppose the disk is cut in half and the pieces arranged as shown in Case 2
In which case is the center of mass highest?
A) Case 1 B) Case 2 C) same
ACT: Disk vs. 2 half-disks
Case 1 Case 2
xCM
x
x
x
x
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Mechanics Lecture 10, Slide 12
If the net external force is zero, the CM won’t accelerate
Kinematic Quantities
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Mechanics Lecture 10, Slide 13
ACT: System of particles
A) 00
B) 0H/2
C) 0H/3
D) H/4H/4
E) H/40
x y
x
y
H
Three tiny equal-mass magnets are placed on a horizontal frictionless surface at the corners of an equilateral triangle. When the magnets are released, they attract and quickly slide to a single point. What are the coordinates of that point?
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Mechanics Lecture 10, Slide 14
C) 0 H/3
X Y
(symmetry)
x
y
H
0CMX
3
H
321
332211
mmm
ymymymYCM
m
Hmmm
3
00
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Mechanics Lecture 10, Slide 15
= -1 m
Homework Problem
= 0.975 m 4321
44332211
mmmm
xmxmxmxmxcm
4321
44332211
mmmm
ymymymymycm
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Mechanics Lecture 10, Slide 16
Homework Problem
4321
,44,33,22,11, mmmm
vmvmvmvmv xxxx
xcm
4321
,44,33,22,11, mmmm
vmvmvmvmv yyyy
ycm
2,
2, ycmxcmcm vvv
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Mechanics Lecture 10, Slide 17
m5 CM moves toward m5
ABCD
cm
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Mechanics Lecture 10, Slide 18
m5 CM moves toward m5
cm
ABC
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Mechanics Lecture 10, Slide 19
CheckPoint: System of Two Masses
Two objects, one having twice the mass of the other, are initially at rest. Two forces, one twice as big as the other, act on the objects in opposite directions as shown.
A) ACM = F/M to the right
B) ACM = F/(3M) to the right
C) ACM = 0
D) ACM = F/(3M) to the left
E) ACM = F/M to the left
Which of the following statements about the acceleration of the center of mass of the system is true?
F2F M2M
About 42% answered correctly.
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Mechanics Lecture 10, Slide 20
CheckPoint Revote: System of Two Masses
Which of the following statements about the acceleration of the center of mass of the system is true:
C) The actual masses are accelerating away from each other at the same rate so the center of mass does not change.
D) CM acceleration is defined as the sum of the total forces divided by the total mass. Total mass is 3m. The forces are not equal, therefore the greater force will determine the direction of acceleration.
E) The acceleration of the center of mass is equal to the external force divided by the total mass.
C) ACM = 0
D) ACM = F/(3M) to the left
E) ACM = F/M to the left
F2F M2M
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Mechanics Lecture 10, Slide 21
ACT: System of 2 Masses
A) B) C) D)
Two objects, one having twice the mass of the other, are initially at rest. A force F pushes the mass M to the right. A force pushes the mass 2M upward. What is the acceleration of the center of mass?
M2MF
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Mechanics Lecture 10, Slide 22
CheckPoint: Two Men Pulling
A) -3 m B) 0 m C) 3 m
-3 m 0 m 3 m
Two guys who weigh the same are holding onto a massless pole while standing on horizontal frictionless ice. If the guy on the left starts to pull on the pole, where do they meet?
Where is the center of mass of the system initially?
Does the center of mass accelerate?
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Mechanics Lecture 10, Slide 23
ACT: 2 guys pulling, II
A) -3 m
B) -1 m
C) 0 m
D) 1 m
E) 3 m
A large skinny guy with mass 2M and a smaller guy with mass M are holding onto a massless pole while standing on frictionless ice, as shown below. If the little guy pulls himself toward the big guy, where would they meet?
-3 m 0 m 3 m
2M M
Where is the center of mass of the system initially?
Does the center of mass accelerate?
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Mechanics Lecture 10, Slide 24
A) -3 m
B) -1 m
C) 0 m
D) 1 m
E) 3 m
A large skinny guy with mass 2M and a smaller guy with mass M are holding onto a massless pole while standing on frictionless ice, as shown below. If the little guy pulls himself toward the big guy, where would they meet?
-3 m 0 m 3 m
2M M
M
MM
3
)3()3(2 m m = -1
m21
2211
mm
xmxmXCM
ACT: 2 guys pulling, II