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Classical Mechanics Lecture 18
Today’s Concepts: a) Sta2c Equilibrium
b) Poten2al Energy & Stability
Mechanics Lecture 18, Slide 1
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Clicker Question
A (sta2c) mobile hangs as shown below. The rods are massless and have lengths as indicated. The mass of the ball at the boJom right is 1 kg.
What is the total mass of the mobile?
A) 4 kg B) 5 kg C) 6 kg
D) 7 kg
E) 8 kg 1 kg
1 m 3 m
1 m 2 m
Mechanics Lecture 18, Slide 4
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CheckPoint
In which of the sta.c cases shown below is the tension in the suppor.ng wire bigger? In both cases the red strut has the same mass and length.
A) Case 1 B) Case 2 C) Same
Mechanics Lecture 18, Slide 7
300
L/2
T2
Case 2
300
T1
LM
Case 1
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CheckPointIn which of the sta2c cases shown below is the tension in the suppor2ng wire bigger? In both cases the red strut has the same mass and length.
A) Case 1
B) Case 2
C) Same
A) Case 1 because the lever arm distance is the largest there B) The torque caused by gravity is equal to the torque caused by the tension. Since in Case 1, the lever arm is longer, the force does not need to be as long to equalize the torque caused by gravity. C) The angles are the same so the tensions are the same, the lengths do not maJer.
Mechanics Lecture 18, Slide 8
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CM
Mg
T1 T2 T1 = T2 = TSame distance from CM:
T = Mg/2So:
Mechanics Lecture 18, Slide 9
T1 + T2 = MgBalance forces:
Homework Problem
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Mechanics Lecture 18, Slide 10
Homework Problem
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These are the quan22es we want to find:
Mechanics Lecture 18, Slide 11
d
Mg y
x
α
T1
M
ACM
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What is the moment of iner2a of the beam about the rota2on axis shown by the blue dot?
A)
B)
C)
L
Clicker Question
Mechanics Lecture 18, Slide 12
dM
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The center of mass of the beam accelerates downward. Use this fact to figure out how T1 compares to weight of the beam?
A) T1 = Mg
B) T1 > Mg
C) T1 < Mg
Clicker Question
Mechanics Lecture 18, Slide 13
T1
Mgy
x
ACM
α
d
M
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The center of mass of the beam accelerates downward. How is this accelera2on related to the angular accelera2on of the beam?
A) ACM = dα
B) ACM = d /α
C) ACM = α / d
Clicker Question
Mechanics Lecture 18, Slide 14
T1
Mgy
x
α
dM
ACM
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Apply
Apply
Plug this into the expression for T1
ACM = dα
Use ACM = dα to find α
Mechanics Lecture 18, Slide 15
T1
Mgy
x
α
dM
ACM
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CM demos
A\er the right string is cut, the meters2ck swings down to where it is ver2cal for an instant before it swings back up in the other direc2on.
What is the angular speed when the meter s2ck is ver2cal?
Mechanics Lecture 18, Slide 16
M
y
x
d
T
ω
Conserve energy:
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y
xMg
d ACM = ω2d
Centripetal accelera2on
Mechanics Lecture 18, Slide 17
T
ω
Applying
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Another HW problem:
We will now work out the general case
Mechanics Lecture 18, Slide 18
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General Case of a Person on a Ladder
Bill (mass m) is climbing a ladder (length L, mass M) that leans against a smooth wall (no fric.on between wall and ladder). A fric.onal force f between the ladder and the floor keeps it from slipping. The angle between the ladder and the wall is φ.
(The wall is fric.onless.)
How does f depend on the angle of the ladder and Bill’s distance up the ladder?
θ
L
m
f
y
x
MBill
Mechanics Lecture 18, Slide 19
φ
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Balance forces:
x: Fwall = f y: N = Mg + mg
Balance torques:
Mg
mg
θ
L/2
f y
xN
Fwall
daxis
Mechanics Lecture 18, Slide 20
f =�mg
dL+
Mg2
�cot θ
Fwall =
�mg
dL+
Mg2
�cot θ
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f =�mg
dL+
Mg2
�cot θ
θf
d
M
m
Lets try it out
Climbing further up the ladder makes it more likely to slip:
Making the ladder more ver2cal makes it less likely to slip:
This is the General Expression:
Mechanics Lecture 18, Slide 21 θ (radians)
cotangent θ
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f =�mg
dL+
Mg2
�cot θ
Moving the boJom of the ladder further from the wall makes it more likely to slip:
If its just a ladder…
Mechanics Lecture 18, Slide 22
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In the two cases shown below iden2cal ladders are leaning against fric2onless walls. In which case is the force of fric2on between the ladder and the ground the biggest?
A) Case 1 B) Case 2 C) Same
CheckPoint
Case 1 Case 2
Mechanics Lecture 18, Slide 23
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In the two cases shown below iden2cal ladders are leaning against fric2onless walls. In which case is the force of fric2on between the ladder and the ground the biggest?
A) Case 1 B) Case 2 C) Same
Case 1 Case 2A) Because the boJom of the ladder is further away from the wall.
B) The angle is steeper, which means there is more normal force and thus more fric2on.
C) Both have same mass.
Mechanics Lecture 18, Slide 24
CheckPoint
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CheckPoint
Suppose you hang one end of a beam from the ceiling by a rope and the boKom of the beam rests on a fric.onless sheet of ice. The center of mass of the beam is marked with an black spot. Which of the following configura.ons best represents the equilibrium condi.on of this setup?
A) B) C)
Mechanics Lecture 18, Slide 25
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CheckPointWhich of the following configura.ons best represents the equilibrium condi.on of this setup?
A) B) C)
If the tension has any horizontal component, the beam will accelerate in the horizontal direc2on.
Objects tend to aJempt to minimize their poten2al energy as much as possible. In Case C, the center of mass is lowest.
Mechanics Lecture 18, Slide 26
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footprint
footprint
Stability & Potential Energy
Mechanics Lecture 18, Slide 27
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A Question of Balance
Picking up $20
Everyone loves to pick up extra money. We bet you can't stand with your heels touching both a wall, the floor and each other, and then bend over (without bending your knees!) and pick up a $20 dollar bill that's lying in front of you without moving your heels away from the floor and the wall. (No fair using a wall with a baseboard either!) You must be able to resume your upright position again without having moved your heels. We're sure enough that this task is very difficult to stake money on it! All of you taking calculus-based introductory physics this semester who can perform this task before the end of the class period under the sharp eye of a bona fide instructor can share the $20 with any others taking the course who can also do the "pickup" job!