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PHYSICS - CLUTCH
CH 13: ROTATIONAL EQUILIBRIUM
EXAMPLE: POSITION OF SECOND KID ON SEESAW
EXAMPLE: A 4 m-long seesaw 50 kg in mass and of uniform mass distribution is pivoted on a fulcrum at its middle, as
shown. Two kids sit on opposite sides of the seesaw. The kid on the left (30 kg) sits on the very edge of the seesaw. How
far from the fulcrum should the kid on the right (40 kg) sit, if they want to balance the fulcrum?
m1 m2
?
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CH 13: ROTATIONAL EQUILIBRIUM
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PRACTICE: BALANCING A BAR WITH A MASS
PRACTICE: A 20 kg, 5 m-long bar of uniform mass distribution is attached to the ceiling by a light string, as shown.
Because the string is off-center (2 m from the right edge), the bar does not hang horizontally. To fix this, you place a small
object on the right edge of the bar. What mass should this object have, to cause the bar to balance horizontally?
m
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PRACTICE: POSITION OF FULCRUM ON SEESAW
PRACTICE: Two kids (m,LEFT = 50 kg, m,RIGHT = 40 kg) sit on the very ends of a 5 m-long, 30 kg seesaw. How far from the
left end of the seesaw should the fulcrum be placed so the system is at equilibrium? (Remember the weight of the seesaw!)
m1 m2
?
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EXAMPLE: MULTIPLE OBJECTS HANGING
EXAMPLE: The system of objects shown is in linear and rotational equilibrium, held by light, vertical ropes and light,
horizontal rods. Calculate the: (a) tension on all 5 vertical ropes; (b) 2 missing masses (mA and mC). Use g = 10 m/s2.
A
4 kg C
1 m
1 m 2 m
4 m
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EQUILIBRIUM WITH MULTIPLE SUPPORTS
● When an object in Equilibrium has MULTIPLE supports, we can think of each support point as a potential ____________.
- Therefore, we can write _____________ for ANY point support, which means treating it as the ____________.
- In fact, we can write ___________ for ANY point, even points that are not the ________ or ____________ points!
- Since you can choose your “reference axis” in writing ___________ equations, you’ll want to pick the easier ones.
- Remember that forces acting ON an axis produce NO torque So pick points with the most forces on it!
EXAMPLE: A board 6 m in length, 12 kg in mass, and of uniform mass distribution, is held by two light ropes, one on its left
edge and the other 1 m away from its right edge, as shown in the first image. An 8 kg object is placed 1 m from the left end.
Calculate the tension of each rope.
m
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PRACTICE: EQUILIBRIUM WITH MULTIPLE SUPPORTS
PRACTICE: A board 8 m in length, 20 kg in mass, and of uniform mass distribution, is supported by two scales placed
underneath it. The left scale is placed 2 m from the left end of the board, and the right scale is placed on the board’s righ t
end. A small object 10 kg in mass is placed on the left end of the board. Calculate the reading on the left scale.
BONUS: Calculate the reading on the right scale.
m
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CENTER OF MASS AND SIMPLE BALANCE
● Remember: An object’s weight ALWAYS acts on its _________________________ ( __________ ).
- Also: If an object has _______________ mass distribution, its ___________ is on its geometric ______________.
- An object “sticking out” of a supporting surface will TILT if its ___________ is located beyond the support’s edge.
- These are Static Equilibrium problems, BUT are solved using ___________, which is much simpler:
X_____ = ________ = _________________
EXAMPLE: HOW FAR CAN YOU GO ON A PLANK?
EXAMPLE: A 20 kg, 10 m-long plank is supported by two small blocks, one located at its left edge and the other 3 m from
its right edge. A 60 kg person walks on the plank. What is the farthest this person can get, to the right of the rightmost
support, before the plank tips?
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NON-UNIFORM MASS DISTRIBUTIONS
● Unless otherwise stated, assume a Rigid Body has UNIFORM mass distribution, so its weight acts on its ____________.
- If it does NOT have uniform mass distribution, you CANNOT assume the location of its _____________________.
- In these problems, you will be given the center of mass and asked to calculate something else (or vice-versa).
EXAMPLE: An 80 kg, 2 m-tall man lies horizontally on a 2 m-long board of negligible mass. Two scales are placed under
the board, at its ends, as shown. If the left and right scales read 320 N and 480 N, respectively, how far from the man’s
head is his center of mass? Use g = 10 m/s2 to simplify your calculations.
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PRACTICE: FORCES ON A PUSH-UP
PRACTICE: A 70 kg, 1.90 m man doing push-ups holds himself in place making 20o with the floor, as shown. His feet and
arms are, respectively, 1.15 m below and 0.4 m above from his center of mass. You may model him as a thin, long board,
and assume his arms and feet are perpendicular to the floor. How much force does the floor apply to each of his hands?
BONUS: How much force does the floor apply to each of his feet?
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STATIC / COMPLETE EQUILIBRIUM IN 2D
● So far we’ve solved Equilibrium problems that were essentially 1 dimensional: all forces acted in the same axis (X or Y).
- More advanced problems have forces in 2 axes, and some will need to be _______________________________.
- Remember however that Torques are _____________, so we will never need to _____________________ them.
EXAMPLE: A ladder of mass 10 kg (uniformly distributed) and length 4 m rests against a vertical wall while making an
angle of 53o with the horizontal, as shown. Calculate the magnitude of the:
(a) Normal force at the bottom of the ladder;
(b) Normal force at the top of the ladder;
(c) Frictional force at the bottom of the ladder;
(d) Minimum coefficient of static friction needed;
(e) Total contact force at the bottom of the ladder.
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PRACTICE: PERSON ON A LADDER
PRACTICE: A ladder of mass 20 kg (uniformly distributed) and length 6 m rests against a vertical wall while making an
angle of Θ = 60o with the horizontal, as shown. A 50 kg girl climbs 2 m up the ladder. Calculate the magnitude of the total
contact force at the bottom of the ladder (Remember: You will need first calculate the magnitude of N,BOT and f,S).
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EXAMPLE: MINIMUM ANGLE AND FRICTION ON LADDER
EXAMPLE: A ladder of mass M (uniformly distributed) and length L rests against a vertical wall while making an angle with
the horizontal, as shown. Derive an expression for the:
(a) Minimum coefficient of static friction necessary for the ladder to stay balanced at an angle of Θ;
(b) Minimum angle at which the ladder can stay balanced, for a coefficient of static friction of μ,S.
(c) Minimum angle at which the ladder can stay balanced, for any coefficient of friction, if there any no masses on it.
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BEAM / SHELF AGAINST A WALL
● Some Static Equilibrium problems have shelf-like objects tensioned against a wall
- In these problems, the hinge (on the wall) applies a force against the beam.
- The hinge always applies a horizontal force against the ________________.
- The hinge almost always applies a force ______ on the beam, to help hold it.
- We’ll assume HY is ______, and if you get a negative for HY, it means it was actually down – which is OK!
EXAMPLE: A beam 300 kg in mass and 4 m in length is held horizontally against a vertical wall by a hinge on the wall and a
light cable, as shown. The cable makes an angle of 37o with the horizontal. Calculate the:
(a) Magnitude of the Tension force on the cable;
(b) Magnitude and direction of the Net Force the hinge applies on the beam.
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PRACTICE: BEAM SUPPORTED BY AN INCLINED ROD
PRACTICE: A beam 200 kg in mass and 6 m in length is held horizontally against a wall by a hinge on the wall and a light
rod underneath it, as shown. The rod makes an angle of 30o with the wall and connects with the beam 1 m from its right
edge. Calculate the angle that the Net Force of the hinge makes with the horizontal (use +/– for above/below +x axis).
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EXAMPLE: BEAM SUPPORTING AN OBJECT
EXAMPLE: A beam 400 kg in mass and 8 m in length is held horizontally against a wall by a hinge on the wall and a light
cable, as shown. The cable makes 53o with the horizontal and connects 2 m from the right edge of the beam. A 500 kg
object hangs from the right edge of the beam. Calculate the magnitude of the net force the hinge applies on the beam.
500
kg
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PRACTICE: INCLINED BEAM AGAINST A WALL
PRACTICE: A beam 200 kg in mass and 4 m in length is held against a vertical wall by a hinge on the wall and a light
horizontal cable, as shown. The beam makes 53o with the wall. At the end of the beam, a second light cable holds a 100 kg
object. Calculate the angle that the Net Force of the hinge makes with the horizontal (use +/– for above/below +x axis).
100
kg
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EXAMPLE: INCLINED BEAM AGAINST THE FLOOR
EXAMPLE: A 100 kg, 4 m-long beam is held at equilibrium by a hinge on the floor and a force you apply on its edge, as
shown. The beam is held at 30o above the horizontal, and your force is directed 50o above the horizontal. Calculate the:
(a) Magnitude of the force you apply on the beam;
(b) Magnitude and direction of the Net Force the hinge applies on the beam.
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PRACTICE: INCLINED BEAM AGAINST THE FLOOR
PRACTICE: A 200 kg, 10 m-long beam is held at equilibrium by a hinge on the floor and a force you apply on it via a light
rope connected to its edge, as shown. The beam is held at 53o above the horizontal, and your rope makes an angle of 30o
with it. Calculate the angle that the Net Force of the hinge makes with the horizontal (use +/– for above/below +x).
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CENTER OF MASS (AND CENTER OF GRAVITY)
● In Physics, sometimes it’s useful to simplify SYSTEM of objects by replacing ALL objects with a single, equivalent object.
- This single object will have mass M = ________ and will be located at the system’s _______________________:
Center of Mass Equation: XCM = _________ = ___________________________.
- If objects are in a 2D plane, we also have: YCM = _________ = ___________________________.
EXAMPLE 1: Two masses are placed along the x-axis: mass A (10 kg) is placed at 0.0 m and mass B (20 kg) at 4.0 m. Find
the Center of Mass of this system.
● A system’s Center of GRAVITY is the same as its Center of MASS IF the gravitational field is ______________.
- Unless otherwise stated, we assume gravitational fields are constant so Center of Gravity = Center of Mass.
EXAMPLE 2: Three masses are placed on an X-Y plane: mass A (10 kg) is placed at coordinates (0, 0) m, mass B (8 kg) at
(0, 3) m, and mass C (6 kg) at (4, 0) m. Find the X, Y coordinates for the Center of Mass of this system.
10 m 2kg 2kg
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TORQUE & STATIC EQUILIBRIUM
● Remember: If the ________________ on an object is ____, then ________, which we call ______________________.
- However, sometimes this is not sufficient for equilibrium. For example:
- So there are actually TWO conditions that are necessary for an object to have “_________________” equilibrium:
(1) First Condition _________ _________ ________________ Equilibrium
(2) Second Condition _________ _________ ________________ Equilibrium
BOTH ________________ Equilibrium
- “Static” refers to the fact that _________ and _________.
- This is sometimes called Equilibrium of Rigid Bodies because we’ll deal with Rigid Bodies only, no Point Masses.
EXAMPLE: In all of the following, a light bar is free to rotate about a perpendicular axis through its center. The bar is not
attached, so it is also free to move horizontally / vertically. All forces have the same magnitude (double arrows are a single
force with double the magnitude). Ignore gravity. For each: Is the object in linear equilibrium? Is it in rotational equilibrium?
[ Linear EQ | Rotational ]
[ Linear EQ | Rotational ] [ Linear EQ | Rotational ]
[ Linear EQ | Rotational ] [ Linear EQ | Rotational ] [ Linear EQ | Rotational ]
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EXAMPLE: BALANCING A BAR WITH A FORCE
EXAMPLE: The bar below is 4 m long and has mass 10 kg. Its mass is distributed uniformly, therefore its center of mass is
located in the middle of the bar. The bar is free to rotate about a fulcrum positioned 1 m away from its left end. You want to
push straight down on the left edge of the bar, to try to balance it.
(a) What magnitude of force should you apply on the bar?
(b) How much force does the fulcrum apply on the bar?
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PRACTICE: BALANCING A COMPOSITE DISC
PRACTICE: A composite disc is made out of two concentric cylinders, as shown. The inner cylinder has radius 30 cm. The
outer cylinder has radius 50 cm. If you pull on a light rope attached to the edge of the outer cylinder (shown left) with 100 N,
how hard must you pull on a light rope attached to the edge of the inner cylinder (shown right) so the disc does not spin?
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EXAMPLE: PIN HOLDING A HORIZONTAL BAR
EXAMPLE: A 20-kg, 3 m-long bar is held horizontally against a wall by a pin (shown as red). Calculate the torque the pin
must provide in order to hold the bar horizontally. You may assume the bar has uniform mass distribution .
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