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Transcript 
Unit 7.4
1
Let’s assume that you have 3 objects: a
solid sphere, a solid cylinder and a
hollow cylinder.
We will ensure that all of the objects
have the same mass & radius.
All the objects will start from rest and
roll down a ramp.
2
Based on what we have previously
learned all objects should hit the
ground at the same time because we
are assuming that mass was uniformly
distributed.
3
However, this would not be so.
In reality, the objects would reach the
bottom at different times due to each
object having a different acceleration.
4
The reason being that these objects are
extended objects.
An extended object is an object that
has a definite, finite size and shape.
5
Although an extended object can be
treated as a point of mass to describe
the motion of its center of mass, a more
sophisticated model is required to
describe its rotational motion.
6
Imagine that you roll a strike while
bowling.
The pins fly backward, spinning in the
air.
7
The complicated motion of each pin can
be separated into a translational
motion and a rotational motion, each
of which can be analyzed.
8
For now we will concentrate on an
object’s rotational motion.
Then we will combine the rotational
motion of an object with its
translational motion.
9
Imagine a cat leaving a house through
a pet door.
When the door is hinged on top, then
the door is free to rotate around a line
that passes through the hinge.
10
This is the door’s axis of rotation.
When the cat pushes at the outer edge
of the door, the door opens.
The ability of a force to rotate an
object around some axis is measured
by a quantity called torque.
11
The closer to the hinge the cat pushes,
the harder it is for the door to rotate.
The farther the force is from the axis of
rotation, the easier it is to rotate the
object and the more torque is
produced.
12
13
The perpendicular distance from the
axis of rotation to a line drawn along
the direction of the force is called the
lever arm or moment arm.
A force applied to an extended object
can produce a torque, causing the
object to rotate.
14
Forces do not have to be perpendicular
to an object to cause the object to
rotate.
The door would rotate but not as easily.
15
The symbol for torque is the Greek
letter tau τ and the magnitude of the
torque is given by the equation:
τ = Fd(sinθ)
Torque = force x lever arm
SI Unit for torque is Nm
16
The following
example, a
wrench pivoted
around a bolt.
In this case, the
applied force
acts at an angle
to the wrench.
17
Torque is a vector quantity.
We will assign each torque a positive
or negative sign, depending on the
direction the force tends to rotate an
object.
18
Positive “+” is counterclockwise
Negative “-” is clockwise
19
To determine the sign of a torque,
imagine that it is the only torque acting
on the object and that the object is free
to rotate.
20
If more than one force is acting on an
object, then each force has a tendency
to produce a rotation and should be
treated separately.
21
The center of mass is defined as the
point at which all the mass of the
body can be considered to be
concentrated when analyzing
translational motion.
22
For a regularly shaped object, like a
sphere or cube, the center of mass is
at its geometric center of the object.
More complicated shapes are more
difficult to find the center of mass and
will not be covered in this course.
In most cases, the center of mass and
the center of gravity are equivalent.
23
The resistance of an object to change in
rotational motion is measured by a
quantity called the moment of inertia.
The moment of inertia is similar to mass
because they are both forms of
inertia.
24
However, there is an important
difference between the inertia that
results changes in translational (mass)
motion and the inertia that resists
change in rotational motion (moment
of inertia).
25
The moment of inertia depends on the
object’s mass and the distribution of
that mass around the axis of rotation.
Usually, the farther the mass of an
object is from the axis of rotation, the
greater is the object’s moment of
inertia and the more difficult it is to
rotate the object.
26
If the net force on an object is zero, the
object is in translational equilibrium.
If the net torque on an object is zero,
the object is in rotational equilibrium.
27
For an object to be completely in
equilibrium, both rotational and
translational, there must be both zero
net force and zero net torque.
28
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