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Rotational Dynamics

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Using conservation of energy we were able to find the speed of an object dropped ... For other rotational objects such as hoops, solid cylinders, etc. ... – PowerPoint PPT presentation

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Title: Rotational Dynamics


1
Rotational Dynamics
  • Speed of a rolling object at the bottom of an
    inclined plane

2
Rotational Dynamics
  • Speed of a rolling object at the bottom of an
    inclined plane
  • Recall
  • Using conservation of energy we were able to find
    the speed of an object dropped from a vertical
    height, h, just before it hits bottom
  • Total mechanical energy at the top mgh
  • Total mechanical energy at the bottom

3
Rotational Dynamics
Total mechanical at top mgh
Ignoring friction
4
Rotational Dynamics
mass cancels
5
Rotational Dynamics
This also works with a translating object down an
inclined plane
(frictionless)
6
Rotational Dynamics
Now, take a rolling object say a solid sphere
- (bowling ball)
7
Rotational Dynamics
  • Whether it rolls down the incline
  • which includes translation
  • Or just translates
  • Objects at the top of the incline have the same
    mechanical energy
  • PE mgh

8
Rotational Dynamics
  • But for a rolling object
  • Some of that energy at the top is going into
    rolling the object
  • With the remainder translating the object.

9
Rotational Dynamics
  • Now, solve for translational speed at bottom, v
  • From Table 8.3, p. 254
  • Mass moment of inertia of a solid sphere

10
Rotational Dynamics
  • Simplify
  • Now, since we want v, lets work on getting rid of
    the angular speed, ?

11
Rotational Dynamics
  • For a rolling, non slipping object, the
    tangential speed of a point on the outer radius
  • Is equal to the translational speed of the center
    of mass --- axis of rotation
  • And tangential speed is related to rotational
    speed by
  • For one revolution, the point on the radius
    traveled one circumference
  • Equal to the distance the center of mass traveled

12
Rotational Dynamics
13
Rotational Dynamics
  • Which reduces to
  • Notice the radius cancels!!

14
Rotational Dynamics
  • AND, masses cancel, leaving
  • So, mass and radius do not make a difference!!

15
Rotational Dynamics
  • Which simplifies to
  • Solving for v

16
Rotational Dynamics
  • For other rotational objects such as hoops, solid
    cylinders, etc.
  • I leave it up to you to derive the velocity
  • Start with several slides ago
  • Insert the appropriate mass moment of inertia
    from Table 8.3, p. 254
  • And solve for v

17
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