Rotational Motion



Rotational Motion

Reading: Chapter 10

Angular Displacement

[pic]

Angular Velocity

[pic]

Average angular velocity

[pic]

Instantaneous angular velocity

[pic]

The magnitude is called the angular speed.

Angular Velocity as a Vector

[pic]

The direction of the vector [pic] points along the axis of rotation, according to the right-hand rule.

Angular Acceleration

Average angular acceleration

[pic]

Instantaneous angular acceleration

[pic]

Rotation with Constant Acceleration

[pic]

[pic]

[pic]

Relating the Linear and Angular Variables

The position

[pic]

The velocity

[pic]

The acceleration

Tangential component:

[pic]

Radial component:

[pic]

Kinetic Energy of Rotation

Consider the kinetic energy of a rotating rigid body:

[pic]

Since v = (r, and ( is the same for all particles, we have

[pic]

[pic] is called the rotational inertia. It tells us how the mass of the rotating body is distributed about its axis of rotation. In summary,

[pic] and [pic]

For continuous bodies,

[pic]

Ring [pic] (axis) [pic] (diameter)

Cylinder [pic]

Rod [pic] (centre) [pic] (end)

Sphere [pic]

Parallel Axis Theorem

[pic]

The rotational inertia of a body about any axis is equal to the rotational inertia (= Mh2) it would have about that axis if all its mass were concentrated at its centre of mass, plus its rotational inertia (= Icm) about a parallel axis through its centre of mass.

Proof

[pic]

which can be written as

[pic]

[pic]

In the first term, x2 + y2 = R2. Hence the first term becomes

[pic]

In the second and third terms, the position of the centre of mass gives

[pic] and [pic]

Hence these terms vanish.

In the last term, a2 + b2 = h2. Hence the last term becomes

[pic]

Perpendicular Axis Theorem

The sum of the rotational inertia of a plane lamina about any two perpendicular axes in the plane of the lamina is equal to the rotational inertia about an axis that passes through the point of intersection and perpendicular to the plane of the lamina.

[pic]

[pic]

[pic]

[pic]

Examples

Given that the rotational inertia of a hoop about its central axis is Ma2, what is the rotational inertia of a hoop about a diameter?

By symmetry, Ix = Iy.

Using the perpendicular axis theorem, Ix + Iy = Iz.

Since Iz = Ma2, [pic].

10-6 A rigid body consists of two particles of mass m connected by a rod of length L and negligible mass.

(a) What is the rotational inertia Icm about an axis through the center of mass perpendicular to the rod?

(b) What is the rotational inertia I of the body about an axis through the left end of the rod and parallel to the first axis?

(a) [pic]

(b) Method 1: Direct calculation:

[pic]

Method 2: Parallel axis theorem:

[pic]

= mL2

10-7 Consider a thin, uniform rod of mass M and length L.

(a) What is the rotational inertia about an axis perpendicular to the rod, through its center of mass?

(b) What is the rotational inertia of the rod about an axis perpendicular to the rod through one end?

(a) [pic]

[pic]

[pic]

(b) Using the parallel axis theorem,

[pic] (ans)

Radius of Gyration

The radius of gyration is that distance from the axis of rotation where we assume all the mass of the body to be concentrated. It is given by

[pic], [pic].

For example, for a thin rod rotating about its center,

[pic] ( [pic].

Torque

The ability of [pic] to rotate the body depends on:

1) the magnitude of the tangential component Ft = Fsin(,

2) the distance between the point of application and the axis of rotation.

Define the torque as

[pic]

It can be considered as either rF( or r(F. Terms:

line of action

moment arm

( is positive if it tends to rotate the body counterclockwise.

It is negative if it tends to rotate the body clockwise.

Considering the vector direction,

[pic]

Newton’s Second Law for Rotation

[pic]

Newton’s second law:

[pic]

Torque:

[pic]

Since at = (r, we obtain

[pic]

Conclusion:

[pic]

If there are more than one forces,

[pic]

Examples

10-9 A uniform disk of mass M = 2.5 kg and radius R = 20 cm is mounted on a fixed horizontal axle. A block whose mass m is 1.2 kg hangs from a massless cord that is wrapped around the rim of the disk. Find the acceleration of the falling block, the angular acceleration of the disk, and the tension in the cord. The cord does not slip, and there is no friction at the axle.

Newton’s law for the hanging block

(downward is positive):

[pic] (1)

Newton’s law for the rotating disk

(clockwise is positive):

[pic] (2)

Since a = R(,

(2): [pic]

(1): [pic]

[pic]

[pic] (ans)

[pic] (ans)

[pic] (ans)

10-10 (Physics of judo) To throw an 80-kg opponent with a basic judo hip throw, you intend to pull his uniform with a force [pic] and a moment arm d1 = 0.30 m from a pivot point (rotation axis) on your right hip, about which you wish to rotate him with an angular acceleration of (6.0 rad s(2, that is, with a clockwise acceleration. Assume that his rotational inertia I is 15 kg m2.

a) What must the magnitude of [pic] be if you initially bend your opponent forward to bring his centre of mass to your hip?

b) What must the magnitude of [pic] be if he remains upright and his weight [pic] has a moment arm d2 = 0.12 m from the pivot point?

See Youtube “Judo hip throw”.

(a) Newton’s law for the rotating opponent

(anticlockwise is positive):

[pic]

[pic] = 300 N (ans)

(b) [pic]

[pic]

(ans)

Remark: In the correct execution of the hip throw, you should bend your opponent to bring his center of mass to your hip.

Center of Percussion

[pic]

The body is free to rotate about an axis through O. Suppose we strike a blow at point O’, at a distance D from O.

Change in angular momentum:

[pic] ( [pic] ( [pic]

Using the linear impulse-momentum theorem,

[pic] ( [pic]

We would like to find the condition that no impulse is felt at O. For this to occur,

[pic]

Since [pic] and [pic], we have

[pic]

O’ is called the center of percussion relative to point O.

Work and Rotational Kinetic Energy

Work done by the force:

[pic]

Total work done:

[pic]

Work-kinetic energy theorem:

[pic]

Integrating over the angular displacement,

[pic]

[pic]

Power

[pic]

Example

10-11 As in Example 10-9, a uniform disk of mass M = 2.5 kg and radius R = 20 cm is mounted on a fixed horizontal axle. A block whose mass m is 1.2 kg hangs from a massless cord that is wrapped around the rim of the disk. What is the rotational kinetic energy K at t = 2.5 s?

Method 1: Use Newton’s law directly.

Using Newton’s law, we have found ( = 24 rad s(2.

[pic]

Rotational inertia: [pic]

Kinetic energy:

[pic]

[pic]

[pic] (ans)

Method 2: Use work-kinetic energy theorem.

Word done by the torque:

[pic]

Since [pic],

[pic]

Using the work-kinetic energy theorem,

[pic] (ans)

10-12 A tall, cylindrical chimney will fall over when its base is ruptured. Treat the chimney as a thin rod of length L = 55 m. At the instant it makes an angle of ( = 35o with the vertical, what is its angular speed (f?

Using the conservation of energy,

[pic]

Rotational inertia about the base:

[pic]

[pic]

[pic]

[pic]

[pic]

Therefore, [pic]

[pic]

= 0.311 rad s(1 (ans)

Equilibrium of Cables and Strings

Cable Supporting Horizontal Load

[pic]

For static equilibrium,

[pic] and [pic]

Solving for T and (, we get

[pic] and [pic]

Taking the torque about P,

[pic] ( [pic] Parabolic cable

Cable Supporting Load Along Its Length

[pic]

Consider the horizontal and vertical components of the forces acting on a small segment of length ds.

[pic]

[pic]

[pic] and [pic]

Note that tan( = y’ is the slope of the curve, and

[pic].

[pic] ( [pic]

The solution to this differential equation is

[pic]

[pic]

[pic]

-----------------------

x

y

z

r

x

y

Rotation axis

O

P

Rotation axis

O

P

Ft

[pic]Ft

[pic]Ft

P

[pic]Ft

(

Rotation axis

Moment arm

O

F’

F

Fr

D

O

O’

C

l

l’

y

x/2

x/2

T

W

T0

P

(

y

ds

T + dT

( + d(

T

(

x

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