Qa 32

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course phy 201

032. Moment of inertia

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Question: `q001. Note that this assignment contains 3 questions.

The moment of inertia of a concentrated mass m lying at a distance r from the axis of rotation is m r^2. Moments of inertia are additive--that is, if an object with a moment of inertia about some axis is added to another object with its moment of inertia about the same axis, the moment of inertia of the system about that axis is found by simply adding the moments of inertia of the two objects.

Suppose that a uniform steel disk has moment of inertia .0713 kg m^2 about an axis through its center and perpendicular to its plane. If a magnet with mass 50 grams is attached to the disk at a point 30 cm from the axis, what will be the moment of inertia of the new system?

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Your solution:

.05 * .3^2 = .0045

.0713+.0045 = .0758 kg m^2

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Given Solution:

A mass of m = .05 kg at distance r = .30 meters from the axis of rotation has moment of inertia I = m r^2 = .05 kg * (.30 m)^2 = .0045 kg m^2.

The moment of inertia of the new system will therefore be the sum .0713 kg m^2 + .0045 kg m^2 = .0758 kg m^2 of the moments of inertia of its components, the disk and the magnet.

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Question: `q002. A uniform rod with mass 5 kg is 3 meters long. Masses of .5 kg are added at the ends and at .5 meter intervals along the rod. What is the moment of inertia of the resulting system about the center of the rod?

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Your solution:

1/12 * 5 * 3^2 = 3.75

There will be masses at .5 , 1 , 1.5

.5 * (.5)^2 = .125

.5 * 1^2 = .5

.5 * 1.5^2 = 1.125

since there are two of each of theses masses it is doubled

added it is 7.25

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Given Solution:

The rod itself, being rotated about its center, has moment of inertia 1/12 M L^2 = 1/12 * 5 kg * (3 m)^2 = 3.75 kg m^2.

The added masses are at distances 1.5 meters (the two masses masses on the ends), 1.0 meters (the two masses .5 m from the ends), .5 meters (the two masses 1 m from the ends) and 0 meters (the mass at the middle of the rod) from the center of the rod, which is the axis of rotation.

At 1.5 m from the center a .5 kg mass will have moment of inertia m r^2 = .5 kg * (1.5 m)^2 = 1.125 kg m^2; there are two such masses and their total moment of inertia is 2.25 kg m^2.

The two masses lying at 1 m from the center each have moment inertia m r^2 = .5 kg * (1 m)^2 = .5 kg m^2, so the total of the two masses is double is, or 1 kg m^2.

The two masses lying at .5 m from the center each have moment of inertia m r^2 = .5 kg ( .5 m)^2 = .125 kg m^2, so their total is double this, or .25 kg m^2.

The mass lying at the center has r = 0 so m r^2 = 0; it therefore makes no contribution to the moment of inertia.

The total moment of inertia of the added masses is therefore 2.25 kg m^2 + 1 kg m^2 + .25 kg m^2 = 3.5 kg m^2. Adding this to the he moment of inertia of the rod itself, total moment of inertia is 3.75 kg m^2 + 3.5 kg m^2 = 7.25 kg m^2.

We note that the added masses, even including the one at the center which doesn't contribute to the moment of inertia, total only 3.5 kg, which is less than the mass of the rod; however these masses contribute as much to the moment of inertia of the system as the more massive uniform rod.

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Question: `q003. A uniform disk of mass 8 kg and radius .4 meters rotates about an axis through its center and perpendicular to its plane. A uniform rod with mass 10 kg, whose length is equal to the diameter of the disk, is attached to the disk with its center coinciding with the center of the disk. The system is subjected to a torque of .8 m N. What will be its acceleration and how to long will it take the system to complete its first rotation, assuming it starts from rest?

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Your solution:

.5 * 8 * (.4)^2 = .64

1/12 * 10 * (.8)^2 = .5333

added is 1.17

alpha = .8 / 1.17

alpha = .683 rad/s^2

I pulled this part from the end I had no idea how to find it with only acceleration

dTheta = 1/2 alpha dt^2

2 pi = .5 .683 dt^2

4 * pi = .683 dt^2

18.39 * pi = dt^2

dt = 7.6

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Given Solution:

The moment of inertia of the disk is 1/2 M R^2 = 1/2 * 8 kg * (.4 m)^2 = .64 kg m^2. The rod will be rotating about its center so its moment of inertia will be 1/12 M L^2 = 1/12 * 10 kg * (.8 m)^2 = .53 kg m^2 (approx).

( Note that the rod, despite its greater mass and length equal to the diameter of the disk, has less moment of inertia. This can happen because the mass of the disk is concentrated more near the rim than near the center (there is more mass in the outermost cm of the disk than in the innermost cm), while the mass of the rod is concentrated the same from cm to cm. ).

The total moment of inertia of the system is thus .64 kg m^2 + .53 kg m^2 = 1.17 kg m^2. The acceleration of the system when subject to a .8 m N torque will therefore be

`alpha = `tau / I = .8 m N / (1.17 kg m^2) = .7 rad/s^2, approx..

To find the time required to complete one revolution from rest we note that the initial angular velocity is 0, the angular displacement is 1 revolution or 2 `pi radians, and the angular acceleration is .7 rad/s^2. By analogy with `ds = v0 `dt + 1/2 a `dt^2, which for v0=0 is `ds = 1/2 a `dt^2, we write in terms of the angular quantities `d`theta = 1/2 `alpha `dt^2 so that

`dt = +- `sqrt( 2 `d`theta / `alpha )

= +- `sqrt( 2 * 2 `pi rad / (.7 rad/s^2))

= +-`sqrt( 12.56 rad / (.7 rad/s^2) ) = +-4.2 sec.

We choose the positive value of `dt, obtaining `dt = +4.2 sec..

INSTRUCTOR'S FURTHER CLARIFICATION

You have the acceleration and you know how far the system travels from rest.

If the system was accelerating along a line these quantities would be a, `ds and v0. The third equation of uniformly accelerated motion (`ds = v0 `dt + 1/2 a `dt^2) would apply, with `dt as the unknown. Since v0 = 0 the equation becomes `ds = 1/2 a `dt^2.

That equation isn't appropriate here because this is a rotating system. So instead of using `ds we use `dTheta, which is the symbol for angular displacement, and instead of a we use alpha, the symbol for angular acceleration.

Our equation therefore translates to

`dTheta = 1/2 alpha `dt^2.

Now using alpha = .7 rad/s^2 and `dTheta = 2 pi radians, we solve for `dt.

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