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course phy 201

I really need to go over this more I realize

031. Torques and their effect on rotational motion

Question: `q001. Note that this assignment contains 9 questions.

Imagine that you are turning the top on a jar of peanut butter. The top is on pretty tight and you have to use the fair amount strength to get the top loose. You can squeeze the top as tightly as you like, but unless you also turn the top it is not going to come loose. However you do know from experience that you do have to squeeze it pretty tightly, or your hand will just slide around the top instead of turning it.

The reason you have to squeeze and turn is that you use the frictional force between your hand and the top of the jar to transmit the turning force exerted by your arm muscles.

The squeezing force is directed toward the center of the circular top and is therefore perpendicular to the arc of the top. It has no rotational effect. The frictional force, by contrast, is directed along the sides of the jar's top, at every point parallel to the arc of the circle and hence perpendicular to a radial line (a radial line is a line from the center of the jar to a point on the circle; the radial line in this case runs from the center to the point at which the frictional force is applied).

This type of force causes a turning effect on the top, called a torque.

The amount of the torque depends on how much force is exerted parallel to the arc of the circle, as well as on how far the force is exerted from the center of rotation. For example, if you exert a force of 50 Newtons in the direction of the sides, on a top of radius 4 centimeters, the torque would be 50 Newtons * 4 cm = 200 cm * Newtons.

If the cap is too tight, you might use a pipewrench to turn it. The pipewrench 'grabs' the top and allows you to exert your force at a point further from the center of the top. You naturally push in a direction perpendicular to the handle of the wrench, which is pretty much perpendicular to the line from the center to the point at which you push. So for example you might exert a force of 20 Newtons at a distance of 15 cm from the center of the top, resulting in a torque of 20 N * 15 cm = 300 cm * N. This torque, though it results from less force, is greater than the torque exerted in the previous calculation.

What would be greater, the torque exerted by a 70 Newton force at a distance of 4 cm from the center of the top, or the torque exerted by a 20 Newton force at a distance of 15 cm from the center of the top?

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Your solution:

70 * 4 = 280

20 * 15 = 300 the 20 newtons is greater

confidence rating #$&*:

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Given Solution:

The first force would be 70 Newtons * 4 cm = 280 cm N, while the second would be 20 N * 15 cm = 300 cm N, so the second would be the greater. This second torque would be more likely to succeed in opening the jar.

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Question: `q002. Imagine that instead of being on top of the jar, the lid from the peanut butter jar was glued to the bottom of a full 1-gallon milk jug. If you were to turn the milk jug upside down and apply the same torque you would use to open a stubborn jar of peanut butter, how long do you think it would take for the milk jug to complete 1/2 of a full turn?

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Your solution:

Uh I'm not sure but probably not at all since it is glued

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Given Solution:

You would be turning pretty hard, and a full milk jug doesn't have that much inertial resistance to turning. So it wouldn't take long--certainly less than 1 second, probably closer to a quarter of a second. With this kind of a grip, it would be very easy to turn the milk jug very quickly.

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Self-critique (if necessary):

I still don't really understand the situation isn't it glued how could it turn at all

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The jar top is glued to the milk jug. The milk just isn't glued to anything. So as the jar top turns, so does the milk jug.

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Question: `q003. Imagine now that you have a fairly strong but light stick about as long as you are tall. If you were to place the stick flat on a smooth floor cleared of all obstacles so the stick can be spun about its center, then glue the peanut butter jar top to the center of the stick in order to give you a good grip in order to spin the stick, then if you applied the same torque as in the previous example, how long do you think it would take to spin the stick through a 180 degree rotation (so that the ends of the stick reverse places)?

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Your solution:

A second maybe two

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Given Solution:

Again it wouldn't take long, probably less that a second. However even for a very light stick it would probably take longer than it would take to spin the milk jug. The ends of the stick would have a long way to go and would end up moving faster than any part of the milk jug.

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Question: `q004. Imagine now that you strap a full 2-liter soft drink container to both ends of the stick. Suppose you support the stick at its center, using a smooth pedestal. The stick will probably bend a bit toward the ends with the weight of the soft drinks, but assume that it is strong enough to support the weight. If you now apply the same torque is before, how long the you think it will take for the system to complete a 180 degree rotation?

STUDENT COMMENT: f it moves faster than any part of the jug then how is it that it would take longer to spin the stick?

INSTRUCTOR RESPONSE

Be careful to distinguish between angular velocity and velocity. A part of a rotating object can move faster in the sense of covering more cm in a second, even though it covers fewer radians in a second.

You can also look at this from the point of view of energy. The speed v is what determines kinetic energy and the longer stick will result in a greater KE, but it will take longer to achieve that KE.

Or you can look at it from the point of view of angular quantities, with which you might not presently be familiar. For present and/or future reference, an equal mass at a greater distance from the axis of rotation makes a greater m r^2 contribution to moment of inertia, which measures how difficult it is to achieve a given

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Your solution:

It weighs more so it would take more force to spin at the same time so it would take longer with the same force

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Given Solution:

With the weight that far from the center, it is going to be much more difficult to accelerate this system than the others. Those milk jugs will end up moving pretty fast. Applying the same torque is before, it will probably take well over a second to accomplish the half-rotation.

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Weight has nothing to do with the motion.

Mass does, but the resistance to a given torque also depends on how the mass is distributed. The further from the axis of rotation, the more a given mass will resist a torque.

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Question: `q005. The three examples given above all involve angular accelerations that result from torques. In each case the object rotates through an angle of 180 deg or `pi radians, starting from rest. However the last example, with the 2-liter drinks tied to the ends of a fairly long stick, will pretty clearly take the longest and therefore entail the smallest angular acceleration. Suppose that the time required for the rotation was .25 sec in the first example (the milk jug) and 1.5 sec in the last example (the soft drink bottles at the ends of the stick). What was the angular acceleration, in rad / s^2, in each case?

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Your solution:

pi radians/.25 = 12.566 average vel which is a 25 final

25/.25 = 100 accel

pi / 1.5 = 2.09 average a 4 final

4/1.5 = 2.66 accel

confidence rating #$&*:

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Given Solution:

In each case the initial velocity was zero and the angular displacement was `pi radians. In the first example the average angular velocity was `pi rad / (.25 s) = 12.5 rad/s. Since the initial angular velocity was 0 the final angular velocity must have been 25 rad/s. Thus the angular velocity changed by 25 rad/s in .25 sec, and the average rate at which the angular velocity changed was 25 rad/s / (.25 s) = 100 rad/s^2. This is the angular acceleration in the first example.

In the second example we follow the same reasoning to obtain an average angular velocity of about 2 rad/s, a final angular velocity of about 4 rad/s and hence and angular acceleration of about 2.7 rad/s^2. This is about 1/40 the angular acceleration of the milk jug.

Note that these estimates are intuitive and might not be completely accurate; in fact the ratio would probably be closer to 1/100. Note also that the mass of two full 2-liter soft drink bottles is only slightly greater (about 7%) than the mass of the milk in the jug. This should make it clear that the difficulty of accelerating rotating objects depends not only on how much mass is involved, but also on how far the mass is from the center of rotation. The further the mass from the center of rotation, the less acceleration results from the application of a given torque.

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Question: `q006. As should be clear from the first set of examples, while the quantity that resists acceleration when a force is applied to an object is mass (a = F / m), the quantity that resists rotational or angular acceleration when a torque is applied involves not only mass but the location of the mass. The important quantity in this case is called moment of inertia. The standard unit for moment of inertia is the ( kg * m^2 ), and this quantity is not given any special name.

The moment of inertia for a thin hoop, where all the mass is pretty much concentrated at the rim of the hoop, is I = M R^2, where M is the total mass and R the radius of the hoop.

By contrast the moment of inertia for a uniform disk with mass M and radius R is I = 1/2 M R^2. A uniform disk of given mass and radius has only half the moment of inertia that would result is all its mass was concentrated at the rim of the disk.

It makes sense that the hoop should resist rotational acceleration more than the disk, because the mass of the hoop is concentrated further from the center than the mass of the disk. The mass of the disk is spread from the center to the rim, so almost all of the mass is closer to the center than the rim, whereas the mass of the hoop is all concentrated at the rim.

The specific law that governs these situations is analogous to the a = F / m of Newton's Second Law (and is in fact equivalent to this law). Rather than force F, rotational effects are produced by torque, which is designated by the Greek letter `tau, with standard unit the m * N (meter * Newton). As mentioned above, rather than mass we use moment of inertia I, in kg m^2. And rather than acceleration a, which would be measured in m/s^2, we have angular acceleration, measured in radians / sec^2. Angular acceleration is designated by the Greek letter `alpha.

With these conventions Newton's Second Law a = F / m becomes

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Your solution:

alpha = tau/I

confidence rating #$&*:

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Given Solution:

`alpha = `tau / I (Newton's Second Law for Rotation),

as force is replaced by torque, mass by moment of inertia, and acceleration by angular acceleration.

If a torque of 3 m * N is applied to a uniform disk whose diameter is 20 cm and whose mass is 4 kg, what will be the angular acceleration?

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Your solution:

I = 1/2 M R^2

I = .5 * 4 * .1^2

I = .02 kg m^2

confidence rating #$&*:

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Given Solution:

We calculate angular acceleration from `alpha = `tau / I. We are given the torque `tau. We need to find the moment of inertia I.

Since we know that the moment of inertia for a uniform disk is I = 1/2 M R^2, and since we are given the mass and diameter of the disk, we note that the radius is half the diameter or 10 cm or .1 meter, and we easily calculate I = 1/2 * 4 kg * (.1 meter)^2 = .02 kg m^2.

A torque of 3 m N thus produces angular acceleration

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Your solution:

3/.02 = 150 rad/s^2

confidence rating #$&*:

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Given Solution:

`alpha = `tau / I = 3 m N / (.02 kg m^2) = 150 rad/s^2.

The units calculation is m N / (kg m^2) = ( m * kg m/s^2 ) / (kg m^2) = 1 / s^2.

[ Units Note: We get the rad/s^2 by noting that one of the meters in the numerator can be regarded as a meter of arc distance while the other is a meter of radius, while the meters in the denominator are regarded as meters of radius, so we end up with a meter of arc distance divided by a meter of radius, which gives us radians. ]

[Note also that the mass and diameter of this disk are about the same as the mass and diameter of a milk jug, and the 3 m N torque is the same as the 300 cm N torque (3 m is after all 300 cm) we postulated in an earlier example. The 150 rad/s^2 is also in the same 'ball park' as the 100 rad/s^2 acceleration the resulted from our rough estimates regarding the milk jug. ]

STUDENT COMMENT:

Oh I just used the mass instead of Inertia

INSTRUCTOR RESPONSE: Different parts of the object have different accelerations. Particles closer to the center have less acceleration than those nearer the rim. So there is no single acceleration that fits the mass of this object.

However since the object is rigid, all parts have the same angular acceleration about the axis. Using moment of inertia and torque you take into consideration the variation in accelerations of various parts of the object, so that alpha = tau / I, as indicated in the given solution. This is the form of Newton's Second Law appropriate to rotating objects.

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Question: `q007. Find the acceleration that would result from a torque of 3 m N on a hoop of mass 4 kg and radius .8 meters.

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Your solution:

I = 1/2 M R^2

I = 1.28

3/1.28 = 2.34

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Given Solution:

The moment of inertia of the hoop is I = M R^2 = 4 kg * (.8 m)^2 = 2.6 m N. The 3 m N torque would therefore produce an angular acceleration of

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Your solution:

I though it was I = .5 * m * r^2 why is there no .5 And where is the question

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Given Solution:

`alpha = `tau / I = 3 m N / ( 2.6 kg m^2) = 1.2 rad/s^2.

[ Note that the 4 kg is concentrated approximately .8 meters from the center; while the two soft drink bottles at the ends of the stick to did not form a hoop, they did have a mass of approximately 4 kg which was concentrated pretty close to .8 meters from the center of rotation, and would therefore accelerate pretty much the same way the hoop did. The acceleration estimate we obtained before was about 2.7 rad/s^2; this calculation gives us a little less than half that. ]

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Any particle of mass m at distance r from the axis has moment of inertia m r^2 relative to that axis.

For a uniform disk, different particles are located at different distances from the axis. If they were all at the same distance R you wouldn't have a disk, you would have a hoop or a cylindrical shell, and its moment of inertia would be M R^2, where M is the total mass of all the particles.

For a disk, most of the particles are closer to the axis than those at the outer rim, and it turns out that if you add the moments of inertia of the individual particles, the total moment of inertia is 1/2 M R^2.

You might want to review your calculus, on applications of the integral. Calculation of moments is a standard topic, and it's very likely that you covered it there. Your knowledge of calculus can help you understand this, and vice versa. The integral for a uniform disk is pretty straightforward.

Of course the calculus isn't required for your course, so that part is optional.

The thing you need to understand is that the moment of inertia of an object depends not only on its mass but on how the mass is distibuted relative to the axis of rotation.

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Question: `q008. A uniform rod rotated about its center has moment of inertia I = 1/12 M L^2, where L is its length; if it is rotated about one of its ends the moment inertia is I = 1/3 M L^2. You can feel the difference by taking something about the length and mass of a golf umbrella and grasping it about halfway along its length, and rotating it end over end, back and forth very rapidly; then try the same thing grasping it near one end. One way will give much slower back-and-forth motion than the other for the same effort.

A uniform sphere rotated about an axis through its center has moment of inertia I = 2/5 M R^2.

If a torque of 2 m N is applied to a uniform sphere whose radius is 10 cm, and if the sphere is observed to accelerate from rest to 30 rad/s in 2 seconds, then what is its mass?

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Your solution:

Accel of 15 rad/s

15 = tau/I

15 = 2/I

I = 2/15

I = .133

(Why is it 1/12)

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The 1/12 comes from a very simple integral, which you very likely did in calculus. You can easily verify that; or if you want me to explain the setup of the integral I'll be glad to do so.

The actual integration is simple (you integrate M / L * x^2 with respect to x, from x = -1/2 L to x = 1/2 L. You can verify that the integral gives you 1/12 M L^2.

M / L is the mass per unit length so the mass in interval `dx is M / L * `dx; if the center of the rod is at the origin then the distance of an increment from the axis is just | x | so the moment of inertia of the increment is M / L * dx * x^2, and the rod runs from -L/2 to L / 2.)

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.133 = 1/12 * m *.1^2

m = 30 kg

Confidence : 3

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Given Solution:

We know the torque exerted on the sphere, and the information given us allows us to calculate the angular acceleration of the sphere, so we will be able to determine its moment of inertia.

The angular acceleration is the rate of change of the angular velocity; the velocity changes by 30 rad/s in 2 sec, so the average rate of change of the angular velocity is 30 rad/s / (2 s) = 15 rad/s^2.

Since this angular acceleration was produced by a torque of 2 m N, we can rearrange `alpha = `tau / I into the form

I = `tau / `alpha

and we calculate

I = 2 m N / ( 15 rad/s^2) = .133 kg m^2.

Now we know that I = 2/5 M R^2, so with the information that the radius is 10 cm = .1 m, we find that

M = 5/2 I / R^2 = 5/2 (.133 kg m^2) / (.1 m)^2 = 30 kg.

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Question: `q009. What angular acceleration would result if a uniform piece of 2 in x 2 in lumber 2.5 meters (about 8 feet) long and with a mass of 1.5 kg was subjected to a torque of 5 m N at its center? What torque would be required to produce the same angular acceleration if applied to the end of the piece of lumber?

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Your solution:

I = 1/12 * 1.5 * 2.5^2

I = .78

a = 5/.78

a = 6.4 rad/s^2

From here I'm usure

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Given Solution:

We know the torque so we need to find the moment of inertia before we can determine the angular acceleration.

The piece of lumber is much longer than its width, so its moment of inertia is very close to that of a uniform rod.

In the first question it is subjected to the torque at its center. Its moment of inertia is therefore

I = 1/12 M L^2 = 1/12 * 1.5 kg * (2.5 m)^2 = .78 kg m^2 (approx).

Subject to a torque of 5 m N this rod will experience an angular acceleration of

`alpha = `tau / I = 5 m N / (.78 kg m^2) = 6.4 rad/s^2 (approx).

To produce the same acceleration rotating the rod from its end would require more torque because, on the average, the mass of the rod is now twice as far from the axis of rotation.

Specifically, the moment of inertia is now 1/3 M L^2 = 1/3 * 1.5 kg * (2.5 m)^2 =3.12 kg m^2.

To produce acceleration 6.5 rad/s^2 would require torque

`tau = I `alpha = (3.12 kg m^2) * (6.4 rad/s^2) = 20 m N (approx).

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