Calculating Power and Torque for Rotational Motion

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To maintain the grinding stone's rotation at a constant angular velocity, the necessary power is calculated using torque and frictional forces. The grinding stone has a radius of 10 cm and a moment of inertia of 0.2 kg*m^2, turning at 200 RPM. The frictional force, derived from the applied radial force and the kinetic coefficient of friction, is 30 N. By converting RPM to rad/s and applying the power formula, the required power is determined to be approximately 62.8 W. The discussion emphasizes the relationship between power, torque, and the work done against friction in rotational motion.
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I would really appreciate if anyone could help me with this problem. My exam is in 3 days and I don't understand how to do this problem!

A grinding stone of radius 10 cm ( I=0,2 kg*m^2) turns at a rate of 200 RPM. A tool is leaned against the circumference of the grinding stone with a force of 50N of radial direction. The kinetic coefficient of friction is equal to 0,6.
(A) What power is necessary to maintain the grinding stone in rotation at a constant angular velocity?

The answer is supposed to be 62,8 W and I know I have to use torque but I really don't know how to do it :confused:
 
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Cyannaca said:
A grinding stone of radius 10 cm ( I=0,2 kg*m^2) turns at a rate of 200 RPM. A tool is leaned against the circumference of the grinding stone with a force of 50N of radial direction. The kinetic coefficient of friction is equal to 0,6.
(A) What power is necessary to maintain the grinding stone in rotation at a constant angular velocity?

The answer is supposed to be 62,8 W and I know I have to use torque but I really don't know how to do it :confused:

power formula: (T is torque, t is time)

P = \frac{T \theta}{t}

P = T\omega


convert 200rpm into rad/s and it should be easy from there.


I just worked the problem all the way through and the answer does work out.
 
Last edited:
There's a real easy way to do this - almost a short cut.

Notice that if the stone must be turning at a constant angular velocity, it's Kinetic Energy must be constant. So the work done by the motor = work done by friction. Dividing by time, we have the power of motor = power removed by friction.

Also we know that power = force * velocity.
The relevant velocity here is the speed of the edge of the grinding wheel (where the friction acts) = w*R, where w is in rad/s. Lastly, the frictional force is 0.6 * 50 N = 30 N.

Plugging in numbers, you'll find that P = 63 W
 
Gokul43201 said:
Notice that if the stone must be turning at a constant angular velocity, it's Kinetic Energy must be constant. So the work done by the motor = work done by friction. Dividing by time, we have the power of motor = power removed by friction.
You totally stole that from my post :-p
 
Shawn how did he steal that from your post?
 

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