Calculating Moment of Inertia for the Falling Mass Method

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Homework Help Overview

The discussion revolves around calculating the moment of inertia of a wheel using the falling mass method. Participants are exploring the relationship between the falling mass, its acceleration, and the rotational inertia of the wheel.

Discussion Character

  • Exploratory, Conceptual clarification, Mathematical reasoning

Approaches and Questions Raised

  • The original poster questions whether the moment of inertia can simply be calculated as mass times radius squared, expressing uncertainty about this approach. Other participants clarify the setup involving a light cable and a mass falling from rest, discussing how to derive the rotational inertia from the acceleration of the falling mass and applying Newton's laws.

Discussion Status

Participants are actively engaging with the problem, with some providing guidance on how to relate the falling mass's acceleration to the wheel's rotational inertia. There is a recognition of the necessary calculations involving torque and angular acceleration, though the original poster expresses uncertainty about applying certain equations.

Contextual Notes

Constraints include the assumption that the wire is massless and that the mass falls from rest. The discussion also highlights the need for accurate measurements of time and distance to determine acceleration.

willwoll100
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Could anyone help me calculate the moment of inertia of a wheel by the falling mass method, the data I've got is below,

Distance mass falls

Time taken

Mass fallen

Radius of shaft that the wire wraps around which is attached to the mass

Is is just the mass*radius^2? It just doesn't seem right?

Thanks
 
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I assume you have a light cable wrapped around the wheel shaft with a mass at the end. Then you let the mass fall from rest? And that the purpose of the experiment is to determine the rotational inertia of the wheel?

Given the acceleration of the falling mass you can figure out the rotational inertia of the wheel. You can figure out the acceleration from measurements of the time and distance (using kinematics).

To see how the rotational inertia relates to the acceleration of the falling mass, apply Newton's 2nd law to the wheel and to the falling mass.
 
Yes the wire is deemed of no mass and the mass added falls from rest, I've calculated the acceleration which is constant due to the force applied never changing which is 2*S/t^2, I've also calculated the angular acceleration which is acceleration/radius in rad/s^2. Force P acting in the wire is m(9.81-a) I have also calculated as well the torque Which is P*radius of shaft.
 
Last edited:
If you've calculated the torque and the angular acceleration, you have all you need to find the rotational inertia: [itex]\tau = I \alpha[/itex].
 
I thought of that but was unsure whether I could use that equation for this problem, thanks for your help :biggrin:
 

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