Frozen Pendulum: How Does it Affect Oscillations?

  • Thread starter Thread starter durt
  • Start date Start date
  • Tags Tags
    Pendulum
AI Thread Summary
The discussion centers on the behavior of a pendulum constructed as a thin-walled sphere filled with water, particularly how its oscillations change when the water freezes. When in liquid form, the moment of inertia varies as the water shifts, affecting the pendulum's oscillation period, while in solid form, the moment of inertia remains constant. This difference in mass distribution leads to slower oscillations when the water is frozen. Participants explore the implications of angular acceleration and rotational energy, noting that the solid state causes the mass to remain fixed, unlike in the liquid state. The conversation concludes with an understanding that the change in oscillation behavior is tied to the distribution of mass and its effect on the moment of inertia.
durt
Messages
149
Reaction score
0
A pendulum is constructed as a light thin-walled sphere of radius R filled up with water and suspended at the point O from a light rigid rod. The distance between the point O and the center of the sphere is equal to l. How many times will the small oscillations of such a pendulum change after the water freezes? The viscosity of the water and the change in its volume on freezing are to be neglected.

Why is the period of a solid pendulum different from that of a liquid one? Is it because the water shifts around inside the sphere? I need a hint. :smile:
 
Physics news on Phys.org
durt said:
Why is the period of a solid pendulum different from that of a liquid one? Is it because the water shifts around inside the sphere? I need a hint. :smile:
Quite so!
In liquid form, the moment of intertia of the whole pendulum will change over time, wheres in the solid form, the moment of inertia is a constant.
 
arildno said:
In liquid form, the moment of intertia of the whole pendulum will change over time, wheres in the solid form, the moment of inertia is a constant.
But how and why does this occur? The shape and mass of the pendulum are constant.
 
The distribution of mass is different throughout time.
 
yes, they are constandt...but the angular accelerationa and rotational energy are not. in soldi form, like wut arildno said, the moment of inertia is constant and is concentrated at the bottom of the ball.now, moment of inertia means measure of the tenddency to make the angular acceleration of the ball as minimal as possible. hence, i think that when frozen, the pendulum would sway much slower than that in liquid form.thats the rotational part, hope you can do the rest of the part involving osscilations
 
Ok, I think I understand now. When its solid, the mass of water does not rotate about the center of the sphere, but it does as a liquid. So its like there's a hinge in the middle of it. Is this the right idea? I'll run through the calculations later. I don't see how this changes any moments of inertia though.
 
The moment of inertia effectively represents the object's mass distribution with respect to the rotation axis.
 

Similar threads

How Does a Moving Support Affect Pendulum Motion?
Replies
23
Views
2K
Finding the period of a pendulum witha string that has mass
Replies
2
Views
2K
How Does Pivot Point Location Affect the Time Period of a Physical Pendulum?
Replies
14
Views
2K
Period of small oscillations for a pendulum
Replies
11
Views
4K
Find an Expression for the Frequency - Pendulum
Replies
4
Views
6K
How Does a Cycloidal Path Ensure Isochronous Oscillations in a Pendulum?
Replies
5
Views
10K
How Does a Circular Hoop's Oscillation Period Change When Displaced by a Breeze?
Replies
1
Views
1K
Cube-Rod Pendulum: Solving Homework Statement & Equations
Replies
15
Views
3K
Pendulum Problem: Solve 100 Oscillations in 50cm Rod
Replies
3
Views
2K
Simple Harmonic Motion - Determine the period of oscillation
Replies
6
Views
3K

Hot Threads

Recent Insights

Back
Top