Two cans rolling down a ramp with the same mass

In summary: So the radial distance of the particles from the center of rotation is actually increased by the can.Ok that makes sense. The demonstration I watched explained how the can with the milk with was as if it was a hollow. If it is hollow, and the mass is still the same, wouldn't the mass be concentrated on the sides of the can; therefore increasing radial distance of the particles from the axis of rotation which in turn, increases the moment of inertia?The fact that the milk is a fluid (and a relatively low friction fluid at that) effectively prevents the milk from having anything to do with the rotation of the can. The can exerts a force on the milk, but because fluids move around so easily, it really only affects
  • #1
henry3369
194
0

Homework Statement


Two cans of the same size, mass, and shape are released from a ramp at the same height. One of the cans has milk and the other has refried beans. Which will reach the bottom first?

Homework Equations


Ktotal = Ktranslation + Krotational

The Attempt at a Solution


Since they start at the same height, their total kinetic energy at the bottom is the same. The can of milk has a higher moment of inertia, so in order total kinetic energy to be the same, it has to have lower translational kinetic energy; therefore, a smaller velocity. So why does the can of milk still reach the bottom first?
 
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  • #2
What's the difference between milk and refried beans?
 
  • #3
gneill said:
What's the difference between milk and refried beans?
Well the demonstration I watched said that the can with the milk acts more like a hollow can while the can with the refried beans is similar to a solid cylinder.
 
  • #4
henry3369 said:
Well the demonstration I watched said that the can with the milk acts more like a hollow can while the can with the refried beans is similar to a solid cylinder.
Can you think why that might be? Again, what's the difference between milk and refried beans?
 
  • #5
gneill said:
Can you think why that might be? Again, what's the difference between milk and refried beans?
The milk moves around slides around in the can while the refried beans don't move around much. I already know that the moment of inertia is higher for the milk because of this. I don't understand how you can use this to determine which will reach the bottom first.
 
  • #6
Exactly- the milk slides against the can, while the refried beans rotate. The milk does not rotate. What does this mean in terms of translational and rotational kinetic energy for the milk by the time it reaches the bottom?
 
  • #7
*What does this mean in terms of translational and rotational kinetic energy for the milk as gravity does work on it?
 
  • #8
AlephNumbers said:
Exactly- the milk slides against the can, while the refried beans rotate. The milk does not rotate. What does this mean in terms of translational and rotational kinetic energy for the milk by the time it reaches the bottom?
Rotational kinetic energy is higher for the milk because the moment of inertia is higher. Doesn't that mean that the linear speed is lower for the can of milk because the total kinetic energy has to be the same?
 
  • #9
No, the moment of inertia of the milk is not higher because, as you said, the milk slides against the can and does not rotate. No torque is applied to the milk, and the milk does not rotate. If the milk does not rotate, does that not mean that all of the work done on the milk is converted into translational kinetic energy?
 
  • #10
AlephNumbers said:
No, the moment of inertia of the milk is not higher because, as you said, the milk slides against the can and does not rotate. No torque is applied to the milk, and the milk does not rotate. If the milk does not rotate, does that not mean that all of the work done on the milk is converted into translational kinetic energy?
Ok that makes sense. The demonstration I watched explained how the can with the milk with was as if it was a hollow. If it is hollow, and the mass is still the same, wouldn't the mass be concentrated on the sides of the can; therefore increasing radial distance of the particles from the axis of rotation which in turn, increases the moment of inertia?
 
  • #11
The fact that the milk is a fluid (and a relatively low friction fluid at that) effectively prevents the milk from having anything to do with the rotation of the can. The can exerts a force on the milk, but because fluids move around so easily, it really only affects the few particles directly in contact with the can. The milk really has very, very little effect on the moment of inertia of the can. Yet, the milk still has mass, and affects the force of gravity on the can.
 

1. What is the purpose of studying two cans rolling down a ramp with the same mass?

The purpose of studying this scenario is to understand the principles of motion and how they apply to objects with the same mass but different shapes. This can help us understand how different factors, such as shape and surface, affect an object's movement.

2. What is the significance of using two cans with the same mass?

Using two cans with the same mass allows us to isolate the effect of shape on the rolling motion. By keeping all other factors constant, we can see the direct impact of shape on the movement of the cans.

3. How does the shape of the cans affect their rolling motion?

The shape of the cans affects their rolling motion in two main ways: the distribution of mass and the amount of surface area in contact with the ramp. Cans with a wider base and lower center of mass will roll more smoothly and consistently compared to cans with a narrower base and higher center of mass.

4. What role does the ramp play in this experiment?

The ramp serves as a controlled surface for the cans to roll on. By using the same ramp for both cans, we can eliminate any variables related to surface friction and focus on the effect of shape on the cans' movement.

5. How can the results of this experiment be applied in real-life situations?

The principles observed in this experiment can be applied in various real-life situations, such as designing more efficient vehicles or predicting the movement of objects on inclined surfaces. Understanding how shape affects movement can also be useful in sports and games that involve rolling objects.

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