Work-energy principle for a block fired up a vertical track

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Homework Help Overview

The discussion revolves around the work-energy principle as it applies to a block or ball released from a spring mechanism on a vertical track. Participants are exploring the implications of initial conditions, particularly regarding the initial velocity and acceleration of the object upon release.

Discussion Character

  • Exploratory, Assumption checking, Conceptual clarification

Approaches and Questions Raised

  • Participants are questioning the initial conditions of the problem, particularly whether the object has an initial velocity or only acceleration when released. There are discussions about the role of the spring and the plunger in imparting motion to the object.

Discussion Status

The discussion is active with multiple interpretations being explored. Some participants suggest that the plunger may impart both velocity and acceleration, while others argue that this would imply infinite acceleration. There is a focus on clarifying the mechanics of the interaction between the spring, plunger, and object.

Contextual Notes

Participants note the presence of friction and the coefficient of restitution as factors that could influence the energy transfer and motion of the object. There is also mention of the mass of the plunger and its potential impact on the system's dynamics.

Andrew1234
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Homework Statement
The problem is attached.
Relevant Equations
Work energy principle
I know how to solve the problem but have a question related to it. When the block is initially released from the spring the spring, having been pulled back, should give an initial velocity to the block. In that case why is the block's initial velocity zero?
 

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What are you calling block?
It seems to me that there is a pre-compression of the spring before the plunge is pulled back and then released and then hits the ball that has been in repose.
 
Andrew1234 said:
When the block is initially released from the spring the spring, having been pulled back, should give an initial velocity to the block. In that case why is the block's initial velocity zero?
The question is a little unclear, but I believe the idea is that when the plunger is pulled back, compressing the spring further, the ball stays in contact with it. Thus, when the plunger is released the ball has acceleration but not velocity.

I note that the question describes it as a ball, not a block, and refers to the existence of friction. It follows that the ball would make rolling contact with the track, though not immediately. Assuming the ball is uniform, 2/7 of the KE imparted by the spring will be lost to friction, and at the point where the ball leaves the track 2/7 of its remaining KE will be in the form of rotational KE.
The statement that the ball is "of negligible size" does nothing to change that.

Where does the question come from?
 
Last edited:
haruspex said:
The question is a little unclear, but I believe the idea is that when the plunger is pulled back, compressing the spring further, the ball stays in contact with it. Thus, when the plunger is released the ball has acceleration but not velocity.

I note that the question describes it as a ball, not a block, and refers to the existence of friction. It follows that the ball would make rolling contact with the track, though not immediately. Assuming the ball is uniform, 2/7 of the KE imparted by the spring will be lost to friction, and at the point where the ball leaves the track 2/7 of its remaining KE will be in the form of rotational KE.
The statement that the ball is "of negligible size" does nothing to change that.

Where does the question come from?
Thanks for the clarification. I asked the question because it was not clear to me that the ball when released from the track has no initial velocity but accelerates forward, but thought that when the plunger comes in contact with it gives it a velocity rather than an acceleration.
 
Andrew1234 said:
Thanks for the clarification. I asked the question because it was not clear to me that the ball when released from the track has no initial velocity but accelerates forward, but thought that when the plunger comes in contact with it gives it a velocity rather than an acceleration.
Yes, that is a possible interpretation; but then you would need more information, like the mass of the plunger and the coefficient of restitution in the impact.
 
Do you mean that it is possible for the plunger when released to give the ball, which is initially at rest, both an initial velocity and acceleration?
 
Andrew1234 said:
Do you mean that it is possible for the plunger when released to give the ball, which is initially at rest, both an initial velocity and acceleration?
Any initial acceleration is irrelevant except to the extent that it results in an initial velocity. Accelerations do not persist after the force is removed.

The plunger could impart some energy (determined in part by considering a coefficient of restitution) which could then be used to determine the initial velocity of the ball/block.
 
Andrew1234 said:
Do you mean that it is possible for the plunger when released to give the ball, which is initially at rest, both an initial velocity and acceleration?
Strictly, no. To go instantly from stationary to a nonzero velocity implies an infinite acceleration, so an infinite force. But in sudden impacts the forces can be very high, and unknowable, so we use conservation of momentum as the main principle and take the transition from rest to velocity after impact as effectively instantaneous.

If we take what I believe is the intended model, we ignore the mass of the plunger and it makes contact with the ball from the start and until the spring returns to its initial state. So, no sudden impact. Since the plunger has no mass, all the lost spring PE goes into the KE of the ball.

Alternatively, pulling back the plunger causes it to lose contact with the ball. The spring PE goes into accelerating the plunger, which strikes the ball just before the spring reaches its initial state. The difficulty with this is arranging that nearly all that energy goes into the KE of the ball. Seems to need that the plunger and ball have equal mass and the collision is perfectly elastic.

Either way, you get the same velocity of the ball as it starts up the ramp.

As I posted, the more serious issue with the question is the energy that goes into friction and rotation. That makes a marked difference to the answer.
 

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