Calculating Final Velocity with Acceleration and Normal Force

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Homework Help Overview

The discussion revolves around a physics problem involving an elevator's motion, specifically calculating the final velocity of the elevator after a period of constant acceleration. The scenario includes a rider whose perceived weight changes due to acceleration, raising questions about normal force and gravitational force interactions.

Discussion Character

  • Conceptual clarification, Assumption checking, Problem interpretation

Approaches and Questions Raised

  • Participants explore the relationship between normal force and perceived weight, questioning how the normal force changes when the rider feels twice as heavy. There are discussions about the calculations for normal force and the implications of acceleration on weight perception.

Discussion Status

Some participants have provided clarifications regarding the concepts of weight and normal force, emphasizing the distinction between actual weight and perceived weight due to acceleration. There is ongoing exploration of the implications of these concepts in the context of the original problem.

Contextual Notes

Participants express confusion about the order of operations in their calculations and the definitions of forces involved. There are references to free body diagrams as a helpful tool for understanding the forces acting on the rider.

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This is a question I keep getting wrong on my Physics homework:
An elevator is moving with an initial velocity of 10 m/s downward with a 47 kg rider standing inside. What should be the final velocity of the elevator after 15 seconds of constant acceleration if the rider is to feel twice as heavy as he does when at rest? Upward is the positive direction.

Please follow the suggested sequence for arriving at the final velocity.

Step 1: What is the normal force on the rider during the 15-second acceleration period? What I did was: find the acceleration and multiplied that by the mass to get the net force. Then I subtracted the force of gravity from the net force to get the normal force. However there are two problems with my approach : (1) The steps I completed to find the normal force were seen further down the line of steps suggested for finding the final velocity (signifying that I did my process out of order) and (2) The answer was marked incorrect.
Please help, I am very confused. :frown:
 
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Confused :P

i thought about it and now I am confused.
Considering the wieght of the perosn is (47)(9.8) = wieght
to get twice the wieght or 2(wieght)= (47)(9.8)(2)
since multiplication is culmative or the order don't matter we can say eithier their mass or 9.8 or gravity has doubled. there mass is probably constant...
so why can't we say the elavator must move up at 9.8m/s in order for their wieght to double that of rest?
 
and so if we assume the velocity is 9.8 m/s, where can we go from there to find the normal force?
 
God64bit said:
i thought about it and now I am confused.
Considering the wieght of the perosn is (47)(9.8) = wieght
to get twice the wieght or 2(wieght)= (47)(9.8)(2)
since multiplication is culmative or the order don't matter we can say eithier their mass or 9.8 or gravity has doubled. there mass is probably constant...
so why can't we say the elavator must move up at 9.8m/s in order for their wieght to double that of rest?
the fact that he feels twice as heavy does not mean that his weight has changed. The weight is always mg downward. There are two forces acting on the person: the force of gravity downward and the normal force exerted by the floor acting upward. The fact that he feels twice as heavy is due to the fact that the *normal* force exerted by the floor is twice what he usually experiences, so the normal force has a magnitude of 2mg and is acting upward. So you get the equation [itex](F_g)_y + N_y = m a_y \rightarrow -mg + 2 mg = m a_ y[/itex].
Therefore a_y is + 9.8 m/s^2.

You should always draw a free body diagram and identify clearly the forces. The weight never changes (unless you go to a very high altitude)
 
lets leave out everything we have done so far at rest what is Fn?
Fn=mg
so his normal force is (47)(9.8) or 460.6N now "if the rider is to feel twice as heavy as he does when at rest?" if that's how much he feels at rest how does he wieght is that's doubled?
 
nrqed said:
the fact that he feels twice as heavy does not mean that his weight has changed. The weight is always mg downward. There are two forces acting on the person: the force of gravity downward and the normal force exerted by the floor acting upward. The fact that he feels twice as heavy is due to the fact that the *normal* force exerted by the floor is twice what he usually experiences, so the normal force has a magnitude of 2mg and is acting upward. So you get the equation [itex](F_g)_y + N_y = m a_y \rightarrow -mg + 2 mg = m a_ y[/itex].
Therefore a_y is + 9.8 m/s^2.

You should always draw a free body diagram and identify clearly the forces. The weight never changes (unless you go to a very high altitude)

So in english I am wrong and what i said won't work?
 
God64bit said:
lets leave out everything we have done so far at rest what is Fn?
Fn=mg
so his normal force is (47)(9.8) or 460.6N now "if the rider is to feel twice as heavy as he does when at rest?" if that's how much he feels at rest how does he wieght is that's doubled?
I am not sure I understand the sentence. But the point is that the weight is actually unchanged. If he *feels* twice as heavy it is because the NORMAL force is twice as large as when there is no acceleration. You are right that the normal force when there is no acceleration is mg (as long as no other force beside gravity is in effect). So if he feels twice as heavy it means that the normal force will be 2mg (but the weight stays the same...mg downward)
 
so the normal force is (2)(460.6)?
 
oooo said:
so the normal force is (2)(460.6)?
yes. And is acting upward. The weight is the same as always, mg acting downward
 
  • #10
thanks for clearing that up for me!
 
  • #11
a related question: If a block whose mass is 17 kg is attached to a rocket that exerts 169.88 N upward on the block, what is its acceleration?
I thought to just do a=F/m, so a= 169.88/17 where a is roughly 9.993 m/s^2. This is wrong. What is the matter with what I am doing?
 
  • #12
oooo said:
a related question: If a block whose mass is 17 kg is attached to a rocket that exerts 169.88 N upward on the block, what is its acceleration?
I thought to just to a=F/m, so a= 169.88/17 where a is roughly 9.993 m/s^2. This is wrong. What is the matter with what I am doing?

Again, you should be thinking in terms of free body diagrams and thinking about all the forces involved. There is the force exerted by the rocket and there is still the force of gravity acting downward! (the weight if you will). SO the equation is +169.88 - mg = m a_y.
 
  • #13
oh, I understand now, thanks.
 

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