Calculating Impulse Force in a Hockey Puck Collision

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In summary: I don't remember what it does, sorry :(Secondly, p=ma will return 0.360 kg m/s, which is what you got when you calculated the momentum in both x and y directions.
  • #1
fernancb
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Homework Statement


A 259 g hockey puck is sliding on ice with a speed of 5.34 m/s hits a wall at an angle of 34.8° to the wall and bounces back at the same angle with the same speed.

If the wall and the hockey puck are in contact for 11.3 ms, find the magnitude of the impulse on the puck.


Homework Equations


p=mv
change in p = J
J=F(change in t)

J is impulse force

The Attempt at a Solution


1st attempt: I tried just multiplying my velocity and mass to get momentum, that failed

2nd attempt: I tried resolving my components
X: (0.259)(5.34)(sin34.8)=0.789 kg m/s
Y: (0.259)(5.34)(cos34.8)=1.14 kg m/s

vf = sqrt((0.789)^2 + (1.14)^2)
= 1.39 m/s

p=ma
= (0.259kg)(1.39m/s)
= 0.360 kg m/s

p=ma = J therefore J=0.360 kg m/s

That FAILED!

I'm really not sure what I'm doing wrong, could someone pls help?
 
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  • #2
In your second attempt, when you calculated the X and Y components, you found the components of the momentum in the two directions. That's fine. But I don't see what you were doing in calculating vf as the square root of the sum of squares of the momenta. That should just give you back the momentum, not a velocity.

When the puck hits the wall, the velocity and momentum in the y-direction remains unchanged (because the angle of reflection is equal to the angle of incidence, and the overall speed is said to be unchanged). But what happens to the velocity in the x-direction?
 
  • #3
Whoops, I have no idea why i did that, vf squared thing. I see that now.
But i assumed that the momentum in the x direction remained constant... should i not have assumed that?
 
  • #4
The puck is hitting the wall and changing direction, so one or both of the momenta components is changing.

So, what are the two components of the velocity (or momentum) before and after the collision?
 
  • #5
So i can do it either way right?
If it's in terms of momentum, x will be: mv cos34.8 & y will be: mv sin34.8
right?
 
  • #6
That'll be the momenta before collision. How about after?
 
  • #7
Since the velocity after is the same wouldn't the momentum be the same?
 
  • #8
The speed is the same (so stated in the problem). But the velocity has changed. Otherwise, the wall wasn't there and no reflection took place!
 
  • #9
Hmm... So does that mean that the components of velocity have changed?

vXf: vcos34.8
vYf: vsin34.8 but I still get the same components?

where v is 5.34 m/s
 
  • #10
Suppose you were to throw a ball straight at a wall. It bounces back with the same speed. Is the velocity the same?
 
  • #11
No, the velocity is negative... Sry, but i still don't see what you're getting at, sure the velocity would be negative, but when i resolve it... wouldn't it still be the same components?
 
  • #12
OH! Wait a minute! Now my angle is going to be 90-34.8 and then
vXf is :5.34sin(90-34.8)
vYf is : 5.34cos(90-34.8)
 
  • #13
Yes, the same *magnitude* of components. But the sign of one of them has changed. This is important. Why is it important? Because you're looking to find the impulse, which is the total change in momentum, ∆p, that occurs during the impact of the puck and wall.

Momentum is a vector quantity, just as velocity is, which means that it has magnitude and direction. Momentum has the same direction as velocity. You are going to want to find the difference between the initial (incoming) momentum vector and the final (outgoing) momentum vector.

Now, only one of the velocity (and momentum) components is changing over the collision. So the change in momentum will be confined to that component that is expressing the change. I'm aiming to get you to identify which component that is, and to calculate the change in momentum.
 
  • #14
In that case, wouldn't both components of the velocity have changed? So now it would be
vYf: 1.18 m/s
vXf: -5.21 m/s

That's what I've got so far... Erm... would i put it in terms of x and y now?
 
  • #15
Attached is a diagram of what is happening. Note that the Y-component isn't changed, and the angle to use is the 34.8° that was given -- it was stated that the angle was with respect to the wall, not the normal to the wall.
 

Attachments

  • Puck Wall.jpg
    Puck Wall.jpg
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  • #16
after calculating the momentum in both x and y directions just think this:
in which direction is the momentum changing- then after simple maths you shall get your answer
 
  • #17
these calculations were very wrong conceptually:
[vf = sqrt((0.789)^2 + (1.14)^2)
= 1.39 m/s

p=ma
= (0.259kg)(1.39m/s)
= 0.360 kg m/s]

firstly sqrt((0.789)^2 + (1.14)^2) will not give you velocity. these would give you the net momentum . then you multiplied this with mass which is of no use.

it had to fail
 
  • #18
Okay, I've got up to there... Now I have my diff velocities for x which is changing from 3.05 m/s to -3.05 m/s after collision. Do i just take the difference in momenta between the 2 components... or do i have to resolve again?
 
  • #19
Oh wow... I can't believe it took me so long. Thanks for being so patient guys! :)
 
  • #20
No need to resolve now, since these two velocities are both lie along the same line parallel to the x-axis; they're x-components.

Just form ∆p from m∆v.
 

1. What happens when a hockey puck strikes a wall?

When a hockey puck strikes a wall, it undergoes a change in momentum and direction. The force of the impact causes it to bounce off the wall in a new direction.

2. Why does the hockey puck bounce off the wall?

The hockey puck bounces off the wall because of the conservation of momentum. When the puck hits the wall, it transfers its momentum to the wall, causing the wall to exert an equal and opposite force on the puck, propelling it in a new direction.

3. How does the angle of the wall affect the trajectory of the puck?

The angle of the wall can greatly affect the trajectory of the puck. A steeper angle will cause the puck to bounce off at a sharper angle, while a flatter angle will result in a more gradual bounce off the wall.

4. What factors determine the speed of the puck after it bounces off the wall?

The speed of the puck after it bounces off the wall is determined by the initial speed and direction of the puck, as well as the angle and material of the wall. A harder wall will cause the puck to bounce off with more force, while a softer wall will absorb more of the impact and result in a slower rebound.

5. Can a puck lose energy when bouncing off a wall?

Yes, a puck can lose energy when bouncing off a wall. Some of the energy from the impact is converted into heat and sound energy, and the puck may also lose some of its kinetic energy if it collides with other objects or surfaces before coming to a stop.

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