Find the change in kinetic energy of the car

AI Thread Summary
The discussion revolves around calculating the change in kinetic energy of a car that weighs 2436 kg and travels at 10.7 m/s before colliding with a tree. The initial kinetic energy is calculated to be 139,449 J, and the change in kinetic energy is determined by considering the car comes to rest. Participants discuss using the Work-Energy theorem to find the work done as the car's front is pushed in and the average force exerted during the deceleration over a distance of 54 cm. They suggest calculating the deceleration assuming constant force to find the magnitude of the force. The conversation emphasizes understanding the relationship between kinetic energy, work, and force in collision scenarios.
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Homework Statement


A 2436 kg car has a speed of 10.7 m/s when it hits a tree. The tree doesn’t move and the
car comes to rest.
a) Find the change in kinetic energy of the car.
b) Find the amount of work done by the car as its front is pushed in.
c) Find the magnitude of the force that pushed the front of the car in by 54 cm.

Homework Equations


Kinetic energy=1/2mass*speed^2


The Attempt at a Solution


1/2*2436(10.7^2)=139449J of kinetic energy now what
 
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hcps-chent1 said:

Homework Statement


A 2436 kg car has a speed of 10.7 m/s when it hits a tree. The tree doesn’t move and the
car comes to rest.
a) Find the change in kinetic energy of the car.
b) Find the amount of work done by the car as its front is pushed in.
c) Find the magnitude of the force that pushed the front of the car in by 54 cm.

Homework Equations


Kinetic energy=1/2mass*speed^2


The Attempt at a Solution


1/2*2436(10.7^2)=139449J of kinetic energy now what
Punt. :biggrin: Or since the problem asks for the change in KE, how much KE does it have when it stops, and what is its change? Then think the Work-Energy theorem.
 
got a and b now what about c
 
question C seems like its a little bit vague. This is my take on it. The car is going 10.7 m/s, and stops to 0 m/s in a distance of 54 centimetres. If you assume that it stops through a constant deceleration (which it probably wouldn't in a real situation), you can find out that deceleration. Once you've found that, you have the mass of the vehicle, and the deceleration of the vehicle, and you should be able to find the magnitude of the force.
 
dacruick said:
question C seems like its a little bit vague. This is my take on it. The car is going 10.7 m/s, and stops to 0 m/s in a distance of 54 centimetres. If you assume that it stops through a constant deceleration (which it probably wouldn't in a real situation), you can find out that deceleration. Once you've found that, you have the mass of the vehicle, and the deceleration of the vehicle, and you should be able to find the magnitude of the force.
Or you could apply the definition of work. The force calculated is an average force.
 
Divide the work done (part b) by distance (0.54 m).

W = Fd
F = W/d
 
thanks
 
haha yeah that's definitely the right way. for some reason i read that it was a work and energy problem, and then decided to not take that into account during my response
 

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