Car Crash Work and Energy Problem

AI Thread Summary
The discussion revolves around a car crash scenario involving a red van and a green van, where the red van's driver claims to have been traveling at 11 meters/second at the moment of impact. Calculations reveal that the work done by the brakes on the red van is -78,400 J, leading to an initial kinetic energy of 110,400 J. The final kinetic energy after the crash is calculated to be 32,000 J, indicating a significant energy loss. Ultimately, the calculations show that the red van's initial speed was approximately 14.85 meters/second, disproving the driver's claim of 11 meters/second. The discussion highlights the importance of accurately interpreting the problem statement and the calculations involved in determining the vehicle's speed before the crash.
a1234
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Homework Statement



A red van came through and crashed into a green van. The driver of the red van claims that he was driving at a speed of 11 meters/second at the moment of the crash. You want to find out if his claim is true.

a. the mass of the red van is 1000 kg
b. the mass of the green van is 800 kg
c. the length of the skid mark from the red van is 20 meters
d. the length of the skid mark from the green van is 2.5 meters
e. the red van was moving at 8 meters/second when the crash happened
f. the coefficient of kinetic friction for the skidding is 0.4

1. Tell how much work the brakes did on the red van.
2. What was the change in energy of the red van before the crash?
3. What was the red van's initial kinetic energy?
4. Is the driver's claim correct?

2. The attempt at a solution

I don't see a use for most of the data given for the green van, but here are my calculations:

Frictional force = coefficient of friction * normal force
Ff = 0.4 * 1000 * 9.8 = 3920

Work = -Ff * d
W = -3920 * 20 = -78,400 J ---> work done on red van

KEf = 1/2mv^2
KEf = 1/2 * 1000 * 8^2 = 32,000 J

W = kinetic energy change
W = KEf - KEi
-78,400 = 32,000 - KEi
KEi = 46,400 J ---> initial kinetic energy of red van

And since we don't know the initial velocity...

KEi = 46,400
46,400 = 1/2mv^2
46,400 = 1/2 * 1000 * v^2
v^2 = 92.8
initial velocity is app. 9.63 meters/second ---> the driver was wrong about going at 11 m/s

The change in kinetic energy is 32,000 - 46,400 = -14,400 J.
 
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Method looks good, but check your work-energy equation you did the math wrong.
 
PhanthomJay said:
Method looks good, but check your work-energy equation you did the math wrong.

You mean this?
W = KEf - KEi

Not sure how to work out the positive and negative signs.
Should 32,000 be negative too?

-78,400 = -32,000 - KEi
-46,400 = -KEi
KEi = 46,400 J
 
a1234 said:
-78,400 = 32,000 - KEi
The red van originally had some initial kinetic energy. It lost 78,400 J of that from skidding. And after skidding, KEf = 32,000.
So KEi = 78,400 + 32,000 = 110,400
 
Last edited:
I'm not making much sense of the problem statement.
a1234 said:
The driver of the red van claims that he was driving at a speed of 11 meters/second at the moment of the crash.
At the instant before the crash, or before slamming on the brakes prior to the crash?
a1234 said:
the length of the skid mark from the red van is 20 meters
Is that skid leading up to the crash point or from it?
a1234 said:
the red van was moving at 8 meters/second when the crash happened
I guess that is the speed of the red van at the instant before the crash, and the 11m/s is something else - or should that say green van?
a1234 said:
1. Tell how much work the brakes did on the red van
If all the deceleration occurred while skidding, the brakes did no work. It was all done by friction between road and tyres.
 
haruspex said:
At the instant before the crash, or before slamming on the brakes prior to the crash?
I took it to mean that 11 ms-1 was his claimed speed before he hit the brakes. But I agree that the wording of the problem is not at all clear.
 
"...he was driving at a speed of 11 meters/second at the moment of the crash."
This is supposed to say that the driver claims he was going at 11 m/s when he felt he had to jam the brakes to avoid hitting the other car. But when the collision actually happened, he was going at 8 m/s. So we still need to find out if the driver's claim is true.
Sorry for the confusion.
 
a1234 said:
W = kinetic energy change
W = KEf - KEi
-78,400 = 32,000 - KEi
KEi = 46,400 J ---> initial kinetic energy of red van
What you wrote here was correct until the very last line. You just did the math wrong.
 
-78,400 = 32,000 - KEi
KEi = 110,400 J
 
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  • #10
So then, was the driver telling the truth?
 
  • #11
KEi = 1/2mv^2
110,400 = 1/2 * 1000 * v^2
110,400/500 = v^2
initial velocity is app. 14.85 m/s. So the driver is still wrong.

32,000 - 110,400 = -78,400 J, the change in kinetic energy.
 
  • #12
Looks good.
 
  • #13
a1234 said:
KEi = 1/2mv^2
110,400 = 1/2 * 1000 * v^2
110,400/500 = v^2
initial velocity is app. 14.85 m/s. So the driver is still wrong.

32,000 - 110,400 = -78,400 J, the change in kinetic energy.
Looks right to me too.
Note that the mass of the vehicle is irrelevant for this part of the question. You can just use the SUVAT equation vf2=vi2+2as, where a=-μg.
 

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