Finding the speed of a bowling ball based on the length of the lane and sound.

AI Thread Summary
To find the speed of a bowling ball traveling down a 16.5 m lane, the total time from release to hearing the sound is 2.60 seconds. The sound takes approximately 0.049 seconds to travel back to the bowler, leaving 2.551 seconds for the ball to reach the pins. By dividing the distance of 16.5 m by the time of 2.551 seconds, the calculated speed of the bowling ball is approximately 6.468 m/s. This method effectively separates the travel times of the ball and the sound for accurate speed determination. The final answer may vary slightly based on rounding during calculations.
Naryeth
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Homework Statement


A bowling ball traveling with constant speed hits the pins at the end of a bowling lane 16.5 m long. The bowler hears the sound of the ball hitting the pins 2.60 s after the ball is released from his hands. What is the speed of the ball? The speed of sound is 340 m/s. Answer to the nearest 0.001 m/s.

Homework Equations


I'm not entirely sure.


The Attempt at a Solution


So, the bowling ball traveled 16.5m down the lane and the sound returned at 340 m/s, all in 2.60 seconds. By that logic, the bowling ball traveled to the end of the lane in 2.60s - the time it took for the sound to return.

That's as far as I've gotten and I'm completely lost. Any help is appreciated, thanks in advance :D
 
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Naryeth said:
By that logic, the bowling ball traveled to the end of the lane in 2.60s - the time it took for the sound to return.
No, that doesn't follow.

Think of the process as having two parts:
(1) The bowling ball travels to the end of the lane (where it hits the pins and emits a sound).
(2) The sound travels back to the bowler.

Start by figuring out the time for part 2.
 
Ah, thank you. I've figured it out:

I know that sound can travel 340m in one second, therefore it traveled those 16.5 meters in 0.049 seconds (16.5/340). That means that the ball was rolling for 2.60-0.049 seconds, which is 2.551 seconds.

The ball traveled 16.5m in 2.251 seconds, so I just have to divide 16.5m/2.551s to get my final answer of 6.468m/s.

Thanks again!
 
Excellent! (Depending on how you round off intermediate steps, your final answer might be slightly different.)
 
Thread 'Variable mass system : water sprayed into a moving container'

Thread 'Variable mass system : water sprayed into a moving container'

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