How Do You Calculate the Time Interval Between Bounces of a Ball?

AI Thread Summary
To calculate the time interval between bounces of a 32 g steel ball bouncing elastically from a height of 20.2 m, the correct approach involves using kinematic equations. The initial upward velocity is 19.9 m/s, and the acceleration due to gravity is -9.81 m/s². The time to reach maximum height can be calculated using the formula t = (v - v0) / a, leading to a time of approximately 2.03 seconds for the ball to ascend and descend. Therefore, the total time interval between bounces is twice this value, resulting in approximately 4.06 seconds. Understanding these calculations is crucial for accurately determining the time between bounces.
taveuni
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Hi:

I am working through this problem regarding a bouncing ball. I have gotten most of the way through, but can't figure out the time interval between bounces. Can someone give me some guidance? What am I not seeing?

A 32 g steel ball bounces elastically on a steel plate, always returning to the same maximum height h = 20.2 m.
a) With what speed does the ball leave the plate?
vup = 19.9m/s
b) What is the magnitude of the total change in momentum of the ball with each bounce?
|Dpball| = 1.27
c) What is the magnitude of the total momentum the ball transfers to the plate at each bounce?
|Dpplate| = 1.27
d) What is the time interval between bounces?
Dt = ?

I tried to simply t=d/v=20.2/19.9 and multiplying that by 2-- wrong. I can't think of any other way to solve this. And the next question builds off of it:

e) Averaged over a long time interval, what is the magnitude of the rate at which momentum is transferred to the plate?
|Dp/Dt| =
f) What is the magnitude of the average force exerted by the ball on the plate?
Favg =
Thank you...
 
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Time interval between bounces...

knowing the laws of kinematics, can you calculate how long it takes for an object to move a set distance, given the acceleration?
 
I know
dx=vo*t+(a*t^2)/2
But that doesn't give me the right answer
I got 0.84s ---
??
 
Is there something I am completely missing here?
dx=vo*t+(a*t^2)/2
20.2 = 19.9t + 9.81/2*t^2
solving for t = 0.84 or -4.9
2*t = 1.68s. Wrong.

Please, does anyone have any suggestions?
Thank you so much.
 
20.2=9.81/2*t^2,=>t=2.03
or 20.2 = 19.90792t - 9.81/2*t^2
 
v = v_0 + at

v - v_0 = at

t = \frac{v - v_0}{a}

v - velocity of the ball when reaches the maximum height
v0 = vup = 19.9m/s
a = g = - 9.80 m/s2
t - That's the time the ball will take to reach the maximum height.

But the time interval between two bounces let's call tb is equal to 2t.
Then:

t_b = 2(\frac{v - v_0}{a})
 

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