Physics Asked by Logan545 on July 22, 2021
I’m doing mechanics and I came across this question:
A ball of mass 0.2 kg is dropped from a height of 2.5 m above horizontal ground.
After hitting the ground it rises to a height of 1.8 m above the ground.
Find the magnitude of the impulse received by the ball from the ground
The answer in the book I’m using says $2.59$ Ns. I first calculated the speed at which the ball hits the ground using $v^2= u^2 +2as$, which is $7$ m/s. The momentum when hitting the ground is therefore $-1.4$ kgm/s.
The final speed is the bit which stumps me. If the answer really is $2.59$ Ns, then the speed has to be $5.9$ m/s. I successfully managed to compute this, when I solve the problem in terms of $mgh$ and $frac{1}{2}mv^2$, however, I haven’t actually covered that yet in the Mechanics course I’m doing, so I feel I shouldn’t do it that way.
However, doing it using SUVAT, and assuming acceleration to be $-9.8$ m/s$^2$ and $u$ as $7$ m/s, my final speed works out to be $3.7$ m/s, so clearly my impulse cannot be $2.59$ Ns. I then thought I should work out final speed using $u$ as $0$, which would make the total distance travelled $2.5-1.8=0.7$ m, and acceleration being $9.8$ m/$s^2$, but I end up with the same answer. The only way I can see to get $5.9$ m/s as the speed, is to take $u$ as $49$ m/s AND s as $0.7$ m, although this isn’t correct at all, as if we get the net distance, we can’t then use any speed that wasn’t the definitive initial speed.
So how do I calculate the final speed of this ball, to then calculate impulse, without having to go into GPE and Kinetic energy?
I'll risk moderatorial opprobium with a partial answer because you have come so close.
You correctly use the SUVAT equation $v^2 = u^2 + 2as$ to find that the velocity of the ball just before it strikes the ground is $v_i = -7$ m/s (using the sign convention that upwards is positive). So far so good.
Now you know the ball rises back up to a height of 1.8m, so you can use the SUVAT equation again. This time $v = 0$ and $s = 1.8$ m so you can solve for $u$. What you've now got is the upwards (positive) velocity of the ball, $v_f$, just after it leaves the ground again. Some may say $v_f$ works out to be $+5.94$ m/s but I couldn't possibly comment.
The change in momentum is then just $mv_f - mv_i$ but remember the sign convention - $v_i$ is negative.
Correct answer by John Rennie on July 22, 2021
You already said if you have $h$ as 1.8 m, then $dfrac{1}{2} m v^2 = m g h$ implies $v$ is 5.9 m/s. However, you were unhappy becuase this involves energy. So just divide both sides of the equation by $m$. Now you have $dfrac{1}{2} v^2 = g h$. The solution must still be 5.9 m/s so you get the right answer, this time using only SUVAT.
Answered by Brian Moths on July 22, 2021
First of all, when a body is been dropped, the initial velocity (U)=0. Then using the 3rd equation of motion, V^2=U^2+2as. This third equation of motion tends to change when a body is been thrown upward or downward. Therefore we have our equation as v^2=u^2+2gh. And from our question, h= 2.5m, g(acceleration due to gravity)= 10ms-1, U=0, V=? From these we have V^2=0^2+2×10×2.5= 7.07m/s. Therefore our final velocity is = 7.07m/s
Now to get our initial velocity, U. We will use same formula which is the third equation of motion. This time the ball rebounds to a height of 1.8m and the final velocity becomes 0 and then we look for the initial velocity this time . From this, we have v^2=u^2+2gh as 0^2=u^2+2×10×1.8. Making u^2 subject of formula our answer is -6m/s.
From all these M= 0.2kg, V=7.07m/s and U= -6m/s Then the formula for calculating IMPULSE= M(V—U) Therefore 0.2(7.07—(—6))= 0.2(7.07+6)=2.614Ns approximately 2.6Ns
The answer you got was 2.59Ns which is approximately 2.6Ns
Answered by Ihediuche Ikenna Anselem on July 22, 2021
Get help from others!
Recent Answers
Recent Questions
© 2024 TransWikia.com. All rights reserved. Sites we Love: PCI Database, UKBizDB, Menu Kuliner, Sharing RPP