How Fast Must a Bullet Travel to Swing a Pendulum Bob Through a Complete Circle?

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The discussion revolves around calculating the minimum speed a bullet must travel to swing a pendulum bob through a complete vertical circle. The first part of the problem was successfully solved using energy and momentum conservation, yielding a speed of approximately 945.0944 m/s. The second part introduces complications due to the flexible cord, which requires analyzing forces at the top of the circle to ensure tension remains positive. Participants suggest applying Newton's second law to determine the minimum speed where tension is zero, but confusion arises regarding the equations and unit consistency. The conversation emphasizes the need for clarity in circular motion dynamics to solve the second part effectively.
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Homework Statement



A bullet of mass .0179kg (m) and speed v passes completely through a pendulum bob of mass 1.3kg (M). The bullet emerges with a speed of v/2. The pendulum bob is suspended by a stiff rod of length 1.08m (L) and negligible mass. What is the minimum value of v such that the pundulum bob will barely swing through a complete vertical circle?

Suppose that the pendulum bob is suspended from a light flexible cord instead of a stiff rod. Now what is the minimum value such that the pendulum bob will swing through a complete vertical circle? Answer in m/s


Homework Equations



1/2 mv^2 = mgh

m1v1 + m2v2 = m'v' + m''v''

The Attempt at a Solution



I already solved the first question and got it right. I used Energy conservation and momentum conservation equations to solve and got and answer of 945.0944 m/s.

The equation that I simplified down to to get my answer for question one was 4M/m(sqrt gl)

I am having a big struggle with the second part. I don't know what effect the flexible string will have on the equation. I know that when it reaches the top of the circle, it will have slack and want to fall back down, so the velocity has to be faster, but I don't know how to solve for it.
 
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jigs90 said:
I know that when it reaches the top of the circle, it will have slack and want to fall back down, so the velocity has to be faster, but I don't know how to solve for it.
You are on the right track. In order to make it around the top of the circle, the cord must have some tension.

Analyze the forces acting on the bob at the top of the circle. Apply Newton's 2nd law to figure out the minimum speed where the tension in the cord just goes to zero. Hint: The motion is circular.
 
Doc Al said:
Analyze the forces acting on the bob at the top of the circle. Apply Newton's 2nd law to figure out the minimum speed where the tension in the cord just goes to zero. Hint: The motion is circular.

So would it just change the equation to 4M/m (sqrt gl) = v^2/r
where r is the length of the rod, because that would be the radius... is that right?
 
jigs90 said:
So would it just change the equation to 4M/m (sqrt gl) = v^2/r
where r is the length of the rod, because that would be the radius... is that right?
How can it be? The units don't match!
 
Doc Al said:
How can it be? The units don't match!

See, this is where I am confused. I just don't know what to do. I thought that since it was circular motion, you would just convert the velocity to circular motion velocity. I am so confused,
 
Try what I suggested in post #2.
 

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