Max Kinetic Energy of Object in Circular Path with Constraint

AI Thread Summary
An object constrained by a cord moves in a circular path with a radius of 0.5m on a frictionless surface, with a maximum tension limit of 16N before the cord breaks. The gravitational potential energy is constant due to the horizontal motion, making it irrelevant to the problem. The centripetal force required for circular motion is provided by the tension in the cord, which can be expressed as mv²/R. To find the maximum kinetic energy, one must determine the maximum speed of the object, which is limited by the tension. By combining the kinetic energy and centripetal force equations, the solution can be derived.
tprofl
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Homework Statement


An object is constrained by a cord to move in a circular path of radius 0.5m on a horizontal frictionless surface. The cord will break if tension exceeds 16N. The maximum kinetic energy the object can have is:

Homework Equations


KE=1/2mv^2
U=mgh

The Attempt at a Solution


Because the object is spinning in a horizontal circle, you may take the tension at any point. Potential can equal kinetic, mgh=1/2mv^2, but I can't figure out how to start this problem.
 
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tprofl said:

Homework Statement


An object is constrained by a cord to move in a circular path of radius 0.5m on a horizontal frictionless surface. The cord will break if tension exceeds 16N. The maximum kinetic energy the object can have is:


Homework Equations


KE=1/2mv^2
U=mgh




The Attempt at a Solution


Because the object is spinning in a horizontal circle, you may take the tension at any point. Potential can equal kinetic, mgh=1/2mv^2, but I can't figure out how to start this problem.

I can't figure out what you're saying in your solution attempt, in particular, the bit about taking the tension "at any point."

Furthermore, since the circle is horizontal, the object never changes height, meaning that its gravitational potential energy is constant. Potential energy, therefore, is somewhat irrelevant to the problem.

Try, instead, to think of it this way: since kinetic energy depends on speed, the object's maximum kinetic energy is going to depend on its maximum possible speed. What determines the speed of an object in uniform circular motion? Hint: what kind of force is the tension in the rope providing in order to produce circular motion?
 
tprofl said:

Homework Statement


An object is constrained by a cord to move in a circular path of radius 0.5m on a horizontal frictionless surface. The cord will break if tension exceeds 16N. The maximum kinetic energy the object can have is:


Homework Equations


KE=1/2mv^2
U=mgh




The Attempt at a Solution


Because the object is spinning in a horizontal circle, you may take the tension at any point. Potential can equal kinetic, mgh=1/2mv^2, but I can't figure out how to start this problem.

Because this object is on a horizontal table, its gravitational potential energy (mgh) doesn't ever change.

The centripetal force required to keep an object in circular motion is given by mv2/R

I was always interested in comparing the kinetic energy formula 1/2 mv2 as they both contain the mv2 expression

By comparing and combining those two expressions/formulas I think you can discover the answer you seek.
 

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