Solving Problems with Work, Energy, and Power

AI Thread Summary
The discussion centers on solving a physics problem involving a block sliding down an inclined plane, focusing on calculating kinetic energy, work done against friction, friction force, and the coefficient of kinetic friction. The user initially struggles with applying the correct formulas and understanding energy conservation principles. Key points include using the kinetic energy formula K=1/2 mv^2, recognizing the relationship between work done against friction and kinetic energy, and the importance of the normal force in calculating friction. The conversation emphasizes the need for proper application of kinematic equations and energy conservation to arrive at the correct answers. Overall, the thread aims to clarify the steps necessary to solve the problem accurately.
Caraniah
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I have question about this chapter (and yes, this is my tutorial question) that i want to ask. I use the formula but i did not get the right answer. Please help me and tell me what's wrong...


Question

A block of 30 kg slides down a rough inclined plane with an acceleration 1.5 meter per second. The plane makes an angle of 28 degree with the horizontal and is 8.0 m long. Find

1) The kinetic energy of the block when it reaches the bottom of the incline. (Ans: 360.15J)

I use K=1/2 mv^2

2) The work done to overcome friction. (Ans:745.2 J)

I use K + U + W other = K + U

3)the friction force that acts on the block. (Ans: 93.2 N)

I use F - friction = ma

4) The coefficient of the kinetic between the block and the plane. (Answer: 0.36)

I use friction =kN
 
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1. Use the basic kinematic equations to determine the final speed of the block, then just use the KE formula.

2. Note that since energy is conserved, the work done to overcome friction + final KE of the block is a constant throughout block's downward slide. You need a formula to find the total energy. Think in terms of potential energy here.

3. Once you have done 2., you can easily determine the force from the work done to overcome friction.

4. The formula is correct but N refers to the normal force exerted on the plane by the block. Use some vector algebra and trigo to figure that out.
 
Thanks. I will try to digest your answer slowly...
 

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