Using Work Energy Theorem to Find Necessary Velocity

AI Thread Summary
The discussion revolves around applying the work-energy theorem to determine the minimum velocity required to push a box up an incline to a receiver positioned vertically above. The problem involves variables such as the angle of the incline, the height difference, and the coefficient of kinetic friction. The solution proposed is that the necessary speed can be expressed as the square root of 2gh(1+μk/tan(a)). Participants clarify the initial conditions, emphasizing that the box is given an initial shove and then slides up the incline without further force. The conversation highlights the importance of understanding the work-energy theorem and the types of energy involved in the scenario.
Thenotsophysicsguy
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1. The problem statement, all variables and given/
You must push a box up an incline plane (the angle being constant : a), to a person waiting to receive it, who is a distance of h(constant) vertically above you. Though the slope is slippery, there is a small amount of friction with kinetic friction coefficient μk. Use the work-energy theorem to determine the minimum speed at which you must push the box, so that it may reach the receiver. Express answer in terms of g, h, μk, and a

Homework Equations


Among many equations there are:
Fkk*Fn (FN being natural force)
Force of Gravity=mg

The Attempt at a Solution


I know that the answer is the square root of 2gh(1+μk/tan(a)), but I am not fully sure what the steps are to reaching this conclusion.
 
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What have you tried? What does the work-energy theorem say? What are the types of energy involved here?
 
I thought the wording of this problem was a little vague. Just to clarify, the person at the bottom gives the box a shove, and releases it at an initial velocity such that the box slides up the incline (without any additional pushing) and just barely makes it to the top.
 
exactly
 
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