Can You Solve These Challenging Friction Problems?

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The discussion focuses on solving two friction-related physics problems. The first problem involves determining the maximum angle at which a car can be parked on a hill, using the coefficient of static friction. The second problem examines whether a motorcyclist can coast through a sandy stretch without restarting the engine, requiring calculations based on Newton's laws of motion and friction. Detailed steps for solving both problems are provided, including the use of equations for forces and motion. The conversation emphasizes understanding the underlying physics rather than just obtaining answers.
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I don't know how to solve these questions and I was wondering if anyone here could help me

First question
The coefficient of static friction between hard rubber and normal street pavement is about .8. On how steep a hill (maximum angle) can you leave a car parked?

Last one
A motorcyclist is coasting with the engine off at a steady speed of 20m/s but enters a sandy stretch where the coefficient of friction is .80. Will the cyclist emerge from the sandy stretch without having to start the engine if the sand lasts for 15m? If so, what will be the speed upon emerging?

Could the person not give me the answer, but show me how it's done? I would be VERY greatful (preferably with a sum of forces in X and Y directions as I find that easier to understand, but I feel inconsiderate at this point so it's not necessary). Thank you.
 
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First: if you use breaks then you have that the maximum static force is given by
\mu N\cos\vartheta
and the parallel to street component of the car weight N is
N sen\vartheta
You start to move when the second is bigger than the first, so the maximum angle is given by
Nsen\vartheta=\mu N\cos\vartheta\Rightarrow\tan\vartheta=\mu\Rightarrow\vartheta=\arctan\mu
 
Second: you must use the Newton´s law. Acceleration equals force so that if x is space then speed and acceleration are \dot{x} and \ddot{x} where the dots mean derivation in time. If \mu is the friction coefficient the Newton´s law gives
m\ddot{x}=-\mu mg\rightarrow\ddot{x}=-\mu g
where g=9,81
You must integrate two times in dt with the conditions
\dot{x}_0=V_0
x_0=0
So you find
\dot{x}=V_0-\mu gt
Then you stop after a time
t=\frac{V_0}{\mu g}
and
x=V_0t-1/2\mu gt^2
in which you must substitute the t found. So you find if x is longer than the sand or not.
Bye
 
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Then, to find the speed upon emerging you must substitute the sand length [15 m] in the x formula, and find the time you need to emerge from the sand. When you find this you substitute this t in the speed formula (\dot{x}) and find the emerging speed.
And you hav finished all the problems.
 
Thank you very much!
 

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