Respuesta :
Answer:
a.) W/3, b.)2g/3 c.) (4gh/3)^0.5
Explanation:
First we have to find tension in terms of torque. To do that we have to find the moment of inertia of a rigid cylinder. From Wikipedia I get:
[tex]I = 0.5mr^2[/tex]
We also know the equation for torque. Let T be the tension, r be the distance, I is the moment of inertia and alpha is angular acceleration (ignore theta because it is perpendicular)
[tex]torque = I*\alpha = T*r[/tex]
We can then substitute a/r for α
Therefore we get:
[tex]I*\frac{a}{r}=T*r[/tex]
Isolating T and substitute the moment of inertia in for I we get
[tex]T = [0.5mr^2]a/r^2= 0.5ma[/tex]
There are two known forces acting on the cylinder, gravity and tension. The sum of these two forces gives us mass times acceleration (Newton's second law)
[tex]F = ma => mg - 0.5ma = ma\\g=\frac{3}{2}a\\a = \frac{2}{3}g[/tex]
This allows us to plug acceleration back into Newton's Second Law:
[tex]mg - T = m[\frac{2}{3}g]\\ T = \frac{1}{3} mg = \frac{1}{3}w[/tex]
w = the weight
For part b, we solved in part a:
[tex]a = \frac{2}{3}g[/tex]
For part c, we use the conservation of energy. We know that the sum of energy in the system is zero.
[tex]mgh + \frac{1}{2} mv^2 + \frac{1}{2}I(omega)^2 = 0\\(omega) = (\frac{v}{r})^2\\ I = \frac{1}{2} mr^2\\-gh +\frac{1}{2} v^2+\frac{1}{4} v^2 = 0\\gh = \frac{3}{4} v^2\\v = \sqrt{ \frac{4}{3}gh }[/tex]
