A low friction pulley, light string deal with two masses is set up as shown. If...
14. Two masses are connected by a string which passes over a pulley with negligible mass and friction. One mass hangs vertically and one mass slides on a frictionless 30.0 degree incline. The vertically hanging mass is 6.00 kg and the mass on the incline is 4.00 kg. The magnitude of the acceleration of the 4.00 kg mass is 15. Two masses are connected by a string which passes over a pulley with negligible mass and friction. One mass hangs...
An Atwood machine consists of a light string draped over a low friction pulley, with a lighter mass (mi) attached to one end of the string and a heavier mass (m2) attached to the other end. A hand holds m2 in place as shown, with the lighter mass just touching the floor and the string taut. The hand then releases m2. The masses increase in speed as m2 moves downward and mi moves upward. hand Discuss what's going on with...
Two masses are connected by a cord that passes over a pulley
as shown in the figure. The pulley and cord have negligible mass
and m1 (2.0 kg) moves on a horizontal surface without friction, m2
(2.0 kg) is suspended vertically. What is the ACCELERATION of
m1?
Question4 2/2 pts Two masses are connected by a cord that passes over a pulley as shown in the figure. The pulley and cord have negligible mass and mı (2.0 kg) moves on...
3. Two masses are connected by a string passing over a frictionless pulley as in the figure. The pulley is a 5 kg, 0.5 m radius ring with five 1 kg spokes. The ramp has a kinetic friction coefficient uk = 0.2. What is the acceleration of the mass on the left? Answer: 1.94 m/s2 10kg
Two blocks of masses m1 and m2 hang at the ends of a string that passes over the very light pulley with low friction bearings. Determine an expression for the acceleration of each block for the case when the blocks have the same mass m, but one is positioned lower than the other. Express your answer in terms of m ( m = m1 = m2) and gravitational constant g.
Two masses are connected by a light string passing over a light frictionless pulley. The 5.00 kg mass is released from rest at a height of h = 4.00 m above the horizontal floor below. (a) Using the law of conservation of energy, determine the speed of the 3.00 kg mass just as the 5.00 kg mass hits the ground. (b) Use one of the sense-making techniques to analyze your solution to part (a). Clearly state which technique you’re using...
Atwood’s machine with a massive pulley and massless string: two
masses are initially at rest at the same height. After the masses
are released, the large mass m2, falls through a height
h and hits the floor, and the small mass, m1, rises
through a vertical height h. Assuming the pulley has mass M and
radius R, find the speed of the masses just before m2
lands, giving your answer in terms of m1, m2,
g, M, R, and h....
Two unequal masses are hanging by ropes from either side of a light weight frictionless pulley. Let m1 = 5 kg and m2 = 10 kg. The masses are at rest. When released, the acceleration of t he heavier mass is (in magnitude) between 0.0 and 9.8 m/s^2 9.8 m/s^2 Impossible to determine 0.0 m/s^2
7. A mass (mı) is connected by a light string that passes over a pulley of mass (m3) to a mass (m2) as shown in the figure. There is no slippage between the string and the pulley. The coefficient of kinetic friction between the mass (mi) and the horizontal surface is 0.25. The inclined surface is frictionless and makes an angle of 30.0° with the horizontal. The moment of inertia of the pulley is 1m3r2. What is the magnitude of...