Use conservation of energy to find the required speed as shown
below***********************************************************************************************
Check the answer and let me know immediately if you
find something wrong or missing... I will rectify the mistakes asap
if any
Review Two masses, ma = 34.0 kg and mg = 40.0 kg. are connected by a...
Two masses, mA = 34.0 kg and mB = 40.0 kg , are connected by a rope that hangs over a pulley (as in the figure (Figure 1)). The center of the pulley is hollowed out so that you may assume all the mass of the pulley is in the rim. The radius of the pulley is 0.381 m and the mass of the pulley is 3.10 kg . Initially mA is on the ground and mB rests 2.50 m...
Two masses, Ma= 35.0kg and Mb = 40.0 kg, are connected by a rope that hangs over a pulley (as in the figure ). The pulley is a uniform cylinder of radius 0.381m and mass 3.4kg . Initially Ma is on the ground and Mb rests 2.3m above the ground. If the system is released, use conservation of energy to determine the speed of just before it strikes the ground. Assume the pulley bearing is frictionless.
Two masses, mA = 29.0 kg and mg = 42.0 kg are connected by a rope that hangs over a pulley (as in the figure). The pulley is a uniform cylinder of radius R. 0.311 m and mass 3.4 kg. Initially, mis on the ground and mp rests 2.5 m above the ground. MA 25 m Part A If the system is now released, use conservation of energy to determine the speed of me just before it strikes the ground....
Suppose you have a system of two masses strung over a pulley. Mass 1 (6.7 kg) hangs on the right side of the pulley suspended over the ground at height 0.8 m. Mass 2 (2.6 kg) hangs over the left side of the pulley and rests on the ground. The pulley is a uniform disk of mass m and radius 13.9 cm. When the system is released, Mass 1 moves down and Mass 2 moves up, such that Mass 1...
Two boxes A and B (mA = 4.00 kg; m, - 2.00 kg) are linked by a weightless rope passing through a pulley. The initial height h of Ais 5.00 m and Bis initially on the ground. It takes 2.5 second for A to reach ground. The pulley's radius is 0.3 m. The rope does not slip on the pulley rim. Use work-energy-theorem to find the moment of inertia of the pulley. ms
3. An Atwood machine consists of two masses, mA 4.3 kg and mB 9.7 kg, connected by a cord that passes over a pulley free to rotate about a fixed axis. The pulley is a hoop of radius Ro 0.75 m and mass M-3.2 kg. mB Im If mB is initially h-2.4 m above the table and released from rest, with what speed will it hit the table? (Hint: Use energy considerations and note that mass ma will go up...
Problem 1 (50 points 2 kg and mg 1 kg are connected by a small pulley. Mass ma is on an inclined plane at angle in which the pulley ls at the origin. What ls the Two masss m4 θ=r/4 radians, and mg is allowed to hang freely (a) Suppose the string has length 10 m. Take a potential energy of the system as a function of the height of mass mg? (b) Find the of which way the masses...
Two masses are connected by a massless rope. The mass of object 1 is 5.5 kg, and it rests on a surface with a 1.7 coefficient for static friction (us) and a .90 coefficient for kinetic friction (uk). Object 2 has a mass of 8.3 kg and hangs over the edge of the surface by a frictionless, massless pulley. The two objects begin at rest when object 2 is released to hang freely. A.) Draw a free body diagram for...
Problem 31 mi ma Two blocks ma = 4 kg and m2 = 9 kg are initially arranged as shown in the figure. They are tied to a massless rope going around the pulley. The pulley has a form of a cylinder e with a mass of M = 8 kg and radius of R = 40 cm. Both the incline and the horizontal surface have a coefficient of kinetic friction uk = 0.15. The incline is at the angle...
Two masses mA = 2 kg and mB = 1 kg are connected by a stnall pulley Mass maks on an inclined plane at angle e-π/4 radians, and mB is allowed to hang freely. (a) Suppose the string has length 10 m. Take a coordinate system in which the pulley is at the origin. What is the potential energy of the system as a function of the height of mass mg? (b) Find the acceleration of mass ma (either using...