An Atwood Machine is composed of a frictionless pulley with two cubes connected by a string' Cube A, on the left, has a mass of 4.0kg and cube B, on the right has a mass of 6.0kg. The pulley has a rotational inertia of 1/2 MR2. How does that affect the acceleration of the masses. Would tension A be the same as tension B? Why or why not?
An Atwood Machine is composed of a frictionless pulley with two cubes connected by a string'...
an atwood machine with massless string and frictionless pulley has masses m1= 0.480 kg and m2=0.720 kg attached to it. derive the equations for and calculate the acceleration of the masses and the tension in the string
In the Atwood machine shown in (Figure 1) , the pulley radius is
0.10 m , and the rotational inertia of the pulley is 0.17 kg?m2 .
Ignore the cord's inertia.
A)Calculate the acceleration of the
blocks.
B)Calculate the tension in the cord on the left
C)Calculate the tension in the
cord on the right.
An Atwood machine is constructed of a solid-disk frictionless pulley of mass m3 and radius R. On the left side is hung a mass m1, and on the right the string is wound around a hollow cylinder of mass m2 and radius r (like a yoyo.) 1) For what mass ratio m2/m1 will mass m1 remain stationary, and what will the acceleration of mass m2 be? 2) Suppose m2 = 2*m1. For what mass m3 will the masses m1 and...
3. Adwood's machine consists of two masses connected by a string over a frictionless pulley of negligible mass. One block has mass mi = 35 kg and the other has mass m2 = 45 kg as shown below. (a) Draw all forces and tensions and find the tension in the string (10 pt) (b) Find the magnitude of the block's acceleration (5 pt)
An Atwood machine consists of a mass of 3.5 kg connected by a light string to a mass of 6.0 kg over a frictionless pulley with a moment of inertia of 0.0352 kg ∙ m2 and a radius of 12.5 cm. If the system is released from rest, what is the speed of the masses after they have moved through 1.25 m if the string does not slip on the pulley? Please note: the professor has told us that the...
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
A mass m1 is connected by a light string that passes over a pulley of mass M to a mass m2 sliding on a frictionless horizontal surface as shown in the figure. There is no slippage between the string and the pulley. The pulley has a radius of 25.0 cm and a moment of inertia of ½ MR2. If m1 is 1.00 kg, m2 is 2.00 kg, and M is 4.00 kg, then what is the tension in the string...
A mass m1 is connected by a light string that passes over a pulley of mass M to a mass m2 sliding on a frictionless horizontal surface as shown in the figure. There is no slippage between the string and the pulley. The pulley has a radius of 25.0 cm and a moment of inertia of ½ MR2. If m1 is 1.00 kg, m2 is 2.00 kg, and M is 4.00 kg, then what is the acceleration of m1?
In the figure, two 6.20 kg blocks are connected by a massless string over a pulley of radius 2.40 cm and rotational inertia of 7.40 Times 10^-1 kg m^2. The string does not slip on the pulley; and there is no friction between the table and the sliding block; the pulley's axis is frictionless. When this system is released from rest the pulley turns through 1.30 rad in 91.0 ms and the acceleration of the blocks is constant. What are...
Two blocks are connected to a string, and the string is hung over a pulley connected to the ceiling, as shown in the figure below. Two blocks, labeled m1 and m2, are connected to a string which is hung over a pulley connected to the ceiling. The pulley is of mass M and radius R. A block labeled m1 hangs suspended off the surface on the left side of the pulley. A block m2 is on the right side of...