In a similar problem as before, a 0.362 kg mass hangs from a frictionless pulley with...
A mass m hangs from string wrapped around a pulley of radius R. The pulley has a moment of inertia I and its pivot is frictionless. Because of gravity, the mass falls and the pulley rotates. The magnitude of the torque on the pulley is.. equal to mgR Not enough information greater than mgR less than mgR
VULSTIUNI A mass of 1 kg hangs from the side of a pulley. The pulley has a moment of inertia of 3/4 MR2, a mass of 10 kg, and a radius of 0.2 m. The pulley and hanging mass are initially at rest. What is the downward speed of the hanging mass when it has fallen 2.0 m? a. 1.15 m/s b. 1.37 m/s c. 1.55 m/s d. 1.83 m/s e. 2.15 m/s QUESTION 2 A5 kg 1.0 m radius...
A mass m hangs from a string. The string is attached to a frictionless pulley of mass M and is wrapped around it many times around it. The hanging mass is released from rest from a height h above the floor. The pulley is a uniform disk. use the rotational and linear second laws to find the acceleration of the mass as it falls. I got a = 2mg/(2m+M). Is this correct? If, so please explain
A 2.20 kg mass is attached to a light cord that is wrapped around a pulley of radius 4.35 cm, which turns with negligible friction. The mass falls at a constant acceleration of 2.05 m/s2. Find the moment of inertia of the pulley.
A 1.60 kg mass is attached to a light cord that is wrapped around a pulley of radius 4.75 cm, which turns with negligble friction. The mass falls at a constant acceleration of 3.40 m/s^2. Find the moment of inertia of the pulley.
As shown, a frictionless pulley hangs from a system of springs and a cable. The pulley is equidistant between the two supports attaching the springs to the ceiling. The distance between the supports is d=1.50 m . The cable cannot stretch and its length between the two springs is 1.8 m. (figure 1) (FIgure 2) A)As shown, a mass is hung from the pulley. This mass causes a tensile force of 17.0 N in the cable and the pulley to...
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?
You have a pulley 13.1 cm in diameter and with a mass of 2.6 kg. You get to wondering whether the pulley is uniform. That is, is the mass evenly distributed, or is it concentrated toward the center or the rim? To find out, you hang the pulley on a hook, wrap a string around it several times, and suspend your 1.9 kg physics book 1.3 m above the floor. With your stopwatch, you can find that it takes 0.65...
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 2 kg mass hangs from a 0.15 kg pulley having radius 3 cm. If the mass starts 1.75 m above the ground, then what is its speed just before it hits the ground? What is the wheel’s maximum angular speed? Draw a free body diagram also.