An Atwood machine consists of two masses connected by a light string of fixed length which...
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...
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...
5. An Atwood machine consists of two masses mi and m2 (with mi > m2) attached to the ends of a light string that passes over a light, frictionless pulley Problem Setup1 FBD ty m2 mi 1-png When the masses are released, the mass mi is easily shown to accelerate down with an acceleration mi m2 mi +m2 Suppose that and m 2 are measured as mn = 100 ± 1 and mg = 50 ± 1, both in grams....
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 two masses m1 and m2 (with m1 > m2) attached to the ends of a light string that passes over a light, frictionless pulley. When the masses are released, the mass m1 is easily shown to accelerate down with an accelerationSuppose that m1 and m2 are measured as m1=100±1 gram and m2=50±1 gram. Derive a formula of the uncertainty in the expected acceleration in terms of the masses and their uncertainties, and then calculate δα for...
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...
4. A simple Atwood machine consists of two masses m1 and m2 that are connected by a string wound over a pulley, as seen in the figure below. Assume m2 is larger than m1. Motion in the upward direction is positive. On a piece of paper, draw two free body diagrams; one for each of the masses, showing all forces acting on each mass. Then answer the following questions. Suppose that m2 starts from rest at a height of 7...
QUESTION 1 An Atwood Machine consists of two masses connected to a cord which is draped over a pulley. In our experiment, what will be true about the masses? Mass 1 will vary with Mass 2 held constant. Mass 1 will vary with Mass 2 held constant. The masses will have a constant sum. The masses will have a constant mass difference. 3 points QUESTION 2 You will get a value for acceleration for each trial from a LoggerPro...
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...