Please explain step by step. 6. In the Atwood's machine shown in Fig. 2, both masses...
Atwood's Machine An Atwood's machine consists of two masses, m1 and m2. connected by a string that passes over a pulley. Part A If the pulley is a disk of radius R and mass M. find the acceleration of the masses.
Review Part A The two masses in the Atwood's machine shown in the figure have an initial speed of 0.19 m/s, and my is moving upward. (Figure 1) How high does my rise above its initial position before momentarily coming to rest, given that m 31 kg and m = 42 kg? Express your answer using three significant figures. Figure < 1 of 1 V AXD O ?
6) Draw free-body diagrams of both hanging masses? masses. What force is acting on both Force sensor Hanging massi 7) Use Newton's Second Law to calculate the theoretical acceleration a of both masses Show your work. Calculated or theoretical acceleration ar 8) Measure the acceleration a of the cart by using the velocity-time (measured or experimental acceleration), The slope of this graph is the experimental or measured acceleration a. Measured or experimental acceleration 9) Calculate the % difference. a.-a, x100...
The masses attached to each side of an ideal Atwood's machine consist of a stack of five washers, each of mass m, as shown in the below. The tension in the light string is T0. When one of the washers is removed from the left side, the remaining washers accelerate and the tension decreases by 0.320 N. (Assume that the pulley is massless and frictionless.) Find m. g Find the new tension and the acceleration of each mass when a...
1. In a classical Atwood's machine setup (like this lab), what are the forces that will be discussed? a)The weight of the masses on each pulley and the tension in the string b) The weight of the masses on each pulley. c) The Mtotal times g and the tension on the string. d) The masses on each pulley and the tension in the string 2. What's the total mass of the system in our case of the Atwood's machine? a)...
(Figure 1) illustrates an Atwood's machine. Let the masses of blocks A and B be 9.00 kg and 2.00 kg, respectively, the moment of inertia of the wheel about its axis be 0.220 kg. m², and the radius of the wheel be 0.120 m. There is no slipping between the cord and the surface of the wheel. Part A Find the magnitude of the linear acceleration of block A. Part B Find the magnitude of linear acceleration of block B. Part C Find the magnitude of...
The Atwood's machine has two hanging masses. The mass of the A is 3m and the mass B is 2m . The pulley C can be considered as a solid cylinder with mass m and radius R . There is no slipping between the cord and the surface of the wheel. Here, m= 2.00 kg, 2m= 4.00 kg, and 3m= 6.00 kg. (Figure 1) Part A Part complete What is the speed of mass A after it falls 2.10 m down? v(f)=…..m/s
illustrates an Atwood's machine. Let the masses of blocks A and B be 6.00 kg and 2.50 kg , respectively, the moment of inertia of the wheel about its axis be 0.220 kgâ‹…m2 , and the radius of the wheel be 0.120 m . There is no slipping between the cord and the surface of the wheel. part a: Part A Part complete Find the magnitude of angular acceleration of the wheel C . α =…. rad/s^2 part b: Find...
Conservative Forces and Potential Energy? A simple Atwood's machine uses two masses, m1 and m2. Starting from rest, the speed of the two masses is 6 m/s at the end of 5 s. At that instant, the kinetic energy of the system is 67 J and each mass has moved a distance of 15 m. Determine the values of m1 and m2
Atwood's machine consists of blocks of masses mi -8.8 kg and m2 - 17.5 kg attached by a cord running over a pulley as in the figure below. The pulley is id cylinder with mass M-7.30 kg and radiusr 0.200 m. The block of mass m2 is allowed to drop, and the cord turns the pulley without slipping. (a) Why must the tension T2 be greater than the tension T1? Score: 1 out of Comment: (b) What is the acceleration...