For the Atwood's Machine problem as described in the course video, mass one hanging from the...
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)...
A device known as Atwood's machine consists of two masses hanging from the ends of a vertical rope that passes over a pulley. Assume the rope and pulley are massless and there is no friction in the pulley. When the masses are of 20.5 kg and 12.1 kg, calculate their acceleration, a, and the tension in the rope, T. Take g = 9.81 m/s2. Answer the acceleration in m/s2 and answer the tension in Newtons.
I need questions 8-11. Thank you. comp Atwood's Machine Equipment Qty Equipment 1 Mass and Hanger Set 1 Photogate with Pully Photogate with Pully 1 Universal Table Clamn 1 Large Rod 1 Small Rod 1 Double rod Clamp I 1 String Part Number ME-8979 ME-6838A ME-9376B ME-8736 ME-8977 ME-9873 Background Newton's 2 Law (NSL) states that the acceleration a mass experiences is proportional to the net force applied to it, and inversely proportional to its inertial mass la t )....
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
An Atwood's machine consists of blocks of masses m,-11.0kg and m2-18.0kg attached by a cord running over a pulley as in the figure below. The pulley is a solid cylinder with mass M 8.50 kg and radius 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? This answer has not been graded yet (b) What is the acceleration...
Three blocks are connected on the table as shown below. The coefficient of kinetic friction between the block of mass m, and the table is 0.405. The objects have masses of m. - 4.75 kg, m,- 1.20 kg, and m, -2.50 kg, and the pulleys are frictionless (a) Draw free-body diagrams for each of the objects. Choose File No lle chosen (b) Determine the acceleration of each object, including its direction m, magnitude m, direction Select m, magnitude m, direction...
from an Atwood's machine experiment using a hanging mass to 2 The table below shows the data accrlerane a art The dfierence of the two masses was kept constant, while the total mass was Total mass M Inverse total mass 1/M (kg) 0500 0.600 0700 0 800 1.01 0.83 0.71 0.62 A Complete the third column in the table. (2 Points) B. Plot Acceleration vs. 1/M in increasing order of 1/M, on graph paper.(8 points) C Draw the best-fit straight...
An Atwood's machine has one block of m1 = 0.370 kg and the other is of m2 = 0.420 kg. The disk pulley, which is mounted in horizontal, frictionless bearings, has a radius of 5.0 cm. When released from rest, the heavier block is observed to fall Δy = 92.0 cm in 4.7 sec. For the following questions, return your answers rounded to 4 significant figures. 1.) The rate of acceleration of each block is m/s2. 2.) The tension in...
An Atwood's machine (see the figure below) consists of two masses: one of mass 3.53 kg and the other of mass 9.36 kg. When released from rest, what is the acceleration of the system? (Enter the magnitude in m/s2.)
The Atwood machine consists of two masses hanging from the ends of a rope that passes over a pulley. The pulley can be approximated by a uniform disk with mass mp=6.33 kg and radius rp=0.250 m. The hanging masses are mL=21.1 kg and mR=14.1 kg.Calculate the magnitude of the masses' acceleration a and the tension in the left and right ends of the rope, TL and TR , respectively.