Approach used:- here we use Newton's law of
motion on a friction less inclined plane to find the tension in the
strings attached to the block., ***************************************************************************************************
This concludes the answers. If there is any mistake,
let me know immediately and I will fix
it....
Problem #2) 77. IIl Two blocks are at rest on a frictionless incline, as shown in...
Problem #2) 77. IIl Two blocks are at rest on a frictionless incline, as shown in Figure P5.77 D What are the tensions in the two strings? Figure P5.77 3.0 kg 2 5.0 kg 20° Problem #3) 79. | The sledder shown in Figure P10.79starts from the top of a frictionless hill and slides down into the valley. What initial speed vi does the sledder need to just make it over the next hill? Figure P10.79 Vi 5.9 m 4.2...
it are at rest on a frictionless incline, as shown in Figure P5.77. What are the ten- sions in the two strings? 3.0 kg 2 5.0 kg 78.)1111 Jason works for a mov- ing company. A 45 kg wooden crate is sitting FIGURE P5.77 on the wooden ramp of his truck; the ramp is angled at 11°. What is the magnitude of the force, directed parallel to the ramp, that he needs to exert on the crate to get it...
Two blocks are at rest on a frictionless incline, as shown in (Figure 1) . Part A What is the tension in the string number 1 if m1 = 4.0 kg and m2 = 5.0 kg ? Part B What is the tension in the string number 2 if m1 = 4.0 kg and m2 = 5.0 kg ?
Answer Two blocks are at rest on a frictionless incline, as shown in (Figure 1). Part A What is the tension in the string number 1 if mi = 9.0 kg and m2 = 2.0 kg ? Express your answer with the appropriate units. T1 = Value Units Figure 1 of 1 Submit Request Answer Part B What is the tension in the string number 2 if mi = 9.0 kg and m2 = 2.0 kg ? Express your answer...
Problem#6 A system comprising blocks, a light frictionless pulley, a frictionless incline, and connecting ropes is shown in the figure. The 9.0-kg block accelerates downward when the system is released from rest. The tension in the rope connects the 6.0-kg block and the 4.0-kg block. (a) Draw the free body diagrams (b) Find the tension in the rope (c) Find the reaction of the incline surface on each block rn +1 30° 10-9 Problem#6 A system comprising blocks, a light...
1. A system comprising blocks, a light frictionless pulley, a frictionless incline, and connecting ropes is shown in the figure. The 9.0-kg block accelerates downward when the system is released from rest. What is the tension in the rope connecting the 6.0-kg block and the 4.0-kg block? [42 N] 6.0 kg 9.0 kg 30
Two blocks are connected by a massless rope over a massless, frictionless pulley, as shown in the figure. The mass of block 2 is ?2=11.7 kg , and the coefficient of kinetic friction between block 2 and the incline is ??=0.200 . The angle ? of the incline is 33.5° . If block 2 is moving up the incline at constant speed, what is the mass ?1 of block 1?
Two blocks are connected by a massless rope over a massless, frictionless pulley, as shown in the figure. The mass of block 2 is ?2=11.3 kg , and the coefficient of kinetic friction between block 2 and the incline is ??=0.200 . The angle ? of the incline is 31.5° . If block 2 is moving up the incline at constant speed, what is the mass ?1 of block 1?
Two blocks are connected by a massless rope over a massless, frictionless pulley, as shown in the figure. The mass of block 2 is m2 = 10.5 kg, and the coefficient of kinetic friction between block 2 and the incline is μk = 0.200. The angle of the incline is 27.5°. If block 2 is moving up the incline at constant speed, what is the mass m1 of block 1?
University Physics Two blocks are connected over a massless, frictionless pulley as shown in the figure below. The mass of block 2 is 12.1 kg, and the coefficient of kinetic friction between block 2 and the incline is 0.200. The angle θ of the incline is 31.5. If block 2 is moving up the incline at constant speed, what is the mass of block 1? kg Friction Previous Give Up & View Solution Check AnswerNext Exit Hint