Find the magnitude of the tension (in N) in each supporting cable shown below. In each case, the weight of the suspended body is 170.0 N and the masses of the cables are negligible. (Due to the nature of this problem, do not use rounded intermediate values in your calculations-including answers submitted in WebAssign.) (a) 45° T2 T3 T, = N T = T3 = (b) 60° 60° T2

Find the magnitude of the tension (in N) in each supporting cable shown below. In each case, the weight of the suspended body is 170.0 N and the masses of the cables are negligible. (Due to the nature of this problem, do not use rounded intermediate values in your calculations-including answers submitted in WebAssign.) (a) 45° T2 T3 T, = N T = T3 = (b) 60° 60° T2

Name: (d)45°45°T260°60°T3T4T1170T298.15X NT398.15V NT4170N Find the magnitu
Uploaded: 2024-03-20T06:56:46.000Z
Channel: Bartleby
Description: (d)45°45°T260°60°T3T4T1170T298.15X NT398.15V NT4170N Find the magnitude of the tension (in N) in each supporting cable shown below. In each case, the weight of the suspended body is 170.0 N and the masses of the cables are negligible. (Due to thenat

Principles of Physics: A Calculus-Based Text

5th Edition

ISBN:9781133104261

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter4: The Laws Of Motion

Section: Chapter Questions

Problem 23P: A bag of cement weighing 325 N hangs in equilibrium from three wires as suggested in Figure P4.23....

See similar textbooks

Similar questions

Find the magnitude of the tension in each supporting cable shown below. In each case, the weight of the suspended body is 100.0 N and the masses of the cables are negligible.
A picture frame hung against a wall is suspended by two wires attached to its upper corners. If the two wires make the same angle with the vertical, what must this angle be if the tension in each wire is equal to 0.75 of the weight of the frame?
A block of mass M = 10 kg is sitting on a surface inclined at angle θ = 45°. Given that the coefficient of static friction is μs = 0.5 between block and surface, what is the minimum force F necessary to prevent slipping? What is the maximum force F that can be exerted without causing the block to slip?
Two large forces, F1 and F2 are applied by using two cables to lift a load weighing 1 kg, as shown in figure. If both the forces make an angle of 1o with the horizontal, what is the tension in the cable? 98.0N 109.8N 281.0N 352.0N
A uniform plank of length 2.00 m and mass 29.5 kg is supported by three ropes, as indicated by the blue vectors in the figure below. Find the tension in each rope when a 685–N person is d = 0.500 m from the left end. magnitude of T1 = magnitude of T2 = magnitude of T3 =
If you hang a car with a mass of 1770 kg from a steel beam, you observe that the beam bends 0.095 degrees. What is the tension in this beam, in newtons? Using the equation T=F/(2*sin(theta))
A bag of cement weighing 400 N hangs in equilibrium from three wires. Two of the wires make angles ?1 = 56.0° and ?2 = 36.0° with the horizontal. Assuming the system is in equilibrium, find the tensions T1 and T2
A mountain climber practices his technique in a mountain climbing school by balancing while suspended by two ropes attached to the ceiling. As shown by the figure, the left rope makes an angle of 60 degrees with the horizontal ceiling and the right rope makes an angle of 30 degrees with the horizontal ceiling. If the right rope has tension T1=322 N, what is the weight of the mountain climber?
Assume an incline makes an angle of 30° with the horizontal. What is the y-component of the weight of an object of mass m on the incline? Group of answer choices mgcos30° 0 mg mgsin30°
A small mass, m = 200 grams, hangs vertically from a thin cable that is attached firmly to the ceiling. The thin cable has negligible mass. Calculate the magnitude of the tension, T, in the cable. Also, state the direction of the tension in the cable. T = 1.96 N, acting downward. T = 19.6 N, acting downward. T = 1.96 N, acting upward. T = 19.6 N, acting upward.
Two masses mA =9.3kg and mB=6.1kg are on inclines and are connected together by a string as shown in the figure. The angles theta subscript A=700 and theta subscript B = 360 . In the absence of the friction, the force F is required to pull the masses at a constant velocity up the fixed inclines. The force F is now removed. What is the magnitude of the acceleration of the two blocks? Take g =9.81 m/s2, and express your answer using two decimal places.
In Fig, a slab of mass m1 =40 kg rests on a frictionless floor, and a block of mass m2 =10kg rests on top of the slab. Between block and slab, the coefficient of static friction is 0.60, and the coefficient of kinetic friction is 0.40. A horizontal force of magnitude 100 N begins to pull directly on the block, as shown. In unit-vector notation, what are the resulting accelerations of (a) the block and (b) the slab?