Consider the traction apparatus shown in the figure, which applies a force to the lower-leg of a patient. Determine the magnitude and direction of this force applied by the traction apparatus if the leg is stationary. The angle is given by θ = 25 degrees and the mass hanging from the chord in the traction apparatus is m = 13 kg. Draw clearly labelled free body diagrams where necessary.
Consider the traction apparatus shown in the figure, which applies a force to the lower-leg of...
Application to the Russell traction system Any traction system can be analyzed by keeping in mind two things. First, the force applied is in the direction of the wire at the point where it is attached to the patient. Second, the force is equal to the weight hung on the wire. When a thigh bone of femur becomes fractured, a potential problem arise in the healing process. There is a tendency for the major leg muscles to pull together and...
Patient with a dislocated shoulder is put into a traction apparatus as shown in figure 1.29. The pulls A and B have equal magnitude as must combined and produce an outward traction force of 5.75N on the patient’s arm how large should these polls be 35.0에 35.001 ▲ FIGURE 1.29
The femur of a human leg (mass 10 kg, length 0.9 m) is in traction, as shown in the figure. The center of gravity of the leg is one-third of the distance from the pelvis to the bottonm of the foot. Two objects, with masses m and m2, are hung at the ends of the leg using pulleys to provide upward support A third object of 8 kg is hung to provide tension along the leg. The body provides tension...
An accident victim with a broken leg is being placed in traction. The patient wears a special boot with a pulley attached to the sole. The foot and boot together have a mass of 4.0 kg, and the doctor has decided to hang a m = 6.3 kg mass from the rope. The boot is held suspended by the ropes and does not touch the bed. A) Determine the amount of tension in the rope by using Newton’s laws to...
Problem 3 (20 points) In the following figure, a horizontal force F is applied to a large block of mass M with a massless pulley attached to it. While the block M is moving to the right, the other two blocks mi and m2 remain stationary problem relative to M. All surfaces are frictionless for this (a) Draw separate free body diagrams for M(including the massless pulley), mi, and m2 respectively. On the free body diagrams, please only draw and...
Question 22 of 30> The femur of a human leg (mass 10 kg, length 0.9 m) is in traction, as shown in the figure. The center of gravity of the leg is one-third of the distance from the pelvis to the bottom of the foot. Two objects, with masses mi and m2, are hung at the ends of the leg using pulleys to provide upward support. A third object of 8 kg is hung to provide tension along the leg....
The femur of a human leg (mass 10 kg, length 0.9 m) is in traction, as shown in the figure. The center of gravity of the leg is one-third of the distance from the pelvis to the bottom of the foot. Two objects, with masses m1 and m2,are hung at the ends of the leg using pulleys to provide upward support. A third object of 8 kg is hung to provide tension along the leg. The body provides tension as...
13 Figure 12-31 shows the anatomical structures in the lower leg and foot that are involved in standing on tip- toe, with the heel raisecd slightly off the loor so that the foot effectively contacts the floor only at point P. Assume distance a- 50 cm, distance b 15 cm, and the Calf muscle Lower leg hones person's weight W 900 N. Of the forces acting on the foot, what are the (a) magni tude and (b) direction (up or...
Figure 4: Top view of force table. (3) Figure 5 is an inclined-plane system that will be stud- ied in the first part of this experiment. As labelled in the figure, the x (y) direction is parallel (perpendicular) to the inclined plane, and the gravitational acceleration is downward. If the hanging mass m is too small, the block mass M on the inclined plane slides down. When the hanging mass is gradually increased to a lower-bound value mi such that...
Requirement: (1) Draw necessary free body diagrams, (2) write necessary equations, and (3) name the adopted principle 3. The mass of block is 10 kg and the horizontal force applied to the block as shown in Figure below is 100 N. The coefficients of kinetic friction between the block and the inclined plane is μ A 0.2. Determine the acceleration of the block and its direction. Draw free body diagram and write the needed equation (25 points) 30P