Patient with a dislocated shoulder is put into a traction apparatus as shown in figure 1.29....
A patient with a dislocated shoulder is put into a traction apparatus as shown in the figure. The pulls A⃗ and B⃗ have equal magnitudes and must combine to produce an outward traction force of 5.70 N on the patient's arm How large should these pulls be?
Constants A patient with a dislocated shoulder is put into a traction apparatus as shown in (Figure 1). The pulls A and B have equal magnitudes and must combine to produce an outward traction force of 11.6 N on the patient's arm Part A How large should these pulls be? Express your answer with the appropriate units. F Value Units Submit Request Answer Provide Feedback Figure 1 of 1 32
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. QUESTION 2 [6] D С Consider the traction apparatus shown in...
The figure below shows a shoulder exercise using a theraband. While in the posture shown, the person slowly pulls their arm down to their side while keeping the elbow straight. During this phase of the exercise the agonist muscle at the shoulder would be: a. The shoulder abductors acting concentrically b. The shoulder abductors acting eccentrically c. The shoulder adductors acting eccentrically d. The shoulder adductors acting concentrically s) MacBook Air The figure below shows a shoulder exercise using a...
The total mass of the arm shown in (Figure 1) is 3.5 kg . The location of the center of mass of the arm is shown, FM is the force exerted by the deltoid muscle on the upper arm, and FJ is the normal force from the shoulder joint on the upper arm. Part A Determine the magnitude of the force required from the deltoid muscle to hold up the outstretched arm in the position shown. Part B Suppose this...
The figure below shows a human arm that weighs 39.3 N. The arm is extended outward and is motionless. The gravitational force Fg on the arm acts at point A, a distance of 0.290 m from the shoulder joint, which is represented by point O. The shoulder pushes down and to the right on the humerus bone of the arm with a force Fs at point O, at an angle θ as shown. The deltoid muscle pulls back on the...
Three ropes are tied in a knot as shown in the figure. One student pulls on rope A with 1.0 pound of force, and another student pulls on rope B with 7.0 pounds of force. How hard and in what direction must you pull on rope C to balance the first two pulls? Give the direction by specifying the angle (clockwise or counterclockwise) of the pull with the direction of rope A. 1. Rope B 2. Find the magnitude and...
2. The nurse is providing education to a patient about Buck's traction for a hip fracture. How does the nurse describe this type of traction? A. This type of traction is applied several times per day. B. This type of traction is applied constantly using a boot. C. A cast will be applied to the affected leg and attached to weights. D. The patient in Buck's traction will have a pin inserted through the femur which will be attached to...
In the Cavendish balance apparatus shown in Figure 13.4 in the textbook, suppose that m1 = 1.00kg , m2 = 28.0kg , and the rod connecting each of the pairs of masses is 32.0cm long. Once the system reaches equilibrium, each pair of masses, m1 and m2, are separated by a distance of 11.0cm center-to-center. Part A Find the magnitude of the net force on one of the small masses, m1 . Part B Find the gravitational torque (about the...