(b) Calculate the magnitude and direction of the force applied to the patient's head by the traction device shown i...
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 split Russell traction mechanism is an orthopedic device that combines suspension and traction to immobilize, position, and align the lower extremities in the correction of orthopedic deformities and in the treatment of congenial hip dislocation and hip and knee contractures. Split Russell traction uses a sling to relieve the weight of the lower extremities. The traction weights are suspended from pulley-and-rope systems at the foot and head of the patient's bed. A leg in a cast is stabilized by...
Determine the magnitude of the component of the applied force that could cause the femoral head fragment to “telescope” (slide along the nail). Where does the maximum moment (and thus the most likely point of failure) occur in the implant? Estimate the approximate magnitude of the maximum moment using the given scale. The figure show an example of a nail-plate combination used to fix an intertrochanteric 2250 N force is applied to the femoral head, in the direction shown with...
Calculate the magnitude and direction of the Coulomb force on each of the three charges shown in the figure below. 6.00 μC 1.50 ,C -2.00 μC 3.00 cm 2.00 cm 6.00 HC charge magnitude 6.00 HC charge direction select B 1.50 HC charge magnitude 1.50 uC charge direction elect. -2.00 HC charge magnitude 2.00 HC charge direction Need Help? Read It 5 -Select--
Calculate the magnitude and direction of the Coulomb force on each of the three charges shown in the figure below. 6.00 µC charge: magnitude Your response differs significantly from the correct answer. Rework your solution from the beginning and check each step carefully. N direction 1.50 µC charge: magnitude N direction -2.00 µC charge: magnitude N direction (6)------(1.5)-------(-2) <---3cm--><----2cm-->
Calculate the magnitude and direction of the Coulomb force on each of the three charges shown in the figure below.
3. (a) Calculate the magnitude and direction of the electric force on each of the three charges in the figure shown below. 6.00 C 1.50yC -2.00 μC 3.00 cm2.00 cm 3. (b) Determine the electric field at a point 1.00 cm to the right of the middle charge shown in the figure above. 3. (c) If a charge of -2.00 uC were placed at the point 1.00 cm to the left of the middle charge shown in the figure above,...
Calculate the magnitude and direction of the electrostatic force on the charge 'q3' shown in the figure. (Given that, the Coulomb's constant, k 9x 10 N.m2/c2 2102 a) F-45 N, Left b) F = 101.25 N, Left c) F = 8.65 N, Left d) F 120.7 N, Right 5.00 uC q1 q2 q3 3.00 cm2.00 cm
Calculate the magnitude and direction of the Coulomb force on each of the three charges shown in the figure below. Three charges lie along a horizontal line. A 6.00 µC positive charge is on the left. 3.00 cm to its right is a 1.50 µC positive charge. 2.00 cm to the right of the 1.50 µC charge is a −2.00 µCcharge. 6.00 µC charge magnitude 6.00 µC charge direction 1.50 µC charge magnitude 1.50 µC charge direction −2.00 µC charge ...
3. Calculate the magnitude and direction of the electrostatic force on the 6OyC charge shown in the diagram. 3.0 cm 2.0 cm 6.0 uC Fi 1.5uC F 2.0