Question 2) The Russell fracture traction device and a mechanical model of the leg are shown in the figure. The leg is kept balanced in the position shown by two weights connected to two cables. The total weight of the leg and the cast is W=250 N. The distance between points A and B, where the cables are attached to the leg, is L=100 cm, and the angle of the leg with the bed is y=6º. The distance between points A and B, where the cables are attached to the leg, is y=6 Dec is given. The point C is at three-fourths of the L measured from the point A (3L/4= 75 cm.) is the network center of the cast and leg located on the ground. The angle that cable 2 makes with the horizontal is B-40° as measured. Accordingly, in order for the leg to remain balanced in the shown position; Wi-Fi a) Find the pulling force T1 formed on the cable T. (Write your result in unit N) b) Find the T2 pulling force generated on cable 2. (Write your result in unit N) c) Find the angle a that cable I makes with the horizontal. 3L/4L с в/в W

Question 2) The Russell fracture traction device and a mechanical model of the leg are shown in the figure. The leg is kept balanced in the position shown by two weights connected to two cables. The total weight of the leg and the cast is W=250 N. The distance between points A and B, where the cables are attached to the leg, is L=100 cm, and the angle of the leg with the bed is y=6º. The distance between points A and B, where the cables are attached to the leg, is y=6 Dec is given. The point C is at three-fourths of the L measured from the point A (3L/4= 75 cm.) is the network center of the cast and leg located on the ground. The angle that cable 2 makes with the horizontal is B-40° as measured. Accordingly, in order for the leg to remain balanced in the shown position; Wi-Fi a) Find the pulling force T1 formed on the cable T. (Write your result in unit N) b) Find the T2 pulling force generated on cable 2. (Write your result in unit N) c) Find the angle a that cable I makes with the horizontal. 3L/4L с в/в W

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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The figure shows the Russel fracture traction device and a mechanical model of the leg. The leg is held in balance in the position indicated by the two weights attached to the two cables. The total weight of the leg and the cast is W=250 N. The distance between the points A and B where the cables are attached to the leg is given as L=100 cm and the angle of the leg with the horizontal is γ=6°. Point C is the center of gravity of the cast and leg at three quarters of the L measured from point A (3L/4= 75 cm). The angle that cable 2 makes with the horizontal is measured as β=40°. Accordingly, in order for the leg to remain in balance in the shown position; a) Find the tensile force T1 in cable 1. (Write your result in N) Answerb) Find the tensile force T2 in cable 2. (Write your result in N) Answerc) Find the angle α of cable 1 with the horizontal. Response
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