The solution of the question is provided in the below figures.
Q-19 Bearing reactions R, and R, are exerted on the shaft shown in the figure, which...
If any table needed you can find it online. Problem 1 (5 Points) Bearing reactions R, and Rz are exerted on the shaft shown in the figure below, which rotates at 950 rev/min and supports an 8-kip bending force. Use a 1020 HR steel. Specify a diameter d using a design factor of ng = 1.6 for a life of 10 hr. The surfaces are machined. F = 8 kip — 10 in— +5 in 5 in d/10 R. 1.4
PROBLEM 4: Calculate the diameter D of the rotating shaft, supported on each end by a radial bearing, to obtain infinite life with a safety factor of 1.2. The shaft is machined from AISI 1040 HR steel, and is subject to a bending moment caused by a static force F-4 KN. The radius r is 0.05D. The length of the shaft L 0.5 m. The shaft rotates at in 1 ㄧㄒㄨ D. In 1000 RPM. Assume full notch sensitivity q...
7-25 A shaft is to be designed to support the spur pinion and helical gear shown in the figure on two bearings spaced 700 mm center-to-center. Bearing A is a cylindrical roller and is to take only radial load; bearingB is to take the thrust load of 900 N produced by the helical gear and its share of the radial load. The bearing at B can be a bal bearing. The radial loads of both gears are in the same...
A rotating shaft of 25-mm diameter is simply supported by bearing reaction forces R and R. The shaft is loaded with a transverse load of 13 kN as shown in the figure. The shaft is made from AISI 1045 hot-rolled steel. The surface has been machined. Determine (a) the minimum static factor of safety based on yielding. (b) the endurance limit, adjusted as necessary with Marin factors. (c) the minimum fatigue factor of safety based on achieving infinite life. (d) If the fatigue factor...
augue application? 6-10 A rotating shaft of 25-mm diameter is simply supported by bearing reaction forces R and R2. The shaft is loaded with a transverse load of 13 kN as shown in the figure. The shaft is made from AISI 1045 hot-rolled steel. The surface has been machined. Determine (a) the minimum static factor of safety based on yielding. (b) the endurance limit, adjusted as necessary with Marin factors. (c) the minimum fatigue factor of safety based on achieving...
The shaft shown in the figure is supported on bearings located at A and D. The shaft is made from steel with a yield strength of 680 MPa and an ultimate strength of 790 MPa. The shaft dimensions are in millimeters and each step has the diameter shown. There are fillets with 2 mm radii at each step in the diameter. The notch sensitivity is 0.840. The shaft has a machined surface finish. A reliability of 99% is desired for...
The shaft shown in the figure is supported on bearings located at A and D. The shaft is made from steel with a yield strength of 680 MPa and an ultimate strength of 790 MPa. The shaft dimensions are in millimeters and each step has the diameter shown. There are fillets with 2 mm radii at each step in the diameter. The notch sensitivity is 0.840. The shaft has a machined surface finish. A reliability of 99% is desired for...
thumps up The shaft shown in the figure is supported on bearings located at A and D. The shaft is made from steel with a yield strength of 680 MPa and an ultimate strength of 790 MPa. The shaft dimensions are in millimeters and each step has the diameter shown. There are fillets with 2 mm radii at each step in the diameter. The notch sensitivity is 0.840. The shaft has a machined surface finish. A reliability of 99% is...
The shaft shown in the figure is supported on bearings located at A and D. The shaft is made from steel with a yield strength of 400 MPa and an ultimate strength of 600 MPa. The shaft has a machined surface finish. The geometric stress concentration at point A, B, C, and D is 1.65. The material has a notch sensitivity of 0.896. All dimensions are in mm. If the shaft rotates, with the force F remaining fixed, find the...
3- The shaft shown in the figure rotates with constant angular velocity and is transmitting a torque from gear B to gear C through the forces Exo and Ez as shown. The shaft is subject to combined bending and torsion due to the forces shown. The weights of the shaft and pulleys may be neglected and the supports can exert only concentrated force reactions. The radius of the gear at B is 50 mm and that at C is 75...