The figure shows a shaft mounted in
bearings at A and D and having pulleys at B
and C. The forces shown acting on the
pulley surfaces represent the belt tensions.
The shaft is to be made of cost iron (class
40) using a design factor N = 2.8. What
diameter that should be used for the shaft
to avoid the failure?
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Problem 1: The figure shows a shaft mounted in bearings at A and D and having pulleys at B and C. The forces shown acting on the pully surfaces represent the belt tensions. The shaft is to be made of AISI 1040 HR steel. Using a conservative failure theory with a design factor of 2, determine the minimum shaft diameter to avoid yielding.
AISI 1018 HR Section #2 (80p) 035 CD 1018 HR Q1. The figure shows a shaft mounted in bearings at A and D and having pulleys at B and C. The forces shown acting on the pulley surfaces represent the belt tensions. The shaft is to be made of AISI 1035 CD steel. Using both conservative failure theory and distortion energy theory with a design factor of 2.5, determine the minimum shaft diameter to avoid yielding. dete n-2.5 127lbt 8y=61&...
The figure shows a 1.5 inch diameter shaft mounted in bearings at A and D and having pulleys at B and C. The forces shown acting on the pulley surfaces represent the belt tensions. Considering static loading, determine the principal stresses in the shaft? 6-in D. 300 lbf 50 lbf 27 lbf 360 lbfID 8-in D.6 in B8 in A 8 in
1. Figure (1) shows a 20 mm diameter shaft mounted in bearings at A and D and having pulleys at B and C. The forces shown acting on the pulley surfaces represent the belt pulls. Find the magnitude and exact location of the following stresses: (1) Principal stresses (2) Maximum shear stress Given dimensions are in millimeters and forces are in Newtons. 150 D 1335 N 225 N 1600 N 120 N 200 D C150 B 200 Figure (1) 200...
1. Figure (1) shows a 20 mm diameter shaft mounted in bearings at A and D and having pulleys at B and C. The forces shown acting on the pulley surfaces represent the belt pulls. Find the magnitude and exact location of the following stresses: (1) Principal stresses (2) Maximum shear stress Given dimensions are in millimeters and forces are in Newtons. 150 D 1335 N 225 N 1600 N 120 N 200 D C150 B 200 Figure (1) 200
Required information The figure shows a shaft mounted in bearings at A and D and having pulleys at B and C. The forces shown acting on the pulley surfaces represent the belt tensions. The shaft is to be made of AISI 1035 CD steel. The design factor is 2. The value of FB1= 240 lb, FB2= 40 lb, FC1= 47.256 lb, and Fc2= 313.974 lb. NOTE: This is a multi-part question. Once an answer is submitted, you will be unable...
The figure above shows a shaft mounted in bearings A and D and having pulleys at B and C. The shaft is 20 mm in diameter and made of AISI 1020 CD steel. The forces shown acting on the pulley surfaces represent the belt tensions. The shaft is concerned with yielding and fatigue failure. [Stress analysis) (1) Draw the free body diagrams and find reaction forces at A and D in the xy and xz planes. (2) Draw the shear force and moment...
Q2 (b) The layout of a shaft carrying two pulleys 1 and 2, and supported on two bearings A and B is shown in Figure 2.2. The shaft transmits 7.5 kW power at 360 rpm from pulley 1 to pulley 2. The diameters of pulley 1 and 2 are 250 mm and 500 mm respectively. The masses of pulley 1 and 2 are 10 kg and 30 kg respectively. The belt tensions act vertically downward and ratio of the belt...
Problem 1 (50 points) A countershaft carrying two V-belt pulleys is shown in the figure. Pulley A receives power from a motor through a belt with tensions shown. The power is transmitted through the shaft and delivered to the belt on pulley B. Assume the belt tension on the loose side at B is 15 percent of the tension on the tight side. 230 mm F: 30-mm dia. 280 mm 300 mm 250-mm dia. 400-mm dia 1000 N 150 N...
A countershaft, made of AISI 1035 CD steel, carrying two V-belt pulleys is shown in the figure. Pulley A receives power from a motor through a belt with the belt tensions shown. The power is transmitted through the shaft and delivered to the belt on pulley B. Assume the belt tension on the loose side at B is 25 percent of the tension on the tight side (F2 - 0.25 F) 1) Based on the equations for yielding conditions discussed...