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Pro Calculate the axial stress, torsional stress, bending stress, and the transverse shear stress at the most critical point in the cylindrical beam. The diameter of the beam is 14mm. You must explain why you chose the said point to be the most critical. Draw the stress state at the most critical point. The diagram must be drawn with a straight edge and should be very clear. You may choose any coordinate system but you must clearly indicate your choice on the cube as well as the above figure. You may start your calculations by directly drawing the axial force, torque, shear force, and bending moment diagrams that were discussed in class for this problem. Note that if these diagrams are not right (sign, shape, and values) you will not get any credit for this problem. Problem 2 (20 points) No0I Noac IOONM 10,000N OONm 0.2m 0.3M 2M Calculate the axial stress, torsional stress, bending stress, and the transverse shear stress at the most critical point in the cylindrical beam. The diameter of the beam is 14mm. You must explain why you chose the said point to be the most critical. Draw the stress state at the most critical point. The diagram must be drawn with a straight edge and should be very clear. You may choose any coordinate system but you must clearly indicate your choice on the cube as well as the above figure. You may start your calculations by directly drawing the axial force, torque, shear force, and bending moment diagrams that were discussed in class for this problem. Note that if these diagrams are not right (sign, shape, and values) you will not get any credit for this problem. 

          Pro
Calculate the axial stress, torsional stress, bending stress, and the transverse shear stress at the most critical point in the cylindrical beam. The diameter of the beam is 14mm. You must explain why you chose the said point to be the most critical.

Draw the stress state at the most critical point. The diagram must be drawn with a straight edge and should be very clear. You may choose any coordinate system but you must clearly indicate your choice on the cube as well as the above figure.

You may start your calculations by directly drawing the axial force, torque, shear force, and bending moment diagrams that were discussed in class for this problem. Note that if these diagrams are not right (sign, shape, and values) you will not get any credit for this problem.

Problem 2 (20 points)
No0I
Noac
IOONM
10,000N
OONm
0.2m
0.3M
2M

Calculate the axial stress, torsional stress, bending stress, and the transverse shear stress at the most critical point in the cylindrical beam. The diameter of the beam is 14mm. You must explain why you chose the said point to be the most critical. Draw the stress state at the most critical point. The diagram must be drawn with a straight edge and should be very clear. You may choose any coordinate system but you must clearly indicate your choice on the cube as well as the above figure.

You may start your calculations by directly drawing the axial force, torque, shear force, and bending moment diagrams that were discussed in class for this problem. Note that if these diagrams are not right (sign, shape, and values) you will not get any credit for this problem.
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pro calculate the axial stress torsional stress bending stress and the transverse shear stress at the most critical point in the cylindrical beam the diameter of the beam is 14mm you must ex 69405

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University Physics with Modern Physics
University Physics with Modern Physics
Hugh D. Young 14th Edition
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Pro Calculate the axial stress, torsional stress, bending stress, and the transverse shear stress at the most critical point in the cylindrical beam. The diameter of the beam is 14mm. You must explain why you chose the said point to be the most critical. Draw the stress state at the most critical point. The diagram must be drawn with a straight edge and should be very clear. You may choose any coordinate system but you must clearly indicate your choice on the cube as well as the above figure. You may start your calculations by directly drawing the axial force, torque, shear force, and bending moment diagrams that were discussed in class for this problem. Note that if these diagrams are not right (sign, shape, and values) you will not get any credit for this problem. Problem 2 (20 points) No0I Noac IOONM 10,000N OONm 0.2m 0.3M 2M Calculate the axial stress, torsional stress, bending stress, and the transverse shear stress at the most critical point in the cylindrical beam. The diameter of the beam is 14mm. You must explain why you chose the said point to be the most critical. Draw the stress state at the most critical point. The diagram must be drawn with a straight edge and should be very clear. You may choose any coordinate system but you must clearly indicate your choice on the cube as well as the above figure. You may start your calculations by directly drawing the axial force, torque, shear force, and bending moment diagrams that were discussed in class for this problem. Note that if these diagrams are not right (sign, shape, and values) you will not get any credit for this problem.
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Transcript

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00:01 Hello students in this question given as this diagram.
00:04 So let divide into this section into the three sections.
00:08 So let this is the first and this is the second and this is third section.
00:14 Now we'll calculate the in different section normal stress.
00:20 So normally stress in the first section that is the sigma 1 is equals to load upon cross sectional area.
00:41 Now this is equals to the 10 ,000 is given in this question load upon cross sectional area of this is equals to 40 into 2 mm.
00:51 So after calculation this is equals to 125 newton per mm square.
01:00 Now second normal stress in the section 2 is equals to again the stress upon strain and the stress upon cross sectional area.
01:10 So stress is for this value is also 10 ,000 is given and 2 into 0 .31 meter 0 .03 meter is given because h is equals to 0 .03 meter...
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