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For the shaft shown below with a uniform diameter of 40 mm, determine the maximum in-plane principal stress at A. Note: The two-dimensional stress element at A has been drawn below. You can use the equations or Mohr's circle to calculate the maximum in-plane principal stress at A. All stresses in the element are in MPa. The shaft is shown below: 75 mm 105 mm 720 N 630N The stress element at A is shown below (All stresses in the element are in MPa): 0.6684 у 12.03 х 12.03 0.6684
For the shaft shown below with a uniform diameter of 40 mm, determine the maximum in-plane shear stress at A. Note: The two-dimensional stress element at A has been drawn below. You can use the equations or Mohr's circle to calculate the maximum in-plane shear stress at A. All stresses in the element are in MPa. The shaft is shown below: 75 mm 105 mm 720 N 630 N The stress element at A is shown below (All stresses in the element are in MPa): 0.6684 y L, 12.03 Х 12.03 0.6684
For the shaft shown below with a uniform diameter of 40 mm, determine the maximum in-plane principal stress at B. Note: The two-dimensional stress element at B has been drawn below. You can use the equations or Mohr's circle to calculate the maximum in-plane principal stress at B. All stresses in the element are in MPa. The shaft is shown below: 75 mm 105 mm 720 N 630 N The stress element at B is shown below (All stresses in the element are in MPa): 0.7639 у LX 10.53 10.53 0.7639
For the shaft shown below with a uniform diameter of 40 mm, determine the maximum in-plane shear stress at B. Note: The two-dimensional stress element at B has been drawn below. You can use the equations or Mohr's circle to calculate the maximum in-plane shear stress at B. All stresses in the element are in MPa. The shaft is shown below: 75 mm 105 mm 720 N 630 N The stress element at B is shown below (All stresses in the element are in MPa): 0.7639 у 10.53 X 10.53 0.7639