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Yes, exactly that! Radial and tangential components are used to find the resulting forces (root of the sum of squares) that cause bending moments on the shaft. For gears that are not spur gears (bevel, helical, worm, etc.), the axial force will cause compression or tension in certain sections of the shaft as well. The axial force component is also important for bearings selection.

Label the top and bottom of the shaft, with A and B respectively. Consider this section of the shaft, subject to a positive bending moment that makes the shaft "smile". The A-fibers will be in compression, and the B-fibers will be in tension. Now spin the shaft 180 degrees, and apply the same loading situation. Now the B-fibers are on the top, and are in compression, and the A-fibers are on the bottom and are in tension. The bending moment that the shaft fibers are experiencing, is now equal and opposite, to what they experienced before. You therefore have completely reversed loading, as far as the bending moment is concerned. It cycles from A-fibers in tension and B-fibers in compression, to the exact opposite, with every rotation of the shaft. Normally, the weight of the shaft, the weight of the rotors, and the radial loads associated with gears/pulleys/sprockets/etc, will cause an amplitude to the bending moment, but not a mean bending moment. An example where you WOULD have a non-zero mean bending moment, is if you had an eccentrically-mounted rotor on the shaft. Suppose it is heavy enough that the mass and centrifugal effect would cause a significant load. The apparent centrifugal force caused by this lop-sided rotor would continuously load one group of fibers in tension, and the opposite group of fibers in compression, since its heavy side always pulls outward on the shaft, due to the centrifugal effect.

Could it also have been moment at C is 0 ?

@@tstvideo1 Not in this problem.