Andrewstructure:
Normally you don’t apply any bending calcs. or bending stresses to the pin design. But, at the same time, they can’t always be completely ignored either. We need much more info. here, to draw the full picture of your detail. What’s the pin dia. and mat’l., and the hole dias. and the pl. mat’l? The loading? Side view of the pls. with dimensions would be helpful too. Is the inside clear dimension btwn. the .75" plates, 1.5" plus 1/16", 1/8" or 1/4" (2 * 1/8")? Your description would allow any of these, and you want the max. possible gap to be as small as possible, to minimize the potential for bending. You also want the pin dia. and the hole dias. to be as close as practical; this tends to minimize potential for pin deflection due to bending, or limits bending; and the bearing stresses btwn. the pin and the plates is very much dependant upon this snug fit. Look up the Hertz bearing (contact) stress problem, and see how Dpin vs. Dhole affect the bearing stresses. I’d look at the pin as though it was a cantilever semi-fixed at the middle of the 1.5" pl. But, almost immediately it is supported by a triangular bearing load which becomes max. at the gap; then it is loaded by a triangular loading (bearing force/ unit length) which is max. at the gap and decreases as you move into the side pl. That’s the general bending picture, putting a number on how much bending actually takes place involves some engineering judgement.
