Two weeks ago, after retrofitting a few more of these binocs with dust shields for some other people, I was about to finish my own. As it usually happens when I am about to finish a project, a thought crossed my mind. I began wondering why, if I already had spent that much time on this project, I shouldn't add a military spec reticle to my own binoculars. My 7x50 Steiner binocs have a reticle, which I find very useful, but the Steiner binocs are not pocketable due to size and weight. I decided to add a reticle to my small 7x20 Nikon binoculars. Some Nikon engineers are probably rolling their eyes now.
I sourced the M-22 reticle from M24 military binoculars (7x28). The reticle is on a small plane parallel piece ("filter") of coated optical glass.
The penny is for size comparison. I had to make a mount for the reticle. I used Delrin, brass, and urethane resin. This picture was taken with the penny and the reticle placed on a light table, so everything is backlit:
The reticle must be installed in the left eyepiece, because the right eyepiece has the diopter adjustment. The diopter is adjusted by turning the eyepiece, which means the reticle would also turn if it were mounted in the adjustable eyepiece.
I removed and took apart the left eyepiece. Red numbers denote original parts, green numbers denote modified, fabricated, or additional parts:
1: Rubber eyecup
2: Knurled eyecup mount
3: Threaded tube that contains lens elements 5 and 7, with spacer 7 between these two elements
4: Threaded adaptor ring that screws on one end to tube 3 and on the other end to the binoculars
5, 7: ocular lens elements
8: Retainer that screws into threaded tube 3 (holds lens 7 in place). This part had to be modified (shortened) to become part 8A.
9: This ring is used to bring the reticle into focus. I cut this brass ring from a brass tube. I then cut the ring open, and it was nice and springy. I widened the diameter with a ring mandrel so the ring would slip over tube 3 and make for a tight fit.
10: The reticle was mounted in another brass tube that fit precisely over tube 3.
A closer look at the spacer 9 and the reticle in its mount:
The width of this spacer is critical for proper focus. The proper width was obtained by lapping spacer on a flat diamond hone and by checking focus visually (required complete assembly of eyepiece):
Here you can see the reticle with its mount (tall brass tube) attached to tube 3. You can also see the ("focusing") spacer already described. Another function of the brass mount is that it allows turning the reticle so it will be properly aligned (plumb) once the eyepiece is screwed into the binoculars. Once the reticle is aligned, the brass tube and the spacer are secured with a piece of tape. That way the assembly can't move, but is still removable (for adjustment and servicing). All the brass parts will be painted with ultra fine matte black pigment camera enamel before final assembly. The eyecup mount and the eyecup have also been attached:
The adaptor ring 4 is screwed onto tube 3:
The eyepiece is now fully assembled and the reticle is in focus. The eyepiece can now be attached to the binoculars:
This how the reticle looks. It can be used to calculate the distance of objects or the size and height of objects.
The so called "constant factor" will need to be determined (easy to do empirically). The formula for calculating the distance of an object is then easily determined: Distance = constant factor x (object size : reticle units). Object size is calculated accordingly, if the distance is known.
Yeah, so now it's all done right? Well, having a compass display under the reticle might be useful. I think I'm about to stroke out.
