Same

Same

Same

It's because your subliminally interested in light & optics.

It started when I clicked on a bartender showing how to make optically clear ice cubes for drinks, next day this was in my feed.

In metalworking terms, it would be very similar to using an aluminum, copper, or tin lap (as in watchmaker's "black polishing"). You want your lap to be softer than the material to be cut. Your lap becomes a matrix to hold the abrasive particles in place, and the cutting happens on the material that can't just grab and hold the abrasive. (Tin, by the way, gives absolutely amazing results when polishing steel. It's just _really_ stringy to machine when you're initially making the lap. Save it for your finest - sub-micron - grits.)

You polish silverware with fine cloth which is softer than silver. If you use sandpaper the result would be terrible.

Very informative yet old video on lapping metal parts by rotation. Check this: kzbin.info/www/bejne/nJ_Sh4ljh7x8jbs It vey clearly explains "how it's made".

@@gvidas1338 This is great, thanks!

I feel there’s a general misconception when it comes to lapping a polishing that is a result of focusing on the lap material. As the first comment responder noted the lap only hold the cutting media. There are three fundamental rules for cutting to occur, though I only usually remember two. The important one here is that the cutting “tool” (in this case lapping or polishing compound) MUST be harder that the workpiece. The second is that there must be relative motion. The third escapes me. But in either case it is not the lap that cuts the work piece but the embedded abrasive. Apologies for the lecture comment but lapping and polishing seem to be no different fundamentally than any other metal removal process; hard removes soft. In the case of polishing silverware presumably there is some residual polishing compound on the cloth that is the effective mechanism for removing the oxide layer. Also, if I’m glaringly wrong please correct me. 👍 Edited for autocorrect errors.

What a cheerfully bright comment! I for one found the video very illuminating, and it seemed to polish out all the rough spots in my dull and hazy knowledge. You could say that it expanded my bandwidth....

@@digitalradiohacker makes me wanna leave my daily grind and do something else

Micronically inquisitive mind lapped up the precision explanations.

If y'all don't cease with immediacy I'm gonna jump into a woodchipper.

😂

It's rather hypnotic.

That's not as bad as the glass blower who accidentally inhaled and now has a pane in his chest.

@@MikeWiggins1235711 Still not as bad as that chef who, while cooking some some chicken broth, fell into the pot and made a laughing stock of himself.

Clearly, I didn't see that coming.

@@Cynthia_Cantrell Did you hear about the guy who wondered why the baseball kept getting bigger and bigger, then it hit him.

Reminds me of the lab technician who spilled some acid on himself. Really left him fuming.

its not the same as true level

@@hindugoat2302 Reality is poison! I can't live like this!

@Andrew Crews I worked on Eaton and Sauer-Sundstrand axial piston pumps and motors. We would replace pistons and cylinder blocks and send them out to be resleeved/refinished.

I appreciate this comment very much after having done very similar work in the 90s. I used to test lapped and partially polished parts with an optical flat to infer the concavity of the part (convex or concave). Once the concavity was determined, I inferred the lapping wheel's (opposite) concavity and would adjust the rings' position to correct the wheel.

Pl.explain the process in detail

If you think that is impressive the Laser Interferometer Gravitational-Wave Observatory uses interferometry to detect changes in length less than a 10 thousandth of the diameter of a proton.

@@kellymoses8566 luckily we don't need *quite* such precision for optics :)

if you like that; then the three plates to make a surface plate is another example of this principle (though wil hardish surfaces)

@@robertmccabe8632 Indeed. I use this principle to keep my sharpening stones flat. Using silicon carbide abrasive, I grind A against B, B against C, and C against A.

Nah...you just use auto tune. Everybody does these days. Hehehe

@@shannonpincombe8485 That's how those T-pain sunglasses are made.

I think there is a tradeoff. It would certainly help, but investing in climate control may not be worth it. Also, it seems heating the plate and then weighing it down removes enough deformity in a small amount of time. These techniques are fascinating.

@@shannonpincombe8485 I respect the pun

They run 24hrs

No actually in this particular case it is borosilicate, which has a thermal expansion coefficient that is about 3 times lower than granite (which is an advantage). You can however use granite without problems if you have good temperature control.

"proper knowledge and materials"--including an old washing machine motor and rollerblade wheels.

Agreed. Like watching This Old Tony.

Polishing is the final stage of producing an optical quality surface and there is only one compound used on a given lap. Grinding the surface to a desired rudimentary curve is called grinding, not lapping. Pitch laps do not grind but only polish. The amount of material you'd remove by polishing is miniscule and nobody wants to waste time doing any more polishing than necessary. Grinding a surface starts as a rough cut to quickly give a desired curvature and to remove casting irregularities. Then a succession of finer grits is used to remove the deep scratches left by the previous grit. This is done with a hard tool on the workpiece and an abrasive slurry is run onto the surface. It looks a lot like lapping with a pitch lap, but because the tool is hard, it can be reliably cleaned off when it is time to change to the next finer grit size.

It's generally a combination of both. If you use a chemical that etches your surface while you are polishing, you can use a very mild (or soft) abrasive agent, which results in a smoother result. By the way, when you use Cerium Oxide to polish glass, chemical interaction also helps speed up the polishing process. For wafers the actual flatness is less important that the smoothness, since modern wafer steppers make a heigh map of the wafer to correct for the total thickness variation when clamping a wafer to the chuck. Modern technology wafers are indeed incredibly smooth and flat (from the dimension of individual components to that of the full chip)

The silicon carbide grinding is not done against pitch but against other glass or granite plates. You have to carefully clean and rinse between grains (not only the plates, the work space, but also your hands) in order to avoid contamination.

Sure, that is the way to store them over longer times. It also avoids the evaporation of the more volatile components from the pitch so it keeps the right viscosity. However, even then you have to put some effort in bringing them back in a usable state, because, they will loose shape on the sub-micron scale.

freeze then chip it off and melt and recast. the polishing compound is micon sized...not grit. used to use rouge, but there are better compounds not so messy.