Researchers from the University of Maryland, Georgia Tech and the University of Notre Dame, have introduced DissolvPCB, a novel 3D printing-based method to fabricate fully recyclable electronic circui
This is not just one of those ivory tower papers with their actual applications far away in time and eventually ending up in some obscure industrial process never heard of again in lay circles; this could have an immediate impact on the maker culture and makerspaces right now and in the near future. The preprint describes the process in a very understandable, digestible manner and provides actual implementation examples, as well as detailed recipes for all of the compounds. If you are even remotely interested in the subject matter, I’d recommend you to try it out for yourself. The “ingredients” are all easily obtainable and handleable. Yes, gallium and indium might be a bit expensive, but it is worth it imo. They literally used consumer kitchen equipment for some of the steps, to demonstrate how this is feasible for tinkerers, makerspaces and prototypes. No expensive machinery required (except for an FFF 3d-printer, of course).
I skimmed through the paper, and I agree that it looks pretty damn digestible for the average tinkerer to understand and implement themselves if they so choose
But just kind of a quick summary for people who still won’t read the article
You basically 3d print a circuit board out of PVA (which is basically the same material as regular white elmers school glue, so non toxic and water soluble) with hollow channels instead of circuit traces.
Then you fill those hollow tubes with the gallium/indium mix, which has a very low melting point, like “glass of warm water” low.
Insert any components you need and secure them into place with a drop of glue, and BOOM you’ve got a circuit board.
And when you’re done, just dump it in a glass of water. The PVA dissolves and you can fish out the metal to reuse in a different project.
Like you said, the only “specialized” equipment you need is a 3d printer that can handle PVA filament.
Not necessarily something that’s going to be useful for any industrial production applications, but this could be huge for hobbyists and even prototyping for businesses. Most traditional methods for making a PCB call for some kind of nasty chemicals and they’re not really reusable, especially not for the home-gamer, this could make for a nice step-up for the people who don’t want to deal with this and want something a little more polished than a breadboard or a mess of soldered wires
It’s arguably easier, but I think it depends on your use case.
Etching usually requires a couple chemicals that not everyone has the space to store properly, like if they live in a small apartment and have kids, and even if you go with safer alternatives like vinegar over ferric chloride, after use the etching solution should still be considered poisonous and needs to be handled and disposed of with some care.
Also worth considering is that this method is solder-free, so in addition to not needing to solder anything, it’s easier to recover components, no desoldering needed, just warm it up a bit and pull out the components for reuse.
Just thinking back to different points in my life, I used to live in a small apartment with my wife and a roommate. I wouldn’t have wanted to keep acetone around there, anytime I used it it would have stunk up the whole place. And I didn’t really want to do any soldering there, our ventilation wasn’t great and our smoke detectors were on a hair trigger, and I lived in fear of losing my security deposit from dropping a stray blob of solder burning a hole in the carpet or something. PVA printing is pretty innocuous as far as fumes go, and I wouldn’t have needed much equipment beyond an electric kettle (other than a printer) to play around with this there.
Really though, I see this being most useful for a situation where you want to prototype a few iterations that you’ll want to field test. I wouldn’t want to etch a dozen prototype boards that can’t really be reused and have to desolder to recover all the components, but I could see printing out a dozen prototypes this way and refusing the liquid metal and such.
I’d probably still want my final board to be etched, but this gives you a good way to workshop a bunch of revisions without throwing out a bunch of etched boards.
Also I don’t know how the cost of PVA filament stacks up against copper clad boards, but just kind of guestimating from my limited knowledge of 3d printing, it seems like the cost of boards vs filament is probably about the same or maybe even better. Sure, there’s the startup costs of getting the metal and a printer, but I feel like a lot of the people who would want to do this probably already have a printer or were looking for an excuse to get one anyway, and the metal is reusable.
This is not just one of those ivory tower papers with their actual applications far away in time and eventually ending up in some obscure industrial process never heard of again in lay circles; this could have an immediate impact on the maker culture and makerspaces right now and in the near future. The preprint describes the process in a very understandable, digestible manner and provides actual implementation examples, as well as detailed recipes for all of the compounds. If you are even remotely interested in the subject matter, I’d recommend you to try it out for yourself. The “ingredients” are all easily obtainable and handleable. Yes, gallium and indium might be a bit expensive, but it is worth it imo. They literally used consumer kitchen equipment for some of the steps, to demonstrate how this is feasible for tinkerers, makerspaces and prototypes. No expensive machinery required (except for an FFF 3d-printer, of course).
I skimmed through the paper, and I agree that it looks pretty damn digestible for the average tinkerer to understand and implement themselves if they so choose
But just kind of a quick summary for people who still won’t read the article
You basically 3d print a circuit board out of PVA (which is basically the same material as regular white elmers school glue, so non toxic and water soluble) with hollow channels instead of circuit traces.
Then you fill those hollow tubes with the gallium/indium mix, which has a very low melting point, like “glass of warm water” low.
Insert any components you need and secure them into place with a drop of glue, and BOOM you’ve got a circuit board.
And when you’re done, just dump it in a glass of water. The PVA dissolves and you can fish out the metal to reuse in a different project.
Like you said, the only “specialized” equipment you need is a 3d printer that can handle PVA filament.
Not necessarily something that’s going to be useful for any industrial production applications, but this could be huge for hobbyists and even prototyping for businesses. Most traditional methods for making a PCB call for some kind of nasty chemicals and they’re not really reusable, especially not for the home-gamer, this could make for a nice step-up for the people who don’t want to deal with this and want something a little more polished than a breadboard or a mess of soldered wires
Tbh toner transfer method is a lot easier and requires less materials and cheaper.
It’s arguably easier, but I think it depends on your use case.
Etching usually requires a couple chemicals that not everyone has the space to store properly, like if they live in a small apartment and have kids, and even if you go with safer alternatives like vinegar over ferric chloride, after use the etching solution should still be considered poisonous and needs to be handled and disposed of with some care.
Also worth considering is that this method is solder-free, so in addition to not needing to solder anything, it’s easier to recover components, no desoldering needed, just warm it up a bit and pull out the components for reuse.
Just thinking back to different points in my life, I used to live in a small apartment with my wife and a roommate. I wouldn’t have wanted to keep acetone around there, anytime I used it it would have stunk up the whole place. And I didn’t really want to do any soldering there, our ventilation wasn’t great and our smoke detectors were on a hair trigger, and I lived in fear of losing my security deposit from dropping a stray blob of solder burning a hole in the carpet or something. PVA printing is pretty innocuous as far as fumes go, and I wouldn’t have needed much equipment beyond an electric kettle (other than a printer) to play around with this there.
Really though, I see this being most useful for a situation where you want to prototype a few iterations that you’ll want to field test. I wouldn’t want to etch a dozen prototype boards that can’t really be reused and have to desolder to recover all the components, but I could see printing out a dozen prototypes this way and refusing the liquid metal and such.
I’d probably still want my final board to be etched, but this gives you a good way to workshop a bunch of revisions without throwing out a bunch of etched boards.
Also I don’t know how the cost of PVA filament stacks up against copper clad boards, but just kind of guestimating from my limited knowledge of 3d printing, it seems like the cost of boards vs filament is probably about the same or maybe even better. Sure, there’s the startup costs of getting the metal and a printer, but I feel like a lot of the people who would want to do this probably already have a printer or were looking for an excuse to get one anyway, and the metal is reusable.