Plastics: Photopolymers For 3D Printing And Beyond | Hackaday

2022-06-01 02:22:18 By : Ms. Ellen Wang

Chances are good that if you’ve done any 3D printing, it was of the standard fused deposition modeling variety. FDM is pretty simple stuff — get a bit of plastic filament hot enough, squeeze the molten goo out of a fine nozzle, control the position of the nozzle more or less precisely in three dimensions, and repeat for hours on end until your print is done. To the outsider it looks like magic, but to us it’s just another Saturday afternoon.

Resin printing is another thing altogether, and a lot closer to magic for most of us. The current crop of stereolithography printers just have a high-resolution LCD display between a UV light source and a build tank with a transparent bottom. Prints are built up layer by layer by flashing UV light patterns into the tank as a build plate slowly lifts it up from the resin, like some creature emerging from the primordial goo.

Of course it’s all just science, but if there is any magic in SLA printing, surely it’s in the resins used for it. Their nondescript brown plastic bottles and information-poor labels give little clue as to their ingredients, although their hydrocarbon reek and viscous, sticky texture are pretty good clues. Let’s take a look inside the resin bottle and find out what it is that makes the magic of SLA happen.

A good basis for understanding the chemical processes behind stereolithography resins is the polymerization of methylmethacrylate (MMA) into polymethylmethacrylate, also known as PMMA or simply acrylic. While formulations for SLA resins vary, many of them are based on acrylates, so the chemistry here is directly applicable to a lot of resins, as are the general principles.

The polymerization of methylmethacrylate is what’s known as a free-radical reaction. It works because MMA has a double bond between two of its carbon atoms, as well as a nearby ester group — the group with two oxygens, one of them in a double bond. The electronic structure of these two groups makes the double-bonded carbon susceptible to reduction, which is the gain of an electron.

Under normal circumstances, MMA monomers don’t react with each other because there are no free electrons floating around to reduce the carbon-carbon double bond. To get MMA to polymerize, an initiator — in this case, benzoyl peroxide — needs to be added to the mix. An initiator is a chemical compound that provides unpaired electrons, or free radicals. Once radicals are present, they bind to the carbon by reducing the double bond. The product of this first reaction will have its own unpaired electron, which can then go on and reduce the double bond in another MMA monomer, and so on. The production of a free radical product after initiation is the key to free-radical polymerization.

So it stands to reason that a bottle of SLA resin will contain monomers of MMA and an initiator of some sort. But what keeps the monomers from just polymerizing in the bottle? If the initiator was something like the benzoyl peroxide used in the example above, that’s exactly what would happen. So to be useful for SLA work, the resin mix has to contain an initiator that can remain inert in the mix until it’s needed.

This is where photoinitiators come into play. Where an initiator like benzoyl peroxide will readily decompose into free radicals with the application of a little heat, photoinitiators need a little more coaxing. Hundreds of different photoinitiators have been developed by chemical companies over the years, each tailored to the specific set of monomers to be polymerized as well as to industrial needs, such as the efficiency of free radical formation, toxicity, and even odors imparted on the finished product. But they all share the common trait of being inactive until they are exposed to light of the correct wavelength.

A good example of a photoinitiator is 2,2-dimethoxy-2-phenylacetophenone, mercifully abbreviated to DMPA and sold under the trade name IRGACURE 651 by Ciba. The compound has two benzene rings joined by a two-carbon chain. One of the carbons in the linker section is double-bonded to oxygen, forming a ketone functional group. When photons of the right wavelength — DMPA has absorption peaks are 250 nm and 340 nm — hit the ketone group, it becomes excited to the point where an electron is knocked off. Through a series of intermediate steps in which the spare electron is shuffled around to different atoms, the linker section of the molecule breaks in a process called α-cleavage. This leaves behind a stable species — methylbenzoate — plus two free radicals that can initiate polymerization.

The mechanism of photopolymerization begs a question: how does the UV light in an SLA printer not just polymerize the whole tank of resin at once? It seems like that would be a problem, since polymerization is basically a chain reaction once initiated. But there are practical limits to the reaction, for both chemical and physical reasons.

Chemically, the amount of initiator in the resin is typically pretty low — just a few percent of the mix. So there aren’t many places to start the polymerization reaction. Polymerization reactions also tend to undergo chain termination spontaneously, either by having two growing radical chains bind together, or by reduction of a radical chain by contaminants such as oxygen. Some resins even have specific inhibitor compounds added to limit the speed of polymerization. Either way, spontaneous termination keeps the tanks from becoming a solid brick of plastic.

There are also physical reasons for photopolymerization not running wild through the build tank. The UV light coming from the LCD display at the bottom of the tank isn’t particularly strong, and tends to get absorbed by the resin before traveling very far. This is why SLA resins tend not to be heavily pigmented, and why any pigments that are added to the resin have to be carefully selected to not absorb UV light. It’s also why SLA prints need an additional cleaning and curing step after printing; the polymerization that occurs in the tank is incomplete, with unreacted resin remaining inside the print. Bathing the print in high-intensity UV light completes the process and hardens the print.

Between initiators, monomers, pigments, and possibly inhibitors, SLA resins already seem like a witch’s brew of chemicals. But we’re not done yet. Resins rarely just use monomers, instead using a special blend of monomers and oligomers — short chains of pre-polymerized monomers. Adding oligomers into the resin tends to speed up polymerization by giving the growing chains a head start. It also tends to increase the viscosity of the resin, so that it’s not runny and doesn’t slosh around in the build tank and get bubbles.

Another common addition to SLA resins is a cross-linker. Cross-linkers are compounds that can form connections between two or more growing polymer chains. Cross-linking tends to make the polymer chain into more of a matrix structure, lending strength and rigidity to the final product. Cross-linking can also change the properties of the material, and even allows for copolymerization of different types of monomers, like adding urethane to acrylates to add toughness and flexibility.

Some SLA resins also contain filler materials. Fillers are pretty common in plastics — a lot of Schedule 40 PVC pipe contains powdered limestone, for instance. In SLA resins, fillers are added to bulk up the plastic by filling the spaces between the cross-linked strands of polymers. A lot of new “eco-friendly” SLA resins are coming to claiming to be made from soybeans, and while that’s true — at least for some resins — there’s still a lot of material in the resin that’s clearly not from soybeans. And the soybean oil that’s in there is really just a filler — without the acrylate monomers and crosslinkers listed or the photoinitiator, the resin would be pretty useless.

While we’ve concentrated mainly on SLA printing resins here, that’s far from the only application for photopolymers. If you’ve had a tooth filled any time in the last three decades or so, chances are good that your dentist used a photopolymer containing methacrylate monomers and cured with a fiber optic wand that emits UV light. Printed circuit board manufacturers make wide use of photopolymers, both in the photoresist coatings that are used to etch the boards, and in the solder mask that’s applied to the board. Photopolymers are also used for masking during the photolithographic processes involved in manufacturing integrated circuits.

The other question is, I wonder how well uv resin works when poured into a mould, perhaps with some sort of reflective inner surface, to cast parts instead of printing them or as part of a post printing process.

that works, but only for small parts. People usually use transparent silicone for the molds and then use UV light from the outside. It’s often used for “Resin art” or “Resin Rings”.

I’ve never seen it done, what are the advantages compared to simpler and cheaper two-part resins such as polyurethane or epoxy? When casting a solid part at once like this, isn’t there an issue with the outside curing faster and preventing the UV light from curing the inside?

Contrary to what the article says, I’ve read that SLA resins include UV-blocking compounds that prevent the UV light from leaking too much outside the exposed area, while not having a significant impact in the 50µm-100µm depth of a single layer.

Maybe having a strong enough UV light would work if the part is exposed long enough, since this is basically what post-curing does, although in this case the curing reaction is already significantly more advanced at that stage.

Yea I think they don’t use UV-printing Resin but “normal” UV-curing resin. The only advantage I see is that you can work faster. Put some in a mold, cure it, add objects… flowers or what ever, add resin, cure done. I personally also prefer two part resins but to each their own ;)

Yes, faster, and better for some applications. For instance, apparently custom key caps (with stuff embedded in them) are much easier with (“normal”) UV resin, and can come out nearly crystal clear. The multi-pour process may be a factor in why UV resin is preferred here.

Indeed, most acrylic resins like LCD glue or nail art gel adhesives do not contain a sunscreen chemistry. Note, the white pigment in many printer resins is usually Titanium dioxide, and thus only allows UV to penetrate a minimal finite distance into the resin.

With normal 390nm/405nm UV sensitive clear resins, a violet laser pointer can cure several cm deep without too much beam dispersion (note a 455nm/blue laser will not work). However, there is a minimum exposure intensity level threshold needed to kick off the curing process, and small LEDs often simply can’t reach the thresholds needed.

As a side note, most UV resins have a rated shelf life as the dormant chemistry is not viable forever (often specified for 1 to 3 years).

The resin meant for 3d priting has uv blocker in it, as to not allow uv to go past the current layer and make the cured layers overexposed, so, once poured on a mould, it would harden as a shell with liquid inside.

There are other types of uv resin out in the market, but i think they may go opaque to uv once cured past a certain thickness

The trouble that I’ve had with resin printing is that it’s brittle, not very tough. Judging by this brief article that may be a limitation that won’t be overcome due to chemistry constraints.

Don’t get me wrong, I’ve had limited success with siryatech Blu and Build resins, but as far as something that will stretch to strings instead of snapping, maybe I’ll have to go back to the cnc hot glue gun (fdm) for some stuff…

As a R&D chemist and process engineer for radiation curing polymers, I am quite impressed of the high quality of the article.

Not being much of a hacker I feel my time finally having come to offer some exposition :)

Regarding the content of the article: – The crosslinkers are like a double-edged sword. They increase mechanical strength but at the cost of increased shrinkage/warpage. And the wrong selection of crosslinkers can make the cured resin shatter like glass, on the slightest impact, or even during curing from the shrinkage stress alone. – The fillers are even more so, as they reduce shrinking (they mainly do nothing at all) but they range from substances that bond with the resin and form extremely sturdy products, over some mid-ranged things down to pure fillers that are only there to add cheap volume and thus reduce manufacturing cost. Talc is one such example, but oils are about the worst example for this, as they are not only remaining unbonded, they can leave the cured resin. They can be extracted from the polymer during cleaning of the print, resulting in stress-cracking and brittleness. But even worse is the fact that oils dissolve unreacted resin and photoinitiator molecules that are unavoidably present (typically between 1 and 5%) and upon skin contact they migrate easily, taking the dissolved substances with them, which can cause severe allergic reactions.

@ Joel: The shelf life, to my experience, is more of a number the R&D and the Sales department are negotiating between themselves to ward off claims and to increase distributor stock turnover. A good resin in a good bottle can easily last 10 to 20 years. In most cases the bottles are not 100% light-tight but only 99.99%. Over time this leads to degradation of the resin quality. Not to mention some chinese bottles where the black pigment in the plastic is something they scraped out of the plant’s central heating and gives the resin a brownish tint that worsens over time.

@ MendesL: If a thick layer of UV resin becomes opaque during curing, the reason is mostly stress due to reaction heat building up inside. The effect can in most cases be avoided by reducing the curing light power and/or applying the resin in layers. The UV-transparency generally does not change much during curing, but the remaining photoinitiator still works as a kind of UV-blocker to the inner layers of resin. There are however, special photoinitiators that (when applied correctly) decompose completely, so the cured outer layers become UV-transparent and the curing can continue indefinitely.

@ Mbc: I can assure you, there is no such limitation. Some months ago I developed a resin composition for a special project, which was so strong, the most humongous mechanic we have in our company could not break a disc of 1,5x40mm (0.06″x1.6″). The disc was however, slightly bent. Together with the mechanic’s ego. :)

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