Yesterday, while the world was fixated on Apple’s WWDC kickoff, Boston-based 3D printing startup Formlabs quietly unveiled a revolutionary new laser sintering printer called the Fuse 1 — and it’s kind of a big deal.
Truth be told, you’re probably never going to use it. It’s about the size of a mini-fridge, it’s designed for professionals, and it costs $10,000 dollars. But even if you never see one, the Fuse 1 has some huge implications for the future of 3D printing. Here’s why you should be excited about it.
The slow march of 3D printing progress
Back when 3D printing was just beginning to make its way into the mainstream, the only printers available to consumers relied on more or less the same technique to create parts — a process known as filament deposition modeling, or FDM. It’s the type of 3D printing you’ve probably seen before: A printer feeds a strand of plastic filament through a hot nozzle, then carefully deposits the molten goo onto a build plate, layer by layer, to create a 3D object. It’s what most people envision when they hear the phrase “3D printing.”
Most 3D printers available to consumers relied on more or less the same technique to create parts — a process known as filament deposition modeling, or FDM.
Thing is, FDM is just one small chunk on the broader spectrum of 3D printing technologies. There are tons of other additive manufacturing techniques out there, like stereolithography, polyjet, and laser sintering — all of which are vastly superior to FDM printers in terms of print quality. But unfortunately, despite the fact that 3D printing has become increasingly mainstream over the past few years, most of these awesome additive manufacturing techniques still aren’t available at a consumer level. The machines are just so ridiculously expensive that you’ll only ever find them in industrial manufacturing facilities.
But that’s starting to change. As 3D printing has entered the consumer space and become more competitive, companies like Formlabs have started to figure out ways to reengineer those high-end industrial technologies and make them more affordable and accessible.
The resin revolution
It all started with stereolithography (SLA). This technique — in which a UV laser is used to ‘grow’ high resolution objects out of a puddle of light-reactive resin — has been around for decades, but up until a few years ago, SLA machines were too expensive for individual consumers to use. But then, in 2012, Formlabs unveiled the Form 1, the world’s first consumer-level SLA printer, in a Kickstarter campaign.
Form Labs
Form Labs
Form Labs
Form Labs
Almost instantly, this sparked a revolution. Shortly after Formlabs wrapped up its hugely successful crowdfunding campaign, other startups followed suit and began releasing SLA printers of their own. Fast forward five years, and now they’re more common and affordable than ever before. Whereas SLA machines used to cost upwards of $100,000, you can get your hands on one for as little as $1,200 online. Of course, they’re still not quite as cheap or ubiquitous as FDM printers, but SLA machines have steadily become more popular, affordable, and accessible in a relatively short amount of time. And all it took was one company hitting it big and proving that better 3D printing tech has mass appeal.
Bold new territory
Now, with the Fuse 1, Formlabs might just do the same thing for selective laser sintering technology — and that’s a pretty exciting prospect.
SLS printing works very differently than FDM and SLA. To create an object, the machine flashes a laser over a bed of superfine powder, fusing the particles together to form a thin, solidified layer. The machine then sweeps more powder over the top of that layer, and repeats the process until the print is complete.
SLS printers can make objects that are nearly as good as parts created through injection molding, milling, and other traditional manufacturing processes.
Printing objects in this fashion has a number of distinct advantages. It works with a broad range of materials, can print large overhangs and spans without using support material, and the parts it produces are extremely high quality. Nylon parts printed with the Fuse 1 are actually durable enough and detailed enough to be sold as end-use parts.
That’s what makes this technology so special. Whereas FDM and SLA printers are good for prototyping, SLS printers can make objects that are nearly as good as parts created through injection molding, milling, and other traditional manufacturing processes. In other words, they can make high-quality stuff that’s ready to use straight out of the printer. Need a new bike pedal, hair-dryer, or smartphone case? Just print one and save yourself a trip to the store.
That’s the road we’re headed down, but we’re not quite there yet. This kind of printing tech still isn’t cheap. Regardless of the fact that the Fuse 1 is 20 times cheaper than most industrial SLS printers, it still costs $10,000 — which puts it out of reach for most of us. But it’s important to remember that this is just the beginning.
[youtube https://www.youtube.com/watch?v=BALUeGV57dE?feature=oembed&w=100&h=100]
If SLS printers can come down from $200K to just $10K, it stands to reason that, in another 5 or 10 years, the technology might just trickle down to an attainable level for non-commercial users.
This kind of democratization is exactly what 3D printing needs in order to become ubiquitous. If we’re ever going to realize a future in which 3D printers are a household staple akin to dishwashers and microwaves, where we can print high-quality products on-demand instead of buying them at a store, then driving down the cost of new printing technologies is the first step.