Find out more about 3D Printing and how this emerging technology will change our world. Its applications range from medical devices to art, and is no longer limited to prototyping. As information is transferred seamlessly, the global web community is steering manufacturing towards a massive revolution, redefining how we acquire and create physical objects.
I had the opportunity last week to spend a day at the RAPID Conference in Atlanta. The annual meeting of Prototyping Solutions and 3D Imaging Providers is organized by the Society of Manufacturing Engineers.
The mix of high-end printers and consumer products makes for an interesting portrait of the 3D printing industry. The opportunities are endless.
Here are some highlights I was able to capture on my phone.
Using Multi-Material Technology, the shoe provides a flexible inner
layer (black), while the outer shell (white) is hardened.
Created in a single build using dissolving support material
How many materials can you count?
MCOR’s Matrix 300 printer uses standard copy paper to build its models. Sheets are stacked and cut with a tiny blade, layer by layer. Adhesive is applied between layers.
Also using the Matrix 300, a finishing technique is used here to create glossy surface.
Interchangeable mouths create scene adaptations for filming
Some booths printed out a basket of their unique puzzle pieces. Attendees of the conference were able to collect and complete the puzzle.
3D printing has become all the rage in the tech world because of its potential to create custom parts on demand. This has opened the door for hobbyists to make toys, amazing art, and other types of objects important to every day life.
Ever considered a day in the life of a criminal? Hackers, thieves, scammers and killers are the types of people who are in need of more creative ways to achieve trickery and deception. As 3D printing allows everyone to make the things they need on demand, more and more instances of misuse have turned up.
Just this morning, a Google search of 3D printing provided a news article about thieves who designed and built their own apparatus to be placed over an ATM card slot. A similar device in Manhattan obtained the information of over 1500 customers, amounting to almost $300,000 worth of fraudulent charges. The plastic housing was created in CAD software then 3D printed with what seems to be Stereolithography which uses resin. The design was clever enough to incorporate a spycam to see the pin numbers of the cards they were stealing, as well as housing the magnetic card reader. Were a 3D printer not readily available, these thieves would have very few options to achieve a similar outcome. To see photos and the full breakdown of the device, here’s the original article.
Another example: Browsing through Thingiverse, the 3D design sharing site created by Makerbot Industries, I was polled as to whether 3D printable weapons should be allowed on the site. Should people of all ages, anywhere in the world have the ability to create, instantly and without accountability, an object that could cause damage to or kill another person? I say no, but then where does the freedom to create come in?
Perhaps the biggest threat to come is the dissolution of branded products. Designers, engineers, marketers and manufacturers all work endlessly to create a product that evokes a certain brand or feel. There are various methods that would allow me to scan or replicate action figures, cell phone housings, kitchen devices, consumer electronics, etc. Not only that, I should hope that this will allow everyday hobbyists to make even better objects using less resources. Either one of these methods are a huge threat to corporations and brands and protective legislation should seriously be considered now by lawmakers. But how do you protect brands while simultaneously opening the floor for innovations in personal manufacturing?
Here’s a great example. Star Wars is a trademarked brand which manufactures and sells toys from probably the most popular Sci-fi series ever. A quick search on Thingiverse shows there are models of X wings and busts of different characters and even a lightsaber handle, all designed for home 3D printers. As long as these designs and copies are only meant for home use and never sold there should be no objection. However, commercial profit being so easy has a very serious appeal for illegal copiers. Surely the toy and model manufacturers aren’t happy.
Public Knowledge, an organization dedicated to promoting an open and safe internet, released a white paper concerning the intellectual property issues brought about by the digitization of physical objects. Follow the link to read more.
3D printing technology is becoming rapidly less expensive and thus more widespread throughout society. The materials and resolution will only get better. These considerations will only make potential misuse more common. So what do we do?
Months back when rapid prototyping technologies were still new to me, I read this post from now Origo co-founder, Joris Peels, announcing his farewell to i.materialise, the wonderful international 3D printing service. He has now ventured out to advance the technology and open it to everyone. He has been kind enough to share his experience at i.materialise with me and how that brought him to create a project like Origo and what it is all about. I would like to thank him for all of his patience and time. I will certainly be keeping an eye on what he does in the coming years.
3DPP: You had your stints at larger 3D printer services and now you have your own project in the works. What are your passions and goals for 3D printing?
Joris: I’m obsessed with 3D printing and I am doing everything I can to let anyone make anything. I love the new i.materialise site and the great and inventive submissions for the Titanium Machine Man Challenge. I also am smitten with designers such as Hugo Arcier and think the 3D printed paperclip the infinite clip is just about the best reinvention.
3DPP: The internet is a great place to learn about 3D printing but many people I speak to have never heard of 3D Printing. How is that?
Joris: 3D printing is a 20 year old industry that until only a few years ago only catered to business-to-business customers. Only a few designers and product development people in any one company would have any contact with it, and their work was usually secret. The industry has also been hampered by several name changes and terms being used interchangeably such as rapid prototyping, additive manufacturing, free form manufacturing etc.
3DPP: What was your experience at Materialise? I know it has many divisions and international offices. How did it start out?
Joris: I joined them after having worked at Shapeways. Materialise is over 20 years old and was started by its CEO Fried Vancrean. Materialise is the market leader in 3D printing software. Most service bureaus and engineers working in 3D printing use its Magics software to check and repair files. It also develops a lot of medical tools such as software that helps surgeons plan surgeries virtually and produce patient-specific surgical guides. It is also one of the world’s largest service bureaus and has its own Mammoth 3D printers.
3DPP: Materialise claims the most 3D printers under one roof. What are some machines and manufacturing techniques used? What are some of the more impressive materials that are supported?
Joris: Materialise mainly uses Stereolithography, Fused Deposition Modeling and Selective Laser Sintering and also has Zcorp, Objet and several other technologies. There are hundreds of 3D printing materials. I really like Ultem which can be used on-board commercial aircraft. Because it is certified and acts as a fire retardant it is actually a functional material. Functional materials, rather than the previous materials that were built to fail or built mainly to look pretty, are the future of the industry.
3DPP: The i.materialise site opens the technology to anyone with a creative design, but not everyone can use CAD software. So how is spreading the technology a function of software learning curves?
Joris: To really know how to 3D model you have to spend two years or so with Rhino or 3DsMax. But, in a shorter time frame you can master Sketchup. This is more limited but much easier to use. In my mind the easiest way for the average person to build is using 3Dtin. 3Dtin lets anyone easily build up an object out of bricks. It works in the web browser and is so easy that we had ten-year-olds making a lot of 3D printed things with it with minimal instruction. 3Dtin is limited, but intelligently limited. In my mind it is the paintbrush for a 3D printed future. Only around 30 million people can 3D model. 3dtin makes 3D printing available to the 2 billion internet users worldwide.
3DPP: This brings us to Origo, your new project. A 3D printer for kids. Really? When can I buy one?
Joris: Yes. We believe that in the long run kids will be the most successful users of the device. Adults like the idea of 3D printers and there are a lot of very creative adults out there. The vast majority though are not makers yet. For them use 3D printing would consistently require a change in behavior. Kids imagine and make things all the time and are unrestricted in their creativity. They just see Origo as a tool.It’s neither a toy that makes toys nor a learning tool. It’s a machine that makes whatever it is the kid wants to make. It’s a pencil that lets kids create in plastic. It will be fun of course, and kids will learn a lot about designing things, manufacturing and engineering. But, primarily it’s just a tool for expression.
It is to be released in 18 months, we hope. Someone needs to give us a lot of money so we can build this.
3DPP: How does 3Dtin help you get kids into the market?
Joris:3Dtin is very easy, you simply place blocks and they build up your model. It also has advanced features such as smoothing, templates and advances shapes.Because it is block-based kids can learn by counting blocks. They can know that if they want something to fit in their pencil case it has to be 15 by 20 blocks. They know that if it is to survive this pencil case it will need to be 3 blocks thick. They tried 2 blocks last time and this didn’t work. By thinking in terms of these blocks and using them to engineer new creations they will learn about 3D printing while doing it.
3DPP:So what about calibration and maintenance? Setting up some of the DIY printers out there is usually more complicated than getting it to print. What do you have in mind for Origo?
Joris: Yes, they can be tricky. We hope to reduce all of this through our design. We hope to minimize the role parents will play but we cannot be completely sure we will be able to do this right now.
3DPP: As someone knowledgeable about the 3D printing world, give us some insight into what you see as the future. Do you think there will ever be storefront printshops? Could this be an education tool for those less familiar with the technology or CAD?
Joris: Yes, to me it is a matter of time before Kinko’s or someone similar steps into this market. It would be very easy to do. FabLabs and Hackerspaces are already “storefront creation shops” with the added benefit of being a place to learn and socialize. This is a very powerful idea that combines the “third place” with access to technology.
3DPP: From a business perspective how do you imagine 3D printing will be be integrated into future markets? What would you like to see happen?
Joris: I believe that 3D printing will be a 90 billion dollar market by the end of the decade. I believe that for the 1% of things we care most about we will turn to 3D printing to get exactly what we want. Furthermore, some companies will integrate 3D printing into their supply chain in order to produce items to order and enter more specific markets. Certain people will use 3D printers in the home to make what they want and others will turn to services and designers to make things for them. All in all, there will be an unbelievable level of competition, and product development will accelerate across the board. I don’t believe that everyone will have a 3D printer in their homes. Even if we could make everything with 3D printing at home, we wouldn’t. We make the things we care about with 3D printing. Sometimes we can’t be bothered and we’d go to a mass produced product. Sometimes we’d like to outsource our design decisions and follow a brand. For many things we’d simply combine a 3D printed element with a mass produced product that is superior in functionality but inferior in its fit. I do believe, however, that 3D printing will help erode all barriers to entry in manufacturing and design. It will fundamentally alter the relationships we have with our things and change the way everything is made. Even in mass-produced products the use of 3D printing in its design will accelerate and change the way these things are made. 3D printing is, in my opinion, the third industrial revolution and will gradually turn back the tide of the wasteful mass manufacturing paradigm we are now in. By letting you make a thing exactly as you’d want that thing to be and by letting that thing perfectly fit you it will expose the mass manufactured crap that surrounds us as inferior.
I was able to catch the last day of the “Modern by Design” exhibit at The High Museum in Atlanta and it displayed plenty of works built from digital models. The entrance to the exhibit held a large experimental project created by the Joris Laarman lab in Amsterdam.
Joris Laarman, "Digital Matter"
Though not considered 3D printing or Rapid Prototyping, this mechanical arm operates via commands. Instead of being told to melt or cure a material in precise layers, the head of this arm picks up individual squares and melds them into this solid table. Created as pixels in digital space, the table is made of small metallic bricks.
Table made from "Digital Matter" project by Joris Laarman Lab
Joris Laarman, "Digital Matter"
Joris Laarman, "Digital Matter"
I knew the exhibit had some 3D printed models but I did not anticipate seeing a totally experimental and ornate display of additive manufacturing. Though seemingly not an efficient use of mechanics I see a few areas to be explored based on the key elements of this project. While 3D printing with even a high grade machine the material is fed at a constant rate and must always be formed in paper thin layers. The technique used here in “Digital Matter” uses blocks, and those tiny blocks can form larger blocks or shapes. Theoretically, the large arm in the first picture could have a bunch of smaller builders on a nearby platform, simultaneously creating forms that will be added to the final model by the main arm. If perfected this could cut down on build times. I think as 3DP technology progresses we will start to see multiple extruders or print heads that move along different axes but communicate with each other. It is a matter of time before the software is available to support such a machine.
Another variation might be an extruder that is designed to build only one shape or section of that shape. If it can build a sturdy structure like a sphere or egg, and build that shape onto itself, such a machine complex and bumpy surfaces in larger scale.
The other floors of the exhibit were mixed with early modern designs such as Eames chairs and industrial parts. The 3D printed parts were pretty much limited to different types of chairs. I have a tricky relationship with chairs in the design world as you can only experience them visually, mostly through exhibits and design criticism. The chair may have an unusual and appealing form but there is never a way to really know how well it was designed, and one is left approximating what it might be like based on experience sitting in chairs. Since a chair’s function is to be sat on, understandably, more effort is put into the form with not much room to improve in the world of sitting.
Collapsible Stool by Patrick Jouin
(Collapsed) Stool By Patrick Jouin
By FRONT Design, Sweden
The stool was printed using selective laser sintering which allows for moving parts. It’s hard to see how it closes but I think the circle in the center is pushed down. The second chair was built with a polymer and then covered in lacquer for the smooth reflective surface. Creating a chair these non-symetrical features is unique to 3D printing over some traditional methods. To build and cut in wood, textiles or even metal uses tools that are designed for accuracy and geometry. Creating fluid, organic shapes like this chair would require more time to experiment with cutting techniques and materials, and even more to actually build it. Having the freedom to create the model in digital space using an array of creative software packages is only made better by not having to build ten of them by hand.
I look forward to the future of digital manufacturing in America as it will bring more manufacturing jobs to produce items at home and locally. When everyday people are exposed to the possibilities that are opened by the technology, their creative and useful ideas will seem less crazy and more feasible to build.
There are many printers popping up in the desktop market and now is the time to see what they are all about. I have taken some time to grab the specs on the popular machines out there. I understand that there may be others, but I have included those with features I want to highlight or just what I know exists.
BFB 3000 – by Bits from Bytes, UK (owned by 3D Systems)
Build size (x-y-z):
Single extruder installed 275 mm x 275 mm x 210 mm,
Three extruders installed 185 mm x 275 mm x 210 mm
Overall weight: 79lbs to 84lbs
Resolution: .125mm layers
Software interface: Axon 2 which is unique to BFB. This interface allows you to scale, rotate and review your item before print if connected through USB. Will also print directly through SD card reader.
Tested in zero gravity: check
Price: $3250 for single extruder, $4065 for triple extruder
Here is an older video of the BFB, before the company was aquired by 3D systems. I chose this one because it highlights all the great features, most notably the translucent material. Also the build specs at the end are helpful. An important factor of this machine which can be seen in the video is the quality and robustness of the parts. Many of the housings and rails are machined metal making for a sturdier base.
Overall Size: 300 x 300 x 410 mm (12″ W x 12″ D x 16″ H)
Build size (x-y-z): 96 x 108 mm x 115 mm
Resolution: .125mm layers, 0.4 mm extruder nozzle
Software interface: Replicator G which allows you to manipulate, scale and create build code from STL format. Via USB or SD card reader. Optional LCD display.
Tested in zero gravity: check
Price: $1299 without assembly, $2500 preassembled
Considered a hot shot of the desktop FDMers, Makerbot is a fairly new open source project based on Reprap. Although you could probably build a Reprap mendel for less than half that of the Thing-O-Matic, I find no major difference between the two other than how they are marketed. Reprap is a research project funded by grants. Makerbot is a company funded by selling machines. But with Makerbot comes a vibrant community of makers, hackers, and builders, freely showcasing their prints via Thingiverse. Because files can be downloaded as STL or in gcode, they are printable to all reprap based printers.
Software Interface: Supporting STL and the native UP3, the Up! has a specially designed interface that allows for the usual rotating, scaling and moving. Some great features include automatic support material for rounded bottoms or overhang and one touch printing.
Resplution: 0.2 mm nozzle
Operating Cost: As little as $.02 per cubed cm
Cost: $2960 for a fully assembled machine
This one of the newest machines in the market and will likely give Makerbot a run. This promo video is well made and highlights the clever design. The build area is completely open and the hardware and motors are mostly hidden. The fact that it weighs 11 pounds really shows the thinking that went into making a printer that will really sit on a desktop. No mention of build speed but surely no chance against the hot new contender.
Software Interface: Libre CAD software, supports STL files via USB. Software available for Windows, Mac and Linux operating systems.
Resolution: 0.4 mm nozzle. Website specs say it has stepper positioning to be less than .05mm
Print Speed: The fastest of anything yet, up to 150mm/s
They don’t really have a promotional video it seems, so I snagged this user submission. The speeds seem to be set to moderate but the mechanized movements are much more fluid. This is achieved because the extruder slides along center based bearings as opposed to threading that is active on the outside frame. From the videos I have seen, when tested at top speed, the print resolution is very poor, which is to be expected.
What I find amazing about the machines mentioned so far is that they are all competing, yet utilizing the exact same technology. Being based on RepRap limits the hardware and materials for a printer that can be sold in quantities. They all print in PLA or ABS, they all have the same range of print resolution and build size, and they all can really only appeal to the tech savvy. The UP! says it requires no maintenance and this seems promising but I think this is only because the hardware is not exposed. Even the pre-assembled Makerbot requires calibration and setup.
This is really the beginning of the desktop fabrication era, and I am always excited to see the work coming off these machines. But I have yet to see a machine with a minimal learning curve to be used by all. A major area which needs improvement is interface design and usability, and breakthroughs in this area are very near. In terms of materials and build techniques, it may just be a matter of researching what works (two of the projects mentioned below are steps in the right direction). When we get into learning about the high end machines, we will see that each company really has patents on a particular build method. . This is what I hope to see emerge in the desktop market, but some people will need to be weaned off RepRap, as amazing as it is.
I have yet to decide which printer to add to my wish list, because the various features are useful in different situations. If I were looking to achieve detailed and complex prototypes I would choose the BFB 3000 as the multiple extruder heads create more options. If I were looking for a usable machine that showcases the amazing ability of desktop manufacturing I would choose the UP!. It was clearly designed with beginners in mind and the open build platform lets you see every aspect of the process, which is an important factor in attracting new users.
Other Notable Machines:
Basic machine with a build size of 305mm x 460mm x 280
Homemade High Resolution Printer:
This is a personal project still being developed. The build technique is quite different from every other machine mentioned here. It is not fused deposition modeling but a resin curing system. The object is pulled out of a small reservoir, being cured by focused light as it emerges. The only way to really understand it is to watch.
The 3D printing world has seen many innovations in the past few weeks, highlighting the range of applications. Probably the most publicized piece of news is the successful flights of an unmanned aerial vehicle, or UAV, that can be 3D printed for snap fit assembly. It reaches speeds over 100mph and is nearly silent. Not only does this signal to the amazing possibilities to the commercial aircraft industry, but military and rescue teams could easily survey an area by creating one on demand instead of waiting for supplies. Or what if a rover on another planet could print one out to map the area?
This too will soon be possible as a new company called Made in Space has successfully tested a number of printers in near zero gravity. Most likely it will be used by astronauts and the International Space Station to print out tools and replacement parts instead of waiting for the mail to come.
From Made in Space
What I find interesting about this zero gravity test is the type of printer that they used. A partner in this project is 3D Systems, an industry giant that produces various printers and services. The BFB 3000 is their entry level machine and the one they decided to highlight of several printers on this flight. I believe they created a wrench out of plastic (no moving parts this time). The success of their most basic machine gives only a small idea of what a more powerful printer could produce. It’s easy to print a basic part of that little machine but what about more complex geometries. Portability is not everything, especially since zero gravity means everything weighs nothing.
BFB 3000 from 3D Systems
Here on earth there are more than a handful of machines that can put the BFB 3000 to shame in areas like build time, materials supported, product rigidity, printer resolution, and so on. They only catch is they weigh probably ten times as much and cost up to twenty times as much.
My goal this week is to have a 3D print off. I will be gathering information from the websites of printer producers as well as private services to compare abilities and limitations of some machines out there. Categorizing them by size will make for fair fights and pricing is generally a function of this. I will do my best to get accurate prices but most companies do no list prices on their public websites.
It is always amazing to hear about the various applications people find for their 3D printers. Most of my experience though is second hand, through sources like blogs or youtube. I rarely meet people who have heard of 3D printing at all, let alone have utilized one. There came a point where I knew I needed to see a print with my own eyes.
In hopes of having some first hand experiences I searched google for “3D printing group Atlanta”. The very first result was a hackerspace called Freeside. A hackerspace, also callled a makerspace, is a place for people to get together to hack and build things. On my first visit to the space I met people with so many skills and interests. To my delight, the first thing you see upon entering the space is a Makerbot Cupcake CNC. They open the space at weekly meetings to discuss current and future projects. Some include building a robot for a Sumobot competition, rebuilding a DeLorean, homebrewing beer and 3D printing all sorts of stuff. Everyone there knows more than me so it is a good place to hang out. Find out more about Freeside
As I walked in for the meeting a few weeks ago I noticed a guy working with 3D modeling software so I asked him what he has been up to. Nick, or Dr. Glass as he calls himself, uses his 3D printer, a Makerbot Thing-0-matic, to find better ways to fix peoples’ feet. Knowing this had to be shared with the world, I told him about my blog and he agreed to an impromptu interview. Thanks Nick for sharing, it is truly amazing work.
3DPforAll: Tell us about yourself. What is your background and how did you become interested in 3D printing?
DR.Glass: I’m a resident for Foot and Ankle reconstructive surgery in Atlanta, GA. I’ve always been a big enthusiast/hobbyist with computer technology, along with biologic and medical sciences. The combination of those two things has lead to me engage with 3D printing for research as well as general curiosity. The reprap community is a pretty exciting platform, and I find the real camaraderie with other members to be somewhat contagious.
3DPforAll: What is the research project you are currently working on? How do you use 3D printing to achieve results?
DR.Glass: My current research project, concerning 3D Printing, is to reconstruct bones of patients lower extremity anatomy for the use of preoperative planning. This is currently being achieved through a combination of high resolution Computed Tomography (CAT) scans and open source software applications to create, modify, and print STL files. By having a copy “template”, I hope to demonstrate improved surgical performance and outcome. 3D printing and reprap devices allow this to be done in a cost effective and timely manner which will continue to increase in convenience as 3D printers become more ubiquitous.
3DPforAll: What kind of things do you print outside of your research? What printer/hardware are you working with? How awesome is it to own one?
DR.Glass: In order to learn more of the science behind it all, I dropped some cash on a Makerbot Thing-o-matic. It’s been quite amusing to practice with while learning to tweak the hardware and software. There’s really a lot that goes into it. I started with expected prints as straight downloads from Thingiverse, like the Calibration Box, Wall Thickness Utility, etc. Eventually I moved on to other classics like the Stanford Bunny, Bottle Opener, and Human Skull. (fun fact: kids love bunnies). Once I got that going, I’ve started printing a few custom objects, created in Newtek’s Lightwave 10 software, like the “Foot-Pumpkin String Light Unit” , (which I’ll upload to Thingiverse before Halloween). Owning your own hardware is awesome, indeed. Beware, that sound effects generated from a Thing-o-matic will drive roommates crazy, and induce the strangest dreams imaginable. I suggest printing wisely.
Prints from Dr. Glass
3DPforAll: We met at Freeside, what attracted you to the space? Do you think it will help you in your research?
DR.Glass: I was invited to come out and visit on a Tuesday meetup. There, I was introduced to a few of the guys, as well as a quick “Crash Course” in 3d printing. I was attracted to the space for the groups projects, classes, and most of all the volumes of enthusiasm. That combined with the hardware made me want to come back again and again. Freeside Atlanta is truly an awesome place for people interested in Hardware, Software, and DIY. It has already helped with research so far, and I’ll be confident to go about future projects with these resources in mind.
3DPforAll: What do you see in the future for 3D printing? Not just in everyday hobbyist machines like Makerbot, but in the consumer goods market.
DR.Glass: In consumer goods markets, I see an unimaginable change to everyday life. When you consider the current progress of “fab labs” and other home manufacturing capabilities combined with Open copyright movements, it’s hard to imagine post-capitalistic world which is perfused with socialistic ideals. How and when this all arrives will remain a mystery to me at this point, but it’s truly revolutionary. I was warned early on that having your own 3D printer will change you. You’ll walk around this world sizing everything up and thinking to yourself “I could make that…” Try walking through Walmart the same way again.
3DPforAll: With my blog, I love sharing about the capabilities of 3D printing. How do you share it?
DR.Glass: I share in proof. Most non-3D enlighted people (normies) don’t get the point with spoken testament. Even after you explain it, it still sounds fairytale to them. Bring in a printed model or show them a youtube video and you can see their eyes deepen with disbelief. I share by showing. My apartment and workplace are collecting some of my favorite prints. As far as videos, I try to share these two to anyone who genuinely wants to know where my enthusiasm stems from.
I show everyone this TED talk from MIT’s Neil Gershenfeld on the future of 3D printing.
There are machines that can 3D print a stainless steel helicopter rotor. Culinary specialists use a basic machine to spurt batter and frosting to make magnificently shaped cakes. Researchers are using huge 3D printers to extrude concrete to form buildings. Another type can layer cultured human cells to literally print a kidney. Check that out here. Even the Objet260 connex (their desktop version) can create a multi-material part with 14 possible materials in a single build.
Arabesque Mugs from Objet Gallery
This is made possible by the microprocessors embedded in the 3D printer. After reading the file, they give commands where to put material and what movements the printer head should make to build that specific object. Because of this build process, the machines are becoming less and less limited by materials. This means that whatever solid objects a human can conceive, they can be created using a single machine. For a more traditional manufacturing technique like injection molding the ability to make an object is carried out through mechanics and hardware so that only one object can be made by the hundreds of thousands.
Another major benefit of 3D printing technology is sustainability. It extrudes the exact amount of material needed, with no excess (one exception is printing support legs for an object with significant overhang). An image that comes to mind is when opening a checkers board game, the circular pieces are still connected to the plastic web that holds them in place during manufacturing. In machining metal parts with subtractive manufacturing, material is cut away to produce the final product. 3D printing is a type of additive manufacturing. Imagine all the waste and inefficiency you don’t see!
The technologies behind the printers are innovations, but more importantly they create pathways to further innovation. How will products we now use be redesigned and reconstructed using these techniques? As more people are exposed, the scope of homemade design will proliferate allowing products to be more available for cheaper.
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