Shanghai-based 3D printer manufacturer INTAMSYS has just announced their plans to host an exciting new event this summer. The company is holding a design competition where participants have to produce the best jigs and fixtures. Whichever contestants print and produce the best designs can win $2,000 prize, along with FUNMAT HT 3D printer, and 2 kg […]
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In the five years it has been in business, Xometry has grown to become the largest on-demand manufacturing platform, with 3D printing playing a significant role in its success. Now the company is growing even further as it has acquired MakeTime, another leading on-demand manufacturing company. Thanks to the acquisition, Xometry’s partner network of manufacturers will grow from 1,110 to more than 2,300. It will also benefit from MakeTime’s enterprise product expertise as well as its Autodesk Fusion add-in and Shop Advantage program.
Meanwhile, MakeTime’s customers will now have access to more manufacturing technologies, including 3D printing, injection molding and urethane casting. They will benefit from faster lead times, better pricing and more capabilities. The merger will create the manufacturing industry’s largest single platform, with more than 10,000 customers and offices in Maryland and Kentucky.
The combined company will continue to do business under the Xometry name. Drura Parrish, MakeTime Founder and CEO, will become Xometry’s Executive Vice President for Platform.
“We’re excited at the prospect of joining forces with Xometry,” said Parrish. “We’ve both been building the future of manufacturing, and now we will be able to offer small- and medium-sized manufacturers access to more jobs, more opportunities for growth and advanced products to power their businesses.”
MakeTime’s investor Foundry Group will lead a new $25 million funding round for the newly merged company. Additional participants in the funding include:
Xometry has now raised a total of $63 million, having secured $15 million last year.
“We’re thrilled to combine Xometry’s online manufacturing platform with MakeTime’s proven success in building a distributed network of over 1,000 manufacturers,” said Randy Altschuler, Co-Founder and CEO of Xometry. “This acquisition will provide our customers with access to massive capacity through the industry’s largest distributed manufacturing network as well enhanced product features.”
Foundry Group’s Seth Levine will also join Xometry’s Board of Directors.
“We are thrilled to help Xometry capture greater share of the $80+ billion on-demand manufacturing marketplace,” said Levine. “By combining both MakeTime’s complementary technology and partner network to that of Xometry’s, we can accelerate platform development and revenue growth to the benefit of both our customers and network partners.”
Xometry has been seeing outstanding success lately; in the first five months of 2018, the company more than doubled its revenues and bookings compared to the same period in 2017.
It also recently introduced a new version – Version 3.0 – of its Xometry Instant Quoting Engine, with several new and enhanced features to provide customers with instant quotes for 3D printing, CNC machining, sheet metal fabrication, and urethane casting.
New features include:
“We are focused on creating a seamless buying experience for our customers. Using customer feedback, we made our quoting interface even more intuitive and efficient,” said Hunter Guerin, Product Manager for the Xometry Instant Quoting Engine. “We want to make it as easy as possible for engineers and procurement managers to generate quotes.”
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Shanghai-based 3D printer manufacturer INTAMSYS, which stands for Intelligent Additive Manufacturing Systems, often makes the headlines for its reliable, industrial-grade FUNMAT 3D printers‘ capabilities in providing 3D printing solutions with tough, functional, high-performance, and high-temperature materials, such as PEEK and PEKK, ULTEM 1010 and ULTEM 9085, PSU, and PPSU, thanks to heated build plates, high-temperature nozzles, and breakthrough thermal technologies on active heated chambers.
INTAMSYS, which partners with many well-known companies around the world, operates several manufacturing and research facilities, and runs its own 3D printing service, provides solutions for many applications, ranging from medical, as in the case of this innovative PEEK knee brace, to industrial, such as making end-use parts, tools, jigs, and fixtures. The company is focusing on the latter for an exciting new event – INTAMSYS is hosting its very first competition this summer.
The Industrial 3D Printing Global Competition for Industry 4.0, focusing on a theme of Jigs and Fixtures, has officially launched, with entries being accepted up until August 31st, 2018. Over $10,000 in cash and prizes are at stake, so you should start preparing your entry soon.
Chun Pin Lim, the Marketing Director of INTAMSYS, said, “During our business visits in the USA, Europe and China, we’ve learned first-hand from our customers and partners that 3D printed jigs and fixtures in polycarbonate, nylon and PEEK have significantly improved lead time, worker safety and costs on their production floors.”
The aim of INTAMSYS’ new Industrial 3D Printing Global Competition is to identify and reward participants who can, as the company puts it, “best exemplify” the use of 3D printing solutions in terms of manufacturing jigs and fixtures, in order to achieve the best possible manufacturing lead time and cost savings.
This competition is open to any and all organizations, companies, and research and educational institutions around the world that currently use 3D printing to manufacture jigs and fixtures. When entering, participants must submit the following:
Competition entries must also include details regarding the cost, durability, lead time, and any other benefits of 3D printing the jig or fixture when compared to previously used fabrication methods. Additionally, entrants must include three photos – one of the jig or fixture being 3D printed, a photo of the fully printed object, and one of it while being used; check out this link to see sample photos.
The three competition winners will be announced on this site, and informed via either email or phone, on September 14th, 2018. The second runner-up will receive US$1,000, while the first runner-up will be awarded a prize of $2,000.
The winner of the competition will receive the grand prize: $2,000, a FUNMAT HT 3D printer, and 2 kg each of INTAMSYS nylon, PEEK, and polycarbonate filaments – all together, this prize is worth a total of $10,000, including global shipping costs for the 3D printer and filaments, which INTAMSYS will provide. Prizes are not exchangeable.
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Formlabs has just released their new castable wax resin for jewelry. It allows users to create direct investment casts for producing all sorts of trinkets and accoutrements. As the latest in its line of jewelry-centric resins, this one focuses on intricate detail for desktop printing. Formlabs calls it “ideal for rapidly expanding custom services and production […]
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Historic Royal Palaces (HRP) is an independent charity that, as the name suggests, deals with historic sites. Their particular interest is in looking after palaces in England and their maintaining their history, but now they’ve taken up the task of restoring them as well. With the aid of 3D systems, HRP turned to additive manufacturing […]
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California 3D printing and space technology firm Made In Space is responsible for such out of this world innovations as the first commercial 3D printer on the International Space Station, the multi-armed 3D printing space robot Archinaut, and the manufacture of the first extended 3D printed objects in a space-like environment. The company works closely with NASA, and two years ago received funding from the agency for its ambitious plan to turn asteroids into autonomous spaceships, which could help NASA finalize its long-term goal of constructing human colonies in space.
Right now, NASA can only bring back small pieces of space rock. But Project RAMA (Reconstituting Asteroids into Mechanical Automata) hopes to establish the concept feasibility of using analog computers and mechanisms – along with 3D printing – to convert asteroids into huge mechanical spacecraft, which could carry large amounts of raw asteroid material. This could be the impetus for the off-Earth mining that will be necessary if humanity wants to survive and thrive among the stars.
Artist’s illustration of an asteroid that has been turned into a giant mechanical spacecraft, which could fly itself to a mining outpost. [Image: Made In Space]
Asteroids are pretty cool – many of them contain valuable resources, such as water and platinum-group metals, and roughly 100 tons of asteroid and comet material hit the Earth’s atmosphere each day. As part of the plan to turn these massive rock formations into functioning spacecraft, Made In Space plans to send an advanced, robotic seed craft out to space, in order to to meet with several near-Earth asteroids.
This craft would then harvest space rock material and turn it into feedstock, which can be 3D printed to build energy storage, navigation, propulsion, and other important systems on-site. Once the converted asteroid is ready, it can be programmed to autonomously fly to a mining station; according to Made In Space representatives, this approach is far more efficient than having to launch new capture probes out to space rocks.
While we don’t currently have the ability or the technology to 3D print something like a digital guidance computer with materials found on an asteroid, Made In Space realized that one doesn’t have to rely on digital electronics if a huge amount of raw material, with no constraints on mass or volume, is available instead.
“At the end of the day, the thing that we want the asteroid to be is technology that has existed for a long time,” said Made In Space Co-Founder and CTO Jason Dunn. “The question is, ‘Can we convert an asteroid into that technology at some point in the future?’ We think the answer is yes.”
Two years ago, NASA’s Innovative Advanced Concepts (NIAC) program, which encourages development of space-exploration technologies, awarded Made In Space a $100,000 Phase 1 grant for nine months of initial feasibility studies. During this phase, the company focused on how the seed craft would have to work, defining its requirements, and building a technological roadmap. If the company chooses, it can also apply for a two-year, $500,000 Phase 2 award for continuing concept development. In the meantime, Made In Space is counting on NASA to push forward in-situ resource utilization (ISRU) – the art of living off the land, which is necessary for astronauts who could someday live on planetary outposts.
Required capabilities of the RAMA craft, arranged in approximate order of mass requirements, showing the source of the materials used to provide each capability as assumed for the rest of this study.
These asteroid ships will probably not look much like traditional spaceships, with their electronic circuitry and rocket engines, but instead would use analog computers and a catapult type of propulsion system that will launch asteroid material in a controlled way. By using mass drivers to shoot chunks of itself in one direction, an asteroid could potentially accelerate itself in the opposite direction. While this method is only about 10% as efficient as a chemical rocket engine, the propellant is free.
3D printing could be used to make some of the asteroid spacecraft parts, like flywheel gyros for guidance and stabilization, tanks for storing volatile materials, and solar concentrators to generate mechanical power through the release of pressure to open the tanks.
While Project RAMA is still moving forward, Dunn acknowledges that its completion is still way in the future…and that eventually, it could even have applications on Earth.
Dunn explained, “The anticipation is that the RAMA architecture is a long time line, and when it becomes capable is about the same time that people really need the resources.
“You could build infrastructure in remote locations somewhat autonomously, and convert resources into useful devices and mechanical machines. This actually could solve some pretty big problems on Earth, from housing to construction of things that make people’s lives better.”
Diagram of an asteroid that has been converted into a mechanical spacecraft by a robotic “Seed Craft.” [Image: Zoe Brinkley]
The other goal of Project RAMA is to be able to make asteroids into self-assembled spacecraft.
“One of the big questions is, how do you take today’s most intricate machines and make them replicate themselves? That seems really hard: how do you replicate electronics and processing units and so on,” Dunn said. “And that’s when we had this concept that there are types of machines that could potentially be easy to self-replicate, and those would be very basic, analog type devices. The problem is if you have a small mechanical machine, it’s not very useful. But what if the machine itself was the size of an asteroid? What could you do with a mechanical machine that large?”
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