U.K. company Wayland Additive, spun out from engineering firm Reliance Precision, licensed the metal AM NeuBeam process from its parent company with an aim to commercialize it by 2021. This goal will soon become a reality, as Wayland has announced a major milestone — it will be commercially launching the Calibur 3, its first production NeaBeam 3D printing system, on January 27th of 2021.
“We are very happy to confirm the launch date for the Calibur 3,” Peter Hansford, the Director of Business Development for Wayland Additive, stated in a press release. “On 27th January next year we will be unveiling the full specs of the machine to our early adopters and partners as well as to the press at a dedicated event. Currently the plan is to bring people in to see it in action for themselves if we are able to with Covid 19 restrictions, but we will also be live-streaming the event for interested parties that may not be able to attend. 2020 has been an unprecedented year in many ways and the global pandemic has caused a great deal of disruption and uncertainty. At Wayland, however, we have been able to navigate through these difficulties and keep our focus on the development of our system. Talking to industrial users of metal AM throughout, it is clear that despite the disruptions, many companies are still making medium and long-term plans, and we look forward to serving them with our ground-breaking technology.”
NeuBeam metal AM technology is an electron beam powder bed fusion (PBF) process, and was created from the ground up, by a team of in-house physicists, in order to negate most of the compromises made when using metal 3D printing for part production. The process can actually neutralize the charge accumulation you normally see with electron beam melting (EBM), which enables more flexibility. The creators used physics principles learned in the semiconductor sector to come up with this unique method, which, as the press release states, is able to overcome “the inherent instabilities of traditional eBeam processes,” along with the typical internal residual stresses that occur with PBF technologies.
Wayland’s NeuBeam technology can print fully dense parts in many different materials, including highly reflective alloys and refractory metals, which are not compatible with traditional laser PBF and eBeam processes; this results in much better metallurgy capabilities. NeuBeam is also a hot “part” process, instead of a hot “bed” process, as it applies high temperatures to the part only, and not the bed. This allows for free-flowing post-build powder and stress-free parts with less energy consumption, which makes for more efficient part printing.
The soon-to-launch Calibur 3 printer is an open system, and was specifically designed by Wayland to be used for production applications. That’s why the company made sure to add completely embedded in-process print monitoring to the system’s features, which allow users to enjoy full oversight during the process and rest easy knowing each part has full traceability.
“Save the date in your diary now. We are in the process of curating an impressive in-person and on-line event which will be of huge interest to industrial sectors that use or are planning to use metal AM for production applications,” said Will Richardson, Wayland Additive’s CEO. “January 27th 2021 will be a pivotal day for Wayland, but also a pivotal day for industry as they get a first clear view of the opportunities that exist through the use of our NeuBeam technology.”
NeuBeam technology
Wayland has said that it plans to start shipping the Calibur 3 to customers later in 2021.
Our 3D Printing News Briefs this week are indeed brief, but no less important. We’ll tell you how 3DEO has reached an important production milestone, and also about the newest member of the 3MF Consortium.
3DEO Reaches 150,000 Production Parts Shipped
Monthly shipment of 3500 pieces to a 3DEO customer
Metal 3D printing company 3DEO, founded in 2016 for the purpose of competing against conventional manufacturing with high-volume metal additive manufacturing, recently announced that it has reached a major milestone: it’s shipped out 150,000 production parts for end-use applications. The California company’s mission is to make metal 3D printing available for mass production through its digital industrial platform, and this announcement is excellent evidence that it’s well on its way. 3DEO has an interesting business model – instead of selling its 3D printers, the company has focused on becoming an expert user of its own patented technology, and built an automated end-to-end industrial platform, to which its customers then have access.
“150 thousand parts is a terrific milestone for 3DEO. It validates our patented technology, our unique business model, and our mission to break metal additive manufacturing (AM) into high-volume production. Today, we routinely win bids against traditional manufacturing because of our competitive cost structure and material performance,” said 3DEO’s President Matt Sand.
“150,000 parts shipped is only the beginning for us. We are scratching the surface of what’s possible with metal AM in the $130 billion U.S. metal parts market. With our additive and automation software and hardware, combined with our world-class R&D team and quality systems, we are primed to scale metal AM into millions of parts next year.”
3MF Consortium Announces New Specification and Member
“In a modern cloud-connected world, data security and end-to-end encryption are playing an increasingly important role to mitigate the risk of leakages and data corruption in globally distributed manufacturing environments. Protecting the integrity and confidentiality of product designs, patient-specific biometric data, and other sensitive manufacturing content is critical to enabling additive manufacturing to scale into final part production in distributed, contractual, and highly regulated manufacturing environments,” stated Scott White, Software Distinguished Technologist at HP Inc. “We are thrilled that Viaccess-Orca joined the consortium and contributed their decades-long expertise to the design of the 3MF Secure Content extension. The final specification defines the payload encryption based on industry standards, and allows third parties to build their own key management ecosystems upon it. We believe this will allow it to be used to address a broad range of critical use cases simply and seamlessly.”
As a consortium member, VO will help address digital asset security aspects in the digital manufacturing industry. The company also announced the general release of its Secure Manufacturing Platform (SMP), which makes sure that digital assets are traceable and secure, in compliance with the new 3MF specification, across digitally distributed supply chains.
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In 2006, NASA selected Lockheed Martin to design, develop, and build Orion, set to embark on both manned and unmanned missions, it is the agency’s newest deep space exploration spaceship that will eventually carry astronauts from the Earth to the Moon, and back. As part of a plan to extend a sustained human presence beyond low Earth orbit (LEO), advance commerce and science in space, the Artemis program is the next step in human space exploration and a part of NASA’s broader Moon to Mars approach. In 2022, the Orion crew capsule is expected to take astronauts on a ride beyond LEO, to the Moon and back, and in five years it will transport the next people to a lunar orbital post.
The Orion crew module for Exploration Mission 1 that will launch atop NASA’s Space Launch System rocket on its first uncrewed integrated flight (Image credit: NASA)
Last September, NASA, and Lockheed finalized a contract for the production and operations of six Orion spacecraft missions with an option to order up to 12 in total. The agency’s Orion Production and Operations Contract (OPOC) is an indefinite-delivery, indefinite-quantity (IDIQ) contract for NASA to issue both cost-plus-incentive-fee and firm-fixed-price orders. Initially, NASA has ordered three Orion spacecraft for Artemis missions III through V for $2.7 billion. Then in 2022, the agency plans to order three additional Orion spacecraft for Artemis missions VI through VIII for $1.9 billion. Up to six additional Orion spacecraft may be ordered under the IDIQ contract through 2030, leveraging spacecraft production cost data from the previous six missions to enable the lowest possible unit prices.
During an interview with Lockheed Martin Space’ specialists Brian Kaplun, Manager of the Additive Manufacturing Lab, and Colin Sipe, Orion Crew Systems Senior Manager, 3DPrint.com delved into the makings of America’s next spacecraft for a new generation of explorers.
How has additive manufacturing helped in the creation of more efficient spacecraft?
“One of the tenants of advanced manufacturing is to increase the cost and the schedule efficiency for any of our platforms, including Orion, and doing so in a way that, at the very least, maintains parity from a technical perspective but in many cases enhances that. So a lot of the work we’ve done with Orion was targeted to allow for a more efficiently reusable, cost-competitive and faster time to delivery spacecraft that will have a better technical performance. For example our docking hatch covers were printed in a cost and schedule effective manner; additionally, thanks to a new ESD compliant polymer (a type of no-static plastic) we provided more technical performance as well,” suggested Kaplun. “AM is one tool in the advance manufacturing toolbox that really allows us to hit all three of those valuable points. The plan is to continue creating AM components that we already utilized and look at increasing the number.”
While Colin Sipe explained that “we do a lot of parts that would be traditionally difficult to produce, such as structural components and brackets, different parts to channel airflow, or fuel containers, like hydrogen fuel tanks. Moreover, on the seats that the astronauts will use on Orion, we 3D printed different spacers (parts that go between the edge of the seat and the hip of the astronaut) and those come in various sizes based on the astronaut using it. We have to be able to accommodate from 1 to 99th percentile of the average American size individual.”
Do 3D printed parts withstand some of the harshest conditions in space?
“We fully qualify any of our spacecraft and platforms, and it is a qualification born of many years of doing this. On 2011 we launched the first-ever 3D printed part going to outer space on our Juno mission and right now those parts are orbiting the gas giant. So just as rigorous as we did in 2011, here in the last throes of 2019 we have to go through and really qualify any of the Orion parts. Even more so, with future manned missions, we are going to further stress those qualifications. Its a challenge that we are very experienced in and really believe we are up for,” claimed Kaplun. “Experience in any way, shape or form is going to be a competitive advantage for Lockheed.”
How do you choose the design for the 3D printed parts?
“We have produced many different parts for our customers that almost have an organic shape to them and so if you look at some of the new designs where you are optimizing for strength in terms of weight and producibility, you will observe that they mimic the bones in your arm like a very evolved and efficient method of support. If we look at some of the structural brackets that we have done, they almost have a tree or a skeletal structure look to them, that is a very unique mindset or would have been a unique mindset when we were looking at the substractive and traditional manufacturing. But now that people are being trained for AM, we notice that there are a lot more technically complex designs. Some of the ESD parts that we made for Orion would be virtually imposible ot make any other way,” revealed Kaplun. “Now, we are able to combine a large number of other parts into one piece and eliminate a lot of the fasteners and the weight that otherwise would have been a parasitic load, providing greater opportunities to put payloads and scienitic instruments onto our platforms.”
In what way does 3D printing drive down spacecraft costs?
“We try for a really ambitious cost reduction, aiming at 50%. Over the last year, we printed roughly 6,500 parts across our entire space division. Recently we even used AM technology to develop mockups for tests, such as the toilet that will be used on Orion, called the UWMS,” proposed Sipe. “We were concerned about one area of interference so we printed the entire mockup of the toilet and put it into the flight vehicle to verify that we could reach and access the bolts. The size of that toilet is probably two feet in diameter and three feet tall, so it was a very large piece to produce.”
How does Lockheed factor in sustainability when 3D printing its pieces?
Kaplun indicated that at Lockheed, engineers are “very proud of how sustainable our technology is. Our polymer builds can be recycled and reused if needed, the powder bed processes are extremely efficient and the industry as a whole is considered very sustainable and cost-efficient from a materials perspective. Some of the waste for our additive processes can be lower than five percent. When you compare that to some of the subtractive and traditional manufacturing applications, those numbers flip completely, producing 90% waste.”
Would you be able to convey how many AM parts were used for Orion?
“We made 200 components for the Artemis II Orion spacecraft. While the Artemis I had over 100 printed pieces and the previous version had only four 3D printed parts. This reveals that only one spacecraft generation later, we were able to double the amount of 3D printed parts,” reported Sipe.
A 3D printed titanium part for NASA’s Orion spacecraft (Image credit: Lockheed Martin)
What can we expect to see during the Artemis II mission scheduled for late 2020?
“Our next mission will launch Orion on a Space Launch System (SLS) rocket, which will be the largest rocket ever built as far as liftoff power. Next year we can expect an unmaned service module to travel to the lunar orbit where it will stay for a month, carry out significant checkouts of all of our modules and will be the first launch on the new rocket. Once it returns to Earth, we will recover it, take it apart, see what we can reuse, what we need to make some improvements on, and at the same time, we’ll be getting ready for our Artemis II mission, with the first astronauts flying on 2022. Then, Artemis III in 2024, will take astronauts to Gateway, a small space station in the lunar orbit, and from there to a human landing system that will put the first woman and next man on the Moon surface. This will be the first of many missions to the Moon’s south pole, where bases and moon mining will begin,” said Sipe.
Are there more engineers interested in AM technology applications?
According to Kaplun, there has been much interest in AM: “we are witnessing a lot of students and scholars contributing to the design space, coming into our engineering and production ranks with a lot of previous work in the field, with new ideas and new abilities to utilize the tools that we can now offer.”
As an engineer, how do you change your mindset to produce something from a subtractive standpoint to an additive one?
“We are starting to corrupt the threshold as we are beginning to design parts that can only be made via the additive route, whereby in the past we would sort of take something that was designed for a normal conventional machine and then transition it to the additive world,” told Sipe. “Today we are generating designs that we know the only way they can be made is through AM. There are certain parts of the spacecraft that couldn’t be done with other technologies, such as hollow, organically grown on the printer parts that create new opportunities for us.”
3D printed Orion docking hatch cover (Image credit: Lockheed Martin)
What 3D printing technologies are being used at Lockheed?
“We have a very large gamut of different types of technologies to make the 3D printed parts for Orion, the docking hedge covers were made on Stratasys FDM printers, but we also use a lot of metal powder bed technologies in various forms as well as different polymer technologies,” the experts proposed.
3D printed Orion docking hatch cover made of PEKK thermoplastic (Image credit: Lockheed Martin)
So what lays ahead for the aerospace company?
“We just got into a long term production contract with NASA for the six upcoming spacecraft missions, so I believe it is our goal to make even more 3D printed parts for spacecraft. A big focus of the contract was to dramatically reduce per-vehicle costs and the major ways of doing that was by having reusable Orion crew modules and systems, using advanced manufacturing technologies, material and component bulk buys and an accelerated mission cadence. I consider that AM is a large part of reducing the cost and increasing the cadence of how often we fly,” enlightened Kaplun.
Both Kaplun and Sipe consider that the “Orion spacecraft is part of NASA’s backbone for deep space exploration.”
The completed Orion spacecraft crew module at the NASA Kennedy Space Center (Image credit: Lockheed Martin)
With work well underway on both the Artemis I and II rockets, with core stage assembly nearly complete at Michoud, Orion will leave Lockheed for testing at NASA’s Stennis Space Center near Bay St. Louis, in Mississippi.
Sipe concluded that: “In 1981, NASA wanted to move back into deep space so since 1981 we were flying the space shuttle, and physically could not go outside the Earth’s orbit, the Apollo was the last spacecraft that physically could leave the gravity of the Earth and move into deep space, and NASA had a desire for mankind to return. Orion is the only spacecraft development that is a true exploration class spacecraft. It’s not like any other, it has unique capabilities never before seen and even though the capsule is a heritage of the Apollo mission, its actually far superior.”
We’ve got news about a contest to start off today’s 3D Printing News Briefs, followed by some business news and 3D printed jewelry. Weerg has announced the second edition of its “3D Printing Project Award” contest. Moving on, Bastian Solutions worked with Fast Radius to create a robotic materials handler using HP 3D printing, while Fast Radius announced that it has closed a round of Series B funding. Finally, an SLM 3D printer is being used by a person you might recognize to fabricate unique metal rings.
2nd Edition of Weerg’s 3D Printing Project Award Contest
3D printing and CNC machining platform Weerg, based in Gardigiano, Italy, just announced the second edition of its “3D Printing Project Award” contest, which promotes creativity, experimentation culture, and innovation in design manufacturing. The company, which offers the largest Italian installation of HP’s MJF 4210 3D printers, invites designers and developers to create “an iconic object completely printed in 3D” for the chance to win a €500 Weerg coupon, and an interesting social media opportunity – star as the protagonist in a professional video that will highlight his/her designer skills, which Weerg will promote.
“After the success we obtained last edition, we decided to put to test once more our recently doubled and enhanced production department, and to give visibility to the most creative talent in 3D Printing. The Weerg Award was created to stimulate the potential and the desire to innovate of tomorrow’s designers who are starting to come face to face with the opportunities offered by additive manufacturing,” said Weerg’s founder Matteo Rigamonti. “In addition, it will allow us to maximize the performance of HP printers by creating very original and sophisticated items.”
You have until this Sunday, April 14th to submit your entry by posting it directly to Weerg’s Facebook and Instagram pages. The winner will be announced on Monday.
New Robot Warehouse Picker Features 3D Printed Parts
Indianapolis-based Bastian Solutions, a Toyota Advanced Logistics company, has launched its Shuttle System: an efficient, flexible robotic materials handler with dexterity to spare. 45% of the final build-of-material (BOM) on the system’s robotic arm were 3D printed with HP and Carbon 3D printers. The durable polymer joints of the robotic picker were made with HP’s Multi Jet Fusion (MJF) technology, while its fingers and gripper were 3D printed out of unique materials, like EPU 40, using Carbon’s Digital Light Synthesis (DLS) technology. The company displayed its new Shuttle System this week at ProMat 2019 in Chicago.
“We envisioned that additively manufacturing specific parts would make the Bastian Solutions Shuttle System the most efficient and agile robotic picker available on the market. The additive manufacturing process will enable us to customize each robot picker to fit a customer’s particular warehouse environment,” said Ron Daggett, the Vice President of Technology and R&D, Bastian Solutions.
These parts were 3D printed at the Chicago headquarters of industrial-grade additive manufacturing facility Fast Radius.
Fast Radius Raised $48 Million in Series B Funding
Speaking of Fast Radius, the company recently announced that it had raised $48 million in a Series B funding round, which it will use to continue expanding its production-grade AM platform through application engineering, sales teams, and software development. Its software platform, the Fast Radius Operating System (FROS), supports customers across the entire lifecycle of a product, helping them conduct engineering and economic evaluations, find potential applications, and 3D print industrial-grade parts at scale. The funding round was led by the company’s previous collaborator UPS, and Drive Capital was also a strong participant; other participants include previous investors Jump Capital, Skydeck, and Hyde Park Venture Partners.
Pat McCusker, the COO at Fast Radius, said, “This additional funding will allow us to further expand our partnerships with leading global companies across aerospace, consumer, industrial, medical, and automotive verticals.”
Bam Margera 3D Printing Jewelry with SLM Technology
And now for something totally different…Bam Margera, a professional skateboarder, stunt performer, filmmaker, musician, and TV personality who rose to fame as one of the main members of MTV’s reality show Jackass from the early aughts, is now designing jewelry, which he 3D prints on an SLM Solutions 125 system that he purchased. He is selling the unique metal rings and pendants on his official BamMerch website.
According to the website, “BamMerch is Bam Margera´s new lifestyle brand offering various jewelry and apparel, our store launched in December 2016.
“All items are crafted in Estonia, using combination of high-tech metal 3D printing and hand crafting to create extremely unique and detailed jewelry.”
All of the jewelry is 3D printed in-house out of sterling silver, and then carefully polished in ten stages. Some of the pieces, like the pretty Margeras Pendant with three intertwined hearts, are available for as little as $17, with prices ranging all the way up to $149 for the Skull Ring v2. Margera also offers a range of bundles. Check out the video below to see the 3D printing process for some of Margera’s rings, but be warned – if you go searching for more information about his 3D printed jewelry on Twitter or Instagram, there’s a lot of profanity and other NSFW content.
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Roboze, a leader in functional 3D printed prototypes produced in industrial materials like PEEK, CarbonPA, and ULTEM AM9085F, manufactures 3D printers that can handle high-performance, high temperature polymers, such as SABIC’s LEXAN EXL AMHI240F. Now, the company is getting extreme with FFF 3D printing, with an announcement about the new desktop production 3D printing series it will debut at next week’s formnext in Frankfurt.
“The new Xtreme solutions, is the result of intense work by the entire Roboze team, that has allowed us today to create a new line of systems capable of meeting the most extreme needs of our customers, offering greater versatility in the materials and accuracy of the prints as well as better performance,” said Alessio Lorusso, CEO & Founder of Roboze. “We have rewritten the history of 3D printing and the Formnext 2018 represents the best showcase to tell the story.”
The new Xtreme 3D printer series, made up of the Roboze One Xtreme and Roboze One + 400 Xtreme, will strengthen the company’s PEEK and CARBON PEEK solutions for FFF 3D printing, bringing users closer to true additive production.
Roboze has become a major manufacturing player thanks to its innovative technology, like the Beltless System that allows operators from around the world to 3D print both finished parts and prototypes with 25-micron mechanical tolerances, which all but guarantees repeatability and, as the company puts it, “immediate economic advantages.”
But this new Xtreme series launch is an even bigger deal for the company, as it sets up a point of contact between the production ARGO 500 3D printer and its desktop One and One + 400 systems.
Rocco Maggialetti, head of the mechanical design of Roboze, explained, “The strong collaboration between all the members of Roboze’s R & D team has allowed us to design this new system that improves the previous one, guaranteeing longer useful life of the machine.”
The newly designed covers for the Xtreme 3D printers are made of sheet metal, and designed to lower maintenance on the machines while also improving their robustness. In addition to providing a more elegant aesthetic, this new feature also makes the Roboze Xtreme series extremely quiet.
The Roboze One Xtreme and Roboze One + 400 Xtreme 3D printers were built by Roboze engineers who changed up the status quo in order to offer extremely versatile and accurate 3D printing solutions. The series feature a new, advanced sensor system, which includes an endstop aimed at leveling the semi-automatic plan, WiFi and USB connections, motor encoders for closed loop control that monitor the printing process, and optical endstop/touchless, which promises less maintenance because it decreases typical issues.
The Beltless System on this new 3D printer series has also evolved from the original, and features racks machined with chemical nickel plating. This lowers the contact friction between the rack and pinion for faster print speed, and also increases the resistance to wear and corrosion.
The Xtreme series also includes a Cabinet Support System (SSC), which is meant for unloading machine vibrations and controlling material temperatures, as well as storing coils so they’re not exposed to atmospheric agents. Just like with the ARGO 500 and the Roboze One + 400, these new 3D printers also house a Vacuum Box for vacuum generation, which provides greater first-layer flatness and print surface adhesion for faster 3D printing.
Roboze 3D printers are certainly impressive, thanks in large part to the versatility of materials they can handle. Many of these were developed specifically to add enhancements to parts with properties not dissimilar from metals. In addition to its Xtreme desktop production 3D printer series, Roboze is also introducing several new materials at formnext 2018.
Carbon PP is the first, and is good for use in automotive applications, because it promises the same high performance of PP (polypropylene), combined with the advantages of carbon fiber.
“Carbon PP’s carbon fiber provides a 25% resistance increase level compared to PP. The addition of specially selected carbon fibers improves the mechanical properties of the material and increases its HDT maintaining its properties even at a higher temperature than that of PEEK,” said Maria Luisa Geramo , PhD, Head of Applications – Roboze R&D Material Engineer.
According to Roboze, its new PP has excellent electrical insulating properties and high resistance against abrasion, chemical agents, and shock, and “represents the most commodities polymer primarily used in applications for objects of common use and automotive components,” while its new Glass PA – a polyamide loaded with glass spheres – is a good electrical insulator, and ensures high dimensional stability because it has lower moisture absorption and increased mechanical properties when compared to standard polyamide.
Carbon PEEK, which has excellent mechanical properties and thermal stability, is already used with the company’s ARGO 500 production 3D printer, and is the only new material that’s available for use solely on the Roboze One + 400 Xtreme.
Come see all of Roboze’s new 3D printing materials and solutions at next week’s formnext – visit the company at booth C78 in Hall 3.1.
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