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Ireland: Characterizing Mechanisms of Metallic 3D Printing Powder Recycling

In order to cut down on material waste, and save money, laboratories will often reuse leftover metal AM powder. A trio of researchers from the I-Form Advanced Manufacturing Research Centre in Ireland published a paper, “X-ray Tomography, AFM and Nanoindentation Measurements for Recyclability Analysis of 316L Powders in 3D Printing Process,” focusing on better understanding and characterizing the mechanisms of metallic powder recycling, and evaluating ” the extent of porosity in the powder particles,” in order to optimize how many times recycled powder can actually be reused in the powder bed fusion process.

Many “risk-tolerant applications,” like in the aviation and biomedical industries, will not use recycled powder, because any part abnormalities that can be traced back to the material can be unsafe and expensive. Parts 3D printed out of recycled powder need to have mechanical properties, like hardness and effective modulus, that are comparable to those of fresh powder parts.

“In order to reuse the recycled powders in the secondary manufacturing cycles, a thorough characterization is essential to monitor the surface quality and microstructure variation of the powders affected by the laser heat within the 3D printer. Most powders are at risk of surface oxidation, clustering and porosity formation during the AM process and it’s environment [1,2],” they explained. “Our latest analysis confirms the oxidation and the population of porous particles increase in recycled powders as the major risky changes in stainless steel 316L powder [3,4].”

A common practice before reusing recycled powders is sieving, but this doesn’t lower the porosity or surface oxidation of the particles. Additionally, “the subsequent use of recycled powder” can change the final part’s mechanical strength, and not for the better.

“Here, we report our latest effort to measure the distribution of porosity formed in the recycled powders using the X-ray computing technique and correlate those analyses to the mechanical properties of the powders (hardness and effective modulus) obtained through AFM roughness measurements and nanoindentation technique,” the researchers wrote.

They used stainless steel 316L powder, and printed nine 5 x 5 x 5 mm test cubes on an EOSINT M 280 SLM 3D printer. They removed the recycled powder from the powder bed with a vacuum, and then sieved it before use; after the prints were complete, they collected sample powders again and labeled them as recycled powders.

“Both virgin and recycled powders were analyzed by number of techniques including XCT and Nanoindentation. XCT was performed by X-ray computed tomography (XCT) measurements were performed with a Xradia 500 Versa X-ray microscope with 80 KV, 7 W accelerating voltage and 2 µm threshold for 3D scan,” they wrote.

“To measure the roughness of the virgin and recycled powder particles, we performed Atomic Force Microscopy (AFM) and confocal microscopy using the Bruker Dimension ICON AFM. The average roughness was calculated using the Gwyddion software to remove the noise and applying the Median Filter on the images as a non-linear digital filtering technique.”

The researchers also ran nanoindentation on multiple powder particles, under a force of 250 µN for no more than ten seconds, in order to determine “the impact of porosity on the hardness and effective modulus of the recycled powders,” and used an optical microscope to identify pore areas on the powder.

XCT imaging of powder. (a) 3D rendered image of 900 recorded CT images, (b) region of interest, (c) internal pores in particles indicated in a 2D slice, (d) identified pores inside particles after image processing.

The XCT images were analyzed, and “a region of interest” was chosen, seen above, from which pore size and interior particle distribution were extracted.

AFM image on a particle showing the boundary of mold and steel and the area where surface roughness was measured.

Software was used to process the AFM topography images of both the virgin and recycled powders, and the team applied nanoindentation on different locations of the particles, with a force of 250 µm.

(a) powder particles placed on hardening mold for nanoindentation, and (b) an indent applied on a particle surface.

They determined that the reused powder particles had about 10% more porosity than the virgin powder, and the average roughness of the powder particle surfaces was 4.29 nm for the virgin powder and 5.49 nm for the recycled; this means that 3D printing “may increase the surface roughness of the recycled particles.” Nanoindentation measurements show that the recycled powder has an average hardness of 207 GPa, and an average effective modulus of 9.60 GPa, compared to an average of 236 GPa and 9.87 GPa for the virgin powder, “which can be correlated to porosities created beneath the surface.”

Pore size distribution in virgin and recycled powders extracted from image processing on XCT measurements.

“The pore size in recycled powders has a wider distribution compared to virgin counterpart. The main population of pore size is around 1-5 µm in virgin powder which slightly reduces to bigger size but for a smaller population. There are also bigger pores in recycled powder but with a smaller population,” they noted. “On the other hand, looking at higher pore population in virgin powder (around 10 µm size), we believe that the out-diffusion of metallic elements to the surface occurs during laser irradiation.”

Surface roughness plots from AFM measurements on powder particles. Average roughness calculated by Gwyiddion software.

The recycled powder hardness, which is smaller than in the virgin powder, “could be attributed to higher pore density in recycled particles,” since porosity causes the powder to be “more vulnerable to the applied force resulted in smaller hardness.”

While change in grain size of the powder particles can lead to reduced mechanical properties, the team’s AFM and SEM results did not show much grain redistribution in the recycled powder. But, their nanoindentation and XCT results did find that higher powder porosity can decrease both the hardness and modulus of the particles, which “will damage the mechanical properties of the manufactured parts.”

Hardness and effective modulus of fresh and virgin particles by nanoindentation.

“We have previously presented our achievement on surface and size analysis using SEM and XPS analysis. Here, we focused on pore distribution in both powders and correlated that to surface roughness, hardness and effective modulus obtained from nanoindentation analysis of the powder particles,” the researchers concluded. “The results indicate that pores population is about 10% more in recycled powders affected by the laser heat and oxygen inclusion/trap in the powder, which in turn, increases the surface roughness but reduces the hardness and modulus of the recycled powders. The pores are filled with gases (such as Argon or Oxygen) since these gases are not able to skip the melt and have a lower solubility in the melt throughout the solidification process.”

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XYZprinting Showcasing da Vinci Color mini and Three New 3D Printing Materials at CES 2019

Today in Las Vegas, CES 2019 officially kicked off, though the official CES Unveiled media event took place on Sunday at the Mandalay Bay hotel. Taiwan-based 3D printer manufacturer XYZprinting attended the media event and showed off its newest product, the consumer-oriented da Vinci Color mini, which was first introduced this summer. The company plans on unveiling several additions to its 3D printer line at the show this year, including an upgraded extruder option and an expanded filament line.

XYZprinting is committed to making 3D printing more accessible to the masses, and the compact da Vinci Color mini, its second-generation desktop full-colored FFF 3D printer, is crushing full-color 3D printing size and price barriers. It’s a good choice for consumers, designers, makers, and small business owners looking to use full-color 3D printing for the purposes of prototyping. The da Vinci Color mini uses the company’s 3DColorJet technology, which creates millions of color combinations by applying a single CMY ink cartridge to a color-absorbing PLA filament; however, it’s also possible to print in monochrome if you wish.

“Our investment in full-color 3d printing technology has opened the door to the next level of 3D printing innovation. By providing an affordable and compact full-color printer, we are very pleased to be bringing color 3D printing technology within reach for small businesses, schools, designers, makers and general consumers,” said XYZprinting CEO Simon Shen. “We will continue to provide innovative, high-quality 3D printers while making it affordable for everyone to utilize this technology and incorporate it into their daily lives.”

The da Vinci Color mini features a 5″ color touchscreen, which gives users an intuitive way to work the user interface, and also comes with a 5.1″ x 5.1″ x 5.1″ EZ-removable print bed.

In addition, there are several upgradeable options for the desktop 3D printer, such as a Laser Engraver module for engraving on leather, paper, wood, and other materials, and a Hardened Steel nozzle for 3D printing with some of the company’s newest materials.

The newest filaments by XYZprinting include a Metallic PLA and a Carbon Fiber PLA, which gives users access to higher-performing materials. The Hardened Steel nozzle upgrade, which is very wear-resistant in terms of these more abrasive materials, will cost 119.95 with the da Vinci Color series, and $79.95 for select XYZprinting 3D printers, like the da Vinci mini-series and the da Vinci Jr. Pro. series.


The company also launched an additional new filament that was designed with antibacterial properties. The special Antibacterial PLA inhabits bacterial growth by at least 99% through the use of silver ions, which majorly lowers the risk of infections.

Antibacterial PLA

Because the Antibacterial PLA comes with enhanced protection against germs and infections, it’s a safer and more hygienic choice of material for young kids who are just starting to learn about 3D printing. Educators and parents who use this new filament can rest assured that their 3D printing experience will yield safe, functional prints that can be used in the household and the classroom with no worries. A 600 gram spool of XYZprinting’s new Antibacterial PLA costs $29.95 on the company’s online eShop, and the material is compatible with the company’s Color series, Nano series, da Vinci Jr. and Jr. Pro series, and the da Vinci Super 3D printer.

The company’s newest 3D printer, along with its other new products, materials, and accompanying software, will be available for purchase by the end of the first quarter of 2019 on the XYZprinting online eShop. At just $1,599, the da Vinci Color mini is a more affordable option for users interested in full-color 3D printing. You can take a look at all of these new products, along with a range of other commercial 3D printers and ancillary products, at XYZprinting’s booth #31524 in South Hall 3 of the Las Vegas Convention Center (LVCC) at CES 2019 this week.

Discuss this news and other 3D printing topics at 3DPrintBoard.com or share your thoughts in the Facebook comments below.

[Images provided by XYZprinting]

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Top 10 3D Printing Aerospace Stories from 2018

3D printing has played an important role in many industries over the past year, such as medical, education, and aerospace. It would take a very long time to list all of the amazing news in aerospace 3D printing in 2018, which is why we’ve chosen our top 10 stories for you about 3D printing in the aerospace industry and put them all in a single article.

Sintavia Received Approval to 3D Print Production Parts for Honeywell Aerospace

Tier One metal 3D printer manufacturer Sintavia LLC, headquartered in Florida, announced in January that it is the first company to receive internal approval to 3D print flightworthy production parts, using a powder bed fusion process, for OEM Honeywell Aerospace. Sintavia’s exciting approval covers all of Honeywell’s programs.

Boeing and Oerlikon Developing Standard Processes

Boeing, the world’s largest aerospace company, signed a five-year collaboration agreement with Swiss technology and engineering group Oerlikon to develop standard processes and materials for metal 3D printing. Together, the two companies will use the data resulting from their agreement to support the creation of standard titanium 3D printing processes, in addition to the qualification of AM suppliers that will produce metallic components through a variety of different materials and machines. Their research will focus first on industrializing titanium powder bed fusion, as well as making sure that any parts made with the process will meet the necessary flight requirements of both the FAA and the Department of Defense.

FITNIK Launched Operations in Russia

In 2017, FIT AG, a German provider of rapid prototyping and additive design and manufacturing (ADM) services, began working with Russian research and engineering company NIK Ltd. to open up the country’s market for aerospace additive manufacturing. FIT and NIK started a new joint venture company, dubbed FITNIK, which combines the best of what both companies offer. In the winter of 2018, FITNIK finally launched its operations in the strategic location of Zhukovsky, which is an important aircraft R&D center.

New Polymer 3D Printing Standards for Aerospace Industry

The National Institute for Aviation Research (NIAR) at Wichita State University (WSU), which is the country’s largest university aviation R&D institution, announced that it would be helping to create new technical standard documents for polymer 3D printing in the aerospace industry, together with the Polymer Additive Manufacturing (AMS AM-P) Subcommittee of global engineering organization SAE International. These new technical standard documents are supporting the industry’s interest in qualifying 3D printed polymer parts, as well as providing quality assurance provisions and technical requirements for the material feedstock characterization and FDM process that will be used to 3D print high-quality aerospace parts with Stratasys ULTEM 9085 and ULTEM 1010.

Premium AEROTEC Acquired APWORKS

Metal 3D printing expert and Airbus subsidiary APWORKS announced in April that it had been acquired as a subsidiary by aerostructures supplier Premium AEROTEC. Premium AEROTEC will be the sole shareholder, with APWORKS maintaining its own market presence as an independent company. Combining the two companies gave clients access to 11 production units and a wide variety of materials.

Gefertec’s Wire-Feed 3D Printing Developed for Aerospace

Gefertec, which uses wire as the feedstock for its patented 3DMP technology, worked with the Bremer Institut für Angewandte Strahltechnik GmbH (BIAS) to qualify its wire-feed 3D printing method to produce large structural aerospace components. The research took place as part of collaborative project REGIS, which includes several different partners from the aerospace industry, other research institutions, and machine manufacturers. Germany’s Federal Ministry for Economic Affairs and Energy funded the project, which investigated the influence of shielding gas content and heat input on the mechanical properties of titanium and aluminium components.

Research Into Embedded QR Codes for Aerospace 3D Printing

It’s been predicted that by 2021, 75% of new commercial and military aircraft will contain 3D printed parts, so it’s vitally important to find a way to ensure that 3D printed components are genuine, and not counterfeit. A group of researchers from the NYU Tandon School of Engineering came up with a way to protect part integrity by converting QR codes, bar codes, and other passive tags into 3D features that are hidden inside 3D printed objects. The researchers explained in a paper how they were able to embed the codes in a way that they would neither compromise the integrity of the 3D printed object or be obvious to any counterfeiters attempting to reverse engineer the part.

Lockheed Martin Received Contract for Developing Aerospace 3D Printing

Aerospace company Lockheed Martin, the world’s largest defense contractor, was granted a $5.8 million contract with the Office of Naval Research to help further develop 3D printing for the aerospace industry. Together, the two will investigate the use of artificial intelligence in training robots to independently oversee the 3D printing of complex aerospace components.

BeAM And PFW Aerospace Qualified 3D Printed Aerospace Component

BeAM, well-known for its Directed Energy Deposition (DED) technology, announced a new partnership with German company PFW Aerospace, which supplies systems and components for all civilian Airbus models and the Boeing 737 Dreamliner. Together, the two worked to qualify a 3D printed aerospace component, made out of the Ti6Al4V alloy, for a large civil passenger aircraft, in addition to industrializing BeAM’s DED process to manufacture series components and testing the applicability of the method to machined titanium components and complex welding designs.

Researchers Qualified 3D Printed Aerospace Brackets

Speaking of parts qualification, a team of researchers completed a feasibility study of the Thermoelastic Stress Analysis (TSA) on a titanium alloy space bracket made with Electron Beam Melting (EBM) 3D printing, in order to ensure that its mechanical behavior and other qualities were acceptable. The researchers developed a methodology, which was implemented on a titanium based-alloy satellite bracket.

Discuss these stories and other 3D printing topics at 3DPrintBoard.com or share your thoughts below. 

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3D Printing News Briefs: November 13, 2018

We should really call today’s 3D Printing News Briefs the formnext 2018 Briefs, as announcements from the show are numerous this week. EnvisionTEC, XYZprinting, BASF, and DSM all introduced new 3D printing materials at the event in Frankfurt today, and in the only news not related to formnext, Imerys Ceramics has announced a new range of ceramic feedstocks.

EnvisionTEC Debuting First 4K 3D Printing System

At formnext, 3D printer manufacturer EnvisionTEC debuted the industry’s first DLP-based 3D printer that uses a true 4K projector with UV optics tuned to the 385 nm wavelength. Available in three production-ready variations, with a gray body and a 2560 x 1600 pixel projector resolution, the Perfactory P4K 3D printer delivers highly accurate parts with an ultra-smooth surface finish. Additionally, the Perfactory P4K, has access to the rest of the Perfactory line’s versatile materials portfolio for production capacity.

“The P4K is the highest resolution advanced DLP printer with the largest build envelope and deploys artificial intelligence in pixel modulation to deliver the highest accuracy parts with the smoothest available surface finish in the 3D printing space. This will deliver the next level of production-grade 3D printing solutions,” said Al Siblani, the CEO of EnvisionTEC.

The new Perfactory P4K will be on display at formnext all week.

XYZprinting Introducing New 3D Printing Materials

Another company introducing new materials at formnext this week is desktop 3D printing brand XYZprinting. In order to expand the capabilities of both domestic and professional grade 3D printers, the company is launching a new antibacterial PLA material, along with copper metallic PLA and Carbon PLA materials. The first of these can destroy up to 99% of bacteria, including E. coli and Staphylococcus aureus, and comes in four colors: white, red, yellow and neon green.

The copper metallic PLA, made of 65% copper powder, is a good alternative for hobbyists when it comes to sculpting metal for ornamental models. The material is being launched in conjunction with XYZprinting’s new nozzle, made of carbon hardened steel. Finally, the new Carbon PLA, which is also compatible with this new nozzle, is made of 10% carbon fiber, and its matte finish is ideal for showing off fine details. You can learn more about these new materials at XYZprinting’s booth D10 in Hall 3.1, where it will also be exhibiting its latest 3D printer, the da Vinci Color AiO, with a 3D scanner and optional laser engraver.

BASF 3D Printing Solutions Presents New Products at formnext

Germany-based BASF 3D Printing Solutions GmbH (B3DPS), a 100% subsidiary of BASF New Business GmbH, is also at formnext this week, to introduce several new materials for photopolymer and laser sintering methods, in addition to announcing some new partnerships and alliances. First, B3DPS is introducing flame-resistant Ultrasint Polyamide PA6 Black FR, Ultrasint PA6 Black LM X085, which is suitable for most current SLS 3D printers, and Ultrasint PP, a polypropylene with great plasticity, low moisture uptake, and resistance to liquids and gases. Additionally, B3DPS has also grouped its photopolymer materials under the new Ultracur3D brand name.

András Marton, Senior Business Development Manager at B3DPS, said, “Our Ultracur3D portfolio enables us to offer customers various UV-curable materials for 3D printing that provide far better mechanical properties and higher long-term stability than most available materials.

“These materials have been developed for functional components that are subject to high stress.”

The subsidiary also announced that it’s partnering with California company Origin and 3D printer manufacturer Photocentric to develop photopolymers and photopolymer 3D printing processes, and working with Chinese 3D printer manufacturer Xunshi Technology, which operates in the US under the name SprintRay, to open up new applications for the Ultracur3D range. Additionally, B3DPS subsidiary Innofil3D is partnering with Jet-Mate Technology in China and US-based M. Holland to distribute plastic filaments. Visit B3DPS at formnext this week at booth F20 in Hall 3.1.

DSM Announces 3D Printing Product Launches

Vent cover used for PIV windtunnel testing, printed in Somos PerFORM Reflect

In today’s final formnext news, science-based company DSM has unveiled two new high-performance materials for 3D printing structural parts. Somos PerFORM Reflect is a groundbreaking new stereolithography material for wind tunnel testing with PIV (Particle Imaging Velocimetry), and saves more than 30% post treatment cost by eliminating the need to apply PIV coatings to printed parts. In addition to helping customers conduct iterations and collect data more quickly, the resin could actually help break speed records for wind tunnel testing.

“Speed is crucial, whether in automotive, aerospace or other transportation design. Eliminating the need to apply PIV coatings is a major breakthrough for customers who are using PIV wind tunnel testing. It allows them to speed up their aerodynamic design optimizations. We are thrilled that our strategy of focusing on helping customers create their applications have enabled us to deliver such tremendous value. Overnight, Somos® PerFORM Reflect will not just set new speed records but new industry standards,” said Hugo da Silva, Vice President of Additive Manufacturing at DSM.

The company’s second new material is the thermoplastic copolyester (TPC) Arnitel ID2060 HT, which is perfect for the FDM 3D printing of structural parts for automotive applications. The material features a balance of prolonged high temperature resistance, flexibility, and chemical resistance against exhaust gas recirculation (EGR) condensate.

Imerys Ceramics Introduces EZ Print 3D Range of Ceramic Feedstocks

As part of the Imerys group, Imerys Ceramics designs, produces, and markets high-performance mineral solutions for the ceramic industries, and is making ceramic 3D printing easy with its new, unique range of ceramic materials called EZ Print 3D.

EZ Print 3D is available as a plug & play cartridge, so users can enjoy efficiency and ease of use when it comes to 3D printing. The materials are also available as a “ready to fill” ceramic feedstock, and have been tested on several 3D printers currently on the market. EZ Print 3D has a low firing temperature of 1220°C that’s compatible with most kiln temperature limits, and the genuine low porosity (<0,5%) of a porcelain. The technology is perfect for tableware and giftware applications, and the company plans to expand EZ Print 3D accordingly as 3D printing adoption grows. Imerys Ceramics also provides technical support and a dedicated team that’s competent in 3D printing to help customers.

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3D Printing News Briefs: November 9, 2018

Buckle your seat belts, because we’ve got a of news to share with you in today’s 3D Printing News Briefs, starting with more event announcements and moving on to several new partnerships, a workshop, and a 3D printing project. Nanogrande introduced its new 3D printer for nanometer metallic particles at Fabtech this week, while Sartomer and Nanoe are launching new 3D printing innovations at formnext. Creatz3D is working to accelerate ceramics 3D printing in Singapore, while partnerships were announced between Valuechain and Clad Korea, PostProcess and Rösler, and Additive Manufacturing Technologies and Mitsubishi Electric. Finally, two Fraunhofer Institutes are hosting an AM materials workshop, and a maker from YouTube channel Potent Printables is sharing a new project.

Nanogrande Introduced First 3D Printer for Nanometer Metallic Particles

At FABTECH 2018 in Atlanta this week, Nanogrande officially introduced its new 3D printer. The MPL-1, enabled with the company’s Power Layering Technology, is actually the first nanoscale 3D printer for metallic particles in the world, and could successfully open up new 3D printing horizons. Nanogrande has spent years working to develop the new 3D printer.

“Power Layering, while maximizing particle compaction, allows MPL-1 to use particles of all shapes, sizes and types. With this approach, we can easily print with particles as small as a nanometer, but also particles of 5 microns, what the industrial sector is currently seeking. At this size, the particles stick to each other, virtually eliminating the need for support structures typical to 3D printing. In this way, there is a considerable reduction in post- printing costs,” said Juan Schneider, the President and Founder of Nanogrande.

“Today we are witnessing the culmination of a long process of research and development that has given us the chance to set up a team that generates many innovative ideas. Alone, it is possible to have excellent ideas; but, as a team, we can bring these ideas to life. I am very pleased to highlight the success of the efforts of the people who work for Nanogrande.”

Sartomer Europe Introducing New UV-Curable Resins

At formnext in Frankfurt next week, the European division of specialty chemical supplier Sartomer, a business unit of Arkema, will be launching new products in its N3xtDimension line of UV-curable engineered resins as part of its new commercial 3D printing-dedicated platform. The new materials will help companies fulfill performance and regulatory requirements for multiple industrial applications, thanks to their excellent tunability and mechanical properties. At its booth H58 in Hall 3.1 at formnext, Sartomer will introduce N3D I-2105, with impact resistance for manufacturing functional parts; N3D-F2115, which can achieve varying levels of flexibility depending on post treatment; and N3D P-2125, which is perfect for prototyping with its homogeneous network and limited evolution of mechanical properties after post-curing is complete.

“We are addressing the needs of demanding and innovative 3D printing markets by partnering with global leaders to deliver custom material solutions for end-use applications. Through our range of products and services dedicated to additive manufacturing, we are supporting the 3D printing sector as it grows and continues to develop new applications,” said Sumeet Jain, the Global Director for 3D Printing Business at Sartomer.

Nanoe Launches Ceramic and Metal 3D Printer

In other formnext news, French company Nanoe, which is a leader in high-tech raw materials and also specializes in ceramics 3D printing, will be introducing its new Zetaprint system for desktop 3D printing of ceramic and metal materials. The team will perform a live demonstration of the 3D printer at the event, and explain the full 3D printing, debinding, and sintering process.

Additionally, the company will be launching its new stainless steel 16L Zetamix filament. These filaments, made up of a ceramic or metal powder and a polymer matrix, can be used to make high density parts in any FDM 3D printer.  Nanoe, which is also developing materials in Inconel and titanium, will also soon be launching a complete line of adapted FDM 3D printers. Visit the company at booth A74 in Hall 3.0 next week at formnext to see a live Zetaprint demonstration and 3D printed parts in various Zetamix materials.

Creatz3D Accelerating Ceramics 3D Printing in Singapore

Speaking of ceramics, Creatz3D Ceramics Service Bureau is dedicated to 3D printing ceramics parts. Founded last year, its parent company is Singapore-based 3D printer and AM software solutions seller Creatz3D, which partnered with 3DCeram Sinto in Limoges to create the service. This partnership, signed in 2016, facilitated the first installation in Singapore of 3DCeram Sinto’s Ceramaker 900 Ceramic 3D printer, at the Advanced Remanufacturing Technology Centre. The Creatz3D Ceramics Service Bureau, which offers diverse material options and a hassle-free experience, is the first, and only, ceramics-focused 3D printing service in the country, and is helping to increase awareness and adoption of ceramics for 3D printing.

“The addition of ceramics to Creatz3D’s portfolio ensures that they stay ahead of the pack in the competitive 3D printing landscape, and their expertise can demonstrate the game-changing capabilities that the technology has to offer to help advance design, engineering, and manufacturing,” said Sean Looi, the General Manager of Creatz3D.

Valuechain Signs Strategic Partnership with Clad Korea

British technology company Valuechain reports that it has signed a strategic partnership with manufacturing company Clad Korea, in order to digitalize 3D printing in East Asia. Both companies will be able to grow their association together in the initial agreement, in addition to bringing Valuechain’s solutions, including its flagship DNA am production control software, to the East Asian AM marketplace. This software addresses 3D printing production process niche requirements, like powder traceability and managing AM build plans.

“Valuechain’s DNA am technology is a unique offering to the market, with great potential to enable rapid and mass production of additive manufactured parts. As we look to enter the additive manufacturing market ourselves, we believe this product will give us a competitive advantage in the industry, and we’re excited to be able to contribute to the growth of this technology in Asia by helping to deliver this solution throughout South Korea,” said Brandon Lee, the CEO of Clad Korea Co. Ltd.

PostProcess Technologies Partnering with Rösler

Moving on with strategic partnerships in the 3D printing world, PostProcess Technologies Inc., a pioneer of software-drive 3D post-processing solutions, is working with Rösler Oberflächentechnik GmbH, which sells finishing systems for traditional manufacturing, to bring automated, intelligent post-print solutions to Europe. Rösler will provide PostProcess’ data-driven support removal and surface finishing solutions for 3D printing to the European market, making it the only surface finishing supplier that will be providing solutions tailored to the needs of both traditional and additive manufacturing. The two companies will debut their partnership next week at formnext, with PostProcess’ technology on display in its booth H68, as well as Rösler’s booth E20, both of which are in Hall 3.0.

“The additive space is rapidly growing, especially in Europe, and as such, the demand for an automated post-printing solution is accelerating. Rösler is a unique partner for PostProcess, bringing expertise in finishing systems with a broad European footprint, thousands of existing customers, and a strong presence across a range of industries that will greatly benefit from PostProcess’ proprietary and integrated software, hardware, and chemistry solution,” said Bruno Bourguet, the Managing Director for PostProcess Technologies.

Additive Manufacturing Technologies Announces Partnership with Mitsubishi Electric

Sheffield-based Additive Manufacturing Technologies Ltd (AMT) has entered into a partnership with Mitsubishi Electric in order to further develop its PostPro3D system with an integrated automation solution, which could provide a major productivity boost for 3D print post-processing. This new solution is based on Mitsubishi Electric’s MELSEC iQ-F Series compact PLC, HMIs, SCADA and MELFA articulated arm robots. While PostPro3D is already pretty impressive, with its ability to automatically smooth an object’s surface to 1μm precision, AMT wanted to further develop the system with certified automation products so it would be suitable for Industry 4.0. Now, PostPro3D is equipped with a Mitsubishi Electric power supply and low voltage switchgear, servo drives and motors, FR-D700 frequency inverters and the optional six-axis robot arm.

“To realise our concept, we needed an automation partner that could provide the whole range of machine control systems, as well as the actual robotics. This is fundamental to truly integrate our machine into the production line of the future as well as to benefit from a lean, single vendor distribution model,” explained Joseph Crabtree, CEO at AMT.

“Mitsubishi Electric was the clear choice because it offers a one stop shop for state-of-the-art automation solutions. In this way, we can be sure that the different components are compatible and can share data. Overall, the company can offer us products that adhere to UL, CE as well as Industry 4.0 requirements.”

Fraunhofer AM Materials Workshop 

On November 29 and 30 in Dresden, Germany, Fraunhofer IKTS and Fraunhofer IWS are holding a workshop called “Hybrid materials and additive manufacturing processes.” The two institutes are working together to organize the workshop, which will be held in English and discuss innovative technologies for 3D printing metallic and ceramic components, in addition to application-specific manufacturing of material hybrids. Participants in the workshop’s practical insight sessions will be able to see diverse AM devices for multimaterial approaches live and in action.

“Why is that interesting? Additive manufacturing technologies for material hybrids open up new possibilities in production for diverse industrial branches,” Annika Ballin, Press and Public Relations for Fraunhofer IKTS, told 3DPrint.com. “It is not only possible to realize complex geometries, but also to functionalize components (sensors, heaters), to individualize production (labeling, inscriptions) and to combine different materials properties in one component (conductive/insulating, dense/porous etc.).”

The workshop, which costs €750, will be held at Fraunhofer Institute Center Dresden, and registration will continue until November 22.

DIY 3D Printed Linear Servo Actuators by Potent Printables

A maker named Ali, who runs the Potent Printables YouTube channel, recently completed a neat design project – 3D printed linear actuators. Ali, who was partly inspired by a Hackaday post, said that the project has received a great response on both Twitter and Instagram. He designed the parts in SOLIDWORKS, and controls them with an Arduino Uno. The simple rack-and-pinion design, perfect for light loads, comes in two sizes for different space constraints and force outputs.

“Each design has a pinion that has to be glued to a servo horn, and a selection of rack lengths to suit your needs,” Dan Maloney wrote in a new Hackaday post about Ali’s project. “The printed parts are nothing fancy, but seem to have material in the right places to bear the loads these actuators will encounter.”

Check out the video below to see the 3D printed linear actuators for yourself:

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Titomic Provides A Closer Look at New Metal 3D Printer, and Its Unique Kinetic Fusion 3D Printing Process

Less than a year ago, Australian industrial 3D printing company Titomic introduced its innovative Kinetic Fusion process for the first time. Since then, the company has been busy commercializing the technology with various MOUs and other agreements, and was able to secure patents for Kinetic Fusion in both Australia and the US. All of this activity culminated in May, with news that the company had introduced a new metal 3D printer, said to be the largest and fastest in the world. Now, the world is finally getting a closer look at Titomic’s new machine…and its unique technology.

Jeffrey Lang, the Founding Director and CTO of Titomic, told Manufacturers’ Monthly, “We are challenging the traditional core of manufacturing.

“While most metal printing processes use an electron beam laser to melt the metal, there is no melting involved in our process. Therefore there are no heat-related distortions and the materials retain their properties.

“This also means that we are not limited by size. Because melting metals in the conventional 3D printing processes causes them to oxidise, the conventional metal 3D printing needs to take place inside a vacuum chamber. Lack of melting in our process means that we are not limited by size.”

Titomic’s Kinetic Fusion process involves a 6-axis robot arm spraying titanium powder particles onto a scaffold at supersonic speeds.

Titomic’s new metal 3D printer has a build area that’s 9 m long by 3 m wide and 1.5 m high, though it’s not constrained to booth size and requires no gas shielding. The company’s Kinetic Fusion process sprays titanium powder particles at supersonic speeds of about 1 km per second, using a 6-axis robot arm, onto a scaffold. These particles move so fast that when they collide on the scaffold, they fuse together mechanically to produce huge, load-bearing 3D forms.

Kinetic Fusion is also far faster than other forms of 3D printing.

“Depending on the complexity of the metal parts, we can deposit between 20-45 kilograms of metal per hour. That’s just with one spray head. We are working on a new system where we could operate a series of robots that connect multi- head robots. That would enable us to deposit up to 200 kilograms of material per hour,” Lang said.

“To put that into perspective, the normal 3D printers can usually deposit about one kilogram in 20 hours. So we are really bringing volume into the additive manufacturing market.”

Titomic’s 3D metal printer.

This unique technology resulted from a Commonwealth Scientific and Industrial Research Organisation (CSIRO) study, at a time when the country’s government was looking to capitalize on its titanium resources.

“The Federal Government did a IndustryFOCUS including putting linings on jet study in 2007 with this idea that while Australia is not a large resource of titanium, we have a large amount of mineral sands that contain titanium,” Lang explained. “The government wanted to find ways to utilise that resource instead of just selling it off, like we always do in Australia.

“I was invited to be a part of the project and look at the ways by which we could use large volumes of titanium powder. We started thinking about how to develop titanium powder from that vast resource and build a whole industry around it.”

Lang and his colleagues were finding that current AM methods were too restrictive for industrial-scale projects…and then they found the cold spray coatings process, which was developed in Russia 30 years ago for high-level metal coatings for aerospace engines; the method was also used in Asia to fabricate high-quality frying pans with copper-coated bases and scratch-proof rice cookers.

Lang said, “What no one had realised was the potential applications of the process in additive manufacturing.

“We haven’t found any scientists who can clearly explain the theory behind the process, but the technique is currently being reviewed at the army labs in the USA. The US Army has already validated the process for doing aluminium repairs on aircraft wings, etc. There are also a couple of big global companies using the technology for defence applications.”

Titomic founding director and CTO, Jeffrey Lang, and Titomic chairman, Philip Vafiadis, at the launch of Titomic’s 3D metal printer in Melbourne.

Together with Professor Richard Fox, Lang began working on how to build a 3D object by incorporating cold spray onto a scaffold, and the two co-inventors asked that CSIRO patent and licence the innovative technology to Force Industries, its composite sporting goods company. Thus, Titomic was founded four years ago and owns the exclusive rights to commercialize the proprietary process.

“These are exciting times. We started the whole project with the view of developing sovereign capabilities for Australia,” Lang said. “But the technology does not benefit just one country. It’s about securing a better future for all humanity and future generations on this planet.”

The technology does need to go through a validation process before being used in industries like aerospace, but the company is also working to 3D print parts for other industries, like defence, sports equipment, mining, and shipbuilding.

“The shipbuilding industry is currently using 50-year old technologies. Nothing much has changed in that area over the past years,” Lang explained. “Our machine can be installed on a gantry system to coat the whole hull of the ship. That shows the significant scale of what we can do.”

The technology is also not strictly limited to 3D printing and could be used to create advanced composite materials by fusing together dissimilar materials, or in the seamless coating of large industrial parts.

“Probably the most exciting advantage of Titomic Kinetic Fusion process is that it enables us to fuse dissimilar materials that could not be fused in any other way,” said Lang. “This puts us at the forefront of pioneering new smart materials that can be specifically designed for different components and parts.”

Lang believes that early adopters in any industry, but especially aerospace, can save on time and material waste with its Kinetic Fusion, in addition to gaining a competitive advantage. The aviation sector is one of the largest customers of titanium alloy products, and according to Lang, Airbus, one of the bigger fans of 3D printing in the industry, loses 50 tons of raw titanium each day to produce only 8 tons of traditionally manufactured parts…a materials loss of about 90%.

“If we could make those parts as near net shape components, that is to create the final shape of the part and then add just a little bit extra burden of the material on it, we could reduce that machining time in some instances by 80 per cent,” Lang said.

“We are not saying this technology can jumpstart now and replace the current aerospace process. But our process is currently one of the most significant processes that those aerospace companies are looking at. We have come up with additional solutions to remove a small amount of porosity to achieve aerospace grade.

“For one of the aerospace components, which can be up to $4 million in cost, we can reduce production time from 200 hours down to 6 hours.”

That’s why Titomic is currently working with a few Tier 1 aerospace companies that are interested in developing carbon fiber parts with a middle structure made of titanium.

However, Lang also says that, while 3D printing titanium is useful for making complex parts, the price will eventually start to go up and match conventional methods of manufacturing.

“The nitrogen and electricity costs for running the machines are not very high,” Lang said. “Our biggest cost restriction at the moment is the cost of metal powders. Titanium powder can be prohibitive for high volume, low value industries.”

But, as we continue to develop more applications for titanium and the demand increases, he believes the cost will go back down.

“When you look back at 150 years ago, the most expensive material in the world was aluminium. And that is now only $2-3 per kilogram,” said Lang. “Things change based on demand. The demand for titanium powder in Australia hasn’t been great until Titomic came along. Now we are in the position where we are securing the supply chain from larger suppliers.”

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