DuPont to launch multiple new semi-crystalline products for 3D printing at RAPID + TCT 2019
DuPont Transportation & Advanced Polymers, a global business unit of DowDuPont Specialty Products Division, will introduce several advanced new semi-crystalline materials at RAPID + TCT 2019 (booth #552), significantly expanding its 3D printing portfolio.
These high-performance materials will offer customers greater manufacturing agility by enabling a seamless transition across different 3D printing scenarios while maintaining consistent properties. They will also open new opportunities to scale up and accelerate production while reducing costs.
Jennifer L Thompson, PhD, Research and Development Programs Manager for DuPont Transportation & Advanced Polymers, will present a technical paper on these new materials during the RAPID + TCT conference.
Her presentation, titled 'High Performance Materials for 3D Printing' will take place on Thursday 23 May at 10:15 am EDT as part of the Material Development and Characterization session.
Thompson will highlight new engineering materials for industrial use, describe alternative 3D printing methods such as pellet extrusion modelling and discuss tailored testing programs for printing materials.
At its booth, DuPont will exhibit automotive ducts and structural components, and a variety of other 3D-printed parts showcasing the diversity and capabilities of its new materials. RAPID + TCT 2019 will be held at the Cobo Center in Detroit, Michigan, between 21 and 23 May. Thompson and other members of the DuPont team will be available during the conference to answer questions about the company's fast-growing portfolio of materials for 3D printing.
India's first mid size single extruder 3D printer with a unique gantry design
Aeqon 400 V3 is India's first mid size single extruder 3D printer with a unique gantry design for easy 3D printing of mid size prototypes, according to its manufacturers divbyzero technologies.
Aeqon 400's low-noise operation, quick-load functionality, super-fast slicer and industrial-grade build quality ensure reliable print-cycles. With specially designed high precision ball screws gantry along with print speed upto 200mm/sec, this 3D printer delivers unmatched precision and repeatability - a prerequisite in rapid prototyping and low-volume batch manufacturing. Superior features like USB and Wi-Fi allow seamless connectivity and the built-in camera allows remote monitoring of print batches. With a unique build volume and an easy-to-use interface, the Aeqon 400V3 is an ideal prototyping machine for product development applications, says the manufacturers
Features of Aeqon 400 V3
1. Future Proof
These machine can grows with the increasing business opportunities. One machine or multiple machines, all AEQON 400V3 machines can be connected through WI-Fi, Ethernet and USB and can be accessed through web browser on the desktop with access to live camera feed of the print and queue the next prints for the operator who has limited machine access if so programed.
2. Fast - 2X Deposition Rate
The advanced extruder design ensures minimum heat creep in the mechanism thanks to the unibody machined extruder that enables to print with 2x deposition rates. Active filament sensor provides alert upon material flow interruption filament consumption, thus saving valuable time and material, ensuring uniform flow during part build.
3. 35% - Small Footprints
Save upto 35% space with unique design that lets one enjoy similar build platform with huge saving on machine foot prints.
4. High speed Z axis - dual ball screw
Their development team has come up with unique dual pre - loaded ball screw mechanism in Z axis to ensure vibration free high precision, high speed operation of the machine. It achieves 25% to 40% better speed without compromising on quality contrary to traditional cantilever gantry mechanism.
5. Versatile - multiple material on one machine
Various print materials like carbon fibre, ABS, Polycarbonate, Polyurethane can be used on the same machine, due to the advanced extruder mechanism design that can handle various abrasive materials, variable flow and temperature. One can also print flexible, high strength, temperature resistant materials in the same machine with almost zero setup time.
Further information from Divide by Zero Office No. 3 & 4, Ground Floor Building No. 3, Sector 3 Millennium Business Park, Mahape, Navi Mumbai - 400710 Phone : +919167943604 / 02262392181 Email : email@example.com
AREVO 3D printing the carbon fiber Emery One eBike frame
Arevo, the Silicon Valley based firm will be 3D printing the carbon fiber eBike frame and the eBike will be sold under the Emery Bikes brand as the Emery ONE and that they've partnered with Franco Bicycles, a specialty bike manufacturer in California, to bring the Emery ONE to the public.
The frame is 3D printed as a single, solid body using Direct Energy Deposition (DED) and a multi-axis robotic motion system. Since it's carbon fiber, it's five times stronger and three times lighter than titanium, making it an ideal material for a bike frame where strength and weight are important. Using 3D printing also enabled faster iterative designs for the frame, cutting the development time from 18 months to just a few days.
“We chose AREVO technology because its iterative and flexible design represents the new age in composites manufacturing, and we wanted to be the first bike company to help lead this revolution,” said Hector Rodriguez, Co-Founder of Emery Bikes. “AREVO's continuous carbon fiber technology has been instrumental in achieving the ride quality and high-performance requirements we set out to accomplish with the Emery ONE.”
AREVO is manufacturing the frames in Milpitas, California, but interested parties could see the prototype Emery ONE at the Sea Otter Classic cycling event in Monterey, Booth S9 until April 14th. “This is the first Composite additively manufactured bike frame and it represents an important milestone for the AM industry as AREVO is delivering on the promise of on-demand manufacturing of composite parts in volume now,” said Hemant Bheda, AREVO Co-Founder and Chairman. AREVO's technology was designed for industrial fabrication, and they do produce jigs and fixtures for other clients, but those parts are visible only to industry insiders. By 3D printing a bike frame for the masses, AREVO is bringing more attention to the manufacturing capabilities of 3D printing.
3D Printed footwear market forecasted to reach $5.9 billion by 2029
Research and Markets recently published a report on the growing 3D printed footwear market that predicts the global market will grow at a CAGR (compound annual growth rate) of 19.5% to nearly $6 billion over the coming decade. That number would represent 1.5% of all footwear revenues in 2029, indicating that the footwear industry is beginning to adopt 3D printing technologies at an increasing rate.
The Adidas Shoe – Production by Carbon3D
Mass adoption of mass customization
Much like the dental segment, the footwear segment is specially poised to benefit from the mass customization and personalization of products enabled by 3D printing. More and more research is telling us that every person's feet are different, even the two feet of the same person. Only 3D printing can provide bespoke footwear at a cost that's affordable, and industry players like adidas, Nike, New Balance, and Under Armour are catching on to that fact. Those shoe manufacturers are partnering with 3D printing experts such as 3D Systems, Stratasys, Carbon, and ScientiFeet to begin offering various personalized footwear products.
Ammonite – Design by Fernando Romero. Production by 3D Systems
Additionally, 3D scanning and data capture devices are being developed and rolled out to generate the necessary biometric and topographic information.
From rapid prototyping to advanced manufacturing
Prototyping with 3D printing is already the norm in the footwear industry, though its use is expected to continue to grow. Faster growth is anticipated in 3D printed end-use parts, including insoles, midsoles, and uppers. Personalization isn't the only driver for this shift as increased performance and comfort are also achieved through 3D printing. The internal geometry of an insole can have a big impact on its spring and cushion, so engineers are pushing their manufacturers to integrate 3D printing technologies. Final parts already represent 34% of all 3D printed footwear revenues so adoption is clearly accelerating. Midsoles are forecasted to represent the majority of future revenues, followed by insoles. Stereolithography (SLA/DLP) vat photopolymerization systems are currently the preferred technology for 3D printing footwear, but powder bed fusion and voxeljet technologies will likely take some of the market share as they're more ideal for mass production.
ACEO launches U.S. based open print lab
WACKER, the Munich based chemical company, has launched its first U.S. based ACEO Open Print Lab. The new facility, located at WACKER's Silicone R&D facility in Ann Arbor, MI, is equipped with 3D printers able to process a broad range of silicone rubber with different Shore A hardnesses and in varying colors. Following the success of WACKER's ACEO Open Print Lab in Burghausen, Germany, and the high demand for additive manufacturing solutions in North America, the print lab will offer first-hand tutorials and hands-on training allowing customers to experience 3D printing with silicone rubber. “We are pleased to announce another milestone in ACEO's history with the launch of the Open Print Lab in Ann Arbor,” says Dr. Bernd Pachaly, Head of Project 3D Printing at WACKER SILICONES. “North America is one of the leading markets in additive manufacturing.Our new facility brings 3D printing with silicones much closer topotential customers in the region.” In 2017, WACKER set up its first ACEO Open Print Lab in Burghausen. It helps customers understand how 3D printing with silicones matches their needs by offering first-hand experience. WACKER introduced the world's first 3D printing web shop in 2016, making ACEO technology and services available to customers worldwide. However, education about a pioneering technology such as ACEO needs a local presence. “Our business partners in the region want to understand how their ideas and products can be brought to market with our support. WACKER's Silicone R&D Center in Ann Arbor was designed to develop advanced and forward-looking solutions for silicones. With the new Open Print Lab we can significantly expand our local portfolio and contribute to the growing demand of the market,” says Ian Moore, Vice President WACKER SILICONES at Wacker Chemical Corporation in Adrian (MI). The new Open Print Lab is headed by Lab Manager Sarah Burke, who previously worked at the Silicones R&D Center in fundamental product research for construction applications and consumer care. The lab will be equipped with two 3D printers, each of which will be able to process a broad range of silicone rubber with different Shore A hardnesses and in varying colors. ACEO's unique additive manufacturing technology for silicone elastomers enables unprecedented product designs and complex geometries for rapid prototyping purposes. It is also suitable for serial manufacturing and cost-efficient production of replacement parts. WACKER's 3D printing technology ACEO is the world's first industrial-scale technology for the additive manufacturing of liquid silicone rubber components. The ACEO team will also offer workshops open to small groups of up to four people. After signing up, customers and the team will be able to define dates, expectations and goals of the workshop. Participants will go through personalized trainings, consisting of theoretical and printing sessions from additive manufacturing basics to advanced design.
Interested parties such as existing and prospective WACKER customers can register for a tailor-made Open Print Lab training at the ACEO Campus in Ann Arbor, MI, at www.aceo3d.com/openprint-lab/.
Evonik celebrates 40 years of PEBA
In 1979, Evonik launched the thermoplastic elastomer polyether block amide (PEBA) under the brand name VESTAMID E from its largest global production site in the Marl Chemical Park. Whether in sports equipment, hydraulic pressure lines in trucks, medical devices or 3D printed high-tech parts, Evonik's polyamide 12 elastomers kept finding their way into new demanding applications over the past four decades. Right from the beginning, the high-performance polymer has stood out for its excellent low-temperature impact resistance, chemical resistance, high elasticity and good resilience. It was easy to process, dye or over-mold. From the beginning, the thermoplastic material offered a uniquely balanced property profile that enabled design-free implementation of demanding applications.
PEBA powder for 3d printing
With over 20 years of expertise in additive manufacturing technologies, Evonik is now a global leader in the development and production of customized polymer powders for various 3D printing technologies. The specialty chemicals company has developed the world's first flexible synthetic material based on polyether block amide for use in 3D printing. The new high-performance powder stands out for its high elasticity and strength and is suitable for a variety of powder-based 3D printing technologies.
PEBA – the material of choice for the sports industry
Performance and design are key attributes for the sports industry. The PA 12 elastomer molding compounds of Evonik quickly became the material of choice for items such as athletic shoes, ski, touring and hiking boots or later, decorative protective films for skis and snowboards.
Ski or hiking boots made of PEBA have remained lightweight, waterproof and wear-resistant to this day. They retain their flexibility even in cold conditions. Thanks to its excellent mechanical properties, the high-performance material can efficiently determine the wall thickness of shoes, which allows for optimizing production costs.
“Our PA 12 elastomer is extremely lightweight thanks to its low density. In comparison with other sole materials, this would eliminate about 100 kg of weight for a player to carry around in the sum of his steps during a 90-minute soccer match. That saves energy and increases endurance,” says Klaus Hülsmann, plastics expert in the Consumer Goods market segment of Evonik.
PA 12 elastomers for medical technology
Nowadays, flexible polymers that also comply with high quality standards are used, among other applications, in the demanding field of medical technology. Over the years, the experts at Evonik have developed and optimized flexible polyamide 12 elastomers in a wide range of hardnesses for use in medical technology, which were successfully launched under the product name VESTAMID Care ME. Evonik has developed custom-tailored polyamide 12 elastomers for demanding applications for 40 years. The product keeps reinventing itself, be it for new supply formats or through lateral entry into new markets – including a short application stint in the mid-1980s for low-noise gears installed in cassette recorders. PEBA is a true quick-change artist among thermoplastic materials. Relying on decades of experience with polymer design and numerous successful customer projects, the experts at Evonik keep researching to continuously expand the property profile of the flexible high-performance polymer.
Further information from: www.vestamid.com/product/vestamid/en/Pages/40-years-of-peba.aspx
Arrow Digital installs Massivit 1500 3d printer
Arrow Digital has recently installed Massivit 1500, the largest, fastest and most advanced large format 3D printing solution for visual communications, at its demo centre based in Ahmedabad. Based on its proprietary GDP (gel dispensing printing) technology that enables instant solidification and high-speed printing, the Massivit 3D is the next revolution in advertising after digital printing. According to Sam Patel of Arrow Digital, the Massivit 3D has become an eye-catching product at the demo centre, attracting customers. “In India, 3D technology has never been so huge and creative. We are sure this will bring a revolution and will raise the standards of marketing,” Patel said. With output speeds incomparable to anything else in the 3D printing industry, the Massivit 1500 printer can produce high quality 3D pieces up to 54-inches high. Another model, Massivit 1800, can produce high quality 3D piece up to 70-inches. Print providers seeking to dramatically extend their product portfolio beyond 2D printing now have the access to a profitable new and unique application capability, and an important business differentiator to enhance their competitive edge and secure their future. Massivit 3D offers a portfolio of large-format 3D printers that leverage patented, high-speed additive manufacturing technology to serve multiple industries including visual communications, entertainment, events and exhibitions, interior design, and concept prototyping. “The Massivit 1500 also utilises techniques that allow it to print non-vertical walls and ceilings, without the need to produce a solid object or intensive support structure. So the Massivit 1500 is able to dramatically increase print speed, while also reducing material costs and product weight — crucial for additional materials handling, transportation and storage benefits,” Patel added. He said with the Massivit 3D, a print provider can start offering its current customers the benefit of super-size 3D displays. “The Massivit 3D printed elements will turn any booth, event or show lively and will do pops up, engage and entertain viewers,” Patel said.
ESJET printing technology for large area active devices awarded
ESJET printing is a new printing technology for large-scale, solution-processed displays of the future. It enables higher hresolution and drop on demand printing. The Potsdam Fraunhofer Institute for Applied Polymer Research IAP, together with its project partners imec and TNO/Holst Centre, has developed this printing technology for solution-processed displays of the future. The Fraunhofer Institute for Applied Polymer Research IAP, imec and TNO/Holst Centre have been awarded with the Best Institute / Academic R&D Award at IDTechEx Printed Electronics 2019.
ESJET printed active matrix 0,5‘‘ display with 10 µm pixels and a 300ppi resolution.
The award is granted for “significant contribution over the past 24 months to the understanding of the principles and accrued knowledge behind printed electronics”, the guidelines state. Dr. Richard Collins, Senior Analyst at IDTechEx, presented the award on April 10th, 2019. Within the EU project, Hi-Response, 13 consortium members are working together to develop a highly innovative Pulsed Electro-Static Printing Technology for high resolution printing for different applications. Within Hi-Response, the researchers of the Fraunhofer IAP, imec and TNO/Holst Centre have developed high-resolution ESJET (electrostatic jetting) printing for conductive and emissive polymers, which opens up new possibilities for various applications. The technology has the potential to be implemented for high-resolution printing of AM OLEDs with pixel sizes below 10 µm yielding in RGB resolutions beyond 500 ppi. This technology - being scalable - enables large area printing of active devices. Furthermore, the ESJET can deposit a much wider range of viscosities from 1 to 10,000 cP, compared to 1-40 cP for inkjet printers.
The advantages of the technology of ESJET printing
“With ESJET, we are able to significantly reduce pixel sizes for printed AM OLEDs”, Dr. Christine Boeffel, project manager at the Fraunhofer IAP says. “One of the remarkable things about the technology is that even at pitches of 25 µm, pixel sizes down to 10 µm are printable. For our demonstrator we printed 62967 single 10 µm wide dots to make a working display with a 300 ppi resolution.” Imec and TNO/Holst Centre developed AM OLED backplanes and provided them to the Fraunhofer IAP for processing of the OLED front plane. High-resolution ESJET printing was implemented for the deposition of the PEDOT:PSS hole injection layer consisting of the print of 62967 single 10 µm wide dots on the 0.5 inch wide active matrix backplane. The subsequent layer of the emitting material was processed by spin coating followed by thermal evaporation of the transparent electrode. “It is a great milestone to print OLED materials in such small dimensions. Improving in the printing resolution opens new possibilities for solution processed OLED display”, Dr. Tung-Huei Ke, senior researcher at imec says. “We have reached an important goal getting the technology of ESJET printing this far. We are convinced that pixel sizes can be reduced even further below the mark of 10 µm. We plan to print OLED materials for RGB display applications at 300 ppi in future projects”, Dr. Manuel Gensler, researcher for ESJET printing at the Fraunhofer IAP says. “With the display industry searching for new and innovative ways to increase display resolution as well as to include new user interfaces into the full display area, high-resolution printing technology is a key enabler to realize these goals by printing OLED materials as well as other functional materials at high resolution”, Dr. Auke Jisk Kronemeijer, GEN1 TFT Pilot Line Manager at TNO/Holst Centre says.
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