Darrel Fry, CEO of ABC3D, at the MIDAS Fab Lab. Image via MIDAS Fab Lab / Tracy Connery
22 Dec
Blog

Superior BioCarbon 3D develops engineering grade wood-based 3D printer filament

A Canadian bioplastics company, Advanced BioCarbon 3D (ABC3D), has developed wood-based bioplastics for 3D printing.

ABC3D was founded in 2016 and was chosen as one of the world’s top five hundred deep tech startups by Hello Tomorrow, a French tech accelerator. ABC3D’s mission is to develop sustainable carbon-free plastics for 3D printing to mitigate the deteriorating environmental situation.

ABC3D environmental scientist Kim Klassen stated, “If extreme weather events continue to occur, it will disrupt every part of society. Therefore, climate change is important above all to other environmental issues, and this is exactly what this company is addressing through product development and sustainable bioplastics made from renewable raw materials. “

“Our products are CO2 negative, which not only reduces the impact on climate change, but also helps to remove greenhouse gases from the atmosphere.”

Technical quality bioplastics

Although bioplastics are available in industry, the ultimate goal of ABC3D is to produce environmentally friendly bioplastics for technical applications. The company prides itself on the fact that its product is superior to other bioplastics made from renewable resources and is non-flammable and moisture-resistant.

Darrel Fry, CEO of ABC3D, said, “People often consider bioplastics to be single-use products with little functionality, but our products are incredibly highly functional, have exceptional heat resistance, and are lightweight at the same time. For example, our goal is to use this material to 3D print something like a piston for your car – it’s so heat-resistant and also very strong. “

Sustainable development

ABC3D’s bioplastic filament is made from scrap wood, so the company does not compete with forest companies. In fact, the wood used by ABC3D comes from poplar (or poplar) trees that are felled by forest companies during wood collection. And since there is no market for poplars, they stay in the forest.

The 3D printing filaments produced by ABC3D are a mixture of 60% plastic and 40% wood, which are mixed according to the method developed by ABC3D, in which resin is extracted from the waste wood. And the leftover wood is turned into a polymer. The resin is then added back to the plastic and this gives the material its heat-resistant and moisture-proof properties.

Classes explained the process, “The process uses green chemistry and starts with wood chips from the forest industry that are mixed with a solvent and subjected to a series of pressurized heating and cooling phases to extract the resin from the wood chips. All solvents from the manufacturing process are returned to the system for reuse. “

The biomaterial was developed with the help of a joint grant of US $ 300,000 granted to ABC3D and Selkirk College by a government-sponsored innovation cluster, Innovate BC.

ABC3D’s materials are currently being tested in the MIDAS (Metallurgical Industrial Development Acceleration and Studies) factory laboratory in Trail.

Darrel Fry, CEO of ABC3D, at the MIDAS Fab Lab. Image via MIDAS Fab Lab / Tracy Connery

ABC3D is currently scaling production to begin sales in Q1 2019. Fry said, “We aim to start sales of 3D filaments in Q1 2019 and then a range of different filaments with additional features such as carbon fiber reinforced filaments, conductive filaments, and filaments reinforced with other wood fibers through our first products which are mixed traditional printing filaments. “

“Our company proves that we can produce sustainable, economical and high-performance plastics from wood.”

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The picture shown shows wood samples from which the ABC3D filament was made. Image via MIDAS Fab Lab / Tracy Connery

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Evonik develops the "world’s first" PEEK filament in implant-grade quality for 3D printing
19 Dec
Blog

Evonik develops the “world’s first” PEEK filament in implant-grade high quality for 3D printing

Evonik claims it is the first company in the world to have developed a polymer filament based on polyetheretherketone (PEEK) in implant quality for use as a 3D printing material for implants.

This high-performance material can be used in FFF technology (Fused Filament Fabrication) and is intended to enable the additive manufacture of three-dimensional plastic parts for medical implants in the human body.

The new PEEK filament is based on Vestakeep i4 G, a highly viscous implant material from Evonik. The product, which has impressive biocompatibility, biostability and X-ray transparency, is easy to process and has for years established itself as a high-performance material for medical technology applications such as spinal implants, sports medicine and maxillofacial surgery.

Evonik will also offer a lower-cost version of its PEEK filament for FFF technology in test quality. The test material has exactly the same processing and mechanical product properties as the implant material – but without the documentation required for approval in applications for medical devices.

This offers a cost-effective way of adapting the processing properties of the high-performance plastic for printing processes. The natural colored filament with a diameter of 1.75 mm is wound on 500 gram spools, which are suitable for direct use in standard FFF 3D printers for PEEK materials. In the first quarter of 2019, the test quality will be followed by an implant grade of Vestakeep i4 G, which can be provided with the required extensive approval documentation.

The development of the world’s first PEEK filament expands Evonik’s existing range of polymer materials for 3D printing. The specialty chemicals company is the world’s leading manufacturer of polyamide (PA) 12 powders, which have been used in additive production technologies for over 20 years. In addition to PEEK filament and PA 12 powders, the material portfolio also includes flexible PEBA powders.

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Kuraray develops soluble 3D printing filament
17 Dec
Blog

Kuraray develops soluble 3D printing filament

Japan’s Kuraray has developed a 3D printing filament for use in FFF (Fused Filament Fabrication) additive processes. The water-soluble, biodegradable filament is based on the company’s Poval polyvinyl alcohol (PVOH) resin, which is commonly used in adhesives, paints and coatings, wood primers, paper and textile applications, cosmetics and emulsions, among others.

The material sold under the Mowiflex brand has excellent adhesion to other resins such as polylactic acid (PLA), polyamide (PA), polyvinyl butyral (PVB) and thermoplastic polyurethane (TPU). Mowiflex filaments can therefore be used as a carrier material for 3D printed products that contain undercuts, moving parts and other complex shapes. Mowiflex is soluble in cold water.

Cold water soluble PVOH 3D printing filament can be used as a carrier material for making products with undercuts.

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3D printing the preform and drawing the filament. Image via US Army.
12 Dec
Blog

U.S. Military develops excessive power multi-polymer filament to be used with low-cost 3D printers

New US Army Research has revealed a new multipolymer filament designed for use with low-cost FFF 3D printers. The high tenacity filament is expected to help in the battlefield and produce business critical parts in a timely manner at a fraction of the cost of traditional parts. The study was featured on the cover of the April issue of Advanced technical materials.

Multi-thermoplastic filament

FFF is the most widely used 3D printing technology today due to its low barrier to entry and relatively low cost. However, parts made with FFF tend to have no mechanical strength, so their use is generally discouraged in high-level field operations where they are exposed to harsh combat conditions. U.S. Army research is aimed at overcoming the limitations of readily available filament and instead creating something as sturdy as the warfighters that will use it.

The researchers combined ABS and polycarbonate (PC) to formulate their novel filament. A 3D printer was used to create a solid preform that consisted of a lower temperature ABS shell and a higher temperature star shaped PC core. A thermal draw tower was then used to feed the solid preform through diameter and tension sensors and convert it back to filament. This newly drawn filament was returned as a starting material, but this time as a mixture of ABS and PC, which gave it superior mechanical properties. To complete the process, parts that were 3D printed from the new filament were annealed in an oven for 24 to 48 hours to completely fuse the layers together for additional structural integrity.

The 3D printed parts came out of the heat chamber with ductilities comparable to injection molded ABS parts and fracture toughness values ​​1500% (15x) higher than those of identical ABS geometries. The researchers concluded that PC infusion helped withstand heat-induced creep and maintain accurate part dimensions during the annealing process. The team hopes to reduce the glow time to four hours or less in the future.

3D printing the preform and drawing the filament. Image via US Army.

Additive manufacturing in the field

Dr. Eric Wetzel, co-author of the study, explains that the army wants to print parts on site to simplify logistics. Moving digital files and raw materials eliminates the need to lug around excessive physical parts. Unfortunately, the technologies for 3D printing high-strength parts in an expeditionary environment have not been practical. The printers are too big, use too much power to operate, are quite delicate in construction, and their raw materials require special storage conditions.

Jeff Wallace, mechanical engineer at the Army’s C5ISR Center at APG, adds, “The ability to additively manufacture parts from a high strength polymer using the FFF process at the field, division, and / or depot level is sure to become an option for warriors give the ability to make better temporary parts much faster – hours versus days or weeks – and at a significantly lower cost – often pennies versus ten dollars. “

Wallace sums it up, “Soldiers also improvise as needed and often find their own design solutions to the problems they face. Offering a higher strength polymer material that can be used in the desktop printers they have access to gives them the opportunity Immediate innovation to temporarily solve a larger number of delivery and design challenges. Your designs would then be sent to the appropriate engineering support activity for evaluation. “

Dr. Eric Wetzel demonstrates the thermal drawing process. Photo via US Army.Dr. Eric Wetzel demonstrates the thermal drawing process. Photo via US Army.

For more details on the study, see the article entitled ‘Robust, additively manufactured structures, made with double thermoplastic filaments‘. It is co-authored by Kevin Hart, Ryan Dunn and Eric Wetzel.

The U.S. Forces has long used additive manufacturing to manufacture parts and conduct research for their field operations. Earlier this year, tThe US Army announced that it would work towards it Development of its supply chain Support the integration of additive manufacturing. More recently, the army began using the University of Delaware for 3D printing High temperature composites with a Roboze ARGO 500 3D printer.

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The picture shown shows the 3D printing of the preform and drawing the filament. Image via US Army.

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(With the kind permission of the LEHVOSS Group.)
03 Dec
Blog

LEHVOSS Develops a New Flame-Retardant 3D Printing Filament > ENGINEERING.com

LEHVOSS is developing a new flame-retardant 3D printing filament
Andrew Wheeler posted June 25, 2020 |

High temperature filaments use ceramic fillers to achieve a high level of thermal stability.

The chemical company LEHVOSS Group announced the introduction of a new 3D printing filament with flame retardant properties. The high-temperature polyamide has ceramic fillers in order to achieve a sufficiently high thermal stability to retard very high temperatures without losing its structural stability.

With the new filament LUVOCOM 3F PAHT, users can 3D print and produce flame-retardant components with a layer thickness of 0.4 millimeters. These components meet the guidelines for the safety of the flammability of plastic materials for parts in equipment and appliances, known as UL-94 V0. According to the company, this standard was achieved on an affordable desktop printer. As an example, they used an Ultimaker S5 3D printer to print flame retardant components that reached UL-94 V0.

(With the kind permission of the LEHVOSS Group.)

The filament is compatible with similar FFF desktop 3D printers (Fused Filament Filament). However, there are already pressure profiles for the Ultimaker S5 on the CURA marketplace, while profiles for the Ultimaker S3 are in progress.

No special temperature-controlled pressure chamber is required to heat the filament. It can also be used together with other materials, HIPS or high impact polystyrene. HIPS is a carrier material that is generally used in combination with ABS filaments. It dissolves after printing with d-lime, so there is no need to remove the carrier material after a part has been 3D printed. The new material can also be used with polyvinyl alcohol (known as PVOH, PVA, or PVAl) backing material, a synthetic polymer that dissolves in water.

Manufacturers who use 3D printers to build electrical components may appreciate access to a practical filament with thermal insulation and flame retardant properties from the new LEHVOSS Group material.

Bottom line

There are already some flame retardant filaments on the market from companies like Makerbot with the PC-ABS FR filament, Markforged with the Onyx FR and the Novamid AM1030 FR from DSM. The demand for these products is growing and more options to choose from are generally better for customers using 3D printers to build components that require electrical insulating properties from materials with high enough thermal stability properties to meet industry standards such as UL-94V0 .