9T Labs webinar presents continuous carbon fiber advancements
Free online webinar offered on June 19 breaks down research into latest technologies and methodologies by 9T Labs and Purdue University experts.
Source | 9T Labs
9T Labs (Zurich, Switzerland) announces “Advancing Composites Research to Meet Industry Demand,” a free online webinar taking place June 19 at 5 p.m. CET (11 a.m. ET). It is aimed at researchers, professionals and academics in the field of composite materials who are looking to enhance their understanding and application of the latest technologies and methodologies.
In this webinar, composites experts Dr. Eduardo Barocio and Dr. Byron Pipes from Purdue University, and Dr. Martin Eichenhofe and Mark Lechler from 9T Labs, will discuss how cutting-edge research in the design, simulation and production of continuous fiber composites is tackling the demand for better performing parts, lighter components and cost-effective, sustainable solutions. Attendees will also have the chance to engage directly with the speakers through a dedicated Q&A session.
“Explore the future of hybrid composites manufacturing,” Yannick Willemin, 9T Labs director of business development, says. “Join us for exclusive insights through this Purdue and 9T Labs collaboration.”
Register here.
Related Content
-
Drawing design cues from nature: Designing for biomimetic composites, Part 1
Biomimicry is an interdisciplinary methodology that can inform composites design and manufacturing via use of more effective and sustainable materials, structural fabrication and technological practices.
-
High-performance, high-detail continuous 3D-printed carbon fiber parts
Since 2014, Mantis Composites has built its customer and R&D capabilities specifically toward design, printing and postprocessing of highly engineered aerospace and defense parts.
-
Optimizing a thermoplastic composite helicopter door hinge
9T Labs used Additive Fusion Technology to iterate CFRTP designs, fully exploit continuous fiber printing and outperform stainless steel and black metal designs in failure load and weight.
.jpg;maxWidth=300;quality=90;format=webp)
