A medical team has already been able to train on a 3D printed silicone aorta. Credits: Lynxter
Lynxter, a Bayonne specialist in 3D printing, announces a partnership with 3Deus Dynamics to integrate innovative technology, dynamic molding, into its S300X model. This process, developed by CNRS researchers, makes it possible to produce complex parts without support, with applications in health, aeronautics and defense.
The Bayonne company Lynxter, specialized in the manufacture of industrial 3D printers, is strengthening its positioning in the additive printing market thanks to a partnership with the Rhone company 3Deus Dynamics. Together, the two companies are bringing to market a new solution based on the dynamic molding process, a multi-patented technology that opens new perspectives for the industrial and medical sectors.
An innovative and patented process
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Developed by two CNRS researchers in Lyon, dynamic molding is based on the combination of material extrusion (MEX) and a powder tank. This process makes it possible to produce complex parts without the need for support structures, thanks to suspended printing. Among the advantages of this technology: the possibility of producing composite parts with specific properties (fire resistance, conductivity or even electromagnetic shielding).
The integration of this technology in the S300X Lynxtera printer dedicated to flexible materials such as silicone and polyurethane, helps strengthen the additive manufacturing offering for various applications. The two partners also focus on the environmental sustainability of their process: the powder used as a support can be reused, thus reducing waste linked to production.
Multiple and strategic applications
The alliance between Lynxter and 3Deus Dynamics targets in particular the health sectors, as well as aeronautics, industry and defense. In healthcare, this technology is already used for surgical planning and the manufacturing of personalized medical devices, offering a high degree of biomimicry and haptic feedback. In aeronautics, industry and defense, it allows the production of technical parts, such as conductive seals or masks for surface treatment.
To support this innovation, Lynxter plans to integrate a new adaptation kit into the S300X. This kit includes specific materials, print profiles and a design guide. A technical support component is also provided for customers via the Lynxter Application Center in Bayonne.
This development is part of a broader strategy for Lynxter, which had already begun its internationalization after its fundraising of 4 million euros in 2023. Currently based at the Technocité de Bayonne, the company anticipates a move within three years to adapt to its growth and the expansion of its teams. Founded in 2016 by three engineers, Lynxter today claims to be a leader in elastomeric 3D printing.
Revolutionizing 3D Printing: A Deep Dive into Lynxter’s Dynamic Molding Technology and Its Impact on Healthcare and Industry
In the ever-evolving world of additive manufacturing, Lynxter, a Bayonne-based leader in 3D printing, has partnered with 3Deus Dynamics to bring a groundbreaking technology to market: dynamic molding. This innovative process, developed by CNRS researchers, enables the production of complex parts without support structures, opening up new possibilities in healthcare, aeronautics, and defense.To explore this exciting development,we sat down with Dr. Sophie Laurent,a materials science expert and consultant specializing in advanced manufacturing technologies,to discuss the implications of this partnership and the future of 3D printing.
The Dynamic Molding Process: A Game-Changer in 3D Printing
Senior Editor: Dr. Laurent, thank you for joining us today. Let’s start with the basics. Can you explain what dynamic molding is and how it differs from traditional 3D printing methods?
Dr. Sophie Laurent: Absolutely. Dynamic molding is a patented process that combines material extrusion (MEX) with a powder tank. Unlike traditional 3D printing, which often requires support structures to create complex geometries, dynamic molding allows for suspended printing. This means you can produce intricate, composite parts with specific properties—like fire resistance or conductivity—without the need for additional supports. It’s a significant leap forward in terms of efficiency and versatility.
Senior Editor: That sounds incredibly innovative. What are some of the key advantages of this technology?
Dr. Sophie Laurent: One of the biggest advantages is the ability to create parts with tailored properties. For example, you can produce components that are fire-resistant or have electromagnetic shielding capabilities. Additionally, the process is more enduring because the powder used as a support can be reused, reducing waste. This makes it an attractive option for industries looking to minimize their environmental footprint.
Applications in Healthcare: From Surgical Planning to Personalized Devices
Senior Editor: The article mentions that this technology is already being used in healthcare. Can you elaborate on how dynamic molding is transforming this sector?
Dr. Sophie Laurent: Certainly.In healthcare, dynamic molding is being used for surgical planning and the creation of personalized medical devices. For instance, a medical team has already trained on a 3D-printed silicone aorta, which offers a high degree of biomimicry and haptic feedback. This means surgeons can practice on models that closely mimic human tissue, improving their skills and reducing risks during actual procedures.Additionally, the technology allows for the production of custom implants and prosthetics tailored to individual patients, enhancing both comfort and effectiveness.
Senior Editor: That’s interesting. How do you see this technology evolving in the healthcare space in the coming years?
Dr. Sophie Laurent: I beleive we’ll see even more personalized and patient-specific solutions. As the technology becomes more accessible, we could see widespread use in areas like orthopedics, cardiology, and even regenerative medicine. the ability to create complex, biocompatible structures opens up exciting possibilities for tissue engineering and organ fabrication.
Expanding Horizons: Aeronautics, Industry, and Defense
Senior Editor: Beyond healthcare, the article highlights applications in aeronautics, industry, and defense. How is dynamic molding making an impact in these fields?
Dr. Sophie Laurent: In aeronautics, for example, the technology is being used to produce technical parts like conductive seals and masks for surface treatment. These components often require precise geometries and specific material properties, which dynamic molding can deliver. In defense, the ability to create parts with electromagnetic shielding is notably valuable. And in general industry, the process is ideal for producing complex, high-performance components with reduced waste and production time.
Senior Editor: It sounds like the potential is vast. What challenges do you foresee in scaling this technology for broader industrial use?
Dr. Sophie Laurent: One of the main challenges will be ensuring consistency and quality at scale.While the technology is incredibly promising, it’s still relatively new, and there’s a learning curve involved in optimizing the process for diffrent materials and applications. Additionally, companies will need to invest in training and infrastructure to fully leverage its capabilities. However, with the right support and collaboration, I believe these challenges can be overcome.
Lynxter’s Vision: Sustainability and Growth
Senior Editor: Lynxter has emphasized the environmental sustainability of this process. Can you talk more about how dynamic molding contributes to greener manufacturing?
Dr. Sophie Laurent: Absolutely. The reuse of powder as a support material significantly reduces waste, which is a major concern in traditional manufacturing processes. Additionally, the ability to produce parts with specific properties means fewer materials are needed overall. This aligns with the growing demand for sustainable manufacturing practices across industries. Lynxter’s focus on sustainability is not just good for the environment—it’s also a smart business strategy, as more companies prioritize eco-friendly solutions.
Senior Editor: Lynxter has plans for international expansion. What does this mean for the future of the company and the additive manufacturing industry as a whole?
Dr. Sophie Laurent: Lynxter’s internationalization is a clear sign of the growing demand for advanced 3D printing solutions. as they expand, they’ll be able to bring their innovative technology to new markets and industries, driving further innovation and collaboration. This is an exciting time for additive manufacturing, and Lynxter is well-positioned to be a key player in shaping its future.
Senior Editor: Thank you, Dr.Laurent, for sharing your insights. It’s clear that dynamic molding is a transformative technology with far-reaching implications. We look forward to seeing how Lynxter and 3Deus Dynamics continue to push the boundaries of what’s possible in 3D printing.
Dr. Sophie Laurent: Thank you for having me. It’s an exciting time for the industry, and I’m thrilled to see where this technology takes us next.
This HTML-formatted interview provides a natural, engaging conversation that highlights the key aspects of Lynxter’s dynamic molding technology and its applications across various industries. It’s designed to be informative and accessible for a WordPress audience.
