Innovation
tomorrow’s breakthroughs start here
Mechanical Design
Our mechanical designs are developed in SolidWorks, ensuring precision and efficiency from concept to production. We deliver complete assembly documentation and maintain a PDM-organized Bill of Materials (BOM) to guarantee traceability and manufacturing consistency.
FEM Simulation
We perform advanced electromagnetic and mechanical simulations using a Comsol Multiphysics. Each design is optimized for maximum performance, minimal cooldown time, and reduced weight, ensuring superior magnet efficiency and reliability.
In house coil-winding
Our in-house coil winding facility supports both prototype and serial production. Equipped with one CNC and one classical Meteor winding machine, we combine precision automation with craftsmanship to achieve exceptional coil quality and repeatability.
Cryogenic test and verification
Every magnet undergoes thorough cryogenic testing and verification in our dry cryogenic test-bed. Using automated test software and standardized test protocols, we ensure consistent, high-quality performance under real operating conditions.
Ludicrously fast cooldown times
Our design process focuses on optimizing the strength-to-weight ratio of materials to achieve shorter cooldown times and superior thermal performance. By integrating parametric design methodologies and FEM-based optimization, we develop lightweight, high-efficiency magnet structures that meet the demanding requirements of research and quantum applications.
Modern manufacturing technology
We apply cutting-edge manufacturing techniques to elevate magnet performance and reliability. Laser welding enhances the integrity of critical thermal interfaces, while additive manufacturing enables complex, weight-optimized geometries for magnet bodies. Through collaborative R&D with leading universities, we actively shape the future of superconducting magnet manufacturing and continuously advance process innovation.
Ridiculously strong magnet performance
We enhance magnet performance through advanced FEM simulations that model complex wire combinations to achieve optimal field characteristics. This approach not only increases manufacturing yield through improved design margins but also enables super-high power-supply stability, supporting persistent-switch-less operation for next-generation superconducting systems.
