UpNano, a 3D printing company, has expanded its NanoOne lineup with the release of the NanoOne Green. Equipped with a 515 nm green laser wavelength, the NanoOne Green achieves breakthrough capabilities in creating detailed, high-precision structures, opening doors for optics, microfluidics, and biomedical engineering applications.
The NanoOne Green delivers an impressive 30% increase in resolution compared to conventional 2PP 3D printers, typically using a 780 nm laser. This improvement allows users to produce ultra-fine details with feature widths as small as 100 nm, advancing what is possible in microscale manufacturing and detailed component creation. Moreover, the green laser wavelength enables transparent, biocompatible, and non-fluorescent materials, essential in applications requiring precise, non-reactive materials.
"With the NanoOne green, we have extended our NanoOne product line with a tool that delivers ultra-high-resolution features and paves the way for diverse industrial applications," said Bernhard Küenburg, CEO of UpNano.
High-Resolution 3D Printers
UpNano is Debuting the NanoOne Green 3D Printer with Improved Features
Trend Themes
1. High-resolution 3D Printers - Enhanced with a 515 nm green laser, these printers can create structures with precision previously unattainable, ideal for micro-manufacturing.
2. Biocompatible 3D Printing Materials - The ability to use transparent, biocompatible, and non-fluorescent materials introduces new possibilities for non-reactive applications in medical and research fields.
3. Ultra-fine Detail Fabrication - Achieving feature widths as small as 100 nm, these printers push the boundaries of detailed component creation, essential for advanced engineering solutions.
Industry Implications
1. Optics - High-resolution 3D printing capabilities allow for the creation of precise optical components, enhancing the development of cutting-edge optical technologies.
2. Biomedical Engineering - Advanced 3D printing with biocompatible materials supports innovations in biomedical devices and implants, improving patient care and treatment options.
3. Microfluidics - The production of detailed microscale structures facilitates advancements in microfluidic devices, which are essential for lab-on-a-chip and diagnostic applications.