Today, Hay Think learned that the CQMY ultra-precision additive manufacturing platform has been fully built.
The platform can achieve ultra-high printing accuracy of 2 microns, ultra-low printing layer thickness of 5 microns, and take into account both micro-scale and macro-scale sample printing, and can complete ultra-high-precision large-format sample production. Its printing accuracy and printing layer thickness It ranks first in the global DLP light-curing additive manufacturing equipment.
It is understood that the platform started operations at the end of December last year. At present, the platform has 23 ultra-high-precision 3D printing equipment, 13 sets of 2-micron additive manufacturing systems, 20 sets of 10-micron additive manufacturing systems, and a number of supporting equipment such as high-definition microscopes, degreasing equipment, and sintering equipment.
The platform has integrated major 3D printing companies in the city, providing high-precision 3D printing services from micro-devices to large-scale devices.
Compared with CNC machining, mold injection and ordinary 3D printing commonly used in precision prototyping, high-precision 3D printing can complete the processing of complex structural parts such as thin walls and holes, as well as complex three-dimensional structure processing, detail accuracy <10m tolerance, and high processing efficiency , the delivery cycle is only 2 days, which can fully meet the small batch processing of precision structural parts.
The CQMY ultra-precision additive manufacturing platform serves the four major fields of precision structural parts, medical treatment, consumer electronics and scientific research. It provides ultra-precision additive manufacturing services for R&D teams, R&D institutions and enterprises, and helps them complete the product verification of technology and design.
At present, the platform has developed a series of printing materials with different characteristics for different application requirements, such as biocompatible materials, ceramic materials and high temperature resins. In addition, metal plating processes have also been developed for terahertz devices.
Complex three-dimensional microstructures have a wide range of applications in metamaterials, bionics, microfluidic devices, biomedicine, micromechanics, micro-nano optical devices, new energy and many other fields. It is difficult for ordinary 3D printing to meet the processing needs of complex three-dimensional structures.
Taking brain-computer interface printing as an example, it is difficult for ordinary 3D printing to print any 3D complex structures required by antifreeze self-adhesive hydrogels. The high-precision 3D printing technology is fully capable. The printed hydrogel can be used as a sensor, which can monitor human movement and slight physiological changes at extremely low temperature or even -80°C in a wide strain range. It has broad application prospects in the fields of sensing, brain-computer interaction, and intelligent bioelectronics.
It is understood that for the printing of complex three-dimensional microstructures, the CQMY ultra-precision additive manufacturing platform can undertake more than 20 kinds of high-precision equipment (products) such as miniature soft surgical robots, flexible wearable sensors, drug-loaded microneedles, and circulating tumor cell acoustic separation chips. Customized printing business. In addition, it can also complete the printing business in industrial application fields such as precision connectors and precision structural parts of communication products.