Based on the underlying science of materials, solving core technical bottlenecks in the transformation of additive manufacturing from prototype verification to functional part production.
Through special molecular chain structure and reinforced filler compounding technology, the mechanical properties of the material are greatly improved, giving it physical strength comparable to traditional injection-molded parts.
Optimize melt rheological properties, eliminate layer lines and stair-stepping effects, achieve a smooth surface, and be ready for direct use without complex post-processing.
Unique crystallization control technology and internal stress release formula significantly reduce the thermal shrinkage rate during the printing process, ensuring that large-scale models do not deform or warp.
Enhance molecular diffusion and physical entanglement between layers, eliminate anisotropy in the Z-axis direction, and achieve consistency in mechanical properties in all directions.
Strict raw material pretreatment and particle size ratio control ensure that the material has no carbonization or impurities in the high-temperature molten state, guaranteeing the smoothness of long-term continuous printing.
Rheological formula optimized for high-speed extrusion significantly improves the melt flow rate of the material while ensuring molding quality, adapting to high-acceleration printing needs.
