Based on the underlying science of materials, we solve the core technical bottlenecks in transforming additive manufacturing from prototype verification to functional part production.
Through special molecular chain structures and reinforced filler compounding technology, the mechanical properties of the material are significantly enhanced, giving it physical strength comparable to traditional injection-molded parts.
Optimized melt rheological properties eliminate layer lines and stair-step effects, achieving a smooth surface that can be used directly without complex post-processing.
Unique crystallization control technology and internal stress release formulation significantly reduce thermal shrinkage during printing, ensuring large-sized models do not deform or warp.
Enhances molecular diffusion and physical entanglement between layers, eliminating anisotropy in the Z-axis direction and achieving consistent mechanical properties in all directions.
Strict raw material pretreatment and particle size ratio control ensure no carbonization or impurities in the material under high-temperature melting, guaranteeing smooth continuous printing over long periods.
A rheology formula optimized for high-speed extrusion significantly increases the material's melt flow rate while ensuring print quality, adapting to high-acceleration printing needs.