Compare 3D Printing Materials

3D printing antistatic resin materials are typically achieved by incorporating conductive fillers or ion-type additives into the resin, effectively reducing the material’s surface resistivity. These materials are specifically designed for applications in electronic devices, precision instruments, and other areas where static interference must be prevented. The material effectively suppresses static accumulation, ensuring that printed parts remain free from charge interference during use, while maintaining excellent mechanical properties and precise printing details. Whether for manufacturing sensitive components or performing high-precision assemblies, antistatic resin is the ideal choice.

PC-like translucent material combines excellent translucency with high stiffness, making it an ideal choice for precision components. Through customized post-processing, functional light-transmitting effects can be achieved, delivering both aesthetic appeal and performance. With high tensile strength and modulus, this material is especially suited for creating functional prototypes that emulate injection-molded polycarbonate, meeting the dual demands of mechanical performance and visual quality for engineering prototypes and small-batch production.

PC-Like Advanced High Temp is a high-temperature reinforced material with properties similar to polycarbonate, specifically designed for functional parts that require a combination of high strength, stiffness, and heat resistance. Post-curing can further increase the heat deflection temperature of the parts, enhancing their stability and reliability in high-temperature environments. It should be noted that post-curing may reduce some aspects of durability, so a balance between strength and toughness should be considered during design.

The high-temperature reinforced ceramic white combines exceptional heat resistance with outstanding strength and stiffness, making it an ideal choice for functional parts and high-performance prototypes. Post-curing further enhances its mechanical properties and thermal stability, providing reliable performance for complex geometries. Whether for aerospace, precision molds, electronic insulators, or laboratory equipment, this ceramic material meets the highest standards under demanding conditions, delivering solid support for innovative designs and high-performance manufacturing.

17-4 PH stainless steel is a precipitation-hardening stainless steel known for its excellent hardness and corrosion resistance. Through vacuum solution heat treatment and H900 aging treatment, printed parts can achieve high strength, high hardness, and good wear resistance. 17-4 PH stainless steel is suitable for manufacturing industrial components that require high strength, corrosion resistance, and complex structures, such as aerospace parts, molds, and high-load machinery.
Disadvantages: Low elongation (≤16% after heat treatment); weak magnetism after heat treatment.

3D printed aluminum alloys, represented by AlSi10Mg and other aluminum-silicon-magnesium alloys, combine lightweight characteristics with excellent mechanical properties. They offer an outstanding strength-to-weight ratio, good corrosion resistance, and thermal conductivity, and demonstrate excellent fatigue and fracture resistance after heat treatment. The material is easy to form, weld, and machine, making it ideal for aerospace, automotive, and tooling applications where lightweight design and structural complexity are critical. Finished parts are typically shot-peened for surface treatment. If you require any other post-processing, please inform our customer service clearly.
Disadvantages: Poor heat resistance (maximum 120°C); surface roughness around Ra10, with slight pits and visible layer texture.