Compare 3D Printing Materials
Explore and compare 3D printing materials to find the best fit for your project. From durable plastics to flexible resins, our guide highlights key properties like strength, flexibility, and surface finish, helping you choose the right material for prototyping, production, or custom parts.
Flame Retardant Resin
Process: LCD
Flame Resistance
Flame-retardant resin is a high-performance material formulated with specialized additives to significantly reduce flammability and slow down flame propagation. While maintaining excellent mechanical strength and processability, it meets stringent fire safety standards. Ideal for electronics enclosures, aerospace components, transportation parts, and other applications requiring superior fire resistance, this resin enables precise 3D printing of complex geometries while ensuring reliable performance under high temperatures and flame exposure.
Titanium
Process: SLM
Temperature Resistance, Corrosion Resistance, Strength, Lightweight
3D printed titanium alloys, represented by Ti6Al4V, feature extremely high specific strength and excellent corrosion resistance, while being lightweight and tough. They enable the creation of complex geometries and topology-optimized designs through additive manufacturing, and are widely used in aerospace, medical implants, automotive, and high-performance sports equipment. Titanium alloys also offer good high-temperature performance and biocompatibility, making them an ideal choice for manufacturing high-performance, lightweight components.
Disadvantages: Poor heat resistance (maximum 120°C); surface roughness around Ra10, with slight pits and visible layer texture.
Aluminum
Process: SLM
HighStrength, CorrosionResistant, Lightweight
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.
