Experience industrial superiority with the only additive manufacturing technology that works with production-grade thermoplastics under a patented self-calibrated heated chamber. The chamber ensures consistent bonding of layers, as every layer is heated at a specific temperature. As FDM technology uses the same tried and tested thermoplastics found in traditional manufacturing processes, there’s always an FDM thermoplastic that suits your requirements.
FDM technology works by first heating the thermoplastic to a semi-liquid state. The ultra-fine beads in the semi-liquid state are then deposited along the extrusion path layer by layer. A removable material is deposited by the printer if support is required. The support can be removed during post-processing either by detergent or water.
FDM technology allows users to build products of unrivalled resistance and strength in chemical, mechanical and thermal properties, which are unlikely to be distorted in ambient conditions with time. The technology is also ideal for the creation of components which require complicated geometries and performance durability. Design ideas are thus freed from the constraints of traditional manufacturing methods, which have often compromised extreme precision.
FDM Thermoplastic Materials
ABS-M30 (Acrylonitrile butadiene styrene), ABS-M30i, ABSi, PC-ABS, ASA (Acrylonitrile styrene acrylate), PC (Polycarbonate), PC-ISO, ULTEM 9085 resin (Polyetherimide), ULTEM 1010 resin, PPSF (Polyphenylsulfone), FDM Nylon 6, FDM Nylon 12, FDM Nylon 12CF, ST-130 (Sacrificial Tooling) and PLA (Polylactic acid).
FDM 3D printer
With a variety of Industrial Grade Thermoplastic 3D printers from Stratasys, it will be able to cater to any of your design and engineering needs in an office environment.