Prints 3D objects by extruding melted plastic, compatible with materials such as PLA, PLA+, PETG, ABS, Carbon Fiber filaments and many more
Stereolithography is used for creating models, prototypes, patterns, and production parts in a layer by layer fashion using photopolymerization, a process by which light causes chains of molecules to link together, forming polymers.
PLA + is used for low-cost, non-functional prototyping. Offers greater detail than ABS, but is more brittle. Unsuitable for high-temperature applications. ( Note: We use PLA + instead of PLA which is Ten times TOUGHER than any PLA on the market.)
PLA + is used for low-cost, non-functional prototyping. Offers greater detail than ABS, but is more brittle. Unsuitable for high-temperature applications. ( Note: We use PLA + instead of PLA which is Ten times TOUGHER than any PLA on the market.)
PLA + is used for low-cost, non-functional prototyping. Offers greater detail than ABS, but is more brittle. Unsuitable for high-temperature applications. ( Note: We use PLA + instead of PLA which is Ten times TOUGHER than any PLA on the market.)
PLA + is used for low-cost, non-functional prototyping. Offers greater detail than ABS, but is more brittle. Unsuitable for high-temperature applications. ( Note: We use PLA + instead of PLA which is Ten times TOUGHER than any PLA on the market.)
PLA + is used for low-cost, non-functional prototyping. Offers greater detail than ABS, but is more brittle. Unsuitable for high-temperature applications. ( Note: We use PLA + instead of PLA which is Ten times TOUGHER than any PLA on the market.)
PLA + is used for low-cost, non-functional prototyping. Offers greater detail than ABS, but is more brittle. Unsuitable for high-temperature applications. ( Note: We use PLA + instead of PLA which is Ten times TOUGHER than any PLA on the market.)
PLA + is used for low-cost, non-functional prototyping. Offers greater detail than ABS, but is more brittle. Unsuitable for high-temperature applications. ( Note: We use PLA + instead of PLA which is Ten times TOUGHER than any PLA on the market.)
PLA + is used for low-cost, non-functional prototyping. Offers greater detail than ABS, but is more brittle. Unsuitable for high-temperature applications. ( Note: We use PLA + instead of PLA which is Ten times TOUGHER than any PLA on the market.)
PLA + is used for low-cost, non-functional prototyping. Offers greater detail than ABS, but is more brittle. Unsuitable for high-temperature applications. ( Note: We use PLA + instead of PLA which is Ten times TOUGHER than any PLA on the market.)
PLA + is used for low-cost, non-functional prototyping. Offers greater detail than ABS, but is more brittle. Unsuitable for high-temperature applications. ( Note: We use PLA + instead of PLA which is Ten times TOUGHER than any PLA on the market.)
PLA + is used for low-cost, non-functional prototyping. Offers greater detail than ABS, but is more brittle. Unsuitable for high-temperature applications. ( Note: We use PLA + instead of PLA which is Ten times TOUGHER than any PLA on the market.)
PLA + is used for low-cost, non-functional prototyping. Offers greater detail than ABS, but is more brittle. Unsuitable for high-temperature applications. ( Note: We use PLA + instead of PLA which is Ten times TOUGHER than any PLA on the market.)
PLA + is used for low-cost, non-functional prototyping. Offers greater detail than ABS, but is more brittle. Unsuitable for high-temperature applications. ( Note: We use PLA + instead of PLA which is Ten times TOUGHER than any PLA on the market.)
PLA + is used for low-cost, non-functional prototyping. Offers greater detail than ABS, but is more brittle. Unsuitable for high-temperature applications. ( Note: We use PLA + instead of PLA which is Ten times TOUGHER than any PLA on the market.)
PLA + is used for low-cost, non-functional prototyping. Offers greater detail than ABS, but is more brittle. Unsuitable for high-temperature applications. ( Note: We use PLA + instead of PLA which is Ten times TOUGHER than any PLA on the market.)
PLA + is used for low-cost, non-functional prototyping. Offers greater detail than ABS, but is more brittle. Unsuitable for high-temperature applications. ( Note: We use PLA + instead of PLA which is Ten times TOUGHER than any PLA on the market.)
This standard resin is formulated for models with very small features, intricate details, and that does not require mechanical or temperature strain.
This standard resin is formulated for models with very small features, intricate details, and that does not require mechanical or temperature strain.
This standard resin is formulated for models with very small features, intricate details, and that does not require mechanical or temperature strain.
This standard resin is formulated for models with very small features, intricate details, and that does not require mechanical or temperature strain.
Castable Wax Resin is an easy-to-cast jewelry resin capable of printing smooth, highly detailed designs
Durable Resin is the most pliable, impact resistant, and lubricious material in our functional family of Tough and Durable Resins. Choose Durable Resin for squeezable parts and low-friction assemblies.
Tough 1500 Resin is the most resilient material in our functional family of Tough and Durable Resins. Choose Tough 1500 Resin for stiff and pliable parts that bend and spring back quickly.
Tough Resin is the strongest and stiffest material in our functional family of Tough and Durable Resins. Choose Tough Resin for prototyping strong and sturdy parts that should not bend easily. *Strong and stiff prototypes *Jigs and fixtures requiring minimal deflection *Simulating the strength and stiffness of ABS
Rigid 4000 Stiff, Strong, Engineering-Grade Prototypes Glass-filled Rigid 4000 Resin prints with a smooth, polished finish and is ideal for stiff and strong parts that can withstand minimal deflection. Consider Rigid 4000 Resin for general load-bearing applications. *Mounts and brackets *Thin-walled parts *Jigs and fixtures *Simulates stiffness of PEEK
Rigid 10K Rigid, Strong, Industrial-Grade Prototypes This highly glass-filled resin is the stiffest material in our engineering portfolio. Choose Rigid 10K Resin for precise industrial parts that need to withstand significant load without bending. Rigid 10K Resin exhibits a smooth matte finish and is highly resistant to heat and chemicals
High Temp Resin offers a heat deflection temperature (HDT) of 238 °C @ 0.45 MPa, the highest among Formlabs resins. Use it to print detailed, precise prototypes with high temperature resistance.
Elastic 50A, Our softest Engineering Resin, this 50A Shore durometer material is suitable for prototyping parts normally produced with silicone. Choose Elastic 50A Resin for parts that will bend, stretch, compress, and hold up to repeated cycles without tearing, and spring back quickly to their original shape. *Wearables, such as straps *Stretchable enclosures and casings *Compressible buttons *Soft tissue anatomy
Flexible 80A, Hard Flexible Prototypes Flexible 80A Resin is the most stiff soft-touch material in our library of Flexible and Elastic Resins, with an 80A Shore durometer to simulate the flexibility of rubber or TPU. Balancing softness with strength, Flexible 80A Resin can withstand bending, flexing, and compression, even through repeated cycles. *Handles, grips, and overmolds *Cushioning, damping, and shock absorption *Seals, gaskets, and masks *Cartilage, tendon, and ligament anatomy
The integrated color mixing solution for resin, the new technology enables 3D printing in a range of colors without the manual work of finishing and painting. Just pick this option, and message us the Pantone color you need your model to be print.
3DXSTAT™ ESD-PETG is an easy to use ESD-Safe filament formulated for a wide array of applications that require electrostatic discharge (ESD) protection and enhanced chemical resistance. Made using high flow PETG copolymer and CNT’s to offer exceptional repeatability and reliability.
Good for Electronic products; Stationery; Cosmetics containers.
Good for Electronic products; Stationery; Cosmetics containers.
Good for Electronic products; Stationery; Cosmetics containers.
Good for Electronic products; Stationery; Cosmetics containers.
Good for Electronic products; Stationery; Cosmetics containers.
Carbon fiber filament uses short carbon fibers, consisting of segments of less than one millimeter in length, which are mixed with a thermoplastic known as the base material.
Material Volume:
cm3
Support Material Volume:
cm3
Box Volume:
cm3
Surface Area:
cm2
Model Weight:
g
Model Dimensions:
x x
cm
Number of Shapes:
Total Path:
cm
Print Time
(hh:mm:ss):
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