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Prints 3D objects by extruding melted plastic, compatible with materials such as PLA, PLA+, PETG, ABS, Carbon Fiber filaments and many more
Prints 3D objects by extruding melted plastic, compatible with materials such as PLA, PLA+, PETG, ABS, Carbon Fiber filaments and many more
Prints 3D objects by extruding melted plastic, compatible with materials such as PLA, PLA+, PETG, ABS, Carbon Fiber filaments and many more
Prints 3D objects by extruding melted plastic, compatible with materials such as PLA, PLA+, PETG, ABS, Carbon Fiber filaments and many more
High Strength & strong toughness
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.
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.
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.
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.
ABS (Acrylonitrile Butadiene Styrene) is a thermoplastic polymer that is commonly used in 3D printing. It is a strong, durable, and impact-resistant material that is widely used in the automotive and consumer goods industries. ABS has a high melting point, which makes it ideal for creating parts that require high-temperature resistance.
ABS (Acrylonitrile Butadiene Styrene) is a thermoplastic polymer that is commonly used in 3D printing. It is a strong, durable, and impact-resistant material that is widely used in the automotive and consumer goods industries. ABS has a high melting point, which makes it ideal for creating parts that require high-temperature resistance.
ASA is a technical material suitable for printing mechanically stressed parts, ASA UV filament has all the properties of 3D filament ABS with the additional features of being weather resistant. Our ASA is UV resistant and resistant to environmental stress cracking. PolyLite ASA can be used outdoor for outside applications such as RC planes or car accessories. ASA can resist temperatures up to 100˚C (212°F) and display high toughness and impact resistance for functional application.
ASA is a technical material suitable for printing mechanically stressed parts, ASA UV filament has all the properties of 3D filament ABS with the additional features of being weather resistant. Our ASA is UV resistant and resistant to environmental stress cracking. PolyLite ASA can be used outdoor for outside applications such as RC planes or car accessories. ASA can resist temperatures up to 100˚C (212°F) and display high toughness and impact resistance for functional application.
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
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.
Tough Resin is the strongest and stiffest material in our functional family of Tough and Durable Resins.  *Simulating the strength and stiffness of ABS
Tough Resin is the strongest and stiffest material in our functional family of Tough and Durable Resins.  *Simulating the strength and stiffness of ABS
Excellent Corrosion resistance. High specific strength
Excellent Corrosion resistance. Good welding performance
Excellent Corrosion resistance. High specific strength
High Strength & strong toughness
High Strength & strong toughness
High Strength & strong toughness
Ideal for stiff and functional parts
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
High Elasticity & Strength - Duramic TPU filament 1.75mm features not only the high elasticity to stretch 3 times more than its original length, but also high strength resistance with shore hardness of 95A. Duramic TPU is a perfect choice if you want to print rubber-like flexible and resistant models, parts, jigs and tools, etc.
 SKU: N/A
Additional information
Weight5.1 lbs
Dimensions12 × 12 × 12 in