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LOXIOL represents high-quality metal filaments specifically developed for additive manufacturing (3D printing). The product range enables the production of high-quality, robust, and precise metal components. LOXIOL filaments offer excellent mechanical properties, corrosion resistance, and versatility, making them ideal for industrial and technical applications. Loxiol Ti6Al4V Titanium Alloy Filament for Lightweight and High-Performance Applications LOXIOL Ti6Al4V is a titanium filament that combines lightweight design, strength, and corrosion resistance. Ideal for aerospace and demanding technical applications. Advantages: High strength at low weight Corrosion-resistant, biocompatible Perfect for aerospace parts and structural components Directions for use Notes on Printing Parameters and Thermal Management The recommended printing parameters for processing this filament are specified in the corresponding technical data sheet and must be strictly followed to ensure reliable and reproducible print quality. Due to the filament’s high thermal conductivity, insufficient cooling by the fan may cause heat to be conducted back into the extruder. This can lead to premature softening of the filament in the feed path, which may ultimately result in increased wear and feeding issues. To minimize this risk, it is recommended to operate the hotend fan continuously at 100% power and to start printing with the lowest possible nozzle temperature. This reduces the amount of heat that needs to be dissipated and ensures a stable and consistent material flow. Please note Post-Processing After 3D Printing After 3D printing, the components are present as so-called green parts, in which the metal powder is held together by a polymer binder system. To obtain a pure metal part, downstream thermal processes are required. The first step is debinding, during which the binder system is removed in a controlled manner. This is followed by sintering, where the components are heated to high temperatures. During this process, the metal particles fuse together, the part densifies, and it achieves its final mechanical properties. After sintering, the result is a nearly fully dense metal component with high strength and dimensional accuracy. Further information on the debinding and sintering process can be found in the technical data sheet.
Product Detail
Material: metal. Stainless Steel Composite Metal Filaments for 3D Printers BASF Forward AM’s Ultrafuse ® Metal Filaments are innovative filaments to produce stainless steel parts. They are designed for ultimate ease of handling on conventional Fused Filament Fabrication 3D printers. They combine greater freedom of design with a lower total cost of ownership – printing metal parts easier, faster and affordable. Ultrafuse ® 316L Stainless steel composite metal filament for 3D printers Advantages: Easy and affordable metal 3D printing Fast material exchange and easy handling For all open source FFF printers Produces parts of stainless-steel 316L metal Uniform particle distribution enhances mechanical properties High flexibility of filament enables successful printing in any FFF printers Compatible with both Bowden and direct drive extruders Application examples: Tooling Jigs and fixtures Functional prototypes Small series production Material: Excellent corrosive resistance Temperature stability Austenitic Non-magnetic
Product Detail
LOXIOL represents high-quality metal filaments specifically developed for additive manufacturing (3D printing). The product range enables the production of high-quality, robust, and precise metal components. LOXIOL filaments offer excellent mechanical properties, corrosion resistance, and versatility, making them ideal for industrial and technical applications. Loxiol Ti6Al4V Titanium Alloy Filament for Lightweight and High-Performance Applications LOXIOL Ti6Al4V is a titanium filament that combines lightweight design, strength, and corrosion resistance. Ideal for aerospace and demanding technical applications. Advantages: High strength at low weight Corrosion-resistant, biocompatible Perfect for aerospace parts and structural components Directions for use Notes on Printing Parameters and Thermal Management The recommended printing parameters for processing this filament are specified in the corresponding technical data sheet and must be strictly followed to ensure reliable and reproducible print quality. Due to the filament’s high thermal conductivity, insufficient cooling by the fan may cause heat to be conducted back into the extruder. This can lead to premature softening of the filament in the feed path, which may ultimately result in increased wear and feeding issues. To minimize this risk, it is recommended to operate the hotend fan continuously at 100% power and to start printing with the lowest possible nozzle temperature. This reduces the amount of heat that needs to be dissipated and ensures a stable and consistent material flow. Please note Post-Processing After 3D Printing After 3D printing, the components are present as so-called green parts, in which the metal powder is held together by a polymer binder system. To obtain a pure metal part, downstream thermal processes are required. The first step is debinding, during which the binder system is removed in a controlled manner. This is followed by sintering, where the components are heated to high temperatures. During this process, the metal particles fuse together, the part densifies, and it achieves its final mechanical properties. After sintering, the result is a nearly fully dense metal component with high strength and dimensional accuracy. Further information on the debinding and sintering process can be found in the technical data sheet.
Product Detail
LOXIOL represents high-quality metal filaments specifically developed for additive manufacturing (3D printing). The product range enables the production of high-quality, robust, and precise metal components. LOXIOL filaments offer excellent mechanical properties, corrosion resistance, and versatility, making them ideal for industrial and technical applications. Loxiol 17-4PH High-Performance Stainless Steel for Industrial Applications LOXIOL 17-4PH combines high mechanical strength with excellent corrosion resistance. Perfect for applications that require structural integrity under demanding conditions. Advantages: Excellent tensile and compressive strength Resistant to chemical exposure Suitable for precise components in aerospace and mechanical engineering Directions for use Notes on Printing Parameters and Thermal Management The recommended printing parameters for processing this filament are specified in the corresponding technical data sheet and must be strictly followed to ensure reliable and reproducible print quality. Due to the filament’s high thermal conductivity, insufficient cooling by the fan may cause heat to be conducted back into the extruder. This can lead to premature softening of the filament in the feed path, which may ultimately result in increased wear and feeding issues. To minimize this risk, it is recommended to operate the hotend fan continuously at 100% power and to start printing with the lowest possible nozzle temperature. This reduces the amount of heat that needs to be dissipated and ensures a stable and consistent material flow. Please note Post-Processing After 3D Printing After 3D printing, the components are present as so-called green parts, in which the metal powder is held together by a polymer binder system. To obtain a pure metal part, downstream thermal processes are required. The first step is debinding, during which the binder system is removed in a controlled manner. This is followed by sintering, where the components are heated to high temperatures. During this process, the metal particles fuse together, the part densifies, and it achieves its final mechanical properties. After sintering, the result is a nearly fully dense metal component with high strength and dimensional accuracy. Further information on the debinding and sintering process can be found in the technical data sheet.
Product Detail
LOXIOL represents high-quality metal filaments specifically developed for additive manufacturing (3D printing). The product range enables the production of high-quality, robust, and precise metal components. LOXIOL filaments offer excellent mechanical properties, corrosion resistance, and versatility, making them ideal for industrial and technical applications. Loxiol 316L High-Quality Stainless Steel Filament for FFF 3D Printing LOXIOL 316L is a stainless steel filament that combines corrosion resistance, strength, and heat resistance in a single material. It is particularly well suited for functional prototypes, small-series production, and complex metal components. Advantages: Excellent corrosion and chemical resistance High strength and toughness Compatible with standard FFF printers Ideal for industrial components and toolmaking Directions for use Notes on Printing Parameters and Thermal Management The recommended printing parameters for processing this filament are specified in the corresponding technical data sheet and must be strictly followed to ensure reliable and reproducible print quality. Due to the filament’s high thermal conductivity, insufficient cooling by the fan may cause heat to be conducted back into the extruder. This can lead to premature softening of the filament in the feed path, which may ultimately result in increased wear and feeding issues. To minimize this risk, it is recommended to operate the hotend fan continuously at 100% power and to start printing with the lowest possible nozzle temperature. This reduces the amount of heat that needs to be dissipated and ensures a stable and consistent material flow. Please note Post-Processing After 3D Printing After 3D printing, the components are present as so-called green parts, in which the metal powder is held together by a polymer binder system. To obtain a pure metal part, downstream thermal processes are required. The first step is debinding, during which the binder system is removed in a controlled manner. This is followed by sintering, where the components are heated to high temperatures. During this process, the metal particles fuse together, the part densifies, and it achieves its final mechanical properties. After sintering, the result is a nearly fully dense metal component with high strength and dimensional accuracy. Further information on the debinding and sintering process can be found in the technical data sheet.
Product Detail
LOXIOL represents high-quality metal filaments specifically developed for additive manufacturing (3D printing). The product range enables the production of high-quality, robust, and precise metal components. LOXIOL filaments offer excellent mechanical properties, corrosion resistance, and versatility, making them ideal for industrial and technical applications. Loxiol Copper Copper Filament for Electrically and Thermally Conductive Components LOXIOL Copper offers excellent thermal and electrical conductivity, combined with the precision of additive manufacturing. Advantages: High electrical conductivity Optimal heat dissipation Suitable for functional prototypes and electronic components Directions for use Notes on Printing Parameters and Thermal Management The recommended printing parameters for processing this filament are specified in the corresponding technical data sheet and must be strictly followed to ensure reliable and reproducible print quality. Due to the filament’s high thermal conductivity, insufficient cooling by the fan may cause heat to be conducted back into the extruder. This can lead to premature softening of the filament in the feed path, which may ultimately result in increased wear and feeding issues. To minimize this risk, it is recommended to operate the hotend fan continuously at 100% power and to start printing with the lowest possible nozzle temperature. This reduces the amount of heat that needs to be dissipated and ensures a stable and consistent material flow. Please note Post-Processing After 3D Printing After 3D printing, the components are present as so-called green parts, in which the metal powder is held together by a polymer binder system. To obtain a pure metal part, downstream thermal processes are required. The first step is debinding, during which the binder system is removed in a controlled manner. This is followed by sintering, where the components are heated to high temperatures. During this process, the metal particles fuse together, the part densifies, and it achieves its final mechanical properties. After sintering, the result is a nearly fully dense metal component with high strength and dimensional accuracy. Further information on the debinding and sintering process can be found in the technical data sheet.
Product Detail
LOXIOL represents high-quality metal filaments specifically developed for additive manufacturing (3D printing). The product range enables the production of high-quality, robust, and precise metal components. LOXIOL filaments offer excellent mechanical properties, corrosion resistance, and versatility, making them ideal for industrial and technical applications. Loxiol 17-4PH High-Performance Stainless Steel for Industrial Applications LOXIOL 17-4PH combines high mechanical strength with excellent corrosion resistance. Perfect for applications that require structural integrity under demanding conditions. Advantages: Excellent tensile and compressive strength Resistant to chemical exposure Suitable for precise components in aerospace and mechanical engineering Directions for use Notes on Printing Parameters and Thermal Management The recommended printing parameters for processing this filament are specified in the corresponding technical data sheet and must be strictly followed to ensure reliable and reproducible print quality. Due to the filament’s high thermal conductivity, insufficient cooling by the fan may cause heat to be conducted back into the extruder. This can lead to premature softening of the filament in the feed path, which may ultimately result in increased wear and feeding issues. To minimize this risk, it is recommended to operate the hotend fan continuously at 100% power and to start printing with the lowest possible nozzle temperature. This reduces the amount of heat that needs to be dissipated and ensures a stable and consistent material flow. Please note Post-Processing After 3D Printing After 3D printing, the components are present as so-called green parts, in which the metal powder is held together by a polymer binder system. To obtain a pure metal part, downstream thermal processes are required. The first step is debinding, during which the binder system is removed in a controlled manner. This is followed by sintering, where the components are heated to high temperatures. During this process, the metal particles fuse together, the part densifies, and it achieves its final mechanical properties. After sintering, the result is a nearly fully dense metal component with high strength and dimensional accuracy. Further information on the debinding and sintering process can be found in the technical data sheet.
Product Detail
LOXIOL represents high-quality metal filaments specifically developed for additive manufacturing (3D printing). The product range enables the production of high-quality, robust, and precise metal components. LOXIOL filaments offer excellent mechanical properties, corrosion resistance, and versatility, making them ideal for industrial and technical applications. Loxiol 316L High-Quality Stainless Steel Filament for FFF 3D Printing LOXIOL 316L is a stainless steel filament that combines corrosion resistance, strength, and heat resistance in a single material. It is particularly well suited for functional prototypes, small-series production, and complex metal components. Advantages: Excellent corrosion and chemical resistance High strength and toughness Compatible with standard FFF printers Ideal for industrial components and toolmaking Directions for use Notes on Printing Parameters and Thermal Management The recommended printing parameters for processing this filament are specified in the corresponding technical data sheet and must be strictly followed to ensure reliable and reproducible print quality. Due to the filament’s high thermal conductivity, insufficient cooling by the fan may cause heat to be conducted back into the extruder. This can lead to premature softening of the filament in the feed path, which may ultimately result in increased wear and feeding issues. To minimize this risk, it is recommended to operate the hotend fan continuously at 100% power and to start printing with the lowest possible nozzle temperature. This reduces the amount of heat that needs to be dissipated and ensures a stable and consistent material flow. Please note Post-Processing After 3D Printing After 3D printing, the components are present as so-called green parts, in which the metal powder is held together by a polymer binder system. To obtain a pure metal part, downstream thermal processes are required. The first step is debinding, during which the binder system is removed in a controlled manner. This is followed by sintering, where the components are heated to high temperatures. During this process, the metal particles fuse together, the part densifies, and it achieves its final mechanical properties. After sintering, the result is a nearly fully dense metal component with high strength and dimensional accuracy. Further information on the debinding and sintering process can be found in the technical data sheet.
Product Detail
LOXIOL represents high-quality metal filaments specifically developed for additive manufacturing (3D printing). The product range enables the production of high-quality, robust, and precise metal components. LOXIOL filaments offer excellent mechanical properties, corrosion resistance, and versatility, making them ideal for industrial and technical applications. Loxiol Copper Copper Filament for Electrically and Thermally Conductive Components LOXIOL Copper offers excellent thermal and electrical conductivity, combined with the precision of additive manufacturing. Advantages: High electrical conductivity Optimal heat dissipation Suitable for functional prototypes and electronic components Directions for use Notes on Printing Parameters and Thermal Management The recommended printing parameters for processing this filament are specified in the corresponding technical data sheet and must be strictly followed to ensure reliable and reproducible print quality. Due to the filament’s high thermal conductivity, insufficient cooling by the fan may cause heat to be conducted back into the extruder. This can lead to premature softening of the filament in the feed path, which may ultimately result in increased wear and feeding issues. To minimize this risk, it is recommended to operate the hotend fan continuously at 100% power and to start printing with the lowest possible nozzle temperature. This reduces the amount of heat that needs to be dissipated and ensures a stable and consistent material flow. Please note Post-Processing After 3D Printing After 3D printing, the components are present as so-called green parts, in which the metal powder is held together by a polymer binder system. To obtain a pure metal part, downstream thermal processes are required. The first step is debinding, during which the binder system is removed in a controlled manner. This is followed by sintering, where the components are heated to high temperatures. During this process, the metal particles fuse together, the part densifies, and it achieves its final mechanical properties. After sintering, the result is a nearly fully dense metal component with high strength and dimensional accuracy. Further information on the debinding and sintering process can be found in the technical data sheet.
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© 2023 Copyright. All Rights Reserved. Unit 19, Euroway House, Roydsdale Way, Bradford, BD4 6SE, UK
