Ceramic Filament – Dev https://dev.additiveplus.com Wed, 01 Oct 2025 10:57:02 +0000 en-US hourly 1 https://wordpress.org/?v=6.8.5 https://dev.additiveplus.com/wp-content/uploads/cropped-AdditivePlus-Logo-Vertical-Dark-32x32.png Ceramic Filament – Dev https://dev.additiveplus.com 32 32 shopengine_activated_templates a:1:{s:6:"single";a:1:{s:4:"lang";a:1:{s:2:"en";a:1:{i:7;a:3:{s:11:"template_id";i:53939;s:6:"status";b:1;s:11:"category_id";s:3:"912";}}}}} Zetamix White Zirconia Filament 1,75mm https://dev.additiveplus.com/product/zetamix-white-zirconia-filament-175mm/ Wed, 01 Oct 2025 10:50:23 +0000 https://dev.additiveplus.com/?post_type=product&p=68781 White zirconia filament: Print FDM ceramic parts → sinter into high-strength components with luxury finishes for tooling & premium goods.

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Zetamix White Zirconia Filament enables direct production of advanced ceramic components using standard FDM 3D printers. Create parts with exceptional mechanical strength, stunning surface finishes, and premium aesthetics—perfect for luxury goods, high-wear tooling, and demanding technical applications that require both beauty and performance.

Why Engineers & Manufacturers Choose Zetamix Alumina

Exceptional Mechanical Performance

  • Outstanding bending strength: 400-1000 MPa

  • High hardness: 10 GPa (Hv10)

  • 98-99% density after sintering for maximum strength

  • Excellent shock and impact resistance

Premium Aesthetic Versatility

  • Beautiful white matte finish after sintering

  • Can be polished to mirror-like gloss

  • Brushed, satin, or high-polish finishes possible

  • Ideal for luxury goods and high-visibility applications

Diverse Application Range

  • Internal tooling and manufacturing fixtures

  • Luxury product prototypes and final parts

  • Technical ceramics requiring high strength

  • Consumer goods with premium aesthetics

Material Properties After Sintering

zetamix-circonia

  • Density: 98-99% of theoretical density

  • Bending Strength: 400-1000 MPa

  • Hardness: 10 GPa (Hv10)

  • Dielectric Constant: 32 (±0.5) at 9.4 GHz

  • Loss Tangent: ≈1×10⁻³

  •  

Your Path to Premium Ceramic Parts

1. Design for Ceramic Manufacturing

  • Scale models by 127.4% (X/Y/Z) for sintering shrinkage

  • Minimum part size: 6mm cube | Minimum wall: 1mm

  • Minimum pin diameter: 2.3mm | Minimum hole: 0.6mm (vertical)

  • Maximum overhang: 40° unsupported, 15° for ceilings

2. Precision Printing Protocol

  • Use grooved drive gears to prevent filament grinding

  • Print on flexible build plates for easy removal

  • 100% fan speed for optimal surface quality

  • 1mm retraction at 20 mm/s recommended

  • Minimum 2 wall layers with 5-100% infill density

3. Controlled Debinding & Sintering

  • Chemical Debinding: 6h acetone bath at 40°C (>5% mass loss)

  • Thermal Debinding: 8°C/h ramp to 500°C (≈2.5 days) or accelerated cycle available

  • Sintering: 50°C/h to 1475°C with 2h hold in air atmosphere

FAQs

What makes zirconia superior to other ceramics for strength applications?

Zirconia offers exceptional bending strength (400-1000 MPa) and fracture toughness, making it significantly more impact-resistant than alumina or other technical ceramics—ideal for functional parts and tooling.

Zirconia can be finished as-matted (natural white finish), brushed, polished to satin, or mirror-polished to high gloss, making it perfect for luxury goods and high-end consumer products.

Luxury watch components, jewelry, high-end consumer goods, dental and medical prototypes, wear-resistant tooling, and any application requiring both aesthetic appeal and mechanical performance.

Sintered parts achieve 98-99% density with mechanical properties comparable to zirconia produced by traditional ceramic manufacturing methods.

Maximum printed size determined by furnace dimensions, minimum wall: 1mm, minimum feature: 0.6mm. Avoid sharp corners and maintain uniform wall thicknesses where possible.

 Yes! The 0.6mm minimum feature size allows for intricate details, text, and complex geometries impossible with traditional ceramic manufacturing.

Printing varies by model. Chemical debinding takes 6h + 2h drying, thermal debinding ≈60h (or 23h accelerated), and sintering ≈29h including ramp times and holding.

 Standard ceramic filament handling—use in well-ventilated areas, wear FFP2 masks during printing and handling. The sintered zirconia is biologically inert.

One year when stored in original vacuum-sealed packaging in cool, dry conditions.

The as-sintered surface has a pleasant matte white finish. For glossy or brushed finishes, mechanical polishing or blasting is required after sintering.

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]]> Zetamix Black Zirconia Filament 1,75mm https://dev.additiveplus.com/product/zetamix-black-zirconia-filament-175mm/ Wed, 01 Oct 2025 10:39:36 +0000 https://dev.additiveplus.com/?post_type=product&p=68771 Black zirconia filament: Print FDM ceramic parts → sinter into high-strength black components with luxury finishes for premium applications.

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Zetamix Black Zirconia Filament enables direct production of advanced black ceramic components using standard FDM 3D printers. Create parts with outstanding mechanical strength, deep black aesthetics, and premium surface finishes—ideal for luxury goods, high-wear tooling, and demanding applications requiring both sophisticated appearance and exceptional performance.

Why Engineers & Manufacturers Choose Zetamix Alumina

Premium Black Aesthetics

  • Deep, consistent black color after sintering

  • Can be finished with matte, brushed, or high-polish mirror surfaces

  • Ideal for luxury consumer goods and high-visibility components

  • Maintains color integrity through finishing processes

Exceptional Mechanical Properties

  • Outstanding bending strength: 400-1000 MPa

  • High hardness: 19 GPa

  • 98-99% density after sintering for maximum durability

  • Excellent impact and wear resistance

Versatile Application Range

  • Luxury goods and premium consumer products

  • High-wear tooling and manufacturing fixtures

  • Technical components requiring strength and aesthetics

  • Architectural and design elements

Material Properties After Sintering

0201-1

  • Density: 98-99% of theoretical density

  • Bending Strength: 400-1000 MPa

  • Hardness: 19 GPa

  • Color: Deep black, consistent throughout

Your Path to Premium Black Ceramic Parts

1. Design for Ceramic Manufacturing

  • Scale models by 127.4% (X/Y/Z) for sintering shrinkage

  • Minimum part size: 6mm cube | Minimum wall: 1mm

  • Minimum pin diameter: 2.3mm | Minimum hole: 0.6mm (vertical)

  • Maximum overhang: 40° unsupported, 15° for ceilings

2. Precision Printing Protocol

  • Use grooved drive gears to prevent filament grinding

  • Print on flexible build plates for easy removal

  • 100% fan speed for optimal surface quality

  • 1mm retraction at 20 mm/s recommended

  • Minimum 2 wall layers with 5-100% infill density

3. Controlled Debinding & Sintering

  • Chemical Debinding: 6h acetone bath at 40°C (>5% mass loss)

  • Thermal Debinding: 8°C/h ramp to 500°C (≈2.5 days) or accelerated cycle available

  • Sintering: 50°C/h to 1475°C with 2h hold in air atmosphere

FAQs

What makes black zirconia different from white zirconia?ics?

Black zirconia contains cobalt iron oxide pigment that provides the deep black color while maintaining the same exceptional mechanical properties as white zirconia—perfect for applications where black aesthetics are required.

Black zirconia can be finished as-sintered (matte black), brushed for satin finish, or polished to high gloss. The black color remains consistent through all finishing processes.

Luxury watch components, black consumer electronics, high-end jewelry, architectural details, premium kitchenware, and any application requiring both black aesthetics and ceramic performance.

Black zirconia offers exceptional bending strength (400-1000 MPa) and hardness (19 GPa), making it significantly stronger than most technical ceramics and ideal for functional, high-wear applications.

No, the black pigment is integrated during manufacturing and does not compromise the exceptional mechanical properties of the zirconia matrix.

Similar to white zirconia: maximum printed size determined by furnace, minimum wall: 1mm, minimum feature: 0.6mm. Follow the same design guidelines as white zirconia.

The material produces a consistent deep black. Different surface finishes (matte, brushed, polished) will affect the appearance but not the base color.

Printing varies by model. Chemical debinding takes 6h + 2h drying, thermal debinding ≈60h (or 23h accelerated), and sintering ≈29h including ramp times and holding.

tandard ceramic filament handling—use in well-ventilated areas, wear FFP2 masks during printing and handling. The sintered black zirconia is safe for handling.

One year when stored in original vacuum-sealed packaging in cool, dry conditions.

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]]> Zetamix Alumina Filament 1,75mm https://dev.additiveplus.com/product/zetamix-alumina-filament-175mm/ Wed, 01 Oct 2025 10:25:07 +0000 https://dev.additiveplus.com/?post_type=product&p=68760 Alumina ceramic filament: Print FDM parts → sinter into high-temperature resistant, electrically insulating components for extreme environments.

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Zetamix Alumina Filament enables direct production of advanced ceramic components using standard FDM 3D printers. Create parts with exceptional temperature resistance, excellent electrical insulation, and superior wear resistance—ideal for high-temperature applications, electrical insulation, and demanding industrial environments where conventional materials fail.

Why Engineers & Manufacturers Choose Zetamix Alumina

Extreme Temperature Performance

  • Withstands temperatures up to 1550°C after sintering

  • Excellent thermal stability and heat resistance

  • Ideal for furnace components, thermocouple tubes, and high-temperature tooling

  • Maintains mechanical properties in extreme thermal environments

Superior Electrical Properties

  • Excellent electrical insulator with dielectric constant of 9 (±0.5)

  • Low loss tangent: ≈1×10⁻³

  • Stable performance from -50°C to +110°C (±5%)

  • Perfect for electrical insulation applications

Exceptional Wear & Chemical Resistance

  • High hardness: 19 GPa (Hv10)

  • Excellent wear resistance for abrasive applications

  • Chemically inert – resistant to most acids and alkalis

  • 98-99% density for maximum durability

Material Properties After Sintering

filtre-bleu-scaled-1

  • Density: 98-99% of theoretical density

  • Bending Strength: 200-500 MPa

  • Hardness: 19 GPa (Hv10)

  • Dielectric Constant: 9 (±0.5) at 9.4 GHz

  • Melting Point: 2072°C

Your Path to High-Temperature Ceramic Parts

1. Design for Extreme Environments

  • Scale models by 126.2% (X/Y) and 130.2% (Z) for sintering shrinkage

  • Minimum part size: 6mm cube | Minimum wall: 1mm

  • Minimum pin diameter: 2.5mm | Minimum hole: 0.6mm (vertical)

  • Maximum overhang: 40° unsupported, 20° for ceilings

2. Precision Printing Protocol

  • Use grooved drive gears to prevent filament grinding

  • Print on flexible build plates for easy removal

  • 100% fan speed for optimal surface quality

  • 1mm retraction at 20 mm/s recommended

  • Maintain room temperature below 25°C (use AC if needed)

  • Minimum 2 wall layers with 5-100% infill density

3. Controlled Debinding & Sintering

  • Chemical Debinding: 6h acetone bath at 40°C (>5% mass loss)

  • Thermal Debinding: 8°C/h ramp to 500°C (≈2.5 days) or accelerated cycle available

  • Sintering: 50°C/h to 1550°C with 2h hold in air atmosphere

FAQs

What makes alumina ideal for high-temperature applications?

Alumina maintains excellent mechanical properties at extreme temperatures (up to 1550°C), offers outstanding thermal stability, and is chemically inert—making it perfect for furnace components, thermal processing, and high-temperature tooling.

Alumina offers superior temperature resistance (1550°C vs 1475°C for zirconia) and better electrical insulation, while zirconia provides higher mechanical strength. Choose alumina for extreme temperatures and electrical applications.

High-temperature furnace components, electrical insulators, thermocouple protection tubes, laboratory equipment, wear-resistant liners, chemical processing parts, and any application requiring thermal stability with electrical insulation.

Yes! Alumina is an excellent electrical insulator with a dielectric constant of 9 and low loss tangent, making it ideal for high-voltage insulation, circuit components, and electrical feedthroughs.

Alumina is highly chemically inert, resisting most acids, alkalis, and corrosive environments. This makes it suitable for chemical processing equipment, laboratory ware, and corrosive fluid handling.

Maximum printed size determined by furnace dimensions, minimum wall: 1mm, minimum feature: 0.6mm. Account for anisotropic shrinkage (different in X/Y vs Z directions).

Printing varies by model. Chemical debinding takes 6h + 2h drying, thermal debinding ≈60h (or 23h accelerated), and sintering ≈30h including ramp times and holding.

Use in well-ventilated areas, wear FFP2 masks during printing and handling. The sintered alumina is biologically inert and safe for handling.

Six months when stored in original vacuum-sealed packaging in cool, dry conditions.

Yes! This is a key advantage over traditional ceramic manufacturing. Create intricate internal cooling channels, complex fluid paths, and geometries impossible with conventional methods.

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]]> Zetamix Silicon Carbide Filament 1,75mm https://dev.additiveplus.com/product/zetamix-silicon-carbide-filament-175mm/ Wed, 01 Oct 2025 10:09:40 +0000 https://dev.additiveplus.com/?post_type=product&p=68747 Silicon carbide filament: Print FDM parts → sinter into ultra-hard, thermal-shock resistant components for extreme environments.

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Zetamix Silicon Carbide Filament enables direct production of one of the hardest technical ceramics using standard FDM 3D printers. Create components with exceptional hardness, superior thermal shock resistance, and outstanding wear performance—ideal for the most demanding aerospace, defense, and industrial applications where extreme durability is required.

Why Aerospace & Defense Engineers Choose Zetamix SiC

Extreme Hardness & Wear Resistance

  • Exceptional hardness: 25 GPa (Hv10) – among the hardest materials available

  • Superior abrasion resistance for high-wear applications

  • 400 MPa bending strength for structural components

  • 98-99% density for maximum performance

Superior Thermal Performance

  • Excellent thermal shock resistance

  • Maintains properties at extreme temperatures

  • Ideal for heat exchangers and thermal management systems

  • Stable in high-temperature environments

Advanced Application Capabilities

  • Aerospace mirrors and optical components

  • Defense and military applications

  • Wear-resistant industrial components

  • Lightweight yet extremely durable structures

Material Properties After Sintering

Nanoe-launches-a-Silicon-Carbide-filament-for-3D-printing-1024x768-1
  • Density: 98-99% of theoretical density
  • Hardness: 25 GPa (Hv10)
  • Bending Strength: 400 MPa
  • Composition: 78% SiC by mass

Your Path to Ultra-Hard Ceramic Parts

1. Design for Extreme Performance

  • Scale models to account for sintering shrinkage: 16.8% (X/Y) & 22.6% (Z)

  • Optimize for SiC’s exceptional hardness and thermal properties

  • Consider anisotropic effects on final part performance

2. Precision Printing Protocol

  • Use standard FDM/FFF printing techniques

  • Follow general Zetamix ceramic printing guidelines

  • Use appropriate drive gears to prevent filament grinding

  • Print on flexible build plates for easy remov

3. Advanced Thermal Processing

  • Chemical Debinding: Acetone process per general guidelines

  • Thermal Debinding: Standard ceramic thermal debinding process

  • Sintering: High-temperature process at 2200°C under controlled atmosphere (partial vacuum with Argon)

FAQs

What makes silicon carbide unique compared to other ceramics?

SiC offers exceptional hardness (25 GPa), superior thermal shock resistance, and excellent wear resistance—making it one of the most durable ceramic materials available, ideal for the most demanding applications.

Aerospace mirrors and optics, defense components, heat exchangers, wear-resistant industrial parts, and any application requiring extreme hardness combined with thermal stability.

At 25 GPa, silicon carbide is significantly harder than alumina (19 GPa) and zirconia (10-19 GPa), making it one of the hardest engineering ceramics available.

Sintering requires a high-temperature furnace capable of reaching 2200°C with controlled atmosphere (partial vacuum with Argon at 90 mb). This is more specialized than standard ceramic furnaces.

Yes! SiC can be polished to create high-quality mirrors and optical components, making it valuable for aerospace and defense applications where precision optics are required.

SiC can withstand rapid temperature changes without cracking, making it ideal for heat exchangers, rocket components, and other applications experiencing extreme thermal cycling

Follow standard ceramic design guidelines—avoid sharp corners, maintain uniform wall thicknesses, and account for significant sintering shrinkage in the Z-direction (22.6%).

Absolutely. SiC maintains its exceptional properties at high temperatures, making it ideal for thermal management systems, furnace components, and high-temperature processing equipment.

Silicon carbide is significantly lighter than most metals while offering superior hardness and wear resistance, providing excellent strength-to-weight ratio for aerospace applications.

Standard ceramic filament handling precautions apply. Use in well-ventilated areas and wear appropriate PPE during printing and handling.

The post Zetamix Silicon Carbide Filament 1,75mm appeared first on Dev.

]]> Zetamix Porcelain Filament 1,75mm https://dev.additiveplus.com/product/zetamix-porcelain-filament-175mm/ Mon, 29 Sep 2025 10:25:21 +0000 https://dev.additiveplus.com/?post_type=product&p=68641 Industrial porcelain filament: Print FDM prototypes → sinter into vitrified functional ceramics for tableware, art & technical applications.

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Zetamix Porcelain Filament bridges digital fabrication and traditional ceramics, enabling you to create authentic porcelain pieces using your standard FDM/FFF 3D printer. Print complex geometries impossible with conventional pottery, then transform your prints into durable, vitrified ceramics through our proven debinding and sintering process.

Why Designers & Engineers Choose Zetamix Porcelain

Proven Workflow Integration

  • Compatible with most FDM/FFF printers (0.4mm-1.0mm nozzles)

  • Clear debinding and sintering parameters for consistent results

  • Predictable shrinkage: 13.8% (X/Y) & 26.4% (Z) for precise scaling

Proven Workflow Integration

  • Compatible with most FDM/FFF printers (0.4mm-1.0mm nozzles)

  • Clear debinding and sintering parameters for consistent results

  • Predictable shrinkage: 13.8% (X/Y) & 26.4% (Z) for precise scaling

Material Properties After Sintering

porcelain-zetamix-1-e1759157759909

  • Density: 98-99% of theoretical density

  • Thermal Stability: Withstands repeated thermal cycling

  • Food Safety: Ideal for tableware applications (when glazed)

  • Mechanical Strength: Comparable to traditional porcelain

Your Path to Perfect Porcelain Prints

1. Design & Print

  • Scale models by 116% (X/Y) and 136% (Z) to accommodate sintering shrinkage

  • Use 3 wall layers minimum and 15-100% infill depending on application

  • Print on flexible build plates for easy removal

2. Debind with Confidence

  • Solvent Debinding: 24h in acetone bath at 40°C

  • Thermal Debinding: 7°C/h ramp from 50°C to 500°C

  • Achieve consistent binder removal for defect-free sintering

3. Sinter to Perfection

  • Heat to 1250°C at 125°C/h with 2h hold time

  • For enameling: pause at 1000°C, apply glaze, complete cycle to 1250°C

  • Achieve full vitrification and mechanical properties

FAQs

What equipment do I need beyond my 3D printer?

You’ll need acetone for solvent debinding and a high-temperature furnace capable of reaching 1250°C for sintering. The Zetasinter furnace is recommended for optimal results.

After proper sintering, parts achieve 98-99% density with mechanical strength comparable to traditionally manufactured porcelain, suitable for functional applications like tableware

Yes, Zetamix Porcelain works with most FDM/FFF printers. We recommend using a grooved drive gear rather than aggressive teeth to prevent filament grinding.

Use in well-ventilated areas, wear safety glasses and FFP2 masks when handling, and follow all MSDS guidelines. The material itself is not classified as dangerous but requires standard material handling precautions.

Printing times vary by model. Debinding takes approximately 2.5 days (including solvent and thermal stages), and sintering requires about 20 hours including ramp times and holding

After proper sintering and application of food-safe glaze, yes. The sintered porcelain itself is inert and non-toxic, making it ideal for tableware applications.

The filament has a one-year shelf life when stored in its original vacuum-sealed packaging in cool, dry conditions.

Failed prints and support material can be disposed of as non-hazardous waste according to local regulations. The unsintered material has minimal environmental impact.

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]]> Fila-MAT Alumina 1,75mm https://dev.additiveplus.com/product/fila-mat-alumina-175mm/ Tue, 08 Jul 2025 07:41:33 +0000 https://dev.additiveplus.com/?post_type=product&p=64023 A high-quality ceramic filament known for its exceptional strength, heat resistance, and outstanding mechanical properties. Ideal for precision 3D printing of complex parts in aerospace, automotive, and industrial applications.

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Parts_3D_printed_in_aluminia_pillars

FEATURES

Discover high-performance silicon carbide filament suitable for advanced thermal and electrical applications. Enhance your manufacturing with durable, heat-resistant, and electrically conductive silicon carbide filament.

Silicon carbide (SiC) filament is a specialized material designed for high-temperature and electrically demanding environments. Composed of finely grained silicon carbide particles spun into a filament, this material combines the exceptional properties of silicon carbide with processability for various manufacturing needs.

Known for its outstanding thermal conductivity and stability, silicon carbide filament can withstand temperatures exceeding 1600°C, making it ideal for aerospace, automotive, and industrial applications. Its high hardness and chemical inertness ensure durability and longevity, even in corrosive environments. Additionally, SiC filament exhibits good electrical conductivity, making it suitable for electronic components, heating elements, and resistive heating applications.

Key Features:

  • High thermal stability and conductivity
  • Superior mechanical strength and hardness
  • Chemical inertness and corrosion resistance
  • Excellent electrical conductivity
  • Suitable for high-temperature environments

This filament is compatible with advanced manufacturing processes like 3D printing, allowing for the creation of complex, high-performance components with precision and efficiency. Its lightweight yet robust nature offers designers and engineers the flexibility to innovate in high-performance material development.

Applications:

  • 3D printing of heat-resistant components
  • Thermal insulation and heat shields
  • Electrical resistors and heating elements
  • Aerospace and automotive parts
  • Chemical processing equipment

All tests have been performed according relevant standards with calibrated test equipment at ESA’s technology centre in the Netherlands (ESTEC).

M.A.T. is an Additive Manufacturing (AM) solution for the production of complex geometries made out of metals and ceramics. With the M.A.T., 3DCERAM TIWARI utilizes the Fused Filament Fabrication (FFF) technique to produce ceramic and metallic parts with a 3D-printer working with special filaments. The 3D- printed parts are then eliminated of any non-metallic or non-ceramic component (binder) with the help of heat treatment at high temperatures, yielding pure and resistant parts suitable for all engineering applications in a matter of days. This cost-effective technique is suitable for a number of metals and ceramics, including metal-ceramic or ceramic-ceramic composites, and is capable of producing parts with high relative density.

Diffusivity:

Temperature °CDiffusivity, α,mm^2/s
-99.773.859
-75.365.278
-50.657.079
-25.349.534
+23.639.24
+49.935.156
+100.728.842

The post Fila-MAT Alumina 1,75mm appeared first on Dev.

]]> Fila-MAT Silicon Carbide 1,75mm https://dev.additiveplus.com/product/fila-mat-silicon-carbide-175mm/ Fri, 04 Jul 2025 15:46:18 +0000 https://dev.additiveplus.com/?post_type=product&p=63978 A high-strength, heat-resistant filament made from silicon carbide particles. Ideal for 3D printing, thermal insulation, and electrical applications, it offers excellent thermal stability, high hardness, and chemical resistance.

The post Fila-MAT Silicon Carbide 1,75mm appeared first on Dev.

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MAT-11

FEATURES

Discover high-performance silicon carbide filament suitable for advanced thermal and electrical applications. Enhance your manufacturing with durable, heat-resistant, and electrically conductive silicon carbide filament.

Silicon carbide (SiC) filament is a specialized material designed for high-temperature and electrically demanding environments. Composed of finely grained silicon carbide particles spun into a filament, this material combines the exceptional properties of silicon carbide with processability for various manufacturing needs.

Known for its outstanding thermal conductivity and stability, silicon carbide filament can withstand temperatures exceeding 1600°C, making it ideal for aerospace, automotive, and industrial applications. Its high hardness and chemical inertness ensure durability and longevity, even in corrosive environments. Additionally, SiC filament exhibits good electrical conductivity, making it suitable for electronic components, heating elements, and resistive heating applications.

Key Features:

  • High thermal stability and conductivity
  • Superior mechanical strength and hardness
  • Chemical inertness and corrosion resistance
  • Excellent electrical conductivity
  • Suitable for high-temperature environments

This filament is compatible with advanced manufacturing processes like 3D printing, allowing for the creation of complex, high-performance components with precision and efficiency. Its lightweight yet robust nature offers designers and engineers the flexibility to innovate in high-performance material development.

Applications:

  • 3D printing of heat-resistant components
  • Thermal insulation and heat shields
  • Electrical resistors and heating elements
  • Aerospace and automotive parts
  • Chemical processing equipment

All tests have been performed according relevant standards with calibrated test equipment at ESA’s technology centre in the Netherlands (ESTEC).

M.A.T. is an Additive Manufacturing (AM) solution for the production of complex geometries made out of metals and ceramics. With the M.A.T., 3DCERAM TIWARI utilizes the Fused Filament Fabrication (FFF) technique to produce ceramic and metallic parts with a 3D-printer working with special filaments. The 3D- printed parts are then eliminated of any non-metallic or non-ceramic component (binder) with the help of heat treatment at high temperatures, yielding pure and resistant parts suitable for all engineering applications in a matter of days. This cost-effective technique is suitable for a number of metals and ceramics, including metal-ceramic or ceramic-ceramic composites, and is capable of producing parts with high relative density.

Diffusivity:

Temperature °CDiffusivity, α,mm^2/s
-99.773.859
-75.365.278
-50.657.079
-25.349.534
+23.639.24
+49.935.156
+100.728.842

The post Fila-MAT Silicon Carbide 1,75mm appeared first on Dev.

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