Metal Filament – Dev https://dev.additiveplus.com Tue, 30 Sep 2025 13:50:16 +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 Metal 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 TiO2 Filament 1,75mm https://dev.additiveplus.com/product/zetamix-tio2-filament-175mm/ Tue, 30 Sep 2025 10:26:57 +0000 https://dev.additiveplus.com/?post_type=product&p=68721 TiO2 ceramic filament: Print FDM RF components → sinter into high-permittivity (ε=75) parts for microwave & antenna applications.

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Zetamix TiO2 Filament enables direct manufacturing of specialized ceramic components with exceptional dielectric properties using standard FDM 3D printers. Create complex RF/microwave devices, antennas, and waveguides with permittivity values unmatched by conventional materials—opening new possibilities in high-frequency electronics and telecommunications.

Why RF Engineers & Researchers Choose Zetamix TiO2

Exceptional Dielectric Performance

  • Very high permittivity: ε = 75 (±5) at 9.4 GHz

  • Low loss tangent: 1×10⁻³ to 5×10⁻³

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

  • Ideal for miniaturizing RF components and antennas

Advanced Ceramic Properties

  • 98-99% theoretical density after sintering

  • Titanium dioxide (rutile) composition – 81% by mass

  • Excellent thermal and chemical stability

  • White ceramic appearance after sintering

Precision Manufacturing Workflow

  •  Predictable shrinkage: 18.97% (X/Y) & 20.44% (Z)
  • Optimized for complex geometries impossible with traditional ceramics
  • Batch-consistent dielectric properties
  • Compatible with most FDM/FFF systems

Dielectric & Material Properties

1743000137463

  • Dielectric Constant: 75 ±5 (@ 9.4 GHz)

  • Loss Tangent: 0.001 – 0.005

  • Sintered Density: 98-99% of theoretical

  • Specific Gravity: 2.59 g/cm³ (filament)

Your Path to Advanced RF Components

1. Design for RF Performance

  • Scale models by 123.4% (X/Y) and 125.7% (Z) for sintering shrinkage

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

  • Optimize for high-frequency performance requirements

  • Consider anisotropic effects on dielectric properties

2. Precision Printing Protocol

  • Use grooved drive gears to prevent filament grinding

  • Print on flexible build plates for easy removal

  • No cooling fan required during printing

  • 0.5mm retraction at 80 mm/s recommended

3. Controlled Debinding & Sintering

  • Chemical Debinding: 6h acetone bath at 40°C (>7% mass loss)

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

  • Sintering: 30°C/h to 1300°C with 2h hold in air atmosphere

FAQs

What makes TiO2 particularly valuable for RF applications?

TiO2 (rutile) offers an exceptionally high dielectric constant (ε=75) with low loss, enabling miniaturization of RF components while maintaining performance—ideal for antennas, filters, and waveguides.

Excellent stability—the dielectric constant varies only ±5% across a wide temperature range from -50°C to +110°C, making it suitable for demanding environmental conditions.

Microwave antennas, waveguide components, RF filters, dielectric resonators, phase array systems, and any application requiring high permittivity with low loss at microwave frequencies.

Proper sintering to 1300°C achieves 98-99% density, which is crucial for consistent dielectric performance. Lower densities may reduce the permittivity value.

Standard ceramic design rules apply—avoid sharp corners, maintain uniform wall thicknesses where possible, and account for anisotropic shrinkage (different in X/Y vs Z).

Yes! This is a key advantage over traditional ceramic manufacturing. Create intricate waveguide structures, complex antenna shapes, and internal channels impossible with conventional methods.

Printing varies by model. Chemical debinding takes 6h + 2h drying, thermal debinding ≈60h, and sintering ≈43h including ramp times and holding.

Standard ceramic filament handling—use in well-ventilated areas during printing and debinding. The sintered TiO2 is biologically inert and safe for handling.

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

The ε=75 is characteristic of fully dense rutile TiO2. Variations in sintering density or the use of composite designs can modify effective permittivity for specific applications

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]]> Zetamix 17-4PH Stainless Steel Filament 1,75mm https://dev.additiveplus.com/product/zetamix17-4ph-stainless-steel-filament-175mm/ Mon, 29 Sep 2025 15:33:38 +0000 https://dev.additiveplus.com/?post_type=product&p=68703 17-4PH stainless steel filament: Print FDM parts → sinter into high-strength, corrosion-resistant components for demanding industrial applications.

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Zetamix 17-4PH Stainless Steel Filament enables direct production of precipitation hardening steel components using standard FDM 3D printers. Create parts with exceptional mechanical properties—high tensile strength, superior hardness, and excellent corrosion resistance—for the most demanding aerospace, marine, and industrial applications without traditional manufacturing constraints.

Why Tooling Engineers & Manufacturers Choose Zetamix H13

Exceptional Mechanical Properties

  • High tensile strength and hardness after sintering and heat treatment

  • Precipitation hardening capability for tailored mechanical properties

  • Superior corrosion resistance compared to standard stainless steels

  • 92% metal content by mass for authentic material performance

Corrosion & Wear Resistance

  • Excellent resistance to corrosive environments including marine applications

  • Maintains mechanical properties in high-stress, corrosive conditions

  • Ideal for valves, pumps, shafts, and marine components

  • Withstands harsh chemical exposure better than 316L stainless

Precision Manufacturing Workflow

  • Predictable shrinkage: 15.4% (X/Y) & 14.7% (Z) for accurate scaling

  • Compatible with Zetasinter furnace for repeatable results

  • Design freedom for complex geometries impossible with machining

  • Batch-specific technical data for consistent outcomes

Material Properties After Sintering

navy-316L-1-560x373-1

  • Density: >90% of theoretical density

  • Tensile Strength: Comparable to wrought 17-4PH (with heat treatment)

  • Corrosion Resistance: Excellent for marine and chemical environments

  • Hardness: Can be precipitation hardened to HRC 40+ with proper heat treatment

Your Path to Advanced Tool Manufacturing

1. Design for Strength & Function

  • Scale models by 118.2% (X/Y) and 117.2% (Z) for sintering shrinkage

  • Minimum wall thickness: 1mm | Minimum feature size: 1.5mm

  • Maximum overhang: 35° unsupported

  • Optimize for anisotropic properties – layer orientation affects strength

2. Precision Printing Protocol

  • Use grooved drive gears to prevent filament grinding

  • Print on flexible build plates for easy removal

  • 3 wall layers minimum with 20-100% infill density

  • 100% fan speed from second layer for optimal surface quality

3. Controlled Debinding & Sintering

  • Chemical Debinding: 24h acetone bath at 40°C (>4% mass loss)

  • Thermal Debinding: 10°C/h ramp from 50°C to 650°C in Ar/H₂

  • Sintering: 50°C/h to 1350°C with 2h hold in controlled atmosphere

  • Atmosphere Control: 0.5 LPM flow at 0.2 bar pressure

FAQs

What makes 17-4PH different from other stainless steels?

17-4PH is a precipitation hardening steel that can be heat treated to achieve high strength (up to 1100 MPa) and hardness (HRC 40+) while maintaining excellent corrosion resistance—making it ideal for high-stress applications.

After sintering, additional heat treatment (aging at 480-620°C) can be applied to achieve the full precipitation hardening effect and maximum mechanical properties.

Aerospace components, marine hardware, chemical processing equipment, high-strength fasteners, pump shafts, valves, and any application requiring the combination of high strength and corrosion resistance.

 17-4PH offers superior strength and hardness while maintaining excellent corrosion resistance, though 316L may have slightly better resistance to certain corrosive environments. 17-4PH is preferred where both strength and corrosion resistance are critical.

Use in well-ventilated areas, wear FFP2 masks and safety glasses. The raw powder form is hazardous, but the filament is not classified as dangerous when handled properly.

Similar to other Zetamix metals: maximum printed size ~200mm, minimum wall: 1mm, minimum feature: 1.5mm. Follow design guide recommendations for successful sintering.

Printing varies by model. Chemical debinding takes 24h + 2h drying, thermal debinding ~60h, and sintering ~28h including ramp times and holding.

The sintered 17-4PH has excellent corrosion resistance and can be used in food processing applications. For medical implants, additional certification and testing would be required.

Sintered parts can be machined, polished, and most importantly, precipitation hardened through heat treatment to achieve specific mechanical properties.

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

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]]> Zetamix H13 Tool Steel Filament 1,75mm https://dev.additiveplus.com/product/zetamix-h13-tool-steel-filament-175mm/ Mon, 29 Sep 2025 13:33:48 +0000 https://dev.additiveplus.com/?post_type=product&p=68663 Print FDM tooling → sinter into high-temp resistant molds, extrusion dies & durable industrial tools.

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Zetamix H13 Tool Steel Filament enables direct manufacturing of high-performance tooling components using standard FDM 3D printers. Create complex injection molds, extrusion dies, and hot work tools with material properties approaching traditional H13 steel—bypassing costly machining and lead times for critical tooling applications.

Why Tooling Engineers & Manufacturers Choose Zetamix H13

High-Temperature Performance

  • Maintains strength and hardness at elevated temperatures

  • Ideal for injection molds, extrusion dies, and hot work applications

  • Excellent thermal conductivity for efficient heat management

  • Resistance to thermal fatigue and cracking

Complex Geometry Capability

  • Create conformal cooling channels impossible with machining

  • Manufacture intricate mold textures and features

  • Produce replacement tooling components on-demand

  • Scale: 118.2% (X/Y) and 119.6% (Z) for sintering compensation

Tooling-Grade Material Properties

  • 90-91% density after sintering for near-wrought performance

  • High ductility reduces risk of brittle fracture in tooling applications

  • Corrosion resistance for extended tool life

  • X40CrMoV5-1 composition (90% steel by mass)

Material Properties After Sintering

navy-316L-1-560x373-1

  • Density: 90-91% of theoretical density

  • Temperature Resistance: Excellent for hot work applications

  • Ductility: High impact resistance for durable tooling

  • Thermal Conductivity: Efficient heat dissipation

Your Path to Advanced Tool Manufacturing

1. Design for Tooling Performance

  • Maximum printed size: 200mm (100mm recommended)

  • Minimum wall thickness: 1mm | Minimum pin diameter: 3mm

  • Minimum unsupported overhang: 35° | Minimum hole size: 1.5mm

  • Avoid abrupt size changes; use rounded corners for stress reduction

2. Precision Printing Requirements

  • Critical: Maintain ambient temperature below 25°C (air conditioning required)

  • Use grooved drive gears to prevent filament grinding

  • No retraction recommended for consistent extrusion

  • 3 wall layers minimum with 20-100% infill density

  • 100% fan speed from second layer for optimal quality

3. Thermal Processing

  • Thermal Debinding: 10°C/h ramp from 50°C to 650°C in Ar/H₂ atmosphere

  • Sintering: 50°C/h to 1350°C with 2h hold in controlled atmosphere

  • Atmosphere Control: 0.5 LPM flow at 0.2 bar pressure

FAQs

What makes H13 steel suitable for tooling applications?

H13 maintains strength at high temperatures (500°C+), offers excellent thermal fatigue resistance, and has good toughness—making it ideal for injection molds, extrusion dies, and hot work tooling.

The printing room must not exceed 25°C. If ambient temperatures are higher, air conditioning is mandatory to ensure successful prints.

Sintered parts achieve 90-91% density with high temperature resistance and ductility suitable for functional tooling applications, though slightly below wrought H13 due to porosity.

Use in well-ventilated areas, wear FFP2 masks and safety glasses. The filament contains phenol (<5%)—avoid skin contact and inhalation of fumes during printing.

Yes! This is a key advantage—create complex internal cooling channels impossible with traditional machining to significantly reduce cycle times.

Maximum printed size: 200mm, minimum wall: 1mm, minimum feature: 1.5mm. Follow design guide recommendations for successful sintering.

Printing varies by model. Thermal debinding takes approximately 60 hours, and sintering requires about 28 hours including ramp times and holding.

Injection molds, extrusion dies, hot stamps, forging dies, and any tooling requiring high temperature resistance, durability, and complex geometries.

No—H13 uses thermal debinding only, simplifying the process compared to other metal filaments.

One-year shelf life when stored in original vacuum-sealed packaging in cool, dry conditions below 25°C.

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]]> Zetamix 316L Steel Filament 1,75mm https://dev.additiveplus.com/product/zetamix-316l-steel-filament-175mm/ Mon, 29 Sep 2025 11:34:21 +0000 https://dev.additiveplus.com/?post_type=product&p=68653 Industrial 316L stainless steel filament: Print FDM tooling → sinter into corrosion-resistant, impact-resistant functional metal parts.

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Zetamix 316L Stainless Steel Filament transforms standard 3D printing into metal manufacturing, enabling you to create industrial-grade metal components with complex geometries impossible through traditional machining. From durable tooling to corrosion-resistant fluid system parts, achieve near-wrought metal properties through our proven debinding and sintering process

Why Manufacturing & Engineering Teams Choose Zetamix 316L

Certified Material Performance

  • Authentic 316L stainless steel composition (92% metal by mass)

  • Corrosion resistance meeting ASTM A240 standards

  • Impact strength 2.5x higher than sintered ceramics

  • 16 W/m·K thermal conductivity for heat management applications

Industrial Application Ready

  • Functional tooling surviving >10k injection cycles

  • Salt-spray resistant marine and chemical processing components

  • CIP/SIP-compatible fluid fittings and valves

  • Biocompatible potential (meets ASTM F138 post-processing)

Precision Manufacturing Workflow

  • Predictable shrinkage: 15.4% (X/Y) & 14.7% (Z) for accurate scaling

  • Zetasinter furnace compatibility for repeatable results

  • Design guidelines for manufacturability and performance

Material Properties After Sintering

316-L-steel-zetamix-1-e1759158817547
  • Density: >90% of theoretical density
  • Corrosion Resistance: Excellent against acids, chlorides, saline
  • Impact Strength: Superior to ceramic alternatives
  • Thermal Performance: Withstands high-temperature applications
  •  

Your Path to Precision Metal Parts

1. Design for Metal

  • Scale models by 118.2% (X/Y) and 117.2% (Z) for sintering shrinkage

  • Minimum wall thickness: 1mm | Minimum pin diameter: 3mm

  • Maximum overhang: 35° unsupported | Minimum hole size: 1.5mm

  • Maximum part size: 200mm (printed) with optimal furnace dimensions

2. Print with Confidence

  • Use grooved drive gears to prevent filament grinding

  • Print on flexible build plates for easy removal

  • Maintain consistent extrusion at 120-130°C

  • 3 wall layers minimum with 20-100% infill density

3. Debind & Sinter

  • Chemical Debinding: 24h in acetone bath at 40°C (>4% mass loss)

  • Thermal Debinding: 10°C/h ramp from 50°C to 650°C in Ar/H₂ atmosphere

  • Sintering: 50°C/h to 1350°C with 2h hold in controlled atmosphere

FAQs

What equipment do I need beyond my 3D printer?

You’ll need acetone for solvent debinding and a high-temperature furnace capable of 1350°C with argon/hydrogen atmosphere control. The Zetasinter furnace is optimized for this process.

After proper sintering, parts achieve >90% density with corrosion resistance and mechanical properties suitable for functional applications, though slightly below wrought metal due to porosity.

Maximum printed size: 200mm (recommended: 100mm), minimum wall thickness: 1mm, minimum feature size: 1.5mm. Avoid abrupt size changes and use rounded corners.

Use in well-ventilated areas, wear FFP2 masks when handling, and safety glasses. The raw powder form is hazardous, but the filament is not classified as dangerous when handled properly.

The sintered 316L meets ASTM F138 for implant-grade biocompatibility with proper post-processing, making it suitable for medical prototypes and some food processing applications.

Printing varies by model. Debinding takes approximately 64 hours (chemical + thermal), and sintering requires about 30 hours including ramp times and holding.

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

Ideal for jigs/fixtures, fluid system components, marine hardware, thermal management parts, and low-volume production where complex geometries make machining impractical.t.

Yes, use standard FDM support structures. They are removed during the debinding process along with the primary binder system.

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]]> Fila-MAT Metal Copper 1,75mm https://dev.additiveplus.com/product/fila-mat-metal-copper-175mm/ Tue, 08 Jul 2025 08:48:30 +0000 https://dev.additiveplus.com/?post_type=product&p=64030 An unique composite material that combines the aesthetic appeal of copper with the ease of Fused Filament Fabrication (FFF).

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TIWARI-copper-780x470-1

FEATURES

Metal Copper filament is an innovative 3D printing material that offers the distinctive look and properties of copper in an easy-to-use format. Formulated with a blend of fine copper particles and a thermoplastic binder, this filament allows you to create stunning metallic prints with an authentic copper finish. One of the standout features of Metal Copper filament is its excellent electrical conductivity, making it suitable for applications that require electrical connections or conductive pathways.

Additionally, it boasts impressive mechanical properties, ensuring that your printed parts are both strong and durable. Compatible with Fused Filament Fabrication (FFF) printers, Metal Copper filament provides the flexibility to create intricate designs and detailed geometries. Its unique composition allows for smooth extrusion and reliable layer adhesion, resulting in high-quality prints with a beautiful metallic sheen.

Ideal for functional prototypes and decorative items, Metal Copper filament opens up a world of creative possibilities.

Whether you’re designing jewelry, custom fixtures, or electronic housings, this filament delivers both aesthetic appeal and performance.

Applications:

• Artistic sculptures and decorative items

• Functional prototypes requiring conductivity

• Custom jewelry and accessories

• Electronic housings and components

• Architectural models with a metallic finish

Advantages:

• Authentic copper appearance with a metallic finish

• Excellent electrical conductivity

• Strong and durable prints

• Easy to print with FFF technology

• Versatile for a wide range of applications

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
-90.168.72
-70.369.38
-45.369.72
-24.269.03
+26.470.33
+51.674.7
+90.977.47

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]]> Fila-MAT Metal 174PH 1,75mm https://dev.additiveplus.com/product/fila-mat-metal-174ph-175mm/ Mon, 07 Jul 2025 16:00:25 +0000 https://dev.additiveplus.com/?post_type=product&p=64017 174PH filament is a high-quality metal filament made from 174PH alloy, renowned for its exceptional strength, heat resistance, and excellent mechanical properties. Ideal for precision 3D printing of complex parts in aerospace, automotive, and industrial applications.

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TIWARI-3-1-640x480-1

FEATURES

174PH filament is a cutting-edge material specifically engineered for advanced metal additive manufacturing. Composed of finely processed 174PH stainless steel, this filament enables the direct 3D printing of intricate, durable components with superior surface finish and mechanical performance.

Known for its outstanding heat resistance and strength, 174PH is widely utilized in demanding environments such as aerospace and automotive industries. Its unique composition provides excellent durability while maintaining lightweight properties, making it suitable for high-performance applications.

The filament’s ability to withstand elevated temperatures ensures reliability in critical components subject to thermal stress.

The 174PH filament allows manufacturers to produce complex geometries with high accuracy and minimal waste. This significantly reduces lead times and costs compared to traditional manufacturing methods. With its impressive strength, heat resistance, and versatility, 174PH filament is perfect for creating functional parts, prototypes, and custom components that require both durability and precision.

Applications:

• Aerospace components and structures

• Automotive parts requiring heat resistance

• Industrial machinery and tools

• Prototypes for high-performance applications

• Custom fixtures and specialized equipment

Advantages:

• Exceptional heat resistance and strength

• Lightweight yet durable

• Suitable for complex designs with high precision

• Compatible with various sintering and finishing processes

• Ideal for applications demanding performance and reliability

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.

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]]> Fila-MAT Metal 316L 1,75mm https://dev.additiveplus.com/product/fila-mat-metal-316l-175mm/ Fri, 04 Jul 2025 16:07:14 +0000 https://dev.additiveplus.com/?post_type=product&p=63984 A high-grade metal filament made from 316L alloy, known for its excellent corrosion resistance, strength, and ductility. Perfect for precision 3D printing of complex metal parts in medical, automotive, and industrial applications.

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Parts_3D_printed_in_aluminia_pillars

FEATURES

Alumina filament is an innovative material specifically engineered for advanced ceramic additive manufacturing. Composed of finely processed alumina, this filament enables the direct 3D printing of intricate, durable components with superior surface finish and mechanical performance.

Renowned for its remarkable heat resistance and strength, Alumina is widely utilized in demanding environments such as aerospace and automotive industries. Its unique composition provides excellent durability while remaining lightweight, making it suitable for high-performance applications. The filament’s ability to withstand elevated temperatures ensures reliability in critical components subjected to thermal stress.

Compatible with cutting-edge 3D printing techniques like Fused Filament Fabrication (FFF), Alumina filament allows manufacturers to produce complex geometries with high accuracy and minimal waste. This significantly reduces lead times and costs compared to traditional manufacturing methods.

With its impressive strength, heat resistance, and versatility, Alumina filament is perfect for creating functional parts, prototypes, and custom components that require both durability and precision.

Applications:

• Aerospace components and structures

• Automotive parts requiring heat resistance

• Industrial machinery and tools

• Prototypes for high-performance applications

• Custom fixtures and specialized equipment

Advantages:

• Exceptional heat resistance and strength

• Lightweight yet durable

• Suitable for complex designs with high precision

• Compatible with various finishing processes

• Ideal for applications demanding performance and reliability

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
-100.834.01
-7626.847
-51.720.682
-24.916.416
23.711.407
50.39.676
100.57.51

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]]> Fila-MAT Metal Titanium 1,75mm https://dev.additiveplus.com/product/fila-mat-metal-titanium-175mm/ Fri, 04 Jul 2025 14:57:15 +0000 https://dev.additiveplus.com/?post_type=product&p=63943 Strength and lightweight durability with our premium Titanium 3D Printing Filament.

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TIWARI-3-1-640x480-1

FEATURES

Experience unmatched strength and lightweight durability with our premium Titanium 3D Printing Filament. Perfect for aerospace, automotive, medical, and high-precision engineering applications, our titanium filament offers superior corrosion resistance, excellent thermal stability, and outstanding mechanical properties.

Key Features:

  • High Strength-to-Weight Ratio: Achieve robust and durable parts without adding unnecessary weight.
  • Corrosion Resistant: Ideal for applications in harsh environments and long-term use.
  • Excellent Surface Finish: Produces smooth, high-quality prints with fine details. –
  • Biocompatibility: Suitable for medical prototypes and implants.

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 °C Diffusivity, α,mm^2/s
-100.9 2.418
-74.9 2.526
-49.4 2.423
-24.1 2.603
+1 2.768
+29 2.803
+50.5 2.877

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