Everything You Need to Know About 3D Print Materials

The Core Categories of 3D Printing Materials

Thermoplastics

Thermosetting Plastics

What Materials Can Be 3D Printed?

Popular Plastic 3D Printing Materials

• PLA (Polylactic Acid): This material is often the preferred choice for many users due to its ease of use, dimensional accuracy, and low cost. It is aesthetically pleasing, useful for creating visualization aids and concept models, and biodegradable. PLA typically offers a good surface quality, prints reliably with low shrinkage, but is not considered strong enough for functional or mechanical parts and has limited resistance to heat and chemicals. It is also an odourless material.

• ABS (Acrylonitrile Butadiene Styrene): Known for its toughness, durability, and resistance to heat (up to 85°C) and impact, ABS is a popular choice for prototyping and fit testing, particularly in industries such as aviation, automotive, and industrial product development. It offers good mechanical properties but is adversely affected by UV light and typically requires a heated print bed and proper ventilation during use.
• PETG (Polyethylene Terephthalate Glycol): This material is known for its ease of printability, smooth surface finish, and resistance to water, humidity, and chemicals. It also boasts high transparency and can be food safe, making it suitable for waterproof applications and snap-fit components. PETG is compatible with lower printing temperatures, allowing for faster production.

• Nylon (Polyamide): Nylon is a strong, impact-resistant, and semi-flexible material that offers high resistance to abrasion and corrosion. It is a reliable and easy-to-use option, popular across a wide range of industries for printing tools, prototypes, and end-use parts. It is also lightweight and stable against UV light, heat, moisture, solvents, temperature, and water.
• TPU (Thermoplastic Polyurethane) / Flexible Filaments: This semi-flexible material is highly valued for its elasticity and flexibility, providing a rubber-like effect for prototypes or end-use parts. It is strong, impact-resistant, and does not deform or break under high impact. TPU is resistant to many common oils and chemicals and is easy to print, making it useful for vibration dampening and flexible prototypes.
• ASA (Acrylonitrile Styrene Acrylate): As a common alternative to ABS, ASA is highly suited for outdoor applications due to its superior resistance to UV light, high temperatures, and impact.

Specialty Plastics & Composites

• CPE (co-polyester) and CPE+: CPE is as strong as ABS but is odourless, making it popular for industrial use in prototypes and tooling. It boasts high tensile strength, dimensional stability, chemical resistance, and emits limited volatile organic compounds (VOCs) and ultrafine particles (UFPs). CPE+ offers even greater strength and heat resistance than CPE.
• PC (Polycarbonate): Favoured by engineers, PC is one of the toughest materials available. It is ideal for applications requiring high heat resistance, impact resistance, UV stability, dimensional stability, chemical resistance, and flame retardancy, such as molds, lighting, and engineering parts.
• HIPS (High Impact Polystyrene): This lightweight material is most commonly used as a dissolvable support structure for ABS models, dissolving in chemical limonene.
• PVA (Polyvinyl Alcohol): PVA is well-known for its ability to dissolve in water and is frequently employed as a support material for complex prints.
• Composites (e.g., carbon fibre, Kevlar, fibreglass-filled): These filaments contain short fibres infused into a PLA or ABS base material to increase strength and stiffness. Their compatibility may be limited to more advanced or industrial FDM 3D printers and they are suitable for functional prototypes, jigs, fixtures, and tooling.
• Metal-filled filaments: These are created by mixing a fine metal powder into a base material, providing a unique metallic finish and added weight to the printed object.
• Wood-filled filaments: Combining a PLA base material with cork, wood dust, or other derivatives, these filaments give models a real wooden look and feel.

Metal 3D Printer Printing Material Options

• Processes: Metal 3D printing can be achieved through various processes, including Metal Fused Filament Fabrication (which extrudes metal rods held by polymer binders, followed by sintering), Selective Laser Melting (SLM), and Direct Metal Laser Sintering (DMLS). SLM and DMLS utilize lasers to fuse metal powder particles layer by layer, creating strong, accurate, and complex metal products ideal for aerospace, automotive, and medical applications.
• Popular Metal Materials:
  • Titanium: A lightweight material with excellent mechanical characteristics, it is strong, hard, and highly resistant to heat, oxidation, and acid.
  • Stainless steel: Offers high strength, ductility, and resistance to corrosion.
  • Aluminum: Known for being lightweight, durable, strong, and possessing good thermal properties.
  • Tool steel: A hard, scratch-resistant material suitable for printing end-use tools and other high-strength parts.
  • Nickel alloys: These materials exhibit high tensile, creep, and rupture strength, alongside good heat and corrosion resistance.
• Alternatives to Metal 3D Printing: Direct metal 3D printing can be costly and complex. Alternatives include using SLA 3D printing for casting workflows, which can produce metal parts at a lower cost and with greater design freedom, or electroplating SLA parts, which coats a plastic material in a layer of metal via electrolysis, combining metal qualities with plastic properties.

Ceramic 3D Printing Materials

How Different 3D Printing Technologies Use 3D Printer Material

Fused Deposition Modelling (FDM): What material does a 3D printer use?

Stereolithography (SLA): What is 3D Printing Material in Liquid Form?

Selective Laser Sintering (SLS): What Materials Can Be 3D Printed with Powder?

Other Key 3D Printing Processes and Their 3D Print Materials

• Material Jetting (MJ) and Drop on Demand (DOD): These technologies use droplets of photopolymer resin.
• Binder Jetting (BJ): This process employs a print head to drop binder droplets onto a powder surface, with sand or metal powder being the optimal material.
• Direct Metal Laser Sintering (DMLS) and Selective Laser Melting (SLM): These metal additive manufacturing processes add metal powder (e.g., aluminum, stainless steel, or titanium) as the object is being printed.

Choosing the Right 3D Print Material: A Practical Guide

Defining Your Project's Performance Requirements for 3D Printing Material

• Low performance: For form and fit prototyping, conceptual modelling, where parts only need to meet low technical performance requirements, such as a good surface finish.
• Moderate performance: For validation or pre-production uses, where parts must behave as closely to final production parts as possible for functional testing, but without strict lifetime requirements.
• High performance: For end-use parts, where 3D printed production parts must withstand significant wear for a specific period, demanding strict lifetime testing and robust properties.

Key Material Properties to Consider in Any 3D Printing Material

Evaluating these properties is paramount:

• Good surface quality: Vital for aesthetic presentations of concepts or architectural models.
• Low shrinkage: Crucial for dimensional precision, ensuring accurate preservation of dimensions during and after printing.
• Toughness and durability: Essential for end-use parts and tools that must withstand repeated use and resist breaking.
• Thermal resistance (Heat deflection temperature): Beneficial for prototypes requiring greater design freedom and for applications exposed to high temperatures, indicating the temperature at which a material deforms under a specified load.
• High tensile strength: Important for tools and structural components that need to withstand high levels of tension without breaking.
• Chemical resistance: Required for objects that will regularly come into contact with chemicals without degrading.
• Ease of use: Materials that print "first-time right" and are not susceptible to atmospheric conditions enhance efficiency.
• Flexibility (Flexural modulus, Elongation): Necessary for products that need to bend, stretch, or flex without snapping under pressure. Flexural modulus indicates stiffness, while elongation measures how much a material can stretch before breaking.
• Electrical resistance: Though less common, some applications require materials that insulate electricity or prevent static electricity discharge for safety reasons.
• Impact strength: The ability of a material to absorb shock and impact energy without breaking, indicating toughness and durability.
• Hardness (Durometer): Resistance of a material to surface deformation, important for selecting the right "softness" for flexible materials.
• Tear strength: Resistance of a material to the growth of cuts under tension, crucial for assessing the durability of soft plastics.
• Creep: The tendency of a material to deform permanently under constant stress; low creep indicates longevity for structural parts.
• Compression set: Permanent deformation after a material has been compressed, important for elastic applications to determine if a material will return to its original shape.

Compatibility and Printer Considerations for Your 3D Printer Printing Material

Frequently Asked Questions about 3D Print Materials

What material is used for 3D printing most often?

What materials can be 3D printed for beginners?

What material does a 3D printer use for high-speed printing?

What material is used in 3D printing for impact-resistant parts?

What material is used for 3D printing dissolvable supports?