What materials can 3d printers print


What Materials Can be 3D Printed?

Using the right material for your 3D printed project can make or break a product. This article covers what materials you can 3d print.

Over the years, 3D printing has become increasingly common. This technology (also known as additive manufacturing) is now readily available — many public libraries and schools offer 3D printing services at no charge, and 3D printing materials can be easily found. From the automotive and aerospace industries to medicine and food safety, supporting material is either soluble and insoluble, and 3D printing processes are everywhere. But what materials can be 3D printed? Let’s take a look at the various options available. 

Many 3D printers rely on Fused Deposition Modeling (FDM). This helps product prototypes by layering from the bottom up with heat and thermoplastic filaments. These machines use a variety of materials, both expensive and affordable.

Stereolithography (SLA) is another method of 3D printing, which relies on a UV laser that cures layers in a photo-reactive epoxy resin. It’s more accurate than FDM and is an excellent choice for engineers who need small features or other detailed work. 

In Selective Laser Sintering (SLS) 3D printing, a high-power laser fuses tiny polymer powder particles. Though we will not be discussing this 3d printing method, it’s important to emphasize that various materials exist for all types of additive manufacturing.

Back to Basics with Thermoplastics

There are many options to choose from when looking to 3D print something using plastic, which is likely the most common material used. Plastic is utilized for its versatility and can be applied to various projects, offering anything from shiny and matte textures to projects with unique colors. The post-processing step for 3D printed plastics may be more robust. Still, the affordability and potential strength often outweigh the minor downfalls. Items 3D printed with plastic are created layer by layer with thermoplastic filaments, which include plastic made from: 

  • Polylactic Acid, or PLA: Biodegradable PLA, produced from corn starch and sugar cane, is a favored 3D printing material because it’s more sustainable than most other materials. It also leads to more robust products overall. PLA is the cheapest material for 3D printing and is used both at home and on larger industrial projects. 
  • Polyamide. Polyamide is a widespread choice for 3D printing, both at home and industrially, because it is so varied. It’s cheap, includes interlinking and interlocking parts, and can be painted and dyed. 
  • Polyvinyl Alcohol Plastic or PVA: PVA is used with some frequency because it is low-cost and the material of choice for many in-home printers used more for play. Overall, it lacks strength but is a decent choice for items that aren’t frequently used and for those new to 3D printing.
  • Acrylonitrile Butadiene Styrene or ABS: Makers lean towards ABS because it offers strength through filaments shaped like pasta. It’s sometimes referred to as Lego plastic, comes in an array of colors, and is ideal for at-home 3D printing.

3D Printing with Metal

Metal is the second most popular 3D printing material. Commonly used in additive manufacturing, metal adds speed to the 3D printing process while maintaining an aesthetic nice enough for high-quality jewelry and has a strong enough foundation for industrial applications. When used as a 3D printed material, metal is in dust form. Many kinds of metal can be utilized in 3D printing (well beyond those listed here), including: 

  • Gold: Gold, primarily used for jewelry, is an interesting (but expensive) choice for 3D printing. 
  • Titanium: Titanium is an ideal metal for fixtures that must be strong and reliable while also maintaining extreme heat resistance.
  • Stainless Steel: Stainless steel is a more affordable metal option often utilized to 3D print cookware, utensils, and objects meant to be waterproof. 

A Wide Assortment of Materials

Many materials are used for additive manufacturing. While some might be more common than others, they are all worth mentioning. The right material can make or break your product. You owe it to yourself to explore many of them. Here are a few you may not be familiar with: 

  • Graphite or Graphene: Because they are strong and conduct heat well, graphite and graphene are excellent materials for 3D printing, especially for devices that require flexibility, since it is arguably one of the most flexible 3D printer materials. This 3D printer material is also very lightweight. 
  • Carbon Fiber: Carbon fiber is a composite material, which acts as a topcoat on plastic materials to make them stronger. Putting carbon fiber over plastic creates a faster and cheaper material than metal but just as strong. 
  • Nitinol: This 3D printed material is commonly found in medical technology because it’s highly elastic. As the name suggests, it is a mix of titanium and nickel and can be folded in half while retaining its shape. 
  • Paper: Although it isn’t useful in applications that require strength, paper is an ideal material for 3D printing, as it gives more life to high-quality prototypes than flat illustrations do. Paper can be used for 3D printing in great detail, is cheap, and easily accessible for all kinds of projects. 

Polymers for High Heat Applications

For high heat applications, there are a few polymers that can be used. These polymers are durable and easy to 3D print with:

  • PEEK, or Polyether ether ketone. Part of the PAEK family, PEEK is used in situations that call for an extremely durable material able to withstand high temperatures. 
  • PEI, or Polyetherimide. PEI is one of the first high-temperature 3D printer materials. It is a more affordable option and is frequently used for aerospace applications, though it isn’t as strong and has less thermal resistance. 
  • PPSU/PPSF, or Polyphenylsulfone. This high-temperature, high strength material has no melting point, thanks to an amorphous internal structure. It’s also chemically resistant. 

The 3D printing process can vary significantly based on your desired outcomes. That said, there’s support material for any project imaginable. Though all require some degree of post-processing, this can vary by material and may be an essential consideration. While this list addresses many, there are endless possibilities that will make a product soar. We hope this blog post has given you a stronger understanding of what materials can be 3D printed.

With digital 3D modeling and design tools, 3D printing is easier than ever before. Autodesk Fusion 360 provides flexible 3D modeling software that encourages creativity and allows for multiple design iterations.

Guide to 3D Printing Materials: Types, Applications, and Properties

3D printing empowers you to prototype and manufacture parts for a wide range of applications quickly and cost-effectively. But choosing the right 3D printing process is just one side of the coin. Ultimately, it'll be largely up to the materials to enable you to create parts with the desired mechanical properties, functional characteristics, or looks.

This comprehensive guide to 3D printing materials showcases the most popular plastic and metal 3D printing materials available, compares their properties, applications, and describes a framework that you can use to choose the right one for your project.

Interactive

Need some help figuring out which 3D printing material you should choose? Our new interactive material wizard helps you make the right material decisions based on your application and the properties you care the most about from our growing library of resins.

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There are dozens of plastic materials available for 3D printing, each with its unique qualities that make it best suited to specific use cases. To simplify the process of finding the material best suited for a given part or product, let’s first look at the main types of plastics and the different 3D printing processes.

There are the two main types of plastics:

  • Thermoplastics are the most commonly used type of plastic. The main feature that sets them apart from thermosets is their ability to go through numerous melt and solidification cycles. Thermoplastics can be heated and formed into the desired shape. The process is reversible, as no chemical bonding takes place, which makes recycling or melting and reusing thermoplastics feasible. A common analogy for thermoplastics is butter, which can be melted, re-solidify, and melted again. With each melting cycle, the properties change slightly.

  • Thermosetting plastics (also referred to as thermosets) remain in a permanent solid state after curing. Polymers in thermosetting materials cross-link during a curing process that is induced by heat, light, or suitable radiation. Thermosetting plastics decompose when heated rather than melting, and will not reform upon cooling. Recycling thermosets or returning the material back into its base ingredients is not possible. A thermosetting material is like cake batter, once baked into a cake, it cannot be melted back into batter again.

The three most established plastic 3D printing processes today are the following:

  • Fused deposition modeling (FDM) 3D printers melt and extrude thermoplastic filaments, which a printer nozzle deposits layer by layer in the build area.

  • Stereolithography (SLA) 3D printers use a laser to cure thermosetting liquid resins into hardened plastic in a process called photopolymerization.

  • Selective laser sintering (SLS) 3D printers use a high-powered laser to fuse small particles of thermoplastic powder.

Video Guide

Having trouble finding the best 3D printing technology for your needs? In this video guide, we compare FDM, SLA, and SLS technologies across popular buying considerations.

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Fused deposition modeling (FDM), also known as fused filament fabrication (FFF), is the most widely used form of 3D printing at the consumer level, fueled by the emergence of hobbyist 3D printers.  

This technique is well-suited for basic proof-of-concept models, as well as quick and low-cost prototyping of simple parts, such as parts that might typically be machined.

Consumer level FDM has the lowest resolution and accuracy when compared to other plastic 3D printing processes and is not the best option for printing complex designs or parts with intricate features. Higher-quality finishes may be obtained through chemical and mechanical polishing processes. Industrial FDM 3D printers use soluble supports to mitigate some of these issues and offer a wider range of engineering thermoplastics or even composites, but they also come at a steep price.

As the melted filament forms each layer, sometimes voids can remain between layers when they don’t adhere fully. This results in anisotropic parts, which is important to consider when you are designing parts meant to bear load or resist pulling.

FDM 3D printing materials are available in a variety of color options. Various experimental plastic filament blends also exist to create parts with wood- or metal-like surfaces.

The most common FDM 3D printing materials are ABS, PLA, and their various blends. More advanced FDM printers can also print with other specialized materials that offer properties like higher heat resistance, impact resistance, chemical resistance, and rigidity.

MaterialFeaturesApplications
ABS (acrylonitrile butadiene styrene)Tough and durable
Heat and impact resistant
Requires a heated bed to print
Requires ventilation
Functional prototypes
PLA (polylactic acid)The easiest FDM materials to print
Rigid, strong, but brittle
Less resistant to heat and chemicals
Biodegradable
Odorless
Concept models
Looks-like prototypes
PETG (polyethylene terephthalate glycol)Compatible with lower printing temperatures for faster production
Humidity and chemical resistant
High transparency
Can be food safe
Waterproof applications
Snap-fit components
NylonStrong, durable, and lightweight
Tough and partially flexible
Heat and impact resistant
Very complex to print on FDM
Functional prototypes
Wear resistant parts
TPU (thermoplastic polyurethane)Flexible and stretchable
Impact resistant
Excellent vibration dampening
Flexible prototypes
PVA (polyvinyl alcohol)Soluble support material
Dissolves in water
Support material
HIPS (high impact polystyrene)Soluble support material most commonly used with ABS
Dissolves in chemical limonene
Support material
Composites (carbon fiber, kevlar, fiberglass)Rigid, strong, or extremely tough
Compatibility limited to some expensive industrial FDM 3D printers
Functional prototypes
Jigs, fixtures, and tooling

Stereolithography was the world’s first 3D printing technology, invented in the 1980s, and is still one of the most popular technologies for professionals.  

SLA parts have the highest resolution and accuracy, the clearest details, and the smoothest surface finish of all plastic 3D printing technologies. Resin 3D printing is a great option for highly detailed prototypes requiring tight tolerances and smooth surfaces, such as molds, patterns, and functional parts. SLA parts can also be highly polished and/or painted after printing, resulting in client-ready parts with high-detailed finishes.

Parts printed using SLA 3D printing are generally isotropic—their strength is more or less consistent regardless of orientation because chemical bonds happen between each layer. This results in parts with predictable mechanical performance critical for applications like jigs and fixtures, end-use parts, and functional prototyping.

SLA offers the widest range of material options for plastic 3D printing.

SLA 3D printing is highly versatile, offering resin formulations with a wide range of optical, mechanical, and thermal properties to match those of standard, engineering, and industrial thermoplastics.

Formlabs MaterialsFeaturesApplications
Standard ResinsHigh resolution
Smooth, matte surface finish
Concept models
Looks-like prototypes
Clear ResinThe only truly clear material for plastic 3D printing
Polishes to near optical transparency
Parts requiring optical transparency
Millifluidics
Draft ResinOne of the fastest materials for 3D printing
4x faster than standard resins, up to 10x faster than FDM
Initial Prototypes
Rapid Iterations
Tough and Durable ResinsStrong, robust, functional, and dynamic materials
Can handle compression, stretching, bending, and impacts without breaking
Various materials with properties similar to ABS or PE
Housings and enclosures
Jigs and fixtures
Connectors
Wear-and-tear prototypes
Rigid ResinsHighly filled, strong and stiff materials that resist bending
Thermally and chemically resistant
Dimensionally stable under load
Jigs, fixtures, and tooling
Turbines and fan blades
Fluid and airflow components
Electrical casings and automotive housings
Polyurethane ResinsExcellent long-term durability
UV, temperature, and humidity stable
Flame retardancy, sterilizability, and chemical and abrasion resistance
High performance automotive, aerospace, and machinery components
Robust and rugged end-use parts
Tough, longer-lasting functional prototypes
High Temp ResinHigh temperature resistance
High precision
Hot air, gas, and fluid flow
Heat resistant mounts, housings, and fixtures
Molds and inserts
Flexible and Elastic ResinsFlexibility of rubber, TPU, or silicone
Can withstand bending, flexing, and compression
Holds up to repeated cycles without tearing
Consumer goods prototyping
Compliant features for robotics
Medical devices and anatomical models
Special effects props and models
Medical and dental resinsA wide range of biocompatible resins for producing medical and dental appliancesDental and medical appliances, including surgical guides, dentures, and prosthetics
Jewelry resinsMaterials for investment casting and vulcanized rubber molding
Easy to cast, with intricate details and strong shape retention
Try-on pieces
Masters for reusable molds
Custom jewelry
ESD ResinESD-safe material to improve electronics manufacturing workflowsTooling & fixturing for electronics manufacturing
Anti-static prototypes and end-use components
Custom trays for component handling and storage
Ceramic ResinStone-like finish
Can be fired to create a fully ceramic piece
Engineering research
Art and design pieces

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Selective laser sintering (SLS) 3D printing is trusted by engineers and manufacturers across different industries for its ability to produce strong, functional parts. Low cost per part, high productivity, and established materials make the technology ideal for a range of applications from rapid prototyping to small-batch, bridge, or custom manufacturing.

As the unfused powder supports the part during printing, there’s no need for dedicated support structures. This makes SLS ideal for complex geometries, including interior features, undercuts, thin walls, and negative features. 

Just like SLA, SLS parts are also generally more isotropic than FDM parts. SLS parts have a slightly rough surface finish due to the powder particles, but almost no visible layer lines.

SLS 3D printing materials are ideal for a range of functional applications, from engineering consumer products to manufacturing and healthcare.

The material selection for SLS is limited compared to FDM and SLA, but the available materials have excellent mechanical characteristics, with strength resembling injection-molded parts. The most common material for selective laser sintering is nylon, a popular engineering thermoplastic with excellent mechanical properties. Nylon is lightweight, strong, and flexible, as well as stable against impact, chemicals, heat, UV light, water, and dirt.

MaterialDescriptionApplications
Nylon 12 Strong, stiff, sturdy, and durable
Impact-resistant and can endure repeated wear and tear
Resistant to UV, light, heat, moisture, solvents, temperature, and water
Functional prototyping
End-use parts
Medical devices
Nylon 11 Similar properties to Nylon 12, but with a higher elasticity, elongation at break, and impact resistance, but lower stiffnessFunctional prototyping
End-use parts
Medical devices
TPUFlexible, elastic, and rubbery
Resilient to deformation
High UV stability
Great shock absorption
Functional prototyping
Flexible, rubber-like end-use parts
Medical devices
Nylon compositesNylon materials reinforced with glass, aluminum, or carbon fiber for added strength and rigidityFunctional prototyping
Structural end-use parts

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Different 3D printing materials and processes have their own strengths and weaknesses that define their suitability for different applications. The following table provides a high level summary of some key characteristics and considerations.

FDMSLASLS
ProsLow-cost consumer machines and materials availableGreat value
High accuracy
Smooth surface finish
Range of functional materials
Strong functional parts
Design freedom
No need for support structures
ConsLow accuracy
Low details
Limited design compatibility
High cost industrial machines if accuracy and high performance materials are needed
Sensitive to long exposure to UV lightMore expensive hardware
Limited material options
ApplicationsLow-cost rapid prototyping
Basic proof-of-concept models
Select end-use parts with high-end industrial machines and materials
Functional prototyping
Patterns, molds, and tooling
Dental applications
Jewelry prototyping and casting
Models and props
Functional prototyping
Short-run, bridge, or custom manufacturing
MaterialsStandard thermoplastics, such as ABS, PLA, and their various blends on consumer level machines. High performance composites on high cost industrial machinesVarieties of resin (thermosetting plastics). Standard, engineering (ABS-like, PP-like, flexible, heat-resistant), castable, dental, and medical (biocompatible).Engineering thermoplastics. Nylon 11, Nylon 12, and their composites, thermoplastic elastomers such as TPU.

Beyond plastics, there are multiple 3D printing processes available for metal 3D printing. 

  • Metal FDM

Metal FDM printers work similarly to traditional FDM printers, but use extrude metal rods held together by polymer binders. The finished “green” parts are then sintered in a furnace to remove the binder. 

SLM and DMLS printers work similarly to SLS printers, but instead of fusing polymer powders, they fuse metal powder particles together layer by layer using a laser. SLM and DMLS 3D printers can create strong, accurate, and complex metal products, making this process ideal for aerospace, automotive, and medical applications.

  • Titanium is lightweight and has excellent mechanical characteristics. It is strong, hard and highly resistant to heat, oxidation, and acid.

  • Stainless steel has high strength, high ductility, and is resistant to corrosion.

  • Aluminum is a lightweight, durable, strong, and has good thermal properties.

  • Tool steel is a hard, scratch-resistant material that you can use to print end-use tools and other high-strength parts..

  • Nickel alloys have high tensile, creep and rupture strength and are heat and corrosion resistant.

Compared to plastic 3D printing technologies, metal 3D printing is substantially more costly and complex, limiting its accessibility to most businesses.

Alternatively, SLA 3D printing is well-suited for casting workflows that produce metal parts at a lower cost, with greater design freedom, and in less time than traditional methods.  

Another alternative is electroplating SLA parts, which involves coating a plastic material in a layer of metal via electrolysis. This combines some of the best qualities of metal—strength, electrical conductivity, and resistance to corrosion and abrasion—with the specific properties of the primary (usually plastic) material.

Plastic 3D printing is well-suited to create patterns that can be cast to produce metal parts.

With all these materials and 3D printing options available, how can you make the right selection?

Here’s our three-step framework to choose the right 3D printing material for your application.

Plastics used for 3D printing have different chemical, optical, mechanical, and thermal characteristics that determine how the 3D printed parts will perform. As the intended use approaches real-world usage, performance requirements increase accordingly.

RequirementDescriptionRecommendation
Low performanceFor form and fit prototyping, conceptual modeling, and research and development, printed parts only need to meet low technical performance requirements.

Example: A form prototype of a soup ladle for ergonomic testing. No functional performance requirements needed besides surface finish.

FDM: PLA
SLA: Standard Resins, Clear Resin (transparent part), Draft Resin (fast printing)
Moderate performance For validation or pre-production uses, printed parts must behave as closely to final production parts as possible for functional testing but do not have strict lifetime requirements.

Example: A housing for electronic components to protect against sudden impact. Performance requirements include ability to absorb impact, housing needs to snap together and hold its shape.

FDM: ABS
SLA: Engineering Resins
SLS: Nylon 11, Nylon 12, TPU
High performanceFor end-use parts, final 3D printed production parts must stand up to significant wear for a specific time period, whether that’s one day, one week, or several years.

Example: Shoe outsoles. Performance requirements include strict lifetime testing with cyclic loading and unloading, color fastness over periods of years, amongst others like tear resistance.

FDM: Composites
SLA: Engineering, Medical, Dental, or Jewelry Resins
SLS: Nylon 11, Nylon 12, TPU, nylon composites

Once you’ve identified the performance requirements for your product, the next step is translating them into material requirements—the properties of a material that will satisfy those performance needs. You’ll typically find these metrics on a material’s data sheet.

RequirementDescriptionRecommendation
Tensile strengthResistance of a material to breaking under tension. High tensile strength is important for structural, load bearing, mechanical, or statical parts.FDM: PLA
SLA: Clear Resin, Rigid Resins
SLS: Nylon 12, nylon composites
Flexural modulusResistance of a material to bending under load. Good indicator for either the stiffness (high modulus) or the flexibility (low modulus) of a material.FDM: PLA (high), ABS (medium)
SLA: Rigid Resins (high), Tough and Durable Resins (medium), Flexible and Elastic Resins (low)
SLS: nylon composites (high), Nylon 12 (medium)
ElongationResistance of a material to breaking when stretched. Helps you compare flexible materials based on how much they can stretch. Also indicates if a material will deform first, or break suddenly.FDM: ABS (medium), TPU (high)
SLA: Tough and Durable Resins (medium), Polyurethane Resins (medium), Flexible and Elastic Resins (high)
SLS: Nylon 12 (medium), Nylon 11 (medium), TPU (high)
Impact strengthAbility of a material to absorb shock and impact energy without breaking. Indicates toughness and durability, helps you figure out how easily a material will break when dropped on the ground or crashed into another object. FDM: ABS, Nylon
SLA: Tough 2000 Resin, Tough 1500 Resin, Grey Pro Resin, Durable Resin, Polyurethane Resins
SLS: Nylon 12, Nylon 11, nylon composites
Heat deflection temperatureTemperature at which a sample deforms under a specified load. Indicates if a material is suitable for high temperature applications.SLA: High Temp Resin, Rigid Resins
SLS: Nylon 12, Nylon 11, nylon composites
Hardness (durometer)Resistance of a material to surface deformation. Helps you identify the right “softness” for soft plastics, like rubber and elastomers for certain applications.FDM: TPU
SLA: Flexible Resin, Elastic Resin
SLS: TPU
Tear strengthResistance of a material to growth of cuts under tension. Important to assess the durability and the resistance to tearing of soft plastics and flexible materials, such as rubber.FDM: TPU
SLA: Flexible Resin, Elastic Resin, Durable Resin
SLS: Nylon 11, TPU
CreepCreep is the tendency of a material to deform permanently under the influence of constant stress: tensile, compressive, shear, or flexural. Low creep indicates longevity for hard plastics and is crucial for structural parts.FDM: ABS
SLA: Polyurethane Resins, Rigid Resins
SLS: Nylon 12, Nylon 11, nylon composites
Compression setPermanent deformation after material has been compressed. Important for soft plastics and elastic applications, tells you if a material will return to its original shape after the load is removed.FDM: TPU
SLA: Flexible Resin, Elastic Resin
SLS: TPU

For even more details on material properties, read our guide to about the most common mechanical and thermal properties.

Once you translate performance requirements to material requirements, you’ll most likely end up with a single material or a smaller group of materials that could be suitable for your application. 

If there are multiple materials that fulfil your basic requirements, you can then look at a wider range of desired characteristics and consider the pros, cons, and trade-offs of the given materials and processes to make the final choice.

Try our interactive material wizard to find materials based on your application and the properties you care the most about from our growing library of materials. Do you have specific questions about 3D printing materials? Contact our experts.

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What material does the 3D printer print with? Plastic for 3d printer.

Layer-by-layer printing of three-dimensional models is made from a variety of materials, be it plastic, concrete or metal, and even hydrogel, chocolate and living cells.

For 3D printing, the use of ABS plastic is most optimal. Acrylonitrile butadiene styrene (official name ABC plastic ) is valued for the absence of foreign smell, toxicity, in addition, it is impact resistant, flexible and elastic. The material begins to melt from 240 to 248 degrees Celsius. Plastic goes on sale in a powdered state, or in the form of bobbins with plastic threads wound around them. Despite the fact that plastic does not tolerate direct sunlight, models made from it are famous for their durability. Plastic for a 3D printer can be bought in our online store.

Unlike ABC plastic, which models are opaque, acrylic is used to create transparent objects. But acrylic is more capricious in the process of use: the melting point of acrylic is reached later, which means that it will take more time and energy to heat up, and at the same time it quickly cools and hardens. The very process of manufacturing the product is laborious, since heated acrylic contains a lot of air bubbles that can distort the finished product.

Concrete applied for 3D printing , improved, and has a formula that differs from the formula of conventional cement by 5%. The “printing” of a residential building with an area of ​​230 m2 on a 3D printer will take no more than 20 hours, during which it carefully “lays out” building blocks and structures from concrete.

The use of hydrogel for 3D printing was successfully tested by scientists from the University of Illinois, who used a 3D printer to print miniature (5-10 mm) biorobots. Living cells isolated from the tissue of the heart muscle were placed on them, which, spreading through the hydrogel, set the biorobot in motion. The speed of such a biorobot is 236 µm/s. As planned by scientists, in the future, with the help of such biorobots, tumors and toxins in the body will be detected and neutralized, and they will also be used to deliver medications to diseased human organs.

There are 3D printers that use ordinary office paper as a material. Pre-cut layers of paper are applied one on top of the other and attached with glue. Paper models are cheap enough that they are accessible to users, but at the same time, paper models are not durable and not aesthetically pleasing. Models created in this way are ideal for prototyping in computer projects.

Gypsum used for 3D printing is a fragile, short-lived material, but at the same time it has a low cost. Therefore, models made of plaster are mainly suitable for presentations, perfectly conveying the shape, structure and size of the original product. The resistance of gypsum to heat treatment makes it possible to use it in the foundry as samples for casting.

Fans of natural wood and products made from it will also enjoy 3D printing, as there is a specially designed “wood” fiber that contains wood and a polymer, and its properties are similar to polyactide (PLA). Outwardly looking like natural wooden models with the smell of fresh wood, they are quite strong and durable. Currently, the material can only be used in the RepRap self-replicating printers.

3D printing with ice is perhaps the most exotic way of making small figures today. The temperature at which the figures are printed is quite low and is -22 degrees Celsius, and the printing material is water and methyl alcohol heated to 20 degrees Celsius.

The pleasant soft sheen and high strength of the metal are far ahead in quality of any plastic used in 3D printing, therefore light and precious metal powders are successfully used in this area. Copper, aluminum and its alloys, gold and silver in powder form are used for printing, adding fiberglass and ceramic inclusions to them.

Nylon printed parts are similar in many ways to ABS plastic parts, but are softer and more practical. Nylon manufacturing technology is more capricious, in particular, it has a longer curing period, the printing temperature reaches 320 degrees Celsius, and it is more toxic.

The 3D printers of the near future will print shaped chocolate molds, which should be in great demand in restaurants and pastry shops.

It is also impossible not to mention polycaprolactone, the most popular consumable for 3D printing. This material is so valued for its excellent physical properties and the possibility of being used in various printing technologies.

Of the plastic materials for printing, it is also worth highlighting polycarbonate (hard plastic), polylactide material obtained from biomass, sugar beet or corn silage, polypropylene, polyphenylsulfone, which came from the aviation industry, and an unsurpassed leader in the field of 3D printing, used in any of its areas - polyethylene low pressure.

Among other things, there are also printers that carry out 3D printing with mixtures of clay, lime powder, food, cells from living organic matter. And what exotic materials will be printed 3D printers in the future, one can only guess.

Everything you need to know about 3D printing materials

Here's a guide to help you learn about the materials used in modern industrial and home 3D printing.

When it comes to 3D printing, there is (almost) nothing impossible when it comes to materials, and researchers are constantly creating new ones.

There are certain "master" materials. The most common of these are plastics, ranging from industrial grade plastics like PEEK to very easy-to-handle plastics like PLA. Another common material is polymers, which are used in SLA printers. Composites are another category, and, as the name suggests, they are created (as if composed by a composer) by combining several materials, and the best is taken from each. The next large group of materials are metals. They are printed only by industrial machines.

In this guide, we will only consider commercially available 3D printing materials. This means that we have excluded those that cannot be bought in the store, such as biological ones.

So, it's time to start talking about what materials you can work with in 3D printing, about their applications, properties and technologies.

Which material should I choose?

Sorry, but it depends on a lot of circumstances. For example, if you need to print a food container, you will need a 3D printing material that is also food compatible, like PETG. If you want to see in advance and on a smaller scale what will then be made as a result of injection molding, then it is not necessary to immediately use expensive materials when thermoplastics such as nylon are available.

There are also additive technologies such as Binder Jetting (jet printing with a binder) or stereolithography, which greatly expanded the range of materials used in 3D printing. Many jobs that have been the domain of manual craftsmen for centuries are now automated and can be done by anyone with even the slightest understanding of 3D printing 3D modeling. Here you can point to the wide possibilities of producing full-color concepts, architectural models and visualization of art projects from paper (SDL), sandstone (Binder Jetting) and polymers (PolyJet). Thus, it can be said that 3D printing materials have led to a kind of democratization of rapid prototyping of design ideas.

Materials for 3D printing with metals have revealed forms and applications that were previously unimaginable. Nowadays, it is no longer surprising that the aerospace industry is creating complex one-piece structures that use less material than before, and are therefore lighter, resulting in lower fuel consumption for aircraft compared to traditional approaches.

PLASTIC

Most consumer goods today are made from thermoplastics, so this guide to 3D printing materials would be incomplete without them. And if we talk about widespread things, then here the plastics come out in all their glory. Designers and engineers prefer to create functional prototypes from 3D printing materials with the same or very similar properties as injection molding materials, the technology that creates the final product.

Most 3D printing thermoplastics can be handled at home in much the same way as professional solutions. The only thing is that some experts began to stare at laser sintering instead of filament fusing (FFF).

ABS

(Source: Wikipedia)

Do you remember the quality of Lego bricks? And this is ABS plastic, which is one of the most common materials for desktop 3D printing today.

It is completely inexpensive, strong and light. ABS filament comes in a variety of colors. There are some complaints about the smell that ABS emits when heated to its melting point, and if you're worried about that, there are alternatives like PLA. Because ABS is printed at temperatures between +220 and +250 °C, it is recommended to use a heated platform and in a closed working space so that the material cools in a controlled manner and does not warp. Also, 3D printing materials like ABS break down when exposed to atmospheric moisture, so you need to store them in airtight bags or containers.

Learn more about ABS: Everything you need to know about ABS filament for 3D printing

  • Technologies: FDM, resin inkjet, SLA, PolyJetting
  • Features: Rugged, lightweight, high resolution, quite flexible
  • Applications: architectural models, concepts, assembly models, mass production

PLA

Another crowd favorite in our guide to 3D printing materials is PLA, which is made from cornstarch (although sugar cane and tapioca are also available). This is a simple material that exudes a pleasant sweetish aroma when heated, which is why many people prefer it over ABS. In addition, it can print disposable tableware and does not shrink as much when cooled compared to ABS. However, PLA is not as durable as ABS, and is afraid of heat. Therefore, ABS is better for any working structures.

(Source: thingiverse)

Don't Miss: PLA Durability, Biodegradability Experiment

PLA is sold in a variety of colors and is found in many composites that give it the appearance of, for example, wood or metal. Like ABS, PLA filament breaks down when exposed to moisture in the air, so store it in airtight bags or containers.

  • Technologies: FDM, SLA, SLS
  • Characteristics: easy to print, no toxic smell when printed, food compatible
  • Applications: concepts, assembly models, functional models, serial production

Nylon (polyamide)

Due to its flexibility and strength, nylon has become a leader in a wide range of applications, from engineering to artistic. In some places it is simply called "white plastic". Nylon printouts have a rough surface that can be easily polished. Among FDM filaments, nylon has the strongest layer bonding, making it ideal for 3D printing parts that require high tensile strength and mechanical strength. Like other thermoplastics, nylon decomposes when exposed to ambient moisture and is best stored in airtight containers or bags.

  • Technologies: FDM, SLS
  • Characteristics: strong, smooth surface (after polishing), rather flexible, chemical resistant
  • Applications: concepts, functional models, medical applications, instruments, visual arts

PEEK


PEEK is another 3D printing material designed for heavy duty parts. Plastics of this family perfectly tolerate mechanical stresses, temperature fluctuations and chemical influences. And that's not it. PEEK parts can be irradiated with X-rays and gamma rays. And with such reliability, this material is easily processed and produced. But here there is an ambush in the temperature, which in a 3D printer should reach +400 ° C, and it is better to entrust such work to professionals. In addition to high cost, security considerations can also be an argument for abandoning it. PEEK materials with their excellent properties are used in the most demanding applications - automotive, aerospace, chemical and medical industries. In particular, medical instruments and semiconductor components can be mentioned.

  • Technologies: FDM, SLS
  • Characteristics: biocompatible, very durable, heat resistant, wear resistant
  • Applications: series production (automotive, aerospace, chemical and medical industries)

PET


Our next 3D printing material is PET, the material used to make plastic bottles, another alternative to ABS. Unlike ABS, PET does not stink when melted and is strong and flexible without the stench. More importantly, PET does not require heated print bed. The material gives a shiny surface, it is not hazardous to food, and this in some cases makes it a popular choice. Store PET materials for 3D printing in airtight bags or containers, the material is afraid of moisture.

  • Technologies: FDM
  • Characteristics: durable, food compatible, flexible, gives a smooth surface
  • Applications: assembly models, serial production, functional models

PETG


PETG is a version of PET combined with glycol that has received a number of desirable properties in the 3D printing business, such as high transparency. What's more, PETG materials can be printed at lower temperatures and at higher flow rates (up to 100 mm/s), which speeds up production. PETG objects are not afraid of the weather, so they can often be found in gardens. Another commercial quality is food compatibility. Store PETG in airtight bags or containers, the material is afraid of moisture.

Don't Miss: All You Need to Know About 3D Printing with PETG Filament

  • Technologies: FDM
  • Features: Rugged, food grade, all weather, flame retardant
  • Applications: concepts, assembly models, functional models, serial production

ULTEM


ULTEM is an amazing 3D printing material often found in demanding applications. On the one hand, the plastics of this family perfectly tolerate mechanical stresses, temperature fluctuations and chemical influences, but at the same time they are easy to process and obtain. The only problem is heat resistance, because the extrusion temperature in a 3D printer must reach +400 ° C, and for safety reasons, it is better not to do this work at home, but to entrust it to specialized 3D printing services. Due to its ruggedness, ULTEM is used in the most demanding applications in the automotive, aerospace, chemical and medical industries. It can be found in electrical circuits, medical instruments, and microchip sockets.

  • Technologies: FDM, SLS
  • Characteristics: biocompatible, very durable, heat resistant, wear resistant
  • Applications: series production (automotive, aerospace, chemical and medical industries)

HIPS

HIPS has two main applications. First of all, it is often used in FDM or SLA printing as a backing material because it dissolves in a substance called limonene. With similar properties, HIPS works best in combination with ABS. But, if you decipher the name of this plastic, and HIPS is High-Impact Polystyrene, i.e. high-impact polystyrene, it becomes clear why it is also widely used for the manufacture of containers and in general where increased impact resistance is important. When printing, HIPS gives off fumes, so the room must be ventilated, especially at home. Like many other materials for 3D printing, this one is also capricious in relation to environmental conditions, so it must be stored tightly.

  • Technologies: FDM, SLA
  • Characteristics: soluble, soft to the touch
  • Applications: assembly models, print stands, shipping containers

PVA

PVA, like HIPS, was designed as a soluble support material, but unlike all other similar materials, it dissolves in plain water. And, like most filaments, it needs to be stored in an airtight container.

  • Technologies: FDM
  • Characteristics: instant
  • Applications: assembly models, printing supports

COMPOSITES

Composites are filaments made up of several materials and using the best qualities of each. PLA, for example, can be paired with everything from wood to metal. Other composites are targeted at specific industries or applications and are used, for example, in engineering applications.

Conductive

A relatively new addition to the filament shelf are 3D printed conductive materials that open up many interesting possibilities. Such materials can be used, for example, in touch panels or in MIDI instruments. Other uses for conductive composites are wearable electronics, computer-to-computer interfaces, Arduino boards, and more for DIY projects. Conductive filaments for 3D printing are usually based on PLA or ABS, each with its pros and cons. Conductive ABS is more durable and heat-resistant than PLA-based, but has the same odor issues as regular ABS.

  • Technologies: FDM
  • Features: conductive
  • Applications: DIY projects


Metal-plastic filament

All "metal" filaments on the market are actually thermoplastics mixed with a small amount of metal. Such 3D printing materials allow you to create objects with the visual properties of these metals. Metal-plastic filaments are heavier than conventional thermoplastics. Popular composites for 3D printing are bronze, copper, steel, and iron. Keep in mind that these printouts require post-processing to make them look like metal. Also make sure your printer's nozzle can handle this material.

  • Technologies: FDM
  • Features: metal look
  • Applications: fine arts

Alumide

This is a nylon variant with aluminum particles. In terms of durability and physical characteristics, it is very similar to nylon. The difference is that it is shiny, wear-resistant and has a porous surface. Objects printed with aluminium can be very precise in size, durable and long lasting. Alumide, like other similar materials for 3D printing, lends itself well to various kinds of post-processing, such as polishing and coating.

  • Technologies: SLS
  • Features: Rugged, heat resistant, high resolution
  • Applications: DIY projects, functional prototypes, mass production

Wood

Human inquisitiveness knows no bounds, so it was only a matter of time before the engineers succeeded in adding wood fibers to plastic filament. Wood 3D prints can be processed like real ones, they can be sawn, sanded and painted. And while this kind of exotic 3D printing material is aesthetically pleasing, it doesn't have the same functional characteristics as the original. For example, you will not be able to make a chair out of it.

Interestingly, by changing the extrusion temperature, it is possible to change the shades of brown in the wood filament. 3D printing at a lower temperature produces a very light shade, while at a higher temperature it produces a solid dark brown. Therefore, if you decide to imitate growth rings in a printout, play with temperature. Depending on the brand of wood filament, the printing process may be accompanied by the smell of wood. Some manufacturers offer a wide selection of such material - birch, olive, bamboo, willow ...

  • Technologies: FDM
  • Characteristics: fragile
  • Applications: concept models, fine arts

METALS

Our guide to 3D printing materials would be incomplete without metals. Metal 3D printing has gained particular popularity in the aerospace, automotive and medical industries for its ability to create complex designs that do not require additional welding or machining. The disadvantage of these materials is that they require a lot of experience in development and combination.

In addition, they cannot be printed at home because they require high temperatures and large, specialized printers.

Learn more about metal 3D printing in our comprehensive article Everything you need to know about metal 3D printing

Aluminum wide range of applications. Basically, we are talking about different alloys based on it. Aluminum elements can have thin walls and complex geometries, they tolerate physical stresses and high temperatures well, which is extremely important for low-cost prototypes, functional models, in particular for engines in the automotive and aerospace industries.

  • Technologies: direct metal deposition, binder inkjet printing
  • Characteristics: light, strong, heat-resistant, not afraid of corrosion
  • Applications: functional models, series production (automotive and aerospace)

Cobalt Chrome


The next material on the list is used for very serious applications. Chrome-cobalt is sometimes referred to as chromium-cobalt-molybdenum or cobalt-chromium, and sometimes simply as a superalloy. Its main use is in medical applications and in the aerospace industry, where it can be found in turbines and jet engines. It has outstanding strength, heat and corrosion resistance and is suitable for fine work.

  • Technologies: direct metal laser sintering, SLM
  • Characteristics: biocompatible, durable, corrosion resistant, heat resistant, wear resistant, low electrical conductivity
  • Applications: series production (medical and aerospace)

Copper and bronze

With rare exceptions, copper and bronze are used in investment casting processes and to a lesser extent in formed bed sintering. Due to their electrical conductivity, they are often used in electrical engineering. They are also very popular as art materials and with artisans.

  • Technologies: investment casting, formed layer sintering, direct metal deposition
  • Characteristics: electrical conductivity, wear resistance
  • Applications: series production (electrical engineering), fine arts

Inconel


Inconel is a super alloy designed for the most extreme conditions. It consists mainly of nickel and chromium and is extremely heat resistant. Also resistant to extreme pressures, Inconel is indispensable in the production of aircraft black boxes and even rocket engine parts. Even more often, these features are used in solutions for the oil and chemical industries. The material is very strong and difficult to process, so direct laser sintering is preferred to obtain products of the desired shape.

  • Technologies: direct metal laser sintering
  • Characteristics: heat resistant, wear resistant
  • Applications: Petroleum, chemical and aerospace

Nickel


Nickel alloys are popular for 3D printing applications. Nickel alloy elements are stronger and more durable than traditional methods such as casting. This, in turn, allows engineers to create thinner parts, leading to more fuel-efficient aircraft, for example. There are many types of alloys that combine the characteristics of nickel and other materials such as monel or inconel.

  • Technologies: formed bed sintering, direct metal deposition
  • Features: strong, lightweight
  • Applications: series production (automotive and aerospace)

Precious metals (gold, silver, platinum)

Most formed bed sintering companies can work with precious metals such as gold, silver and platinum. Here, in addition to the aesthetic qualities of materials, it is very important not to lose a single crumb of precious powder. Therefore, such parts are more often produced where a more easily controlled investment casting technology is used. Precious metals are used as materials for 3D printing in jewelry, medical solutions and electronics. Depending on the technology used, some of these materials may be used for casting.

  • Technologies: Formed-bed sintering, investment casting, bonded inkjet printing
  • Features: high resolution, smooth surface
  • Applications: jewelry, dentistry, functional models

Stainless steel


If you're looking for cheaper metal in this guide to 3D printing materials, it's stainless steel. It is also very durable and can be used in many industrial and even artistic applications. Stainless steel alloys containing cobalt or nickel are extremely difficult to break, but have excellent elasticity and good magnetic properties. If you need a different color - please: steel can be coated, for example, with gold. The materials in question are mainly used for industrial purposes.

  • Technologies: direct metal deposition, binder inkjet printing
  • Characteristics: high resolution, corrosion resistance, some flexibility, strength
  • Applications: tools, function models, mass production

Titanium

Pure titanium powder is often used in 3D printing. This is one of the most versatile materials - it is both durable and lightweight. They work with it using the technology of sintering in the formed layer or inkjet printing with a binder. It is most commonly found in demanding medical solutions, such as custom-made prostheses. Other uses for this material are parts and prototypes for aerospace, automotive and tool manufacturing. In addition to the price, it has another unpleasant feature - its powder explodes easily. Therefore, they print in a vacuum or in argon.

  • Technologies: formed bed sintering, binder inkjet printing, direct metal deposition
  • Characteristics: biocompatibility, high resolution, heat resistance, high wear resistance
  • Applications: tools, function models, mass production (automotive, aerospace and medical)

CERAMIC

(Source: SONY DSC)

Ceramic is such a popular material for 3D printing in specialized services that custom-made coffee mugs, for example, have become commonplace. And with specialized extruders such as the WASP Clay 2.0, ceramics are also relevant in home 3D printing.

Clay consists of kaolinite and some other minerals, as well as a certain amount of water, which gives it plasticity. After the ceramic piece is printed, it is cured in an oven. The water evaporates and the minerals fuse together, maintaining the object's shape and strength. To make the printout shine, it is covered with glaze and placed in the oven again.

Ceramics can be printed using both conventional FDM technology and complex methods such as SLA. Beginning "potters" are offered a choice: glass, porcelain or carborundum (silicon carbide). The resulting products are distinguished by heat resistance and wear resistance and today most often act as works of art, as well as dishes and dentures.

  • Technologies: FDM, binder inkjet, SLA
  • Characteristics: heat resistance, wear resistance, brittleness, porous surface
  • Applications: fine arts, serial production (dishes, dentistry)

WAX


Wax 3D prints are not usually the final product, but they are an important milestone in a long journey. They are relevant for very high resolution molding (0.025 mm), as well as for investment casting. They are often used in the creation of custom-made jewelry, and at a relatively low price. Another industry that uses this kind of 3D printing materials is dentistry. When creating complex structures, wax, due to its low melting point, is an excellent material for props.

  • Technologies: SLA, PolyJet
  • Features: high resolution, smooth surface
  • Applications: series production (jewelry, dentistry)

PAPER


With Selective Deposition Lamination (SDL) technology, good old stationery around the corner finds its niche in 3D printing. SDL objects are tree-like, full-color, and this makes them popular in architectural and other conceptual models. On the other hand, parts made from SDL are not as strong as those made from other materials and do not have the level of detail that those made from PolyJet plastic or plaster.

  • Technologies: Selective Deposition Lamination
  • Features: cost effective, recyclable, full color
  • Applications: concept models, fine arts

SANDSTONE


Sandstone as a printing medium is sometimes called gypsum (in fact, gypsum is a component of natural sandstone) and is used to create impressive full-color objects in one process. To enhance the color and add strength, the printouts are covered with a protective layer of epoxy, without this the moisture will do its job and the sandstone will discolour. Objects turn out to be fragile, like porcelain, and this must be taken into account at the design stage. Bearing in mind the capriciousness of sandstone, it is mainly used in architectural models, concept prototypes and art projects.

  • Technologies: FDM, binder inkjet, formed bed sintering
  • Features: fragile, full color
  • Applications: concept models, fine arts

(PHOTO)POLYMERS

(Photo: Nervous System)

Photopolymers are a type of liquid resin that hardens when exposed to ultraviolet (UV) electromagnetic radiation or visible light. Today, they work mainly on two technologies - SLA (stereolithography) and PolyJet. SLA uses a UV laser to project a slice of an object onto the surface of a photopolymer poured into a bath, which solidifies into the shape of the object's layer. This is repeated for all layers.
PolyJet technology takes a different approach. The printer directs a jet of resin onto a substrate, on which the resin is continuously cured by a UV lamp. SLA prints layers no thinner than 0.1 mm, and PolyJet produces up to 16 microns. And although the methods are similar and they use similar materials, the big difference lies in the methods of working with materials.

All photopolymers are sensitive to sunlight.

SLA Resins

Many SLA Resins are designed to mimic the different properties of the "traditional" materials discussed above. For example, there are materials that are compatible with wax, they are used to create impressions in investment casting. And if biocompatibility is important, then there are thermoplastics for SLA, which are very similar to PLA. Other SLA plastics can be as strong as ABS. There are even composite materials for SLA printing that have the properties of ceramics: the objects obtained on the printer can be put in an oven and then treated like ceramic.

Resins are an excellent choice for functional and conceptual models. They are especially good if you want to get a large object in a short time, while with a high level of detail. Some polymers even become hard enough for machining after quenching. In addition, high-temperature polymers are a cost-effective replacement for mold materials for low-volume moldings.

The popularity of the SLA process lies in its excellent speed and accuracy. The downside is that polymers are still significantly more expensive than everything that was mentioned here.

SLA printers are sold, you can work with them both at home and in a small office and use very interesting materials for semi-professional 3D printing.

  • Technologies: SLA
  • Characteristics: smooth surface, some flexibility
  • Applications: concept models, functional models, fine arts, tools (prototypes)

PolyJet resins

(Source: Printshow)

Like SLA resins, PolyJet materials mimic the different properties of "traditional" 3D printing materials. Most PolyJet resins have fairly descriptive names. For example, rigur is designed for strength and sounds similar to the Latin root for hardness. It is also called "simulated propylene" for the similarity of the surface and functionality. A number of 3D printing materials are referred to as "digital ABS" because they are heat resistant and durable. Rubber-like materials are designed for non-slip surfaces and to absorb vibrations. Since there are so many PolyJet polymers, we decided to refrain from a detailed description of each of them.

It should be noted, however, that PolyJet polymers differ from SLA in that they allow obtaining the so-called. digital materials. These are mixtures of up to three 3D printing materials to obtain specific properties (strength, heat resistance, transparency, etc.) for a specific part and in a specific color range. This is a bright path to radiant prospects. While other materials described in this review allow you to create only a visual imitation of "traditional" objects, objects from PolyJet can also imitate tactile sensations, actually replacing reality.


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