What is Additive Manufacturing?
What is Additive Manufacturing?
3D printing, also known as additive manufacturing (AM), refers to various innovative processes that are used to manufacture three-dimensional products.
In additive manufacturing, successive layers of material are formed under computer control to create an object. These objects can be of almost any shape or geometry and are produced from a digital 3D model or other electronic data sources.
Great attention has been given to this subject for a while now since it offers new opportunities for polymers in factories of the future.
Additive manufacturing may be a more appropriate term to use than 3D printing because it includes all processes that are “additive”. The term “3D printing” applies more specifically to additive manufacturing processes that use a printer-like head for deposition of the material (e.g., material jetting). 3D printing is now only one of the processes that is a part of the additive manufacturing universe.
Technical articles and standards generally use the term “additive manufacturing” to emphasize this broader meaning.
Additive Manufacturing – Market Growth
Additive manufacturing applications appear to be almost limitless. Early use of 3D printing in the form of rapid prototyping focused on preproduction models. However, additive manufacturing is now being used to fabricate:
- High-tech industrial (aerospace, medical/dental, automotive, electronic), and
- Consumer (home, fashion, and entertainment) products
...and today’s materials include not only polymers but also metals and ceramics.
The 3D printing market was valued at USD 13.7 billion in 2020, and it is expected to reach a value of USD 63.46 billion by 2026, at a CAGR of 29.48% over the forecast period (2021 - 2026).8
Overall, the demand in the global 3D Printing market1 is gaining traction from a number of factors such as:
- Strikingly higher resolution
- Reduction in manufacturing cost owing to recent technological advancements
- Ease in the development of customized products
- Growing possibilities of using multiple materials for printing, and
- Government investments in 3D printing projects
Today, some of the producers providing 3D printing polymers include: BASF, DSM, SABIC, 3D Systems, ADVANC3D Materials, Materialise, and many more.
Additive Manufacturing vs Conventional Manufacturing
Additive Manufacturing vs Conventional Manufacturing
The growing success of additive manufacturing is due to its advantages over conventional manufacturing. However, these strengths often come along with certain weaknesses. The weaknesses provide opportunities for corrective action through the development of new polymeric materials.
Strengths |
Limitations |
- Elimination of design constraints
- Allow parts to be produced with a complex geometry: honeycomb structures, cooling channels, etc., and no additional costs related to complexity
- Build speed; reduction of lead time
- Flexibility in design
- No expensive tooling requirements
- Dimensional accuracy
- Wide range of materials (polymers, metals, ceramics)
- Well suited to the manufacture of high-value replacement and repair parts
- Green manufacturing, clean, minimal waste
- Small footprint for manufacturing and continually shrinking equipment costs
|
- Surface roughness
- Low density, porosity
- Lack of data regarding end-use properties to be expected of parts (e.g., thermal and chemical stability, strength, etc.)
- Limited to relatively small parts
- Limited to low volume manufacturing
|
General Strengths and Weaknesses of Additive Manufacturing Over Conventional Manufacturing
Additive Manufacturing Processes Classification
Additive Manufacturing Processes Classification
Additive manufacturing processes are classified into seven areas on the basis of:
- Type of materials used
- Deposition technique, and
- The way the material is fused or solidified
These classifications have been developed by the ASTM International Technical Committee F42 on additive manufacturing technologies. The work of this Committee focuses on the promotion of knowledge, stimulation of research, and implementation of technology through the development of standards.
The seven major additive manufacturing processes as classified per ASTM F42 are listed below.
- Photopolymerization
- Material Jetting
- Binder Jetting
- Material Extrusion
- Powder Bed Fusion
- Sheet Lamination
- Direct Energy Deposition
The end-user generally first chooses an additive manufacturing process that best meets his needs, and then the most appropriate material for the process and application.
As far as polymers are concerned, the most popular additive manufacturing processes are photopolymerization, material jetting, powder bed fusion, and material extrusion. The materials used in these processes can be in the form of liquid, powder, or solid (formed materials such as polymer film or filament).
The method of consolidation and applicable additive manufacturing process is illustrated in the figure below.
Additive Manufacturing Processes Along with Classes of Materials and Method of Deposition
The specific chemical types and forms of the polymer materials that are used in each process are discussed in detail below. Print materials made of plastics and polymers are defined by the parameters of their parent 3D printing processes.
Common to all additive manufacturing processes is the use of a computer, 3D modeling software, layering material, and a manufacturing machine. The layering material can be almost anything, but polymers, both in solid and liquid form, have generally been used because of their available forms, formability, and end-use properties.
3D printable models may be created with a computer-aided design (CAD) package, via a 3D scanner or by a plain digital camera and photogrammetric software. 3D printed models created with CAD result in reduced errors and can be corrected before printing, allowing verification in the design of the object before it is printed.
Generalized steps of 3D printing process (Source: Research Gate)
Let’s discuss the methods by which 3D polymers are consolidated into a three-dimensional shape. For a more detailed description of the technologies behind computer technology and the specific equipment used, you can refer to other references.2,3
Photopolymerization
Photopolymerization
In the photopolymerization process (also known as stereolithography) a pre-deposited liquid photopolymer in a vat is selectively cured by light-activated polymerization (see figure below). It is one of the earliest and most widely used rapid prototyping technology. Photopolymerization builds parts a layer at a time by tracing a highly focused UV or laser beam on the surface of the liquid polymer.
Photopolymerization Additive Manufacturing Process
Materials Used in Photopolymerization Process
The polymeric materials used in the photopolymerization process are mainly radiation curing acrylics and acrylic hybrids.
- The light-activated polymer quickly solidifies wherever the beam strikes the surface of the liquid.
- Once one layer is traced, it is lowered a small distance into the vat and a second layer is traced on top of the first layer.
The self-adhesive property of the photopolymer causes the layers to bond to one another, and eventually, a complete three-dimensional object is fully deposited and hardened. Designs are then immersed in a chemical bath in order to remove any excess resin and post-cured in an ultraviolet oven. It is also possible to print objects "bottom-up" by using a vat with a somewhat flexible, transparent bottom, and focusing the UV upward through the bottom of the vat.
Photopolymerization – General Characteristics
Photopolymerization generally provides the greatest accuracy and best surface finish of any AM prototyping technology. Over the years, a wide range of materials with properties mimicking those of engineering thermoplastics have been developed.
Other characteristics of the photopolymerization process include:
- Support structures are required during build
- Post-processing is required to wash and post cure parts
Advantages |
Weakness |
Major Applications |
- High resolution and accuracy
- Ability to produce complex parts, smooth surface
- Accommodates large build areas
|
- Parts are not as durable as those manufactured with other AM processes
|
- Prototyping
- Consumer toys
- Electronics
- Guides and fixtures
|
Although photopolymerization can be used to produce virtually any design, it is often costly. The cost of resin and stereolithography machines was once very high. Recently, interest in 3D printable products has inspired the design of several models of 3D printers which feature drastically reduced prices (less than $10,000 for an industrial-sized printer. Several companies are now producing photopolymerizable resins at prices as low as $80 per liter.
Photopolymers used in 3D imaging processes must be designed to have a low volume shrinkage on polymerization in order to avoid distortion of the solid object.
- Common monomers utilized include multifunctional acrylates and methacrylates combined with a non-polymeric component in order to reduce volume shrinkage.
- A competing composite mixture of epoxide resins with cationic photoinitiators is becoming increasingly used since their volume shrinkage upon ring-opening polymerization is significantly below those of acrylates and methacrylates Free-radical and cationic polymerizations composed of both epoxide and acrylate monomers have also been employed, gaining the high rate of polymerization from the acrylic monomer and better mechanical properties from the epoxy matrix.
Download Brochure – UV curable monomers for molding stability of 3D print application »
Continuous Liquid Interface Production (CLIP)
Although stereolithography was originally touted as a fast process for building prototype models, it is not fast enough for most full-production manufacturing. Conventional 3D printing processes are in reality only two-dimensional printing that is done over and over again.
Full parts may take many hours or even days to produce. Very recently, a new photopolymerization technology, called Continuous Liquid Interface Production (CLIP), was introduced that claims speed 25-100 times faster than traditional 3D printing.4
The Continuous Liquid Interface Production process
enables fast print speeds
and layer less part construction4
The CLIP process works by carefully balancing the interaction of UV light (which initiates photopolymerization) and oxygen (which inhibits the reaction). Part production is achieved with an oxygen-permeable window below the UV image projection plane.
This creates a “dead-zone” where photopolymerization is inhibited between the window and the elevating polymerizing part (see figure above). In this way parts that usually take hours to manufacture can be made in minutes.
Parts are not as durable as those manufactured with other AM processes |
Material Jetting
Material Jetting
Material jetting creates objects in a similar method to a two-dimensional inkjet printer.
- Material is jetted onto a build surface or platform, where it solidifies, and the model is built layer by layer.
- The material is deposited from a nozzle which moves horizontally across the build platform.
Machines vary in complexity and in their methods of controlling the deposition of material. The material layers are then cured or hardened using ultraviolet (UV) light.
As material must be deposited in drops, the number of materials available to use is limited.
Schematic representation of the material jetting process (Source: Research Gate)
Materials Used in Material Jetting Process
Photopolymerizable resins are suitable and commonly used due to their viscous nature and ability to form drops. However, molten polymers can also be used with an elevated temperature printing head, and the molten polymers then solidify at ambient temperature.
One distinct advantage of this process is that it allows changing of product material during a build. In this way graded material properties are possible. Other characteristics of the material jetting process are:
- Major sub-classification is “3D printing” using low viscosity ink.
- Light curable materials are generally used; however, molten thermoplastic materials, polymer solutions, and dispersions can also be used.
- Wax is often used as a support.
Advantages |
Weakness |
Major Applications |
- Good surface finish
- High resolution
- Allows full color parts
- Enables multiple materials
|
- Part may have low strength and durability
- Low viscosity prevents fast build-up
|
- High resolution prototypes, circuit boards and other electronics
- Consumer products
- Tooling
|
Binder Jetting
Binder Jetting
In binder jetting, a thin layer of powder (polymer, metal, or ceramic) is rolled across the building platform.
- A printer head then sprays a liquid adhesive binder to fuse the powder particles together.
- The binder is applied only in the places specified in the digital computer program.
- This process repeats until the three-dimensional object is formed and the excess powder that supported the object during the build is removed and saved for later use.
Binder Jetting Process – A Step-by-step Approach
Powder material is spread over the build platform using a roller
↓
The print head deposits the binder adhesive on top of the powder where required ↓
The build platform is lowered by the model’s layer thickness ↓
Another layer of powder is spread over the previous layer ↓
The object is formed where the powder is bound to the liquid ↓
Unbound powder remains in position surrounding the object ↓
The process is repeated until the entire object has been made
Materials Used in Binder Jetting Process
The binder jetting process uses two materials:
- A powder for part build-up and
- A binder to consolidate the powder
The binder is usually in liquid form. Binder jetting is capable of printing a variety of materials including metals, sands, and ceramics.
Some materials, like sand, require no additional processing. Other materials are typically postured, sintered, or sometimes infiltrated with another material depending on the application and final density requirements for the part.
Binder jetting is unique in that it does not necessarily employ heat during the build process. Other additive techniques utilize a heat source which can create residual stresses in the parts. These stresses must be relieved in a secondary post-processing operation.
Additionally, the parts produced via binder jetting are supported by the loose powder, thus eliminating the need for a build-plate. Spreading speeds for binder jetting outperform other processes. Binder jetting has the ability to print large parts and is often more cost-effective than other additive manufacturing methods.
Other notable characteristics of the binder jetting process are:
- Uses fine polymer powders (100 mm) and jetting of a liquid polymeric binder to bind the powder, subsequent infiltration is possible
Advantages |
Weakness |
Major Applications |
- Low waste
- Relatively fast and simple process
- Allows for full color
- Uses a wide range of materials
|
|
|
Material Extrusion
Material Extrusion
Material extrusion is becoming one of the most prominent additive manufacturing processes. In this process, the part is made by depositing an extruded material layer by layer. Generally, a thermoplastic filament is unwound from a coil and supplies material to an extrusion nozzle.
- The nozzle is heated to heat the filament and provide for a semi-molten polymer to be extruded in either horizontal or vertical directions.
- The plastic hardens immediately after being extruded and bonds to the layer below as shown in the figure below.
- The entire system is contained within a chamber which is held at a temperature slightly below the melting point of the plastic.
Material Extrusion Additive Manufacturing Process
Materials Used in Material Extrusion
Several materials are available for this process. ABS is the most widely used polymer, but other polymers have also be used such as:
In addition parts have been produced from biopolymers such as polylactic acid and from processed plastic waste (See table below).
Material extrusion is somewhat restricted in the variations of shapes that can be fabricated. Other notable characteristics include:
- Material extrusion additive manufacturing is also known as fused deposition modeling (FDM) or fused filament fabrication (FFF)
- Thermoplastic filament (3mm in diameter) has become a commonly available build material
- Multiple materials can be used for both the product build and support
Advantages |
Weakness |
Major Applications |
- Multiple materials and colors can be used
- Availability of equipment
- Parts have good structural properties
- Inexpensive and economical
|
- Surface quality may require post-processing
- Relatively slow build times
- Requires strong filament and
- High processing temperatures
|
- Prototyping
- Tooling
- Office manufacturing
|
Materials extrusion is one of the simplest and least expensive additive manufacturing process. In fact a toy 3D printer5 including software that will be on the market in the fall of 2016 for a price of $299.
FDM printers use two kinds of materials:
- A modeling material, which constitutes the finished object, and
- A support material, which acts as a scaffolding to support the object as it is being printed. Support materials are usually water-soluble wax or brittle thermoplastics, like polyphenylsulfone (PPSF).
Because thermoplastics are environmentally stable, part accuracy (or tolerance) doesn’t change with ambient conditions or time. This enables FDM parts to be among the most dimensionally accurate. Check out the complete list of 3D polymers that use fuse deposition modeling »
Once an object comes off the FDM printer, its support materials are removed either by soaking the object in a water and detergent solution or, in the case of thermoplastic supports, snapping the support material off by hand. Objects may also be sanded, milled, painted or plated to improve their function and appearance.
Materials and their Characteristics |
Acrylonitrile Butadiene Styrene (ABS) and ABS Blends
An ABS prototype has up to 80% of the strength of injection molded; this means that ABS printed products using FDM are extremely suitable for functional applications.
- ABSi is an ABS type with high impact strength. The semi-translucent material is USP Class VI approved. It has a good blend of mechanical and aesthetic properties.
- ABS-M30 is 25-75% stronger than the standard ABS material and provides realistic functional test results along with smoother parts with finer feature details. It is biocompatible (ISO 10993) and an ideal material for medical, pharmaceutical and food packaging industries. It is sterilizable using gamma radiation or ethylene oxide (EtO) sterilization methods.
- ABS-ESD7 is a durable and electrostatic dissipative material suited for electronic products, industrial equipment and jigs and fixtures for the assembly of electronic components.
|
Polylactide (PLA)
Polylactide (PLA) is a popular plant-based thermoplastic material used in 3D printing.
- It is both light and strong.
- The wide range of available colors and translucencies and glossy feel often attract those who print for display or small household uses.
- When properly cooled, PLA seems to have higher maximum printing speeds, lower layer heights, and sharper printed corners.
- Combining this with low warping on parts make it a popular plastic for home printers, hobbyists, and schools.
|
Polycarbonate (PC) and PC Blends
Polycarbonate is the most widely used industrial thermoplastic in 3D printing. In FDM products it is accurate, durable, and stable for strong parts. PC has superior mechanical properties, heat resistance, and high tensile strength.
- PC-ABS is a blend of polycarbonate and ABS plastic which combines the strength of PC with the flexibility of ABS. It has superior mechanical properties and heat resistance of PC, excellent feature definition and surface appeal of ABS, and high impact strength.
- PC-ISO is a strong, heat-resistant engineering plastic commonly used in food and drug packaging and medical device manufacturing. It is biocompatible, gamma and EtO sterilizable and complies with ISO 10993 and USP Class VI. The material gets its name from being a polycarbonate (PC) material with ISO certification.
|
Polyimide (PI)
ULTEM™ Resin 9085 is a high-flow polyetherimide blend that is strong, lightweight and flame retardant (UL 94-V0 rated). It was developed primarily for the aerospace industry and also has applications in other niche industries. It is an ideal candidate for functional prototyping and end-use parts applications. In aerospace, it has a high strength-to-weight ratio and a high heat deflection temperature (160°C).
|
Polyphenylsulfone (PPSU)
PPSU is a thermoplastic with the highest heat and chemical resistance of all FDM Materials. It has great strength and is sterilizable by all processes. PPSU is ideal for applications in caustic and high-heat environments.
|
Powder Bed Fusion
Powder Bed Fusion
Powder fusion is similar to binder jetting, except the layers of powder are fused together using a heat source, such as a laser or electron beam. This process is also known as selective laser melting (SLM) or electron beam melting (EBM) when using metal powder. An alternative method to liquifying the powder by heat is to use sintering.
Selective laser sintering (SLM) is the process of compacting and forming a solid mass of material by heat and/or pressure without melting it to the point of liquifaction.
All processes involve the spreading of the powder material over previous layers usually with a roller or a blade as shown in the figure below. A hopper or a reservoir below of aside the bed provides fresh material supply.
Powder Bed Fusion Additive Manufacturing Process
Some other additive manufacturing processes, such as stereolithography (SLA) and fused deposition modeling (FDM), often require special support structures to fabricate overhanging designs. While SHS does not need a separate feeder for support material because the part being constructed is surrounded by unsintered powder at all times, this allows for the construction of previously impossible geometries.
Materials Used in Powder Bed Fusion
Polymer powders used in powder bed fusion processes can be either amorphous or crystalline thermoplastic particles. Typical polymers are:
Polyamide 12, either pure or blended is the major option.
The utilization of polyamide 11, polyamide 6, and elastomeric polymers such as TPE and TPU are growing. Thermosetting powders such as epoxy have also been used to produce pure plastic parts or as a binder to use with metal or ceramic particles. Kruth6, et. al., provides an excellent dissertation on the consolidation of polymer powders by selective laser sintering, and Schmid7, et. al., provides information regarding the combination of intrinsic and extrinsic polymer properties necessary to generate a polymer powder likely for SLS application.7
Polymeric powders are commonly produced by ball milling. However, most SLS machines use two-component powders, typically either coated powder or a powder mixture. In single-component powders, the laser melts only the outer surface of the particles (surface melting), fusing the solid non-melted cores to each other and to the previous layer.
The shape and surface of the particles determine the behavior of the resulting powder to a great extent. In case of SLS powders, the particles should be at least as feasible formed spherical. This is in order to induce an almost free-flowing behavior on the part bed of an SLS machine. Certain particle size and distribution are necessary to be processable on SLS equipment. This distribution is favorably between 20 μm and 80 μm for commercial systems.
Thermoplastic Polymers Used in Selective Laser Sintering (in Red)
Powder bed fusion (and selective laser sintering specifically) is considered a forward-looking additive processing technology mainly because parts with high mechanical strength can be created.
However, a major disadvantage has been the limited spectrum of suitable materials due to the high cost for cryogenic processing of powder and the available powder properties (size, molecular weight, melt flow, etc.) required for manufacturing.
Other notable characteristics of the powder bed fusion process are:
- Part is embedded in a block of unsintered powder which acts as a support that must be removed.
- Part can be produced in a vacuum to reduce porosity.
- Various thermal energy sources can be used, and as a result, there are several variations of this process: Direct Metal Laser Sintering (DMLS), Electron Beam Melting (EBM), Selective Heat Sintering (SHS), Selective Laser Melting (SLM), Selective Laser Sintering (SLS).
Advantages |
Weakness |
Major Applications |
- Low waste
- Relatively fast, complex structures are possible
- Wide range of materials
- No support required
- High heat and chemical resistant materials
|
|
- Aerospace
- Automotive
- Medical products
- Tooling
- Dental implants
|
Sheet Lamination
Sheet Lamination
In the sheet lamination additive manufacturing process, thin sheets of material are bonded together using adhesives or a heat source to form a three-dimensional product. The sheet lamination processes are also known as:
- Ultrasonic additive manufacturing (UAM) when ultrasonic bonding is used to laminate thermoplastic sheets together
- Laminated object manufacturing (LOM) when adhesives are used for lamination
Materials Used in Sheet Lamination
Polymers are often used but paper or metal foils are also typically processed and find application in cases where heat-sensitive materials cannot be used, and low costs must be realized. Almost any polymer can be used as long as it is available in thin sheet form and can be bonded by either adhesives or heat.
The main advantages of sheet lamination are:
- Low materials cost
- Many substrates are available (e.g., paper, film, foil)
- Process does not require a closed environment
- High volumetric build rates
- Allows combination of materials and embedding components
The primary disadvantages are that complex geometries are difficult to produce, and this method can be less accurate than other additive manufacturing processes. Other characteristics of this process are:
- Uses binding materials such as adhesives or energy (e.g., ultrasonic welding)
- Relatively large parts can be produced
- Possibility to use low cost, easily available building materials such as paper, plastic film, or metal foil
- Bonding equipment can be simple (even by hand) or automated
- Major applications: Large parts, Tooling
Directed Energy Deposition
Directed Energy Deposition
Directed energy deposition processes generally do not use polymeric materials but employ metal wire or powder. High energy heating sources such as a laser are directed at the material to melt it and build-up the product.
Directed energy deposition is considered to be a more complex and expensive additive manufacturing process, but it is commonly used to repair or add additional materials to existing components.
Other characteristics of directed energy deposition include:
- Similar to powder bed fusion except the material is first injected into an energy field
- Common substrates are metal, metal wire, glass, and ceramics
Strengths |
Limitations |
- Can operate in open air
- Multiple materials can be used
- Large parts are possible
- High single point deposition rates
- Not limited by direction or axis
|
- Expensive equipment lower resolutions and reduced ability to manufacture complex parts
- Final machining is often required
|
Major applications: Repair or build-up of high volume parts |
3D Processing Methods – Quick Summary
The table below provides a quick recap and description of these processes.
Process |
Description |
Technology |
Photopolymerization
|
A vat of liquid photopolymer resin is cured through selective exposure to light (via a laser or projector).
This then initiates polymerization and converts the exposed areas to a solid part. |
- Stereolithography (SLA)
- Digital Light Processing (DLP)
- Continuous Liquid Interphase Production (CLIP)
- Scan, Spin, and Selectively Photocure (3SP)
|
Material Jetting |
Droplets of material are deposited layer by layer to make parts.
Common varieties include jetting a photo-curable resin and curing it with UV light, as well as jetting thermally molten materials that then solidify at ambient temperature.
This process was the origin of the term “3D Printing”.
|
- 3D Printing (3DP)
- Multi-Jet Modeling (MJM)
- Drop on Demand (DOD)
|
Binder Jetting
|
Liquid bonding agents are selectively applied onto thin layers of powdered material to build up parts layer by layer.
The binders include organic and inorganic materials. Metal or ceramic powdered parts are typically fired in a furnace after they are printed.
|
- Drop on Powder (DOP)
- Powder Bed printing
|
Material Extrusion
|
Material is extruded through a nozzle or orifice in tracks or beads, which are then combined into multi-layer models.
Common varieties include heated thermoplastic extrusion (similar to a hot glue gun) and syringe dispensing.
|
- Fused Deposition Modeling (FDM)
- Fused Filament Fabrication (FFF)
|
Powder Bed Fusion
|
Powdered materials are selectively consolidated by melting them together using a heat source such as a laser or electron beam.
The powder surrounding the consolidated part acts as support material for overhanging features.
|
- Selective Heat Sintering (SHS)
- Direct Metal Laser Sintering (DMLS)
- Electron Beam Melting (EBM)
- Selective Laser Melting (SLM)
- Selective Laser Sintering (SLS).
|
Sheet Lamination
|
Sheets of material are stacked and laminated together to form an object. The lamination method can be adhesives, ultrasonic welding, or brazing (metals).
Unneeded regions are cut out layer by layer and removed after the object is built.
|
- Selective Deposition Lamination (SDL)
- Laminated Object Manufacturing (LOM)
- Ultrasonic Additive Manufacturing (UAM)
|
Direct Energy Deposition
|
Metal powder or wire is fed into a melt pool which has been generated on the surface of the part where it adheres to the underlying part or layer.
The energy source is usually a laser or electron beam. This process is essentially a form of automated build-up welding.
|
- Laser Metal Deposition (LMD)
- Electron Beam Free-Form Fabrication (EBF3)
- Direct metal deposition (DMD)
- Laser Engineered Net Shaping (LENS
|
|
Additive Manufacturing Processes as Defined by ASTM F42
How to Accelerate Complex Parts Manufacture?
Bernard Alsteens will help you how to successfully manufacture complex 3D-printed thermoplastic parts that reach the right mechanical performance by introducing simulation early in your process. He will also share advanced simulation solutions for SLS, FDM/FFF, and discuss the effect of the 3D-printing process on the final performance of the part.
Now that we’ve reviewed the seven major additive manufacturing processes as classified per ASTM F42, let's discover the various types of polymer materials used in the additive manufacturing process.
Polymers Used in Additive Manufacturing
Polymers Used in Additive Manufacturing
The specific chemical types and forms of the polymer materials that are used in each process are identified in the table below. Although at first glance, this may seem to be an abundance of materials, there is a growing need to develop and process a much greater variety of materials than currently possible.
The general feeling is that the materials that now exist for additive processing processes do not meet the requirements of the majority of industrial products, and materials need to be developed specifically for additive manufacturing processes and end-user applications.
Polymeric Materials for Building 3D Parts |
Photo-polymerization |
Material Jetting |
Binder Jetting |
Material Extrusion |
Powder Bed Fusion |
Selective Heat Sintering |
Sheet Lamination |
LIQUIDS |
Epoxy resin |
X |
X |
X |
|
|
|
|
Acrylic resin |
X |
X |
X |
|
|
|
|
Binder/powder hybrids |
|
X |
|
|
|
|
|
POWDER |
PA 12 |
|
|
|
|
X |
X |
|
PA 11 |
|
|
|
|
|
X |
|
PC |
|
|
|
X |
X |
X |
|
PS |
|
|
|
X |
X |
X |
|
ABS |
|
|
|
X |
|
|
|
ABS – PC blend |
|
|
|
X |
|
|
|
PP |
|
|
|
|
|
X |
|
PPSU |
|
|
|
X |
|
|
|
Starch |
|
X |
X |
|
|
|
|
Elastomer / cellulose |
|
X |
X |
|
|
|
|
PLA |
|
X |
X |
|
|
|
|
TPU |
|
X |
X |
X |
|
|
|
HDPE |
|
|
|
X |
|
|
|
PEEK |
|
|
|
X |
|
X |
|
PEI |
|
|
|
X |
|
|
|
SOLID SHEET
|
Polyester film |
|
|
|
|
|
|
X |
Polyolefin film |
|
|
|
|
|
|
X |
Polyvinyl copolymer film |
|
|
|
|
|
|
X |
Other thermoplastic film |
|
|
|
|
|
|
X |
Other thermosetting film |
|
|
|
|
|
|
X |
MELT (MOLTEN LIQUID) |
ABS |
|
|
|
X |
|
|
|
ABS/PC blend |
|
|
|
X |
|
|
|
PPS |
|
|
|
X |
|
|
|
Latest Game Changing Innovations in 3D Printing
Dr. Donald Rosato will take you through the new opportunities with 3D materials & technologies to focus your R&D on the right projects. He will also lay focus on major innovations which include: amorphous PLA grade formulated for large-format 3DP applications, 50% bio-based TPU market and PAEK filaments tailored to 3DP mechanical part manufacturing.
Find Suitable 3D Printing Polymers
View a wide range of polymers used in 3D printing, analyze technical data of each product, get technical assistance or request samples.
References:
- Wohlers Report 2017, Wohlers Associates & 1a. Transparency Market Research, 3D Printing Market, Global Industry Analysis, Size, Share, Growth, Trends and Forecast 2017 - 2025
- Wendel, B., et. al., “Additive Processing of Polymers”, Macromolecular Materials and Engineering, Vol. 293, 2008, pp. 799-809.
- Negi, S., et. al., “Basic Applications and Future of Additive Manufacturing Technologies: A Review”,
Journal of Manufacturing Technology Research, Vol. 5, No. 1/2 , 2013, pp. 75-95.
- Tumbleston, J.R., et. al., “Continuous Liquid Interface Production of 3D Objects”, Science, Vol. 347, March 20, 2015.
- Mattel, ThingMaker 3D Printer, http://www.pocket-lint.com/review/136836-mattel-thingmaker-preview-3d-printing-for-the-minecraft-generation
- Kruth, J-P, et. al., “Consolidation of Polymer Powders by Selective Laser Sintering”, Proceedings of the 3rd International Conference on Polymers and Moulds Innovations. 2008.
- Schmid, M, et. al., “Polymer Powders for Selective Laser Sintering (SLS), AIP Conference Proceedings, 1664, 160009, 2015.
- https://www.mordorintelligence.com/industry-reports/3d-printing-market