What is Multi Jet Fusion (MJF) 3D Printing?

Multi Jet Fusion (MJF) is a 3D printing technology for producing rigid and flexible polymer parts of medium size and resolution. It is proprietary technology that has recently been developed by Hewlett Packard (HP). Like SLS, MJF belongs to the category of polymer powder bed fusion processes.

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The most common material for MJF is Polyamide 12, abbreviated as PA 12. PA 12 is also called nylon. Other popular materials are glass filled PA 12 and PA 11. It is also possible to produce flexible parts with MJF by using Thermoplastic Polyurethane, also known as TPU.

Automotive Prototype MJF 3D Printed
Prototype of a cover for an automotive component, manufactured in MJF PA12.

Part Quality

MJF is an excellent process for manufacturing prototypes, tools and functional parts that range from 10’s of millimetres to 100’s of millimetres in size with a dimensional accuracy of up to 0.3 mm. The material properties of MJF parts are almost isotropic. The surface quality is consistent, with a roughness of about Ra ~ 5 µm after bead blasting.

Build VolumeUp to 380mm x 284 mm x 380 mm
Layer Thickness0.08 mm
Dimensional Accuracy0.3 mm
Surface RoughnessRa ~ 5 µm (after bead blasting)
Multi Jet Fusion 3D printed skeleton hand.
Multi Jet Fusion 3D printed skeleton hand.

Build Cycle

The part is produced by adding the powdery build material layer by layer along with the injection of two other components called “fusing agent” and “detailing agent”. The process begins with adding the first layer of material on the build platform which gets exposed to thermal energy. Then the fusing agent is selectively printed where the particles need to be fused, followed by a detailing agent which helps the fusion process at the boundary interface to be either amplified or reduced. Then the layer is exposed to a high-power infrared source, causing the selected areas to be fused together. This process is repeated until the part is printed.

In a HP Jet Fusion 3D printer, dual carriages are used to scan across the working area in perpendicular directions. One carriage carries the fresh material and other carries hp functional agents. The machine is equipped with high intensity and high voltage bulbs that heat the chamber, a powder dispenser and the binding head. In effect, the exposure time per layer is constant, and in turn the build rate is independent from the part volume, it only depends on the number of layers.

End use 3D printed MJF components
End use MJF components for a combine harvester.


After the build cycle has finished, the entire build unit needs to cool. This can take more than a day, although faster cooling is possible at the possible expense of part quality. After the build unit has cooled down, the parts are removed and separated from the powder. Each part needs to be blasted to remove residual powder from the part surface. After blasting, the parts are cleaned with pressurized air to remove remaining blasting material and loose powder. This is the standard process, and the part is considered finished afterwards. MJF parts with standard finish have a rough surface finish compared to injection molding or Resin 3D Printing.

There are several additional post-processing methods in use to further increase the surface quality of MJF parts. Vibratory grinding is a common finishing option for a smoother surface.

The default color of MJF parts is grey. If the parts need to have a different color, they need to be dyed during post-processing. Due to the natural grey color, it can be challenging to produce bright and vibrant colors. However, darker colors such as black can easily be achieved. There is one type of MJF machine that can print in full color, but it is not yet widely available and has a smaller build volume than the standard machines.

A personalized orthesis, manufactured wtih MJF 3D Printing.
A personalized orthesis, manufactured wtih MJF 3D Printing.

About the author:
Harald Schmid is the founder and managing director of Gramm GmbH. Gramm is located in Regensburg, Germany.
[email protected]
Website: gramm.online
Prototype Hubs Profile: Gramm

What is Metal 3D Printing?

Metal 3D Printing is an advanced manufacturing method that builds metal parts from a CAD file using a layer-by-layer technique known as additive manufacturing.

Introduction to Metal 3D Printing

To understand metal 3D Printing, we first must understand the difference between “what it’s made of” (the material) and “how to make it” (the technique). Metal refers to the category of materials that we use and 3D Printing – also known as Additive Manufacturing (AM) – refers to the category of material processing techniques that consolidate the metal materials, one layer at a time, from the bottom up. Software is used to slice a solid three-dimensional (3D) computer generated model into a set of layers for the 3D printer hardware. The first layer attaches directly to a dedicated build plate, the second layer fuses with the first layer, and so on. In metal 3D Printing, production builds can consist of thousands or tens of thousands of layers and can take days, weeks, or even months to complete.

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Finished metal 3D printed part still on the build plate.
Finished metal 3D printed part still on the build plate.

In the world of metal 3D Printing, the end that we have in mind is a 3D metal part that matches the exact size and shape of our 3D CAD model. This one-to-one equivalence is sometimes difficult to achieve with metal materials. The bottom of each build for most metal 3D Printing processes is a large piece of metal called a build plate. The build plate must be flat within the 3D printer prior to starting any metal 3D Printing process.
The first step in the process is to attach the initial layer of metal to the build plate successfully. Subsequent layers are added one-at-a-time, until the 3D geometry is realized.

The particulars of exactly how the metal is attached to the build plate, and subsequently to previous layers of the build, is where things get interesting and processes differ from one another. Methods of realizing metal 3D geometries differ primarily in two dimensions: 1) by the feedstock delivery system used (the way new material is fed into the system), and 2) by the consolidation mechanism leveraged (the physics of how the new material is fused to the build plate and to previous layers).

Metal 3D Printing Processes

As the metal 3D Printing industry continues to grow in scale and complexity, especially in the automotive, maritime, medical, aerospace, and space industries, more and more R&D-grade and production-level solutions continue to be developed. This proliferation of technology is a potential boon for advanced manufacturers across the globe; however, not all metal 3D Printing processes are created equally. As mentioned, each process comes down to 1) how new material feeds into the 3D printer, and 2) how that material is consolidated into a 3D geometry. At the time of writing, there are several popular industrial solutions on the market, listed here in order of perceived popularity.

  • Powder Bed Fusion (PBF)
    • Feedstock: Metal Powder
    • Consolidation Mechanism: High Temperature Laser or Electron Beam Melting
  • Binder Jetting (BJ)
    • Feedstock: Metal Powder and Chemical Binder
    • Consolidation Mechanism: Chemical Binding and Heat Treating
  • Direct Energy Deposition (DED)
    • Feedstock: Metal Powder or Wire/Filament
    • Consolidation Mechanism: High Temperature Laser or Electron Beam Melting
  • Bound Powder Extrusion (BPE)
    • Feedstock: Metal Powder encapsulated in Polymer
    • Consolidation: Low Temperature Conduction Melting, Polymer Removal, and Sintering
Powder Bed Fusion (PBF) using a laser to fuse a layer of metal material.
Powder Bed Fusion (PBF) using a laser to fuse a layer of metal material.

There are several industry-leading manufacturers that use each technology, and more competitors are entering these spaces all the time as the global metal 3D Printing ecosystem evolves and grows. We will dive further into the details of each process above in future articles in this series on Metal 3D Printing – stay tuned!

About the author:
Greg Loughnane is a university professor at the University of Dayton, Ohio. Greg completed his PhD in Computational Design & Optimization in 2015.
[email protected]


Typically, a lithophane is described as thin translucent porcelain that has been etched or carved with an image and is viewed when back lit with a light source. A 3D printed lithophane embodies the same principle with the exception that instead of the image being etched or carved – plastic filament, deposited layer-by-layer from a nozzle, is used to form the image. The parts of the image that appear darkest are where the printer has extruded the thickest amount of filament and the parts that appear the lightest are where the thinnest amount of material has been deposited.

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3D Printed Lithophane Back lit
3D printed white lithophane that is back lit with a light source.

Filament, Colour, & Quality

The quality and color of filament chosen will affect the final outcome of the 3D printed lithophane. Various shades of white – from bright white to cool white and the subtle hues in-between – can be used to create the perfect lithophane. Although white may be the most commonly used color to generate 3D printed lithophanes, beautiful results are possible with an assortment of translucent shades. Some lighter greys, pale browns, coffee based filaments, and even some wood fill 3D Printing materials have been used to produce lithophanes.

Regardless of the chosen color, the most important variables to consider are layer height, infill percentage, print speed, and the source image. The quality of the image used along with how much manipulation is done to that image will have a large effect on the final product.

Horizontal vs. Vertical

3D printed lithophanes are generally produced using 2 different printing methods. The first method of printing the lithophane horizontal to the Z-axis is the most common method. The main advantage to using this method is that the print is laying directly on the 3D printer bed and takes much less time to print when compared to the second method. Although there are many great benefits to using this method, the quality of the finished 3D printed lithophane can be lower than expected.

Diagram displaying the axis of a 3D printer.
Diagram displaying the X, Y, and Z axis of a 3D printer.

The second method that is ever-increasing in popularity is vertically 3D printed lithophanes. This method involves printing the lithophane perpendicular to the X-axis and Y-axis of the printer bed. Depending on the 3D printer being used, it will be necessary to determine which way to position the print for stability. This is done to limit the influence that the bed and gantry will have on the movement of the lithophane as build height increases.

The Right Balance

To achieve the highest quality lithophanes, a small layer height and slow print speed are recommended. Aim for a 0.12 – 0.18 mm layer height when printing as it will provide the greatest amount of detail. Printing speed is equally important; slower print speeds mean a higher chance for success of a superior quality lithophane. Printing too fast, even by 2-3 mm/s, could result in the filament being improperly placed and potentially ruining the final product. Another important variable to remember is the infill percentage. A common misconception is to use 100% infill for 3D printed lithophanes; this is not always the best option and some testing is required to determine the right combination of settings to achieve the best results.

Design, Test, & Iterate

One of the great advantages of 3D Printing is the ability to iterate and test a design with minimal costs involved. After conducting a series of 3D lithophane print tests while achieving acceptable and repeatable results, make sure to save the optimized slicer settings for future prints. The quality of filament, cost of 3D Printing, and software applications available make 3D printed lithophanes an affordable way to treasure a photographic memory in a new light!

If you have a lithophane design that you would like 3D printed, you can upload your 3D printable file to Prototype Hubs and get an instant price from a Prototype Hubs 3D Printing Partner.

About the author:
Kennet McCoy is an author for Inov3D.  Having stared 3D Printing in 2012, Kennet’s first 3D printer was a MakerBot dual extruder printer.
Instagram: @Inov3d_printing
Facebook: @Inov3d
Twitter: @Inov3D
YouTube: Inov3D

What is 3D Resin Printing?

Stereolithography (SLA), Digital Light Processing (DLP), and Liquid Crystal Display (LCD) are 3 different types of 3D Resin Printing processes. In these vat polymerization methods, light sources are used to cure liquid resin, layer-by-layer, to form a desired 3D model. Although SLA, DLP, and LCD all use a light source, a build platform, and a vat of resin, each process uses a different type of light source.

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3D Resin Printer
Bottom-up 3D resin printer showing build platform and resin vat.

SLA 3D Resin Printing

SLA, the original form of 3D Printing, was patented in 1986. In this technique, galvo mirrors focus an ultraviolet (UV) laser that solidifies the cross-section of each layer, point-by-point. In general, SLA 3D Printing may be top-down, as is used in some industrial applications, or bottom-up, as is used for desktop printers.

In top-down SLA 3D Printing, the laser source is positioned above the vat of resin. The build platform begins at a predetermined layer height under the top surface of the liquid resin. After solidifying a layer, the build platform drops by a specified layer height, typically between 25-100 microns, to solidify the next layer and merge it with the previous. This process repeats until the model is complete, at which point it rises from the vat. Unlike other 3D Printing methods, curing continues after completion. Extra exposure to UV light is generally needed to fully cure the resin and improve the model’s hardness and temperature resistance.

In bottom-up SLA 3D Printing, the light source is positioned under the vat and the model is formed upside down. The build platform begins at a predetermined layer height above the tank’s bottom surface, which is transparent to allow light to penetrate the liquid resin. After each layer is solidified, the build platform rises, removing the cured resin from the bottom of the tank in a process called “peeling.” Forces applied to the model during peeling are the main cause of print failures in bottom-up SLA 3D Printing.

SLA/DLP (Stereolithography / Direct Light Processing)
Dental SLA 3D printer with model on build plate.

DLP 3D Resin Printing

DLP is similar to bottom-up SLA 3D Printing in that the light source is positioned below the vat of resin. However, instead of a using a UV laser, DLP uses a projector screen to flash a pixelated 2D image of the layer onto the tank bottom. This allows for faster processing times. The disadvantage of DLP is the restriction of build accuracy, which is determined by pixel size.

LCD 3D Resin Printing

LCD is similar to DLP in that it also uses a pixelated 2D image. You may recognise the term LCD from computer monitors and other display devices. In LCD 3D Printing, an array of UV LCDs shine the entire layer image directly onto the tank bottom to cure the liquid resin. As no mirrors are used to project each layer image, there is no distortion of the light. This means that the quality of LCD 3D Printing is determined by the LCD density. LCD generally uses cheaper components than both SLA and DLP, which is often a good introduction to Resin 3D Printing for the first-time owner.

SLA, DLP, LCD Printed Chess Pieces
High detail 3D printed chess rook from resin plastic.

With 3D Resin Printing, high levels of accuracy can be achieved with smooth surfaces. As the UV curing method tends to leave models brittle, most 3D Resin Printing is better suited for non-functional parts and visual models. But, as material science continues to develop, functional resin printed parts are now becoming a reality. Visit the 3D Printing comparison page for more information about the ideal 3D Printing method for your next project.

About the author:
Chris Brennan is a Manufacturing Engineer and the founder/owner of Thirteen Design Consultancy based out of County Louth, Ireland.
[email protected]
Instagram: @thirteendesignconsultancy
Facebook: @thirteendesignconsultancy
Twitter: @13DesignIreland
Prototype Hubs Profile: Thirteen Design Consultancy


Whether you’re a 3D Printing enthusiast who dreams about printing and sharing designs, or an engineer who’s familiar with mechanical or industrial design looking for new ways to use 3D design skills, these ideas will help you better understand how to get started with artistic design for 3D Printing.

Choosing Which Software to Use

Generally speaking, 3D modeling software programs fall into one of three categories: solids, surfaces, & digital clay. This article will focus on the first category: solids, as most engineers and designers already know and use it. More importantly, though, it’s a favorable choice for beginners.

Solid Modeling 

With solid modeling, bodies are extruded and cut from a reference surface, plane, or point. Using solid modeling for 3D Printing comes with advantages. For instance, due to their parametric nature, models are watertight (manifold) and easy to edit and customize.  A timeline of these individual steps are saved, allowing for easy editing at any previous point in time. Once a user changes something, adjustments and updates happen automatically. Traditionally, mechanical and design engineers use this type of modeling to draw parts and molds that are fabricated through traditional manufacturing methods. Solid Modeling programs include SolidWorks, SolidEdge, Inventor, CATIA, and NX, which are all professional-level programs requiring a paid license. Meanwhile, Fusion 360, TinkerCAD, SelfCAD, OnShape, and other design software can be used for free.

Surface & Digital Clay Modeling

When it comes to the engineering and manufacturing world, surface and digital clay modeling software are not common due to a lack of precision. This software is, however, better suited for organic or freestyle designs that don’t require specific measurements or perfectly straight lines. Projects that would work best under surface and digital clay modeling include characters, animals, motion graphics, animation, and scenery commonly used in video games. Popular programs that fall under this type of design software are Rhinoceros, ALIAS, Blender, Maya, and Zbrush—just to name a few.

Solid Modeling Design Process

Although solid modeling is used mostly for industrial and engineering design purposes, it is possible to use it in a more artistic way. The best starting point is to think outside the box, and to not be afraid of trying traditional design tools in unconventional ways. Using any of the solid modeling software mentioned above, first get familiar with some of the most basic extruding and cutting tools and functions, as these will be used most throughout the design process. Next, try to model a favorite sci-fi starship or city landmark with a general, roughly outlined shape. As the design starts to evolve, more detailed features can be added or eliminated using the extrude and cut tools of the modeling software. Adding details to make the final model more realistic without complex tools does not require a substantial amount of knowledge or skill. However, understanding how to use complex modeling software, along with its elaborate tools and procedures, requires a greater amount of time.

MiniWorld 3D Helsinki Cathedral Step 1
Step 1: Simple volumes with proportional dimensions.

MiniWorld 3D uses mainly a combination of SolidWorks and Fusion 360 to create free miniature models of world famous landmarks and monuments for 3D Printing.

MiniWorld 3D Helsinki Cathedral Step 2
Step 2: Extruding volumes to enhance the level of detail.

By starting with broad outlining of geometric shapes and then gradually adding smaller details, the design software is used as a sculpting tool to produce the final model.

MiniWorld 3D Helsinki Cathedral Step 3
Step 3: continued detail enhancement using both extrudes and cuts.

With a bit of patience and time, it is possible to carve the solid bodies into beautiful shapes. The majority of the operations used include both cuts and extrudes with some combinations of patterns.

MiniWorld 3D Helsinki Cathedral Step 4
Step 4: using a combination of multiple cuts, it is possible to carve the details of the object.

Complex or fancy operations are rarely used, so even a beginner with little knowledge has the tools required with free modeling software to design intricate models.

Modeling with 3D Printing in Mind

Some general 3D Printing design recommendations:

  • Manifold – Always keep models watertight, or manifold. In layman’s terms, this means it isn’t hollow, there aren’t any missing edges or faces, and there aren’t any surface holes. This is not so much a concern with solid modeling as compared to surface and digital clay modeling.
  • No Supports – Try to avoid supports and overhangs. Use 45 degree planes, chamfers, or rounds if possible.
  • Small Features – Avoid thin or micro features. If the printing nozzle is 0.4 mm, be sure to make the smallest features at least 0.6 or 0.8 mm. Otherwise, the slicing software may omit them.
  • Orientation – Think about printing orientation before modeling in order to avoid supports when possible and maximize the print bed adhesion area. Consider that the best way to print a part may be upside down, or even on its side.
  • Parametric – Take advantage of parametric software to make adjustments after test-printing a design. It’s easy to edit lengths, diameters, thicknesses, or adding ribs and fillets, etc.

About the author:
Dany Sánchez is the founder of MiniWorld 3D, a collective of 3D artists who contribute models to make the best gallery of 3D printable landmarks around the world. Check out over 100+ free models on MyMiniFactory and keep up with news and updates.
Instagram: @miniworld3d
Facebook:  @miniworld3d
Twitter:  @LDIbarra


Three-dimensional (3D) Printing is a relatively new manufacturing process that was first patented in 1980. Since the inception of the open source RepRap project in 2005, the 3D Printing industry has exploded at an exponential pace. The RepRap project allowed the maker community to acquire 3D Printing at an affordable price point, enabling it to grow from the expensive scientific based experiment it started out as to part of the current Industry 4.0 manufacturing revolution of today.

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Over the past decade, several new types of 3D Printing technologies have emerged including concrete, metal, and even chocolate. With the development of these new technologies, it is now possible to create new inventions that were not possible with traditional design and manufacturing methodologies. Used by small home based businesses and large corporate manufacturing companies, 3D Printing has become a versatile and affordable technology in a wide range of industries.

3D printing is the Additive Manufacturing (AM) method of building up a 3D object from a Computer Aided Design (CAD) file with a material in a layer by layer process. There are different technologies and methods for 3D Printing that include: Fused Deposition Modeling (FDM), Stereolithography (SLA), Digital Light Processing (DLP), Selective Laser Sintering (SLS), and Direct Metal Laser Sintering (DMLS), to mention a few. All 3D printers use this layered process of building up a material in order to create a 3D design.

3D Printing Process

To help better understand how 3D Printing works from start to finish, the process can be broken down into five steps:

  1. Design – design is the beginning of any 3D Printing idea. Once the design has been finalized in a CAD program, it is typically exported in an OBJ, STL, or any file format that slicing software can understand and interpret.
  2. Slicing – slicing turns the CAD model into a file format that a 3D printer can understand. The slicer creates a G-code file that has the commands for the printer to create the desired object. G-code tells the printer the exact coordinates for every move of the printer extruder. Slicer settings are usually the part of the 3D Printing process that requires the most amount of tuning to obtain a high quality print.
  3. Printing – the information from the G-code file is used by the 3D Printing machine to build up each individual layer. This step may look different for different printing methods, but the layer-by-layer AM process holds true for each method.
  4. Post-processing – this is the process of cleaning up the printed object. This can involve removing unnecessary support material or adding finishing touches like filler and paint. Some 3D Printing methods require more post-processing time than others due to the nature of the build method.
  5. Iteration – iterative design is an affordable step with 3D Printing, whereas with traditional manufacturing technologies this step would not exist because of the costly downside.

One of the biggest advantages of 3D Printing is that it is easily the most cost-effective rapid prototyping process that is currently available. While 3D Printing does have some downfalls and drawbacks, the many advantages outweigh the negative associations of this ever growing technology.

About the author:
Isaac Feemster is the owner of BenchBot Printers, a new large scale 3D printer design and manufacturing company.
[email protected]
Instagram: @benchbot_printers
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Fused Deposition Modeling (FDM), sometimes referred to as Fused Filament Fabrication (FFF), is one of the most popular types of extrusion 3D Printing. The FDM process creates plastic 3D models by superimposing multiple layers of melted thermoplastic polymer material into a predefined area via a computer controlled printing nozzle. While FDM may not be the strongest, fastest, or most advanced example of 3D Printing technology, it is one of the most affordable and is ideal for producing concepts and prototypes.

A direct drive or Bowden type extruder is used for FDM, depending on the 3D printer type and setup. Thermoplastic polymer materials in the form of a continuous filament are fed from the extruder cold end to the hot end. The hot end contains an interchangeable nozzle that can be sized according to the specifications of the printed object. To control the movement and placement of the nozzle, the printer is equipped with a gantry system, generally powered by individual stepper motors. These motors make sure the extruded filament is laid down in the correct position for each printed layer. With every pass, the nozzle lays the filament down on top of the previous layer, gradually building up the required shape of the object.

With FDM technology, the quality of the 3D printed object depends on various parameters such as layer height, nozzle diameter, and the use of support materials. Because of the layered build process, support structures must be printed under high degree overhangs and large unsupported bridges to stop the extruded filament from sagging. Although printed supports can increase post-processing time, they are often necessary to produce high quality prints. Because FDM uses one single-point nozzle to extrude a single layer of material at a time, the finished object contains layer lines that are often visible on the exterior surfaces. These layer lines can be removed with various post-processing methods.

FDM offers a wide variety of materials to print with, including flexible thermoplastics; objects can be either rigid or flexible. FDM printing uses a wide variety of high-performance, engineering, and basic filaments that allow for the practical application and use of each printed object to be uniquely different. Available filaments include ABS, PLA, PETG, Nylon, and PEEK, to name but a few, and most come in a wide variety of colors. Then there are TPU plastics, which tend to be the most flexible and may require specific types of extruders and hot ends to print properly. The mechanical properties of FDM objects are anisotropic because of the layered build process.

The benefits of FDM include the cost-effectiveness for producing prototypes and functional objects, the ability to create complex new designs that are not possible with traditional manufacturing technologies, and the wide selection of build materials – for applications ranging from basic to high-performance. Along with these great benefits, however, FDM does have its limitations, namely its anisotropic mechanical behaviour, the visible layer lines that may require extra post-processing time to remove, and lower dimensional accuracy and resolution when compared with other 3D Printing technologies.

About the author:
Chris Dudek
[email protected]
Instagram: @chris_dudek

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Selective Laser Sintering (SLS) is an Additive Manufacturing (AM) process that uses laser power to sinter powdered material, typically plastics, into a solid 3D model. Sintering—using atomic diffusion to create objects from powdered material—has been around for thousands of years. However, it was first developed as an AM technique in the 1980s at the University of Texas at Austin and has been used as a foundation to develop similar processes for metals, glass, ceramics, and some composites. Although desktop and hobby 3D printers are widely available, there are very few SLS versions due to the complexity of the process.

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The main benefit of SLS over other AM processes (such as Stereolithography (SLA), Fused Deposition Modelling (FDM), or Fused Filament Fabrication (FFF)) is the unfused powder acting as a self- supporting material, eliminating the need for including support structures in the model. In addition to reduced print times, this results in the creation of intricate and complex geometries, including interlocking parts, moving parts, and complex lattice structures that maximize the part’s strength in desired locations, while also minimizing weight. SLS is a popular technique in the aerospace and medical device industries due to its ability to quickly produce low quantities at mass production accuracy levels, as well as the variety of materials that can be utilized.

The theory behind SLS is similar to other AM processes, in that source material is heated and built up layer by layer to complete a 3D structure imported as a STL file from Computer-Aided Design (CAD) software. The laser pulses on to the build platform, mapping a cross-section of the model on the loose powder, heating the powder to slightly below the melting point which fuses the particles together. While the layer height is dependent on the machine and the required accuracy, it is generally in the region of 100 microns. Once all the layers have been constructed, the object is left to cool before being removed for post-processing.

In addition to minimizing material wastage, post-processing can be less involved than other AM processes due to the absence of solid support structures. Unlike many other AM processes generally used for prototyping, SLS parts can be used in production, which would be the reason for the majority of post-processing. Due to the nature of the process, SLS parts have a grainy surface finish. Polishing can be included in post-processing for a smoother surface finish, including a coating with a watertight material to counteract the porosity of the finished part. Depending on the intended use of the part, metal plating can also be added. In comparison to other AM techniques, the grainy surface finish and internal porosity would be considered as negative aspects, but the main downside to SLS printing is its susceptibility to warping, which affects the accuracy of large flat surfaces and small holes.

Selective Laser Sintering is a relatively new technique that has allowed the manufacturing world the opportunity to reconsider the design process, design opportunity costs, and how parts and assemblies are produced, even within the sphere of AM.

About the author:
Chris Brennan is a Manufacturing Engineer and the founder/owner of Thirteen Design Consultancy based out of County Louth, Ireland.
[email protected]
Instagram: @thirteendesignconsultancy
Facebook: @thirteendesignconsultancy
Twitter: @13DesignIreland
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