20% off your first order. Save up to $1,000/€1,000. Ends 31 Dec 2024. Get a quote

Get instant quote

What is Binder Jetting 3D printing?

In this introduction to Binder Jetting 3D printing, we cover the basic principles of the technology. After reading this article you will understand the fundamental mechanics of the Binder Jetting process and how these relate to its benefits and limitations.

Introduction to Binder Jetting 3D printing

What is Binder Jetting?

Binder Jetting is a family of additive manufacturing processes. In Binder Jetting, a binder is selectively deposited onto a powder bed, bonding these areas together to form a solid part one layer at a time. The materials commonly used in Binder Jetting are metals, sand, and ceramics that come in a granular form.

Binder Jetting is used in various applications, including the fabrication of full-color prototypes (such as figurines), the production of large sand casting cores and molds and the manufacture of low-cost 3D printed metal parts.

With such diverse applications, it is essential for a designer who wants to use the capabilities of Binder Jetting to the fullest, to understand the basic mechanics of the process and how these connect to its key benefits and limitations.

The Binder Jetting process

How does Binder Jetting work?

Here is how the Binder Jetting process works:

I. First, a recoating blade spreads a thin layer of powder over the build platform.

II. Then, a carriage with inkjet nozzles (which are similar to the nozzles used in desktop 2D printers) passes over the bed, selectively depositing droplets of a binding agent (glue) that bond the powder particles together. In full-color Binder Jetting, the colored ink is also deposited during this step. The size of each drop is approximately 80 μm in diameter, so good resolution can be achieved.

III. When the layer is complete, the build platform moves downwards and the blade re-coats the surface. The process then repeats until the whole part is complete.

IV. After printing, the part is encapsulated in the powder and is left to cure and gain strength. Then the part is removed from the powder bin and the unbound, excess powder is cleaned via pressurized air.

Depending on the material, a post-processing step is usually required. For example, metal Binder Jetting parts need to be sintered (or otherwise heat treated) or infiltrated with a low-melting-temperature metal (typically bronze). Full-color prototypes are also infiltrated with acrylic and coated to improve the vibrancy of colors. Sand casting cores and molds are typically ready to use after 3D printing.

This is because the parts are in a “green” state when they leave the printer. Binder Jetting parts in the green state have poor mechanical properties (they are very brittle) and high porosity.

Schematic of a Binder Jetting 3D printer

What are the characteristics of Binder Jetting 3D printing?

Printer Parameters

In Binder Jetting, almost all process parameters are preset by the machine manufacturer.

The typical layer height depends on the material: for full color models the typical layer height is 100 microns, for metal parts 50 microns and for sand casting mold materials 200-400 microns.

A key advantage of Binder Jetting over other 3D printing processes is that bonding occurs at room temperature. This means that dimensional distortions connected to thermal effects (such as warping in FDM, SLS, DMSL/SLM or curling in SLA/DLP) are not a problem in Binder Jetting.

As a result, the build volume of Binder Jetting machines are amongst the largest compared to all 3D printing technologies (up to 2200 x 1200 x 600 mm). These large machines are generally used to produce sand casting molds. Metal Binder Jetting systems typically have larger build volumes than DMSL/SLM systems (up to 800 x 500 x 400 mm), which allows the parallel manufacturing of multiple parts at a time. The maximum part size though is restricted to a recommended length of up to 50 mm, due to the post-processing step involved.

Moreover, Binder Jetting requires no support structures: the surrounding powder provides to the part all the necessary support (similar to SLS). This is a key difference between metal Binder Jetting and other metal 3D printing processes, which usually require extensive use of support structures, and allows for the creation of freeform metal structures with very few geometric restrictions. Geometric inaccuracies in metal Binder Jetting come mainly from the post-processing steps, as discussed in a later section.

Since the parts in Binder Jetting do not need to be attached to the build platform, the whole build volume can be utilized. Thus, Binder Jetting is suitable for low-to-medium batch production. To take advantage of the full capabilities of Binder Jetting, it is very important to consider how to fill effectively the whole build volume of the machine (bin packing).

Small metal Binder Jetting with fine holes of great dimensional accuracy.

Image courtesy ofDigital Metal

Full Color Binder Jetting

Binder Jetting can produce full color 3D printed parts in a similar way to Material Jetting. It is often used to 3D print figurines and topographical maps, because of its low cost.

Full-color models are printed using sandstone powder or PMMA powder. The main printhead first jets the binding agent, while a secondary print head jets a colored ink. Inks with different colors can be combined to produce a very large array of colors, in a similar way to a 2D inkjet printer.

After printing, the parts are then coated with cyanoacrylate (super glue) or a different infiltrant to improve part strength and enhance the vibrancy of the colors. A secondary epoxy layer can then also be added to further improve strength and color appearance. Even with these extra steps, full-color Binder Jetting parts are very brittle and they are not recommended for functional applications.

To produce full-color prints, a CAD model that contains the color information must be provided. Color can be applied to CAD models via two methods: on a per face approach or as a texture map. Applying color on a per face basis is quick and easy to implement, but using a texture map allows for more controls and greater detail. Refer to your native CAD software for specific instructions.

A full color print printed in sandstone with Binder Jetting

Sand Casting Cores and Molds

The production of large sand casting patterns is one of the most common uses for Binder Jetting. The low cost and speed of the process make it an excellent solution for elaborate pattern designs that would be very difficult or impossible to produce using traditional techniques.

The cores and molds are generally printed with sand or silica. After printing, the molds are generally immediately ready for casting. The casted metal component is usually removed from them after casting by breaking the mold. Even though these molds are used only once, the time and cost savings compared to traditional manufacturing are substantial.

Multi-part sand casting assembly used to cast an engine block.

Image courtesy of ExOne

Metal Binder Jetting

Metal Binder Jetting is up to 10x more economical than other metal 3D printing processes (DMSL/SLM). Moreover, the build size of Binder Jetting is considerably large and the produced parts require no support structures during printing, enabling the creation of complex geometries. This makes metal Binder Jetting a very appealing technology for low-to-medium metal production.

The main drawback of metal Binder Jetting parts are their mechanical properties, which are not suitable for high-end applications. Nevertheless, the material properties of the produced parts are equivalent to metal parts produced with Metal Injection Molding, which is one of the most widely used manufacturing methods for the mass production of metal parts.

Infiltration & Sintering

Metal Binder Jetting parts require a secondary process after printing, like infiltration or sintering, to achieve their good mechanical properties, as the as-printed parts basically consist of metal particles bound together with a polymer adhesive.

Infiltration: After printing, the part is placed in a furnace, where the binder is burnt out leaving voids. At this point, the part is approximately 60% porous. Bronze is then used to infiltrate the voids via capillary action, resulting in parts with low porosity and good strength.

Sintering: After printing is complete, the parts are placed in a high temperature furnace, where the binder is burnt out and the remaining metal particles are sintered (bonded) together, resulting in parts with very low porosity.

An oil and gas stator printed from stainless steel and infiltrated with bronze. Notice the surface finish, which is typical for Binder Jetted parts.

Image courtesy of ExOne

Characteristics of metal Binder Jetting

Accuracy and tolerance can vary greatly depending on the model and are hard to predict as they are greatly dependant on the geometry. For example, parts with length up to 25 - 75 mm shrink between 0.8 to 2% after infiltration, while larger parts have an estimated average shrinkage of 3%. For sintering, the part shrinkage is approximately 20%. The dimensions of the parts are compensated for shrinkage by the machine’s software, but non-uniform shrinkage can be an issue and must be accounted for during the design stage in collaboration with the Binder Jetting machine operator.

The post-processing step can also be the source of inaccuracies. For example, during sintering, the part is heated to a high temperature and becomes softer. In this softer state, unsupported areas might deform under their own weight. Moreover, as the part shrinks during sintering, there here is friction between the plate of the furnace and the lower surface of the part, which may lead to warping. Again, communication with the Binder Jetting machine operator is key here to ensure optimal results.

Sintered or infiltrated Binder Jetting metal parts will have an internal porosity (sintering produces 97% dense parts, while infiltration approximately 90%). This affects the mechanical properties of metal Binder Jetting parts, as the voids can lead to crack initiation. Fatigue and fracture strength and elongation at break are the material properties that are most affected by internal porosity. Advanced metallurgical processes (like Hot isostatic pressing or HIP) can be applied to produce parts with almost no internal porosity. For applications where mechanical performance is critical though, DMLS or SLM are the recommended solutions.

An advantage of metal Binder Jetting compared to DMLS/SLM, is the surface roughness of the produced parts. Typically, metal Binder Jetted parts have a surface roughness of Ra 6 μm after post-processing, which can be reduced to Ra 3 μm if a bead-blasting step is employed. In comparison, the as-printed surface roughness of DMLS/SLM parts is approximately Ra 12-16 μm. This is particularly beneficial for parts with internal geometries, for example internal channels, where post-processing is difficult.

The table below summarizes the differences in the main mechanical properties of Stainless Steel parts, printed with Binder Jetting and DMLS/SLM:

Binder Jetting Stainless Steel 316 (sintered) Binder Jetting Stainless Steel 316 (bronze infiltrated) DMLS/SLM Stainless Steel 316L
Yield Strength 214 MPa 283 MPa 470 MPa
Elongation at Break 34% 14.5% 40%
Modulus of Elasticity 165 GPa 135 GPa 180 GPa

What are the common Binder Jetting materials?

Binder Jetting powders come in range of materials. The final application of the part defines the most appropriate powder. The cost of the ceramic powders is usually low. Metal powders are more expensive, yet more economical than DMSL/SLM materials. Unlike the SLS 3D printing process, 100% of the unbonded powder can be recycled, leading to more material savings.

Material Characteristics
Full Color Sandstone
Full colour non-functional models
Very brittle
Silica Sand
Very high thermal resistance
Excellent for sand casting applications
Stainless steel (bronze infiltrated)
Good mechanical properties
Can be machined
~10% internal porosity
Stainless steel (sintered)
Very good mechanical properties
High corrosion resistance
~3% internal porosity
Inconel alloy (sintered)
Excellent mechanical properties
Good temperature resistance
High chemical resistance
Tungsten carbide (sintered)
Very high hardness
Used for the production of cutting tools

What are the benefits & limitations of Binder Jetting 3D printing?

The key advantages and disadvantages of the technology are summarised below:

Binder Jetting produces metal parts and full-color prototypes at a fraction of the cost compared to DMLS/SLM and Material Jetting respectively.
Binder Jetting can manufacture very large parts and conplex metal geometries, as it is not limited by any thermal effects (e.g. warping).
The manufacturing capabilities of Binder Jetting are excellent for low to medium batch production.

Metal Binder Jetting parts have lower mechanical properties than DMSL/SLM parts, due to their higher porosity.
Only rough details can be printed with Binder Jetting, as the parts are very brittle in their green state and may fracture during post processing.
Compared to other 3D printing process, Binder Jetting offers a limited material selection.

The main characteristics of Binder Jetting are summarized in the table below:

Binder Jetting
Materials Metals, Ceramics (sand)
Dimensional accuracy Metal: ± 2% or 0.2 mm (down to ± 0.5% or ± 0.05) Full-color: ± 0.3 mm Sand: ± 0.3 mm
Typical build size Metal: 400 x 250 x 250 mm (up to 800 x 500 x 400 mm) Full-color: 200 x 250 x 200 mm (up to 500 x 380 x 230 mm) Sand: 800 x 500 x 400 (up to 2200 x 1200 x 600 mm)
Common layer thickness Metal: 35 - 50 μm Full-color: 100 μm Sand: 200 - 400 μm
Support Not required

What are Protolabs Network’s top tips & tricks for Binder Jetting 3D printing?

  • Choose metal Binder Jetting to 3D print metal parts at a low cost, especially for applications that do not require very high performance.
  • For metal 3D printed parts, Binder Jetting offers greater design freedom than DMLS/SLM, as thermal effects are not an issue during the manufacturing process.
  • Full-color Binder Jetting parts are very brittle and only suitable for visual purposes.
  • Use Binder Jetting to produce very large sand casting cores and molds.

More resources for engineers

ABS 3D printed part

When to use 3D printing vs when to use injection molding

Read article

3D printing for industrial purposes

Read article
A custom designed part printed on MJF printer.

What is MJF (HP's Multi Jet Fusion) 3D printing?

Read article
FDM Rapid Prototyping Service

What is rapid prototyping?

Read article
Introduction to Binder Jetting 3D printing

What is Binder Jetting 3D printing?

Read article
Simulations in 3D Printing

Simulations in 3D printing

Read article
Selecting the right 3D printing process

What’s the right 3D printer for prototyping? Comparing 3D printing processes

Read article
Introduction to Metal 3D printing

What is metal 3D printing and how does it work?

Read article
HP MJF vs. SLS: A 3D Printing Technology Comparison

What is the difference between Selective Laser Sintering (SLS) and Multi Jet Fusion (MJF) 3D printing?

Read article
Introduction to Material Jetting 3D Printing

What is Material Jetting 3D printing?

Read article
Introduction to SLS 3D Printing

What is SLS 3D printing?

Read article
Introduction to SLA 3D Printing

What is SLA printing? The original resin 3D print method

Read article
ABS 3D printed part

When to use 3D printing vs when to use injection molding

Learn what to consider when making a choice between 3D printing and injection molding, the benefits of each manufacturing method, and more.

Read article

3D printing for industrial purposes

Learn about the advantages and disadvantages of various methods of industrial 3D printing, materials that are commonly used, and more

Read article
A custom designed part printed on MJF printer.

What is MJF (HP's Multi Jet Fusion) 3D printing?

Multi Jet Fusion (MJF) is a 3D printing process for building prototyping and end-use parts fast. This article explains how MJF works and its main advantages.

Read article
FDM Rapid Prototyping Service

What is rapid prototyping?

Rapid prototyping uses 3D computer-aided design (CAD) and manufacturing processes to quickly develop 3D parts or assemblies for research and development and/or product testing.

Read article
Introduction to Binder Jetting 3D printing

What is Binder Jetting 3D printing?

In this introduction to Binder Jetting 3D printing, we cover the basic principles of the technology. After reading this article you will understand the fundamental mechanics of the Binder Jetting process and how these relate to its benefits and limitations.

Read article
Simulations in 3D Printing

Simulations in 3D printing

Learn about the benefits and current state-of-the-art of 3D printing simulations. This article describes why, what and how to use simulations in 3D printing and gives tips to help you get started.

Read article
Selecting the right 3D printing process

What’s the right 3D printer for prototyping? Comparing 3D printing processes

What 3D printing process is optimal for prototyping? This article explores the best 3D printers for the prototyping phase of product development, including design advice to get the most out of each manufacturing technology.

Read article
Introduction to Metal 3D printing

What is metal 3D printing and how does it work?

What is metal 3D printing? How does this additive technology work? This article covers the basic principles of SLM (selective laser melting) and DMLS (direct metal laser sintering) and how these relate to the key benefits and limitations of 3D printing.

Read article
HP MJF vs. SLS: A 3D Printing Technology Comparison

What is the difference between Selective Laser Sintering (SLS) and Multi Jet Fusion (MJF) 3D printing?

What is the difference between MJF and SLS 3D printing technology in terms of accuracy, materials, cost and lead times? Here’s how to choose the right additive manufacturing technology for your custom part needs.

Read article
Introduction to Material Jetting 3D Printing

What is Material Jetting 3D printing?

What is Material Jetting 3D printing and how does it work? In this comprehensive intro to this additive process, we explore the main principles of the technology and how to tell if it's the right way to manufacture your custom parts. After reading this article you will understand the fundamental mechanics of the Material Jetting process and how these relate to its benefits and limitations.

Read article
Introduction to SLS 3D Printing

What is SLS 3D printing?

Learn about the basic principles of selective laser sintering, also known as SLS 3D printing. Discover how SLS 3D printing works, the advantages of SLS techniques for rapid prototyping and low-production runs, and the various materials and options available that will suit your part or project.

Read article
Introduction to SLA 3D Printing

What is SLA printing? The original resin 3D print method

SLA printing is the original method used for 3D printing parts in resin. This is everything you need to know about SLA 3D printing!

Read article

Show more

Show less

Ready to transform your CAD file into a custom part? Upload your designs for a free, instant quote.

Get an instant quote