Process characteristics of metal L-PBF

Process characteristics of L-PBF

Highly accurate and fully dense parts

Metal Laser Powder Bed Fusion (L-PBF), is capable of producing high-quality parts and is today used across all industries for a wide range of applications. 

This section provides an overview of the most important process characteristics. 

Image source: Hydrovision, H&H

Design guidelines

High design freedom only limited by support structures

Regarding the design of parts fabricated with L-PBF technology, several principles have to be considered. Overhanging structures must be braced by support structures to enable heat dissipation and to avoid part deformations due to internal stresses.

Horizontal holes or channels have to be supported, too, or designed in a drop shape to avoid overhangs. Minimal wall-thickness depends on the optical resolution of the machine and parameter set. In general, a wall-thickness of more than 1 mm is recommended.

Theoretically, the maximum part size depends only on the build volume of the machines and is in the range of several decimeters in all directions for standard machines up to >1m for large-scale machines. In practice, process stability and resulting residual stresses in massive metal parts have to be considered and may limit the component size.

When designing a part for L-PBF, the guidelines presented in this chapter can act as a general rule of thumb for designers. Once it comes to the actual printing of the part, machine- and process-related aspects then need to be considered and might give additional design freedom or add restrictions. 

  • Typical part size

    Typical part sizes range from 15 mm to 300 mm. Larger parts are possible but can cause complications due to distortion.

  • Resolution

    Layer thicknesses are in a range of 0.025 – 0.09 mm. The typical geometrical accuracy is ± 50 µm, even higher detail processes exist.

  • Surface roughness

    The surface roughness depends on the layer thickness and the material. Typical Ra values are between 5 – 10 µm.

  • Wall thickness

    Thick walls can cause porosity. Typically walls between 1 – 10 mm are recommended, walls down to ~0.2 mm still possible. Sudden jumps in thickness should be avoided.

  • Hollow bodies

    Hollow bodies are possible as long as the support material and residual powder can be removed.

  • Shrinkage

    There is not shrinkage that has to be considered.

  • Distortion

    Residual stresses can cause distortion. Especially for overhangs and large parts, distortion can be a problem. Advanced simulation tools are available.

  • Supports

    Usually overhangs of 45° can be build support free. In some cases, process modifications allow for even lower overhangs up to 10°.

  • Lattice

    Lattice structures are possible and easy to achieve.

Materials

Laser Powder Bed Fusion material variety

For L-PBF a large variety of alloys is commercially available. The most important prerequisite is a good weldability. Furthermore, the material must be available as a powder with a suitable particle size distribution. The powder fraction is system and process specific and differs between about 20 µm to 60 µm. With an adaptation of process parameters larger as well as finer powder fractions are possible, too. Very fine powder fractions tend to agglomerate during handling and coating due to extremely fine dust particles in the distribution and should be avoided.

Typical alloys processed with L-PBF are Ti-6Al-4V, CoCr, stainless and tool steels, nickel-based superalloys, aluminum alloys and also precious metals. High purity copper is difficult in processing with today’s machine systems as the available laser wave lengths is only poorly absorbed.

  • Stainless steel alloys

    Stainless steel is widely available.

  • Maraging Steel

    Maraging steels are possible with L-PBF.

  • Aluminum

    Aluminum alloys are possible and available. High strength aluminum alloys in development but challenging due to cracking.

  • Titanium Alloys

    Titanium alloys are available for L-PBF.

  • Nickel based Alloys

    Nickel based alloys are available for L-PBF.

  • Carbides

    Carbides are challenging for L-PBF and currently not available.

  • Copper and Bronze

    Copper is possible with modifications, such as a green laser or higher laser power.

  • Cobalt

    Cobalt alloys are available for L-PBF.

  • Magnesium

    Magnesium has been processed in R&D environment but is not commercially available.

  • Precious metals

    Some precious metals like platinum or gold are available for L-PBF.

Material Properties

Laser Beam Powder Bed Fusion with high material properties

Parts fabricated with L-PBF technology exhibit similar properties as parts fabricated with conventional methods. Parts usually exceed a density of 99.7 % by far. However, the surface is rather rough due to staircase effects or adhering powder particles. Functional surfaces typically require post processing to decrease surface roughness.

Due to high temperature gradients during cooling a fine-grained microstructure is the result in the part. In comparison to conventional material properties, L-PBF exhibits in general static mechanical properties with very high strength. A brittle behavior with relatively low elongation at break may be observed. Using common heat treatments, the material properties can be influenced as desired.

Fatigue resistance is highly dependent on surface quality, i.e. surface defects, and residual porosity. Parts exhibit good fatigue strength, if post processing achieved high surface quality and residual porosity was reduced through hot isostatic pressing.

Typical cross section of Laser Beam Powder Bed Fusion components

Typical material properties for L-PBF exceed ISO standard for surgical implants

Sinter-based AM technologies and process chain

Sinter-based AM - a technology overview

Many different printing technologies - one sintering process

The sinter-based AM (SBAM) technologies have, as the name suggests, the sintering process in common. In this process, the printed green part is consolidated into a dense part and receives its final properties. The green part can be printed in advance using different technologies.They all have in common that metal powder is bound to the desired shape by a binder. The best-known printing technologies include Binder Jetting and Filament Material Extrusion.

In this section, you learn everything about the sinter-based AM  process chain and get an overview of the different printing technologies.

Goal and structure of this course

This course is aimed at engineers, designers and other professionals that are working closely with sinter-based AM technologies. The goal is to cover the most important aspects that will enable engineers and designers to fully grasp the capabilities and technical limitations of the printing technologies and the sintering process to succeed in technology selection and part design. Besides going through the course from the beginning until the end, this course can also act as a constant source of knowledge while working on AM projects. 

The course is structured into the following sections.

This section will start with an overview of the sinter-based AM process chain and its printing technologies, followed by a technology deep dive into the most important aspects of the BJT technology, followed by a closer look at the debinding and sintering step also including sintering simulation .

The second section will provide an overview of the different materials that are available as well as part characteristics that can be achieved with the BJT process and typical methods for quality assurance. Finally, several common defects in the BJT process are presented. 

The last section will act as a guideline for designers. Besides generally describing the process when designing for Additive Manufacturing, actionable restrictions and guidelines for the BJT process are provided. The final section will present several design examples from different industries. 

What you will find in this section

Sinter-based AM process chain

From digital model to finished part

Data preparation

Simulation to compensate the deformation during the sintering step, nesting of parts and definition of printing parameters

Printing

Through various printing processes, different feedstocks such as metal powders, filaments, pellets or dispersions are processed into green parts

Unpacking

Unpacking of fragile green parts needs to be done carefully and is typically a manual process.

Debinding

Debinding describes the process of removing the binder which results in a brown part

Sintering

To reach the structural integrity of a metal part, a sinter process is required. The powder particles fuse together to a coherent, solid structure via a mass transport that occurs at the atomic scale driven via diffusional forces.

The brown part shrinks ~13-21 % in each direction.

The process chain of sinter-based technologies differs from other AM Technologies. Especially the post-printing processes (debinding and sintering) are crucial to achieve the intended mechanical properties.

Technology principle

How does Binder Jetting work?

Binder Jetting is a powder based Additive Manufacturing technology in which a liquid polymer binder is selectively deposited onto the powder bed binding the metal particles and forming a green body.

The metal powder is applied to a build platform in a typical layer thickness of 40 µm to 100 µm. Subsequently a modified 2D print head apply a binder selectively onto the powder bed. Depending on machine technology a hardening or curing process of the binder is performed in parallel for each layer and/or at the end of the whole build. During the in-situ curing process a heat source is used to solidify the binder and form a solid polymer – metal powder composite.

Working Principle of Binder Jetting

Afterwards the build platform moves downward by the amount of one layer thickness and a new layer of powder is applied. Again, the liquid binder is deposited and hardened in the required regions of the next layer to form the green body. This process is repeated until the complete part is printed. After the complete printing process is finished the parts have to be removed from the “powder cake” meaning the surrounding loose but densified powder. To improve the removal of the excess powder from the green body often brushes or a blasting gun with air pressure are used.

To create a dense metal part the 3D printed green body has to be post-processed in a debinding and sintering process. Similar to the metal injection molding process BJT parts are placed in a high temperature furnace, where the binder is burnt out and the remaining metal particles are sintered together. The sintering results in densification of the 3D printed green body to a metal part with high densities of 97 % to 99,5%, dependent of the material.

Printing Technologies

Metal Binder Jetting

Binder Jetting is a powder based Additive Manufacturing technology in which a liquid polymer binder is selectively deposited onto the powder bed binding the metal particles and forming a green body.

The metal powder is applied to a build platform in a typical layer thickness of 40 µm to 100 µm. Subsequently a modified 2D print head apply a binder selectively onto the powder bed. Depending on machine technology a hardening or curing process of the binder is performed in parallel for each layer and/or at the end of the whole build. During the in-situ curing process a heat source is used to solidify the binder and form a solid polymer – metal powder composite.

Working Principle of Binder Jetting

Material Extrusion

Binder Jetting is a powder based Additive Manufacturing technology in which a liquid polymer binder is selectively deposited onto the powder bed binding the metal particles and forming a green body.

The metal powder is applied to a build platform in a typical layer thickness of 40 µm to 100 µm. Subsequently a modified 2D print head apply a binder selectively onto the powder bed. Depending on machine technology a hardening or curing process of the binder is performed in parallel for each layer and/or at the end of the whole build. During the in-situ curing process a heat source is used to solidify the binder and form a solid polymer – metal powder composite.

Working Principle of Binder Jetting

Mold Slurry Deposition

Binder Jetting is a powder based Additive Manufacturing technology in which a liquid polymer binder is selectively deposited onto the powder bed binding the metal particles and forming a green body.

The metal powder is applied to a build platform in a typical layer thickness of 40 µm to 100 µm. Subsequently a modified 2D print head apply a binder selectively onto the powder bed. Depending on machine technology a hardening or curing process of the binder is performed in parallel for each layer and/or at the end of the whole build. During the in-situ curing process a heat source is used to solidify the binder and form a solid polymer – metal powder composite.

Working Principle of Binder Jetting

Metal Selective Laser Sintering

Binder Jetting is a powder based Additive Manufacturing technology in which a liquid polymer binder is selectively deposited onto the powder bed binding the metal particles and forming a green body.

The metal powder is applied to a build platform in a typical layer thickness of 40 µm to 100 µm. Subsequently a modified 2D print head apply a binder selectively onto the powder bed. Depending on machine technology a hardening or curing process of the binder is performed in parallel for each layer and/or at the end of the whole build. During the in-situ curing process a heat source is used to solidify the binder and form a solid polymer – metal powder composite.

Working Principle of Binder Jetting