Powder Bed Fusion: Pros and Cons | Additive Manufacturing & 3D Printing
Powder Bed Fusion is a 3D printing process that involves partially melting powder particles in a pattern and letting them solidify into a pattern. Using layers, the fused powder patterns stack to create a part.
More Materials
The powder that melts may be the main material, or a binder material that acts as an adhesive. Since a binder material can be used to fuse particles, multiple materials can be used. Ceramics, metals, and polymers are some of the materials that can be used with PBF. Metal powders can be fully melted when the heat source (laser) is powerful and moves slowly, giving denser parts with better properties.
With full melting on metals, the part usually achieves a density over 99% (that is, very little porosity). This means that parts printed with PBF can approach the same material properties as bulk material. For some Titanium alloys, the material strength is actually better with full melting in a PBF process! Compare this to most 3D printed materials, which tend to be porous and weaker than conventional materials.
Powder Recycling
The powder is expensive, but even more expensive is throwing out partially melted or unused powder. To speed up the print process, powder is often preheated. This means that some powder is affected by the heat despite not being in the final part. For any PBF process of scale, the cost of recycling or throwing out powder needs to be considered.
Supports
On one hand, you might not really needs supports for some materials. This is because the powder (which has been scraped over for the next pattern) serves as a support. However, support should be considered for metal or asymmetrical parts. Residual stresses from printing can cause the part to warp. Cutting out metal supports and other post processing measures are a drawback of PBF.
Surface and Quality
With PBF, powder is being fused together, so most parts will have a noticeably lesser quality surface finish than a part made from other processes. Vat Polymerization, for instance, should have better surface quality than powder bed fusion. If you are willing to pay more for a better printer and powder, you can get smaller particles, which will have a better surface finish. However, small particles tend to clump and are more difficult to spread into a uniform layer.
Most PBF parts should shrink about 3 to 4% of the true size, which can lead to even more warping if the part is metal or asymmetrical.
Longer Print Times
Because the powder bed is preheated, and the part needs to cool, the print time is usually longer than other processes.
Great post! Thanks!
I don’t really get how 3D printing works or in what fields it’s used. I think everyone has seen those special pens that can create 3D shapes, which seem like toys. As far as I know, they use heated plastic that quickly solidifies. But through various articles, I’ve learned that 3D printing is used in many fields, including medicine, which I find surprising.
Even though I’m not an expert in 3D printing or these new technologies, I’ve read about their applications and learned a bit. In medicine, 3D printing and additive metal post processing technologies are relevant for making implants, like joint replacements. With 3D printing, specialists can create high-quality parts with the precise texture and exact shapes needed for effective use in both aerospace and medical fields.