A Review on Binder Jet Additive Manufacturing of 316L Stainless Steel

• Published in: Journal of Manufacturing and Materials Processing Vol. 3; no. 3; p. 82
• Main Authors: Mirzababaei, Saereh, Pasebani, Somayeh
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.09.2019
• Subjects: 3-D printers; Additive manufacturing; Alloys; binder jetting; Ceramics; Crack propagation; Densification; Density; diffusion; Geometry; Heating rate; Laser applications; Lead time; Mechanical properties; Medical research; Metals; Optimization; porosity; Post-production processing; powder bed; Powder beds; Powder metallurgy; Printing; Process parameters; Rapid prototyping; Raw materials; Residual stress; Sintering; Sintering (powder metallurgy); Stainless steel; stainless steel (SS) 316L; Stainless steels; Stress concentration; Thickness; three-dimensional printing
• ISSN: 2504-4494; 2504-4494
• DOI: 10.3390/jmmp3030082

Binder jet additive manufacturing enables the production of complex components for numerous applications. Binder jetting is the only powder bed additive manufacturing process that is not fusion-based, thus manufactured parts have no residual stresses as opposed to laser-based additive manufacturing processes. Binder jet technology can be adopted for the production of various small and large metallic parts for specific applications, including in the biomedical and energy sectors, at a lower cost and shorter lead time. One of the most well-known types of stainless steels for various industries is 316L, which has been extensively manufactured using binder jet technology. Binder jet manufactured 316L parts have obtained near full density and, in some cases, similar mechanical properties compared to conventionally manufactured parts. This article introduces methods, principles, and applications of binder jetting of SS 316L. Details of binder jetting processes, including powder characteristics (shape and size), binder properties (binder chemistry and droplet formation mechanism), printing process parameters (such as layer thickness, binder saturation, drying time), and post-processing sintering mechanism and densification processes, are carefully reviewed. Furthermore, critical factors in the selection of feedstock, printing parameters, sintering temperature, time, atmosphere, and heating rate of 316L binder jet manufactured parts are highlighted and summarized. Finally, the above-mentioned processing parameters are correlated with final density and mechanical properties of 316L components to establish a guideline on feedstock selection and process parameters optimization to achieve desired density, structure and properties for various applications.