Abstract
Although various alloy systems have been explored for additive manufacturing (AM) during the past decade, introducing a new alloy remains a challenging task. Most of the materials require iterative builds, for investigating numerous parameters and determining a viable and repeatable process window.Among the challenging yet highly demanded materials, Haynes 282 superalloy was chosen. It was initially processed through conventional density cube approach, by varying the process parameters for each processed cube. Although the relative densities of the initial builds were not dramatically low, micro-cracks were present in all of them, mostly evolved on a selective number of grain boundaries and spanning only across a single laser path. Detailed modelling and advanced characterization techniques were employed to understand the root cause and cracking mechanism. It was found that the grain boundary precipitates are responsible for crack initiation, amid stress gradient across the grain boundary due to the adjacent grain orientations. Therefore, the failure mechanism is determined as ductility-dip cracking. Based on the findings, a new process window was defined using elevated temperature and novel scanning strategy. No cracks were observed under the modified processing window, meaning that the material can reliably be processed by laser beam powder bed fusion (PBF-LB).
Highlights
We present the roadmap for processing the HAYNES® 282® (H282) superalloy using Powder Bed Fusion (PBF)-LB technology
A study on PBF-LB processing of H282 was conducted successfully. It consists of stepwise parameter studies, variation of build plate heating, innovative scanning strategies and the manufacturing of several cubic samples
Those samples were characterized for their microstructural features including defects, precipitates, hardness, and surface roughness
Summary
Additive Manufacturing (AM) is known to enable new design concepts and processing approaches for various modern materials. Laser Beam Powder Bed Fusion (PBF-LB) technology is in focus. This process has several trademarked names, e.g., Laser Cusing, Selective Laser Melting, Direct Metal Laser Melting, etc. The addition of layers is challenging for the structural integrity of the final product due to the recursive thermal cycles and associated solidification phenomena. This limits material choices as most of the engineering alloys cannot tolerate such processing conditions without appropriate modifications
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