One of the significant challenges in additive manufacturing is ensuring process reliability, particularly in metal 3D printing. Professionals often hesitate to adopt this technology due to concerns about whether 3D-printed parts will meet specifications and withstand the test of time. Researchers at Lawrence Livermore National Laboratory (LLNL), specifically within the Non-Destructive Evaluation (NDE) group, are working on enhancing control and ensuring consistent quality in metal 3D printing.
The crux of the issue lies in how metal parts react during the printing process, where heat sources are used to fuse metal particles. Metals are sensitive to thermal changes that impact their structural integrity. The uneven diffusion of heat can lead to failures or defects in the final product. To address this, LLNL is focused on improving NDE techniques to observe material behavior during the printing process, thereby ensuring parts are produced to a higher standard.
David Stobbe, the group leader for NDE ultrasonics and sensors at LLNL, emphasized the importance of demonstrating that additively manufactured parts perform as intended. He noted that proving reliability is crucial for the implementation of metal additive manufacturing in critical sectors such as aerospace and energy.
The NDE techniques leverage various signals, including electrical currents, X-rays, and ultrasound waves, to monitor the printed components. Research scientist Saptarshi Mukherjee highlighted their innovative use of eddy currents to measure internal temperatures during the powder bed laser fusion process. This real-time monitoring provides valuable data on the temperature profiles within the parts being produced.
Additionally, projects are ongoing to employ X-ray computed tomography and other advanced techniques to analyze complex lattice structures and geometric designs. The ultimate aim is to create machine learning algorithms that can correct errors in real time during the printing process, potentially paving the way for greater adoption of metal additive manufacturing.
For more detailed information on LLNL’s research and its implications for the future of metal 3D printing, you can learn more here.