Calibrated closed-loop control to reduce the effect of geometry on mechanical behaviour in directed energy deposition

Directed energy deposition (DED) is an emerging technology with significant industrial potential in the repair of critical aerospace components, however its adoption has been limited by concerns about geometry-driven microstructural and mechanical property variation. These could be resolved by controlling the local tempera-ture field, which would result in a consistent and predictable cooling profile. Closed-loop control approaches have been investigated previously, but with limited assessment of mechanical properties and only on small builds. In this work, we confirm that using fixed build parameters results in a statistically significant, geometry -driven variation in the bulk mechanical properties of DED-built 316 L steel. To address this issue, we have developed an industrially-suitable control algorithm using a low-cost coaxial camera, applying statistical process control techniques to identify representative melt pool images from the livestream. This has been tested on long builds, maintaining a control adjustment frequency of 1 Hz on build durations of > 1 h. Performance has been quantified through bulk mechanical testing, which confirmed that the control algorithm successfully eliminated the component-scale trends in melt pool size, and achieved a geometry-agnostic process with improved me-chanical homogeneity.

Automated summary

Directed energy deposition (DED) is a promising technology for repairing aerospace components, but concerns about variation in microstructure and mechanical properties have limited its adoption. In this study, we developed an industrially-suitable control algorithm using a low-cost coaxial camera and statistical process control techniques to identify representative melt pool images. Testing on long builds confirmed that the control algorithm successfully eliminated component-scale trends in melt pool size and achieved improved mechanical homogeneity.