Monitoring concept for powder flow monitoring in Laser-Directed Energy Deposition (L-DED) process based on flexible piezoelectric sensors

Materials Open Research Pub Date : 2022-05-04 DOI:10.12688/materialsopenres.17427.1

Vojislav Petrovic-Filipovic, R. Görgl, M. Suppan, J. Hesse, W. Waldhauser

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Abstract

Background: The quality of powder-blown Laser-Directed Energy Deposition (L-DED) is mainly governed by the energy density per unit of mass employed to melt the material. In most of the previous works, the focus in process monitoring and control was on the control of energy input, by controlling the properties of the melt pool. However, the powder mass input is as important to monitor as the energy input, in order to preserve the equilibrium of the process. Methods: In this paper, the authors present the first test results of the Pyzoflex® sensor for powder flow monitoring in L-DED using real powder feeding system in the robot-based laser-processing cell. The sensor was tested against the powder projected from the powder feeder under typical flow regimes and the real-time measurements were taken using a specifically designed software tool. Results: The graphical representation of the registered sensor signals are clearly correlated with the powder flow values set at the powder feeder, which demonstrates that the piezoelectric sensors can detect the powder flow with elevated precision in real time. Conclusions: The first laboratory tests of flexible printed piezoelectric sensors demonstrate that they are fast and precise in the powder flow measurement, but that more effort must be invested in the robustness of the measurement setup as well as in clearing and stabilization of the registered signal.

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基于柔性压电传感器的激光定向能量沉积（L-DED）过程粉末流动监测概念

背景：粉末吹制激光定向能量沉积（L-DED）的质量主要取决于熔化材料所用的每单位质量的能量密度。在以前的大多数工作中，过程监测和控制的重点是通过控制熔池的特性来控制能量输入。然而，为了保持过程的平衡，粉末质量输入与能量输入一样重要。方法：在本文中，作者介绍了Pyzoflex®传感器在基于机器人的激光加工室中使用真实的粉末进给系统在L-DED中监测粉末流量的首次测试结果。在典型的流动状态下，针对从粉末进料器投射的粉末对传感器进行了测试，并使用专门设计的软件工具进行了实时测量。结果：记录的传感器信号的图形表示与在给粉机上设置的粉末流量值明显相关，这表明压电传感器可以实时检测粉末流量，精度更高。结论：柔性印刷压电传感器的首次实验室测试表明，它们在粉末流量测量中快速而精确，但必须在测量设置的稳健性以及记录信号的清除和稳定方面投入更多的精力。

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