Abstract
A tool-based hybrid laser-electrochemical micromachining process involves concurrent application of two process energies i.e. electrochemical and laser in the same machining zone by means of a hybrid tool which serves as an ECM tool as well as a multimode waveguide. It is a relatively novel process finding applications in defect-free machining of difficult-to-cut materials without affecting their microstructure. In order to understand the physical phenomena occurring during this process, in-situ observations are required. Therefore, in this work, a real time observation was carried out of a novel tool-based hybrid laser electrochemical micromachining process. A combination of high-speed imaging and Large Scale Particle Image Velocimetry (LSPIV) was used to visualize the tool-based hybrid laser-ECM process in real time. It also allowed to carry out experimental investigations on the by-products and bubble generation which have a direct effect on process performance in terms of accuracy and efficiency. The real-time on-machine observations are unique of its kind and they will facilitate the understanding of underlying mechanisms governing this hybrid laser-electrochemical micromachining process. This will ultimately help in improving the quality of parts manufactured. This research is also a step forward towards making these physics-based hybrid processes deterministic by employing high-speed imaging in a closed loop control.
Highlights
A tool-based hybrid laser-electrochemical micromachining process involves concurrent application of two process energies i.e. electrochemical and laser in the same machining zone by means of a hybrid tool which serves as an ECM tool as well as a multimode waveguide
25% reduction in passivation layer was observed for Ti6Al4V with laser-ECM as compared to the ECM process this was not the case with WC and NbC where there was no difference in the oxygen content of the surface with ECM and laser-ECM as observed from EDX analysis
By further advancements in tool-based hybrid laser-ECM process in combination with the fundamental knowledge generated from real-time observations, this technology can create a technological breakthrough in scalable micromachining of advanced functional materials
Summary
A tool-based hybrid laser-electrochemical micromachining process involves concurrent application of two process energies i.e. electrochemical and laser in the same machining zone by means of a hybrid tool which serves as an ECM tool as well as a multimode waveguide. The real-time on-machine observations are unique of its kind and they will facilitate the understanding of underlying mechanisms governing this hybrid laser-electrochemical micromachining process. This will help in improving the quality of parts manufactured. Several physical phenomena govern the quality of electrochemically machined workpieces, including hydrogen bubble generation, oxygen gas generation, workpiece passivation, heat generation, generation of reactionbyproducts Since, these phenomena occur in and around a machining gap of less than 100 μm, it is difficult to study the mechanism of the process experimentally owing to technological limitations. By further advancements in tool-based hybrid laser-ECM process in combination with the fundamental knowledge generated from real-time observations, this technology can create a technological breakthrough in scalable micromachining of advanced functional materials. This research is a first step towards making these hybrid processes deterministic by employing high speed imaging in closed loop control
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