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Abstract
Micron-sized particles generated during laser-induced event are difficult to control in large optical systems such as final optics assembly (FOA) and have a great impact on load capacity. The related removal methods of these particles have become concerns. This study investigated a latest removal method of dual dynamic airflow protection for micron particles of diameters from 0.5 to 50 μm by laser-induced fused silica in the FOA. Firstly, a device for obstructing longitudinal movement of particles was established, which adopted the vertical “air curtain” coupled with laminar background flow to realize the first step to weaken threat of small diameter particles (0.5–5 μm). Next, numerical simulations of coupled field in the neutral plane was applied to help analyze the whole protective process and the dynamic removal mechanisms. Secondly, individual air knives were locally installed on the top of each optics to form high speed films as a secondary protection to avoid large-diameter particles (5–50 μm, with different initial velocities which could break through the curtain) from landing onto the surfaces. By statistically comparing the results, we found that the dual dynamic protection methods mixed with laminar flow and air knives in various arrangement could basically achieve the goal of pre-protection and removal of laser-induced micron particles of fused silica to maintain high cleanliness levels of optics surface.
Copyright © 2019 American Association for Aerosol Research
EDITOR:
Acknowledgments
We would like to acknowledge Prof. Lihua Lu and Jiaxuan Chen for useful conversations and practical guidelines. Thanks for the sample supporting from Mr. Miao and text review from Prof. Yuqin Zhao and Dr. Dong. This work was performed under the auspices of Center for Precision Engineering, Harbin Institute of technology and Laser Fusion Research Center, China Academy of Engineering Physics.