不锈钢表面高质量微陷阱结构的激光辅助水射流加工

刘莉; 姚鹏; 褚东凯; 徐相悦; 屈硕硕; 黄传真

doi:10.37188/CO.EN-2024-0004

Volume 17 Issue 6

Nov. 2024

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Article Contents

Chinese Optics > 2024 > 17(6): 1476-1488.

LIU Li, YAO Peng, CHU Dong-kai, XU Xiang-yue, QU Shuo-shuo, HUANG Chuan-zhen. Laser-assisted water jet machining of high quality micro-trap structures on stainless steel surfaces[J]. Chinese Optics, 2024, 17(6): 1476-1488. doi: 10.37188/CO.EN-2024-0004

Citation:

LIU Li, YAO Peng, CHU Dong-kai, XU Xiang-yue, QU Shuo-shuo, HUANG Chuan-zhen. Laser-assisted water jet machining of high quality micro-trap structures on stainless steel surfaces[J]. Chinese Optics, 2024, 17(6): 1476-1488. doi: 10.37188/CO.EN-2024-0004

Citation:

LIU Li, YAO Peng, CHU Dong-kai, XU Xiang-yue, QU Shuo-shuo, HUANG Chuan-zhen. Laser-assisted water jet machining of high quality micro-trap structures on stainless steel surfaces[J]. Chinese Optics, 2024, 17(6): 1476-1488. doi: 10.37188/CO.EN-2024-0004

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Laser-assisted water jet machining of high quality micro-trap structures on stainless steel surfaces

doi: 10.37188/CO.EN-2024-0004

cstr: 32171.14.CO.EN-2024-0004

LIU Li^{1, 2
,},
YAO Peng^{1, 2
,
,},
CHU Dong-kai^{1, 2
,
,},
XU Xiang-yue^{1, 2},
QU Shuo-shuo^{1, 2},
HUANG Chuan-zhen³

1.
Center for Advanced Jet Engineering Technologies (CaJET), School of Mechanical Engineering, Shandong University, Jinan 250061, China
2.
Key Laboratory of High Efficiency and Clean Mechanical Manufacture, Ministry of Education, Shandong University, Jinan 250061, China
3.
School of Mechanical Engineering, Yanshan University, Qinhuangdao 066004, China

Funds: Supported by National Natural Science Foundation of China (No. 52075302); Shenzhen Science and Technology Plan (No. GJHZ20210705142537003)

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Author Bio:
LIU Li (1988—), female, born in Rizhao, Shandong Province, Doctoral student. She obtained her master's degree from Shandong Agricultural University in 2013, mainly engaged in the research of ultra fast laser micro nano processing, stainless steel surface micro groove processing, and ultra fast laser ablation of atherosclerotic plaque technology. E-mail: liuli0685@163.com

YAO Peng (1979—), male, born in Dalian, Liaoning Province, PhD, Professor, Doctoral Supervisor. He received his doctoral degree from Northeastern University (Japan) in 2011, Mainly engaged in research on grinding and ultra precision machining technology, multi energy field composite precision machining technology, and laser micro/nano machining technology. E-mail: yaopeng@sdu.edu.cn

CHU Dong-kai (1991—), male, born in Lvliang, Shanxi Province, PhD, Assistant researcher, master's supervisor. He received his doctoral degree from Central South University in 2020. Mainly engaged in research on ultrafast laser micro nano manufacturing, functional surface preparation for release wave-absorbing, and ultra precision machining technology. E-mail: chudongkai@sdu.edu.cn
Corresponding author: yaopeng@sdu.edu.cn; chudongkai@sdu.edu.cn
Received Date: 01 Feb 2024
Rev Recd Date: 18 Mar 2024
Accepted Date: 29 Apr 2024

Available Online: 11 May 2024

Abstract

Abstract

Secondary electron emission (SEE) has emerged as a critical issue in next-generation accelerators. Mitigating SEE on metal surfaces is crucial for enhancing the stability and emittance of particle accelerators while extending their lifespan. This paper explores the application of laser-assisted water jet technology in constructing high-quality micro-trap structures on 316L stainless steel, a key material in accelerator manufacturing. The study systematically analyzes the impact of various parameters such as laser repetition frequency, pulse duration, average power, water jet pressure, repeat times, nozzle offset, focal position, offset distance between grooves, and processing speed on the surface morphology of stainless steel. The findings reveal that micro-groove depth increases with higher laser power but decreases with increasing water jet pressure and processing speed. Interestingly, repeat times have minimal effect on depth. On the other hand, micro-groove width increases with higher laser power and repeat times but decreases with processing speed. By optimizing these parameters, the researchers achieved high-quality pound sign-shaped trap structure with consistent dimensions. We tested the secondary electron emission coefficient of the "well" structure. The coefficient is reduced by 0.5 at most compared to before processing, effectively suppressing secondary electron emission. These results offer indispensable insights for the fabrication of micro-trap structures on material surfaces. Laser-assisted water jet technology demonstrates considerable potential in mitigating SEE on metal surfaces.
- laser-assisted water jet,
- 316L stainless steel,
- micro-trap structures,
- "well" structure,
- surface morphology,
- secondary electron emission (SEE),
- groove depth,
- groove width

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References(23)

References

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