Review of burst-mode lasers for high-speed PLIF imaging diagnostics

被引：3

作者：

Li X.-D. ^{[1
]}

Mei F. ^{[1
]}

Yan R.-P. ^{[1
]}

Liu Z.-X. ^{[2
]}

Jiang Y.-G. ^{[3
]}

Chen D.-Y. ^{[1
]}

机构：

[1] National Key Laboratory of Tunable Laser Technology, Harbin Institute of Technology, Harbin

[2] Shenzhen Aerospace Industry Technology Research Institute, Shenzhen

[3] Tianjin Key Laboratory of Optical Thin Film, Tianjin Jinhang Technical Physics Institute, Tianjin

来源：

Guangxue Jingmi Gongcheng/Optics and Precision Engineering | 2019年 / 27卷 / 10期

关键词：

Burst-mode; Laser diagnosis; LD-pumped; Q-switched;

D O I：

10.3788/OPE.20192710.2116

中图分类号：

学科分类号：

摘要：

Planar Laser-induced Fluorescence (PLIF) is an imaging diagnostic technique that is based on the sheet laser beam, fluorescence emission from free radicals or tracer particles in a stimulated flow field, and the spatial distribution information of the flow field obtained through fluorescence imaging. Currently, the burst-mode laser is an effective light source that can satisfy the requirements of a high repetition rate and high energy laser source for high-speed PLIF technology. The study provides a comprehensive overview of burst-mode lasers used in high-speed PLIF imaging diagnosis. The characteristics and development of different burst-mode lasers are compared and explained. The prospects of burst-mode lasers as high-speed laser diagnostics light sources are also presented. © 2019, Science Press. All right reserved.

引用

页码：2116 / 2126

页数：10

共 28 条

[1] Boxx I., Slabaugh C., Kutne P., Et al., 3 kHz PIV/OH-PLIF measurements in a gas turbine combustor at elevated pressure, Proceedings of the Combustion Institute, 35, 3, pp. 3793-3802, (2015)
[2] Mansour M.S., Alkhesho I., Chung S.H., Stabilization and structure of n-heptane flame on CWJ-spray burner with kHZ SPIV and OH-PLIF, Experimental Thermal and Fluid Science, 73, pp. 18-26, (2016)
[3] Ma L., Wu Y., Xu W.J., Et al., Comparison of 2D and 3D flame topography measured by planar laser-induced fluorescence and tomographic chemiluminescence, Applied Optics, 55, 20, (2016)
[4] Richardson D.R., Sukesh R., Gord J.R., Femtosecond, two-photon, planar laser-induced fluorescence of carbon monoxide in flames, Optics Letters, 42, 4, (2017)
[5] Hu Y., Yin S.X., Bjorn A., Et al., Design of laser schlieren test system for mine gas/air premixed gas deflagration, Opt. Precision Eng., 27, 5, pp. 1045-1051, (2019)
[6] Li X., Jiang L.Q., Yang H.L., Et al., Measurement of OH and CH radicals in micro-jet flames using planar laser induced fluorescence and CH filter, Opt. Precision Eng., 5, pp. 1119-1125, (2017)
[7] Thurow B., Jiang N.B., Lempert W., Review of ultra-high repetition rate laser diagnostics for fluid dynamic measurements, Measurement Science & Technology, 24, 1, (2012)
[8] Becker H., Arnold A., Suntz R., Et al., Investigation of flame structure and burning behaviour in an IC engine simulator by 2D-LIF of OH radicals, Applied Physics B, 50, 6, pp. 473-478, (1990)
[9] Kaminski C., Hult J., Alden M., High repetition rate planar laser induced fluorescence of OH in a turbulent non-premixed flame, Applied Physics B, 68, 4, pp. 757-760, (1999)
[10] Liu J.R., Hu Z.Y., Zhang Z.R., Et al., Laser spectroscopy applied to combustion diagnostics, Opt. Precision Eng., 19, 2, pp. 284-296, (2011)

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