亥姆霍兹光声光谱多气体检测器设计和优化

赵彦东; 方勇华; 李扬裕; 李大成

doi:10.3788/IRLA201746.0620005

亥姆霍兹光声光谱多气体检测器设计和优化

doi: 10.3788/IRLA201746.0620005

1.
中国科学院安徽光学精密机械研究所通用光学定标与表征技术重点实验室,安徽合肥 230031;
2.
中国科学技术大学,安徽合肥 230031

基金项目:

安徽省自然科学基金（1608085QD80）

详细信息

作者简介:
赵彦东(1990-),男,博士生,主要从事光声光谱检测技术方面的研究。Email:ydz2007274067@126.com;方勇华(1966-),男,研究员,博士生导师,主要从事遥感与光谱图像分析和红外遥感,大气辐射校正等方面的研究。Email:yhfang@aiofm.ac.cn

赵彦东(1990-),男,博士生,主要从事光声光谱检测技术方面的研究。Email:ydz2007274067@126.com;方勇华(1966-),男,研究员,博士生导师,主要从事遥感与光谱图像分析和红外遥感,大气辐射校正等方面的研究。Email:yhfang@aiofm.ac.cn

中图分类号: O433.1

Design and optimization of Helmholtz-based photoacoustic spectroscopic sensor for multi-gas detection

1.
Key Laboratory of Optical Calibration and Characterization,Anhui Institute of Optics and Fine Mechanics,Chinese Academy of Sciences,Hefei 230031,China;
2.
University of Science and Technology of China,Hefei 230031,China

摘要: 光声光谱技术作为一种先进的光学检测技术，已成功应用于各种痕量气体检测场合。实现多气体的光声光谱检测，同时保证高的检测灵敏度是检测器设计的核心目标。针对测量需求设计，优化了一种基于亥姆霍兹共振的光声光谱多气体检测器，使用有限元分析方法对检测器进行了设计和仿真分析，对光声池的结构参数以及温度和压力特性进行了优化和分析。仿真结果表明：对光声池结构参数进行优化和对温度压力进行控制可以提高检测器检测灵敏度；采用光源IR-19时，激发腔38 mm9 mm，连接管5.9 mm10.2 mm和探测腔30 mm5.8 mm为光声光谱检测器的最优化参数。经实验验证，检测器对CO气体的检测精度达到5.08 ppm（1 ppm=10-6）。研究结果为痕量多气体的光声光谱检测提供了设计参考。
- 光声光谱 /
- 亥姆霍兹共振 /
- 有限元分析 /
- 参数优化
Abstract: As one of the most advanced optical detection techniques, photoacoustic spectroscopy has been successfully used in the area of trace gas detection. Realizing a multi-gas photoacoustic spectroscopy sensor while keeping a high detection sensitivity was the design purpose. For the detection application, a multi-gas photoacoustic spectroscopy sensor based on the Helmholtz resonance was designed and optimized. The sensor was modeled by using the finite element method and optimized for its parameters, including the dimensions of excitation cavity, connecting tube and detection cavity. Also the temperature and pressure properties of the sensor were investigated. As a result, the detection sensitivity could be improved by optimizing the parameters and controlling the temperature and pressure. The optimizing result shows that the gas sensor has a best performance with the infrared light source IR-19, and parameters with excitation cavity of 38 mm9 mm, connecting tube of 5.9 mm10.2 mm and detection cavity of 30 mm5.8 mm. Tested by the experiment, the detection limit of 5.08 ppm is achieved for the CO gas detection. The study results also provide the reference for design of photoacoustic sensor in multi-gas detection.
- photoacoustic spectroscopy /
- Helmholtz resonance /
- finite element analysis /
- parameter optimization

[1]	Zhang Zhirong, Xia Hua, Dong Fengzhong, et al. Simultaneous and on-line detection of multiple gas concentration with tunable diode laser absorption spectroscopy [J]. Optics and Precision Engineering, 2013, 21(11): 2771-2777. (in Chinese)张志荣, 夏滑, 董凤忠, 等. 利用可调谐半导体激光吸收光谱法同时在线监测多组分气体浓度[J]. 光学精密工程, 2013, 21(11): 2771-2777.
[2]	Zheng Shouguo, Liu Miao, Zhang Jian, et al. Design and implementation of N2O detection system [J]. Optics and Precision Engineering, 2012, 20(10): 2154-2160. (in Chinese)郑守国, 李淼, 张健, 等. 痕量N2O气体检测系统的设计与实现[J]. 光学精密工程, 2012, 20(10): 2154-2160.
[3]	Zhao Yongjing, Pan Yuee, Rutherford Jerry, et al. Estimation of the interference in multi-gas measurements using infrared photoacoustic analyzers [J]. Atmos, 2012, 3(2): 246-265.
[4]	Stenberg J, Amand L E, Hernberg R, et al. Measurement of gas concentrations in a fluidized bed combustor using laser-induced photoacoustic spectroscopy [J]. Combus Flame, 1998, 113(4): 477-486.
[5]	Choi S S. Wavelength-modulated differential photoacoustic spectroscopy for early detection of breast cancer and Hypoxia monitoring [J]. University of Toronto, 2015: 36(5): 1305-1311.
[6]	Miao Shaofeng, Yang Hong, Huang Yuanhui, et al. Research progresses of photoacoustic imaging [J]. Chinese Optics, 2015, 8(5): 700-713. (in Chinese)苗少峰, 杨虹, 黄远辉, 等. 光声成像研究进展[J]. 中国光学, 2015, 8(5): 700-713.
[7]	Favier J P, Buijs J, Mikls A, et al. Photoacoustic characterization of different food samples[J]. European Food Resesrch and Technology, 1994, 199(1): 59-63.
[8]	Adamowicz R, Koo K. Characteristics of a photoacoustic air pollution detector at CO2 laser frequencies[J]. Appl Opt, 1979, 18(17): 2938-2946.
[9]	Zheng Huadan, Dong Lei, Ma Ying, et al. Scattered light modulation cancellation method for sub-ppb-level NO2 detection in a LD-excited QEPAS system [J]. Opt Express, 2016, 24(10): 752-761.
[10]	Barbieri S, Pellaux J P, Studemann E, et al. Gas detection with quantum cascade lasers: an adapted photoacoustic sensor based on Helmholtz resonance [J]. Rev Sci Instr, 2002, 73(6): 2458-2461.
[11]	Mattiello Mario, Nikls Marc, Schilt Stphane, et al. Novel Helmholtz-based photoacoustic sensor for trace gas detection at ppm level using GaInAsSb/GaAlAsSb DFB lasers [J]. Spectrochim Acta Pt A, 2006, 63(5): 952-958.
[12]	Liu Qiang, Wang Guishi, Liu Kun, et al. Measurements of atmospheric aerosol optical absorption coefficients using photoacoustic spectrometer [J]. Infrared and Laser Engineering, 2014, 43(9): 3010-3014. (in Chinese)刘强, 王贵师, 刘锟, 等. 基于光声光谱技术的大气气溶胶吸收系数测量[J]. 红外与激光工程, 2014, 43(9): 3010-3014.
[13]	Kosterev A A, Bakhirkin Yu A, Tittel F K, et al. Quartz-enhanced photoacoustic spectroscopy[J]. Opt Lett, 2002, 27(12): 1902-1904.
[14]	Wu Xiaoye, Zhang Lichao, Shi Guang. Optical-thermal and optical-acoustic detecting techniques applied for characterization of high performance optical thin films [J]. Chinese Optics, 2014, 7(5): 701-711. (in Chinese)武潇野，张立超，时光. 应用于高性能光学薄膜表征的光热光声检测技术[J]. 中国光学, 2014, 7(5): 701-711.
[15]	Koskinen V, Fonsen J, Kauppinen J, et al. Exremely sensitive trace gas analysis with modern photoacoustic spectroscopy [J]. Vib Spectrosc, 2006, 42(2): 239-242.
[16]	Ulasevich A L, Gorelik A V, Kouzmouk A A, et al. A miniaturized prototype of resonant banana-shaped photoacoustic cell for gas sensing [J]. Infrared Physics and Technology, 2013, 60(5): 174-182.
[17]	Chen Weigen, Wan Fu, Zhou Qu, et al. Pressure characteristics of dissolved Acetylene in transformer oil based on photoacoustic spectroscopy detection [J]. Transactions of China Electrotechnical Society, 2015, 30(1): 112-119. (in Chinese)陈伟根, 万福, 周渠, 等. 基于光声光谱检测的变压器油中溶解乙炔气体的压强特性[J]. 电工技术学报, 2015, 30(1): 112-119.
[18]	Yun Yuxin, Lv Tianguang, Han Hong, et al. Effects of pressure and temperature on gaseous infrared absorption properties [J]. Infrared and Laser Engineering, 2011, 40(6): 992-996. (in Chinese)云玉新, 吕天光, 韩洪, 等. 气体红外吸收特性受压强与温度的影响分析[J]. 红外与激光工程, 2011, 40(6): 992-996.

[1]	王晓迪, 曹玉岩, 王富国, 初宏亮, 李延伟. 大口径透镜混合柔性支撑结构优化设计 . 红外与激光工程, 2022, 51(6): 20210670-1-20210670-11. doi: 10.3788/IRLA20210670
[2]	张鹏辉, 赵扬, 李鹏, 周志权, 白雪, 马健. 基于有限元法的激光声磁检测系统优化研究 . 红外与激光工程, 2022, 51(7): 20210533-1-20210533-9. doi: 10.3788/IRLA20210533
[3]	李小明, 王隆铭, 朱国帅. 激光通信一体化SiC/Al摆镜支撑参数优化 . 红外与激光工程, 2021, 50(11): 20210143-1-20210143-8. doi: 10.3788/IRLA20210143
[4]	王朋朋, 辛宏伟, 朱俊青, 王永宪, 沙巍, 陈长征. 长条反射镜及柔节的参数优化设计 . 红外与激光工程, 2021, 50(8): 20200493-1-20200493-6. doi: 10.3788/IRLA20200493
[5]	张超杰, 习兴华, 王永宪, 朱俊青, 关英俊. 空间遥感相机大口径反射镜结构优化设计 . 红外与激光工程, 2020, 49(2): 0214002-0214002. doi: 10.3788/IRLA202049.0214002
[6]	徐广州, 阮萍. 高精度光学抛物面面形参数计算新方法 . 红外与激光工程, 2019, 48(6): 617001-0617001(7). doi: 10.3788/IRLA201948.0617001
[7]	王小勇, 张博文, 郭崇岭, 刘湃. 3 m口径空间反射镜的参数优化 . 红外与激光工程, 2019, 48(S1): 205-210. doi: 10.3788/IRLA201948.S118002
[8]	邢艳秋. 空间微型光学载荷主结构优化设计与试验 . 红外与激光工程, 2018, 47(11): 1113002-1113002(7). doi: 10.3788/IRLA201847.1113002
[9]	穆永吉, 万渊, 刘继桥, 侯霞, 陈卫标. 星载激光雷达望远镜主镜光机分析与优化 . 红外与激光工程, 2018, 47(7): 718002-0718002(7). doi: 10.3788/IRLA201847.0718002
[10]	袁海璐, 查冰婷, 张合. 几何截断定距激光引信系统参数优化 . 红外与激光工程, 2018, 47(8): 806001-0806001(6). doi: 10.3788/IRLA201847.0806001
[11]	张永强, 刘朝晖, 李治国, 谢友金. 空间二维转台照准架的结构优化设计 . 红外与激光工程, 2017, 46(S1): 104-109. doi: 10.3788/IRLA201746.S113003
[12]	王凤蕊, 李青芝, 郭德成, 黄进, 耿锋. KDP晶体激光预处理参数的优化 . 红外与激光工程, 2017, 46(3): 321005-0321005(6). doi: 10.3788/IRLA201746.0321005
[13]	樊鹏格, 吴易明, 贾森, 王先华. 冷原子干涉仪中二维磁光阱线圈的优化设计 . 红外与激光工程, 2016, 45(6): 618003-0618003(6). doi: 10.3788/IRLA201645.0618003
[14]	张耀平, 樊峻棋, 龙国云. 变形镜在激光辐照下热畸变有限元模拟 . 红外与激光工程, 2016, 45(11): 1136002-1136002(5). doi: 10.3788/IRLA201645.1136002
[15]	Sekou Singare, 陈盛贵, 钟欢欢. 激光透射焊接聚碳酸酯的有限元分析 . 红外与激光工程, 2016, 45(2): 206005-0206005(6). doi: 10.3788/IRLA201645.0206005
[16]	付世欣, 周超, 曹玉岩, 范磊, 韩西达. 基于拓扑优化的4 m 望远镜底座结构设计 . 红外与激光工程, 2015, 44(8): 2441-2447.
[17]	齐光, 许艳军, 刘炳强. 空间相机反射镜SiC/Al 支撑板轻量化结构优化设计 . 红外与激光工程, 2014, 43(7): 2214-2218.
[18]	刘强, 王贵师, 刘锟, 陈卫东, 朱文越, 黄印博, 高晓明. 基于光声光谱技术的大气气溶胶吸收系数测量 . 红外与激光工程, 2014, 43(9): 3010-3014.
[19]	崔文达, 杜少军. 角谱传输数值模拟中参数优化分析 . 红外与激光工程, 2014, 43(9): 2935-2940.
[20]	颜胜美, 苏伟, 王亚军, 陈樟. 0.85 THz 折叠波导行波管的高频特性与结构参数优化分析 . 红外与激光工程, 2014, 43(9): 2901-2906.

点击查看大图

计量

文章访问数: 465
HTML全文浏览量: 75
PDF下载量: 97
被引次数: 0

姓名
邮箱
手机号码
标题
留言内容
验证码

留言板

亥姆霍兹光声光谱多气体检测器设计和优化

doi: 10.3788/IRLA201746.0620005

Design and optimization of Helmholtz-based photoacoustic spectroscopic sensor for multi-gas detection

计量

亥姆霍兹光声光谱多气体检测器设计和优化

doi: 10.3788/IRLA201746.0620005

1. 中国科学院安徽光学精密机械研究所通用光学定标与表征技术重点实验室,安徽合肥 230031;

2. 中国科学技术大学,安徽合肥 230031

English Abstract

Design and optimization of Helmholtz-based photoacoustic spectroscopic sensor for multi-gas detection

1. Key Laboratory of Optical Calibration and Characterization,Anhui Institute of Optics and Fine Mechanics,Chinese Academy of Sciences,Hefei 230031,China;

2. University of Science and Technology of China,Hefei 230031,China

全文HTML

目录

留言板

亥姆霍兹光声光谱多气体检测器设计和优化

doi: 10.3788/IRLA201746.0620005

Design and optimization of Helmholtz-based photoacoustic spectroscopic sensor for multi-gas detection

计量

出版历程

亥姆霍兹光声光谱多气体检测器设计和优化

doi: 10.3788/IRLA201746.0620005

1. 中国科学院安徽光学精密机械研究所 通用光学定标与表征技术重点实验室,安徽 合肥 230031; 2. 中国科学技术大学,安徽 合肥 230031

English Abstract

Design and optimization of Helmholtz-based photoacoustic spectroscopic sensor for multi-gas detection

1. Key Laboratory of Optical Calibration and Characterization,Anhui Institute of Optics and Fine Mechanics,Chinese Academy of Sciences,Hefei 230031,China; 2. University of Science and Technology of China,Hefei 230031,China

全文HTML

目录

1. 中国科学院安徽光学精密机械研究所通用光学定标与表征技术重点实验室,安徽合肥 230031;

2. 中国科学技术大学,安徽合肥 230031

1. Key Laboratory of Optical Calibration and Characterization,Anhui Institute of Optics and Fine Mechanics,Chinese Academy of Sciences,Hefei 230031,China;

2. University of Science and Technology of China,Hefei 230031,China