| 光谱学与光谱分析 |
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| Research on Formaldehyde Concentration Detection System Based on Photo-Elastic Modulation |
| LI Yang-jun1, JIAO Ning2, WANG Rui-jun2, LEI Shu-feng2, WANG Gao1 |
1. National Key Laboratory for Electronic Measurement Technology, North University of China, Taiyuan 030051, China
2. Shanxi North Jindong Chemical Co. Ltd., Yangquan 045000, China |
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Abstract There is a growing number of environmental pollution caused by excessive indoor formaldehyde, and in order to quickly and accurately quantify the concentration of formaldehyde gas in indoor air, a system for detecting the concentration of formaldehyde gas based on photo-elastic modulation was designed. It consists of the infrared light source, filters, elastic light modulator, and infrared detectors, and photo-elastic crystal refractive index of cyclical changes was controlled by elastic light modulator. Refractive index caused by the changes in the optical path provided a spectrum distribution function of the optical path difference. Optical path difference function of the system was derived through the HITRAN spectral database. Experiments were carried out using infrared light source combined with narrow band filters, and the transmittance of the center wavelength was more than 90%. Photo-elastic crystal is ZnSe crystal as photo-elastic light modulator, and the drive frequency of the system is 100 kHz. For three different environments at different locations, 10 groups of sample gas were collected for analysis, and the concentration of formaldehyde gas was detected using standard spectrometer and the system for comparing the test data. Experimental results show that when the concentration of formaldehyde gas is high, the system performance is good; When the concentration of formaldehyde gas is low, the signal-to-noise ratio of the system is decreased, and the detection accuracy is slightly reduced, but it still meets the design requirements.
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Received: 2013-02-24
Accepted: 2013-05-18
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Corresponding Authors:
LI Yang-jun
E-mail: liyangjunnuc@163.com
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[1] Katie M Krause, Jerome Genest. Applied Optics, 2006, 45(19): 4684.
[2] LI Xiao-lu, JIANG Yue-song(李小路, 江月松). Science in China·Series E: Information Sciences)(中国科学E辑·技术科学),2006, 11: 105.
[3] ZHANG Ya-ni(张亚妮). Acta Physica Sinica(物理学报),2010, 12(48): 1456.
[4] Zhang Yuan, Shen Yifeng, Zhou Jie. Chinese Optics Letters,2011, 2(22): 81.
[5] Fu Dejian, Kaley A Walker. Journal of Quantitative Spectroscopy & Radiative Transfer. 2007, 10(3): 36.
[6] Homayon Ahmad Panahi, Amir Abdollah Mehrdad Sharif, Mehrnaz Bigonah. Korean Journal of Chemical Engineering,2009, 26(6): 1723.
[7] WANG Shao-lin, XIE Jun, CAO Kai-fa(汪少林, 谢 军, 曹开法). Chinese Journal of Lasers(中国激光),2008, 5(22): 98.
[8] Tiziani H J, Uhde H M. Appl. Opt., 1994, 33(4): 567.
[9] Schwarze C R, Vaillancourt R M, Carlson D. J. Engel. Proc. of SPIE,2005,5787:176.
[10] PENG Fu-min, XIE Pin-hua,ZHANG Ying-hua(彭夫敏, 谢品华, 张英华). Journal of Atmospheric and Environmental Optics(大气与环境光学学报),2008,1(1): 51.
[11] PENG Zhi-hong, ZHANG Chun-min, ZHAO Bao-chang(彭志红,张淳民, 赵葆常). Acta Physica Sinica(物理学报),2006, 55(22): 6374.
[12] LI Yang-jun, WANG Gao(李仰军, 王 高). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2011, 31(12): 3332.
[13] Angelmahr M, Miklós A,Hess P. Applied Physics B: Lasers and Optics, 2006, 85(2-3): 285.
[14] Michael Staak, Edward W Gash, Dean S Venables. Journal of Molecular Spectroscopy,2005, 229(1): 115. |
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