基于SO2吸收谱线的光谱仪波长在线校准方法

doi:10.16085/j.issn.1000-6613.2023-1439

化工进展 ›› 2024, Vol. 43 ›› Issue (2): 818-822.DOI: 10.16085/j.issn.1000-6613.2023-1439

基于SO₂吸收谱线的光谱仪波长在线校准方法

苗丰¹^,²(), 许传龙¹(), 李健¹, 张彪¹, 韩少鹏², 汤光华²

^1.东南大学能源与环境学院，江苏南京 210096
^2.南京国电环保科技有限公司，江苏南京 210061

收稿日期:2023-08-17 修回日期:2023-12-17 出版日期:2024-02-25 发布日期:2024-03-07
通讯作者: 许传龙
作者简介:苗丰（1986—），男，博士研究生，研究方向为烟气监测技术。E-mail：13852287920@163.com。
基金资助:
国家自然科学基金(52376158)

Online calibration of the wavelength of spectrometer based on SO₂ absorption spectrum

MIAO Feng¹^,²(), XU Chuanlong¹(), LI Jian¹, ZHANG Biao¹, HAN Shaopeng², TANG Guanghua²

^1.School of Energy and Environment, Southeast University, Nanjing 210096, Jiangsu, China
^2.Nanjing Guodian Environmental Protection Technology Co. , Ltd. , Nanjing 210096, Jiangsu, China

Received:2023-08-17 Revised:2023-12-17 Online:2024-02-25 Published:2024-03-07
Contact: XU Chuanlong

摘要/Abstract

摘要：

紫外差分吸收光谱技术已被广泛用于工业污染源废气排放浓度监测。光谱仪作为紫外烟气分析仪的核心器件，易受到温度变化而产生波长漂移，进而影响监测结果的准确性。本文提出了一种光谱仪波长“软”标定方法，通过实验建立标准SO₂吸收谱线极值波长数据库，利用SO₂吸光度极值像素点和标准SO₂吸收光谱极值波长，对光谱仪像素点与波长的对应函数进行重新拟合，以实现光谱仪波长实时校准。搭建了实验系统，并开展了光谱仪波长标定方法验证研究。结果表明，当光谱仪所处环境温度变化范围为10℃时，采用本文方法可以使993mg/m³NO标气的测量误差从115.2mg/m³降低至21.4mg/m³，绝对误差减小了93.8mg/m³；当被测SO₂为1430mg/m³时，测量系统信噪比较高，波长校准效果最佳；针对低浓度测量现场，可通过增加光谱平均次数来增强光谱信号的信噪比，提高波长在线校准方法的效果。

关键词: 紫外差分吸收光谱, 光谱仪, 波长校准, 吸收光谱

Abstract:

Ultraviolet differential absorption spectroscopy technology has been widely used in the monitoring of industrial flue gas emissions. The spectrometer, a core component of the UV flue gas analyzer, is susceptible to wavelength drift caused by temperature changes, which in turn affects the accuracy of pollutants monitoring results. In this paper, a soft wavelength calibration method for spectrometers is proposed. A standard SO₂ absorption spectrum peak wavelength database is established through experiments. When the wavelength drift exceeds 0.02nm, the corresponding function between the spectrometer pixel and wavelength will be re-fitted using the pixel of the SO₂ absorption peak in conjunction with the database. This method enables real-time calibration of the spectrometer wavelength. Experiments are conducted to validate the proposed calibration method. Results showed that with a 10℃ environmental temperature range, this method can reduce the measurement error of 993mg/m³ NO standard gas from 115.2mg/m³ to 21.4mg/m³, with an absolute error reduction of 93.8mg/m³. The best wavelength calibration effect is achieved when the measured SO₂ concentration is 1430mg/m³. For low-concentration measurement sites, the signal-to-noise ratio of the spectral signal can be amplified by increasing the number of spectral averages, thereby improving the effectiveness of the online wavelength calibration method.

Key words: ultraviolet differential absorption spectroscopy, spectrometer, wavelength calibration, absorption spectrum

中图分类号:

TQ533.6

苗丰, 许传龙, 李健, 张彪, 韩少鹏, 汤光华. 基于SO₂吸收谱线的光谱仪波长在线校准方法[J]. 化工进展, 2024, 43(2): 818-822.

MIAO Feng, XU Chuanlong, LI Jian, ZHANG Biao, HAN Shaopeng, TANG Guanghua. Online calibration of the wavelength of spectrometer based on SO₂ absorption spectrum[J]. Chemical Industry and Engineering Progress, 2024, 43(2): 818-822.

图/表 7

参考文献 13

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校准基本点集波长/nm	校准前波长/nm	校准前 Δλ₁/nm	校准后波长/nm	校准后 Δλ₂/nm
199.663	199.7865	0.123490	199.6659	0.002877
204.191	204.3060	0.114987	204.2109	0.019889
209.287	209.3922	0.105199	209.3218	0.034808
211.030	210.9871	-0.04288	210.9236	-0.01635
216.102	216.1948	0.092826	216.1513	0.049341
281.118	281.1139	-0.00408	281.1225	0.004482
284.288	284.2808	-0.00719	284.2898	0.001751
286.214	286.2048	-0.00920	286.2142	0.000206
288.138	288.1260	-0.01200	288.1361	-0.00192
294.437	294.4189	-0.01814	294.4329	-0.00411
297.303	297.2817	-0.02133	297.2985	-0.00445
301.385	301.3605	-0.02448	301.3828	-0.00223
308.836	308.8051	-0.03087	308.8419	0.005948

校准基本点集波长/nm	校准前波长/nm	校准前 Δλ₁/nm	校准后波长/nm	校准后 Δλ₂/nm
199.663	199.7865	0.123490	199.6659	0.002877
204.191	204.3060	0.114987	204.2109	0.019889
209.287	209.3922	0.105199	209.3218	0.034808
211.030	210.9871	-0.04288	210.9236	-0.01635
216.102	216.1948	0.092826	216.1513	0.049341
281.118	281.1139	-0.00408	281.1225	0.004482
284.288	284.2808	-0.00719	284.2898	0.001751
286.214	286.2048	-0.00920	286.2142	0.000206
288.138	288.1260	-0.01200	288.1361	-0.00192
294.437	294.4189	-0.01814	294.4329	-0.00411
297.303	297.2817	-0.02133	297.2985	-0.00445
301.385	301.3605	-0.02448	301.3828	-0.00223
308.836	308.8051	-0.03087	308.8419	0.005948

SO₂浓度/mg·m^-3	校准后波长与汞灯特征谱线误差/nm
57.2	0.0475
143	0.0397
228.8	0.0301
286	0.0291
600.6	0.0208
829.4	0.0192
1086.8	0.0112
1430	0.0090
1658.8	0.0105
1830.4	0.0101

SO₂浓度/mg·m^-3	校准后波长与汞灯特征谱线误差/nm
57.2	0.0475
143	0.0397
228.8	0.0301
286	0.0291
600.6	0.0208
829.4	0.0192
1086.8	0.0112
1430	0.0090
1658.8	0.0105
1830.4	0.0101

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基于SO₂吸收谱线的光谱仪波长在线校准方法

Online calibration of the wavelength of spectrometer based on SO₂ absorption spectrum

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