煤粒度对煤质近红外定量分析模型的影响

doi:10.3964/j.issn.1000-0593(2013)01-0065-04

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摘要：为了减少因煤样粒度而产生的光谱采集误差，研究0.2，1，3和13 mm粒度等级下的煤质近红外分析模型。采用PCA方法提取特征信息，建立基于GA-BP和GA-Elman神经网络算法的定量分析模型。实验结果表明，经数据归一化与多元散射校正预处理后，0.2 mm粒度等级的光谱与煤炭标准之间的相关性最强，模型的学习精度最高;经平滑处理后1 mm粒度等级的分析结果最佳。平滑法对特征谱峰不明显的光谱的预处理效果较差，多元散射校正方法的适用性最强。在0.2 mm粒度等级下原光谱的信息准确度最高，1和3 mm其次，13 mm最差。煤样粒度越大，光谱的不稳定因素越多，从而导致分析模型的负面影响增加。

关键词：近红外光谱分析技术;煤粒度;光谱预处理;定量分析模型

Abstract：In order to reduce the errors of near-infrared spectral acquisition, analytical models of coal spectra with different particle sizes, 0.2, 1, 3 and 13 mm, were studied in this paper. The feature information of spectra was extracted by PCA method, then two quantitative analytical models were established based on GA-BP and GA-Elman neural network algorithms. Through spectral preprocessing with data normalization and multiplicative scatter correction methods, the results showed that with the 0.2 mm size, the correlations between spectra and the standard value were the strongest, and the analytical precision of models were the best. But for smoothed spectra, the models, under 1 mm size, were better than others. Smoothing method was not suitable for the spectra with less obvious wave crest characteristics, while multiplicative scatter correction method was better. According to original spectra, particle size of 0.2 mm had the highest accuracy, followed by 1 and 3 mm and the worst was under 13 mm. Overall, the larger the size for coal particle, the more the unstable factors for spectra, increasing negative influences on analytical models.

Key words：NIRS;Coal particle size;Spectral preprocessing;Quantitative analytical model

收稿日期: 2012-05-23 修订日期: 2012-09-15

中图分类号:

O657.3

通讯作者: 李明 E-mail: liming@cumt.edu.cn

引用本文:

雷萌¹，李明^1*，吴楠²，李颖娜³，程玉虎¹ . 煤粒度对煤质近红外定量分析模型的影响 [J]. 光谱学与光谱分析, 2013, 33(01): 65-68.
LEI Meng¹, LI Ming^1*, WU Nan², LI Ying-na³, CHENG Yu-hu¹ . Influence of Different Coal Particle Sizes on Near-Infrared Spectral Quantitative Analytical Models. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2013, 33(01): 65-68.

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[1] Kim Dongwon, Lee Jongmin, Kim Jaesung. J. Chem. Eng., 2009, 26(2): 489.
[2] Li Ming, Xu Zhibin, Yu Lei, et al. Proceedings of 2009 Chinese Control and Decision Conference, 2009: 194.
[3] Vohland Michael, Michel Kerstin, Ludwig Bernard. Journal of Plant of Plant Nutrition and Soil Science, 2011, 174(5): 695.
[4] CHENG Fang, FAN Yu-xia, LIAO Yi-tao(成芳, 樊玉霞, 廖宜涛). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2012, 32(2): 354.
[5] YANG Hui-hua, GUO Tuo, MA Jin-fang, et al(杨辉华 ,郭拓, 马晋芳，等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2012, 32(5): 1247.
[6] Andres J M, Bona M T. Analytica Chimica Acta, 2005, 535: 123.
[7] Fan Wei, Li Hongdong, Shan Yang, et al. Analytical Methods, 2011, 3: 1872.
[8] Kodzue Kinoshita, Hiroyuki Morita, Mari Miyazaki, et al. Analytical Methods, 2010, 2: 1671.
[9] HE Xuan-ming(何选明). Coal Chemistry(Second Edition)(煤化学, 第2版). Beijing: Metallurgical Industry Press(北京: 冶金工业出版社), 2010, 5.
[10] National Standard of the People’s Republic of China(中华人民共和国国家标准). GB 474—2008, Method for Preparation of Coal Sample(煤样的制备方法)，2008.
[11] National Standard of the People’s Republic of China(中华人民共和国国家标准). GB/T 212—2008, Proximate Analysis of Coal(煤的工业分析方法)，2008.
[12] Mattle Christian, Heigl Nico, Abel Gudrun, et al. JPC-Journal of Planar Chromatography-Modern TLC, 2010, 23(5): 348.
[13] XIE Jun, PAN Tao, CHEN Jie-mei(谢军, 潘涛, 陈洁梅). Chinese Journal of Analytical Chemistry(分析化学), 2010, 38(3): 342.
[14] Niu Xiaoying, Zhao Zhilei, Jia Kejun. Food Chemistry, 2012, 133(2): 592.
[15] Cui Anqi, Xu Hua, Jia Peifa. Expert Systems with Applications, 2011, 38(7): 8186.
[16] Ding Shifei, Su Chunyang, Yu Junzhao. Artificial Intelligence Review, 2011, 36(2): 153.