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近红外光谱智能分析煤直接液化柴油组分OA

Intelligent analysis of direct coal liquefaction diesel components by near-infrared spectroscopy

中文摘要英文摘要

煤直接液化产品中柴油占比超过60%,与石油基柴油相比,煤直接液化柴油十六烷值为30-40,无法满足≥45车用柴油标准.快速准确地分析煤直接液化柴油化学组成,通过组分调和来实现燃料性质满足柴油标准意义重大.气相色谱等传统分析方法虽精确但也存在分析速度慢、维护复杂且成本高等缺点,难以满足快速实时控制的需求.近红外光谱技术具有快速、无损检测优势,但光谱数据解析的复杂性限制了其应用;机器学习方法能够有效挖掘光谱信息,建立高精度预测模型.本研究结合近红外光谱与机器学习技术,构建煤直接液化柴油的光谱-组成数据库,并采用相关系数法和互信息法进行特征提取,筛选关键波长变量,降低数据维度.在此基础上,对比Lasso、SVR和XGBoost三种机器学习模型的预测性能.结果表明,剔除吸光度大于1的数据可显著提升模型精度,测试集R2从0.85提高至0.96.特征提取后,最优波长变量减少至177列,大幅提高计算效率.其中,基于互信息特征选择的SVR-MI-0.9模型表现最佳,训练集和测试集R2均超过0.98,能精准预测链烷烃、环烷烃和芳烃含量,从而为智能化在线质量监控提供了可靠方法.基于所构建的智能分析模型,自主开发了近红外光谱数据智能分析软件,与全二维气相色谱分析柴油组分结果对比,解析时间节约98%以上的软件分析,预测的绝对误差不超过0.2%,完全实现了煤直接液化柴油组分的快速解析.

Diesel accounts for over 60%of the products derived from direct coal liquefaction(DCL).Compared to petroleum-based diesel,DCL diesel exhibits a cetane number ranging from 30 to 40,which fails to meet the automotive diesel standard requirement of ≥45.Therefore,rapid and accurate analysis of its chemical composition is crucial for property optimization to meet fuel specifications by component blending.Thought traditional methods like gas chromatography offer high accuracy,they are unsuitable for rapid online analysis under industrial conditions.Near-infrared(NIR)spectroscopy can provide advantages in rapid,non-destructive analysis.Its application however,is limited by the complexity of spectral data interpretation.Machine learning(ML)is effective method for extracting valuable information from spectra and establishing high-precision prediction models.This study integrates NIR spectroscopy with ML to construct a spectral-composition database for DCL diesel.Feature extraction was performed using the correlation coefficient and mutual information methods to screen key wavelength variables and reduce data dimensionality.Subsequently,the predictive performance of three ML models-Lasso,SVR and XGBoost-was compared.Results indicate that excluding spectral data with absorbance greater than 1 significantly enhances model accuracy,increasing the test set R2 from 0.85 to 0.96.After feature extraction,the optimal number of wavelength variables was reduced to 177,substantially improving computational efficiency.Among the models evaluated,the SVR-MI-0.9 model,based on mutual information feature selection,demonstrated the best performance,achieving training and test set R2 values both exceeding 0.98.This model enables precise prediction of paraffin,naphthene,and aromatic hydrocarbon contents.This research provides a robust methodology for intelligent online quality monitoring.An intelligent NIR spectroscopy data analysis software was independently developed based on the established model.Compared with comprehensive two-dimensional gas chromatography,the software reduced the analysis time by over 98%,with an absolute prediction error below 0.2%.Thus,rapid analysis of DCL diesel components was successfully realized.

王喜武;李皓玮;齐振东;王兴宝;冯杰;祝一蒙;李文英

太原理工大学省部共建煤基能源清洁高效利用国家重点实验室,山西太原 030024||中国神华煤制油化工有限公司鄂尔多斯煤制油分公司,内蒙古鄂尔多斯 017209太原理工大学省部共建煤基能源清洁高效利用国家重点实验室,山西太原 030024太原理工大学省部共建煤基能源清洁高效利用国家重点实验室,山西太原 030024||中国神华煤制油化工有限公司鄂尔多斯煤制油分公司,内蒙古鄂尔多斯 017209太原理工大学省部共建煤基能源清洁高效利用国家重点实验室,山西太原 030024太原理工大学省部共建煤基能源清洁高效利用国家重点实验室,山西太原 030024北京东土科技股份有限公司,北京 100144太原理工大学省部共建煤基能源清洁高效利用国家重点实验室,山西太原 030024

化学化工

煤直接液化油光谱实时检测机器学习特征提取组分预测

direct coal liquefaction dieselreal-time spectral detectionmachine learningfeature extractioncomponent prediction

《燃料化学学报(中英文)》 2026 (4)

17-28,12

Supported by National Natural Science Foundation of China(U24B6018,22178243).

10.1016/S1872-5813(25)60620-7

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