激光诱导击穿光谱结合机器学习的煤质多指标同步快速检测

熊凯; 邹祥波; 陈创庭; 杨先茂; 陈公达; 张爽; 卢伟业; 陈小玄; 卢志民; 姚顺春

doi:10.19666/j.rlfd.202408177

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激光诱导击穿光谱结合机器学习的煤质多指标同步快速检测

热能科学研究 | 更新时间：2025-12-26

- 激光诱导击穿光谱结合机器学习的煤质多指标同步快速检测
- Simultaneous rapid determination of multiple coal quality indicators using laser-induced breakdown spectroscopy combined with machine learning
- 热力发电 2025年54卷第4期页码：129-139
- 作者机构：
  
  1. 广东省能源集团有限公司
  2. 广东能源集团科学技术研究院有限公司
  3. 华南理工大学电力学院
  4. 广东省特种设备检测研究院顺德检测院
- 作者简介：
- 基金信息：
  
  国家重点研发计划项目（2021YFF0601001）;广东省新型电力系统技术创新项目（1688950422168）;广东省自然科学基金杰出青年项目（2021B1515020071）;广东省自然科学基金项目（2022A1515010741）;中央高校自然科学类项目（2023ZYGXZR090）~~
- DOI：10.19666/j.rlfd.202408177
  中图分类号： O657.38;TP181;TM621
- 纸质出版：2025
- 稿件说明：
移动端阅览
熊凯, 邹祥波, 陈创庭, 等. 激光诱导击穿光谱结合机器学习的煤质多指标同步快速检测[J]. 热力发电, 2025,54(4):129-139.

XIONG Kai, ZOU Xiangbo, CHEN Chuangting, et al. Simultaneous rapid determination of multiple coal quality indicators using laser-induced breakdown spectroscopy combined with machine learning[J]. Thermal Power Generation, 2025, 54(4): 129-139.
熊凯, 邹祥波, 陈创庭, 等. 激光诱导击穿光谱结合机器学习的煤质多指标同步快速检测[J]. 热力发电, 2025,54(4):129-139. DOI： 10.19666/j.rlfd.202408177.

XIONG Kai, ZOU Xiangbo, CHEN Chuangting, et al. Simultaneous rapid determination of multiple coal quality indicators using laser-induced breakdown spectroscopy combined with machine learning[J]. Thermal Power Generation, 2025, 54(4): 129-139. DOI： 10.19666/j.rlfd.202408177.

摘要

煤质快速全面检测对锅炉燃烧优化和燃煤电厂数智化转型具有重要意义，激光诱导击穿光谱（laser-induced breakdown spectroscopy

LIBS）在煤质快速检测中具有巨大应用潜力。为满足煤炭现场快速检测的应用目标，利用煤粉颗粒流式LIBS检测实验装置采集了不同电厂的46组煤样光谱数据，系统开展了LIBS与机器学习相结合的煤质多指标同步快速检测研究。针对颗粒流状态下光谱波动较大的特点，对单脉冲光谱采集个数进行了优化，并建立无效光谱筛选、光谱平均、光谱归一化数据预处理方法，进一步对比了PLSR、SVR、PSO-SVR和LSTM 4种机器学习算法以及全光谱、特征波段、强度积分和PCA提取4种光谱特征输入对模型预测煤质多指标性能的影响。结果表明：单次检测累计采集200个单脉冲光谱进行光谱平均，光谱信号不确定性可控制在5%以内；煤质多指标定量分析中PSO-SVR算法的预测性能最佳，利用PCA算法对光谱数据进行降维，在减少模型计算量的同时提高了模型预测性能，两者结合所建立的模型对煤发热量预测均方根误差为0.289 MJ/kg，平均绝对误差为0.231 MJ/kg；对煤碳质量分数、灰分和挥发分预测结果同样较理想，均方根误差分别为0.987%、1.310%和1.612%，平均绝对误差分别为0.839%、1.014%

1.033%。研究结果表明结合合适的机器学习算法，LIBS技术可以实现煤质多指标同步精准快速检测，在煤炭高效清洁利用场景中具有广阔的应用前景。

Abstract

The rapid and comprehensive determination of coal quality is of great significance for the optimization of boiler combustion and the digital transformation of coal-fired power plants. Laser-induced breakdown spectroscopy(LIBS) has the potential to be applied effectively in the rapid determination of coal quality. In order to meet the application goal of rapid coal inspection

46 sets of spectral data of coal samples from different power plants were collected by the experimental device of coal particle flow LIBS

and the research of simultaneous rapid inspection of multiple indicators of coal quality by combining LIBS with machine learning was carried out systematically. In view of the considerable spectral fluctuations observed in the particle flow state

the number of single-pulse acquisitions was optimized. In addition

invalid spectral screening

spectral averaging and spectral normalization data preprocessing methods were established. Furthermore

four machine learning algorithms(PLSR

SVR

PSO-SVR

and LSTM) and four spectral feature inputs(full spectra

eigenbands

intensity integration

and PCA extraction) were compared in terms of their performance in predicting multiple indicators of coal quality. The results demonstrate that the uncertainty of the spectral signals can be maintained at a maximum of 5% when 200 single-pulse spectra are collected for spectral averaging in a single test. The PSO-SVR algorithm exhibits the most optimal prediction performance in the quantitative analysis of coal quality indicators

and the PCA algorithm reduces the dimensionality of the spectral data

which reduces the amount of model computation and at the same time improves the prediction performance of the model

and the model established by combining both of them has the best performance

the root mean square error(RMSEP) of the coal heat content is 0.289 MJ/kg

and the mean absolute error(MAE) is 0.231 MJ/kg. The coal carbon mass fraction

ash content and volatile matter content are also predicted satisfactorily

with the RMSEP of 0.987%

1.310% and 1.612%

and the MAE of 0.839%

1.014%

and 1.033%

respectively. The results show that

combined with appropriate machine learning algorithms

the LIBS technique can achieve simultaneous accurate and rapid determination of multiple indicators of coal quality

which has a broad application prospect in the scenario of efficient and clean coal utilization.

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