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提高深部煤矿瓦斯浓度预测及通风效率:一种混合的深度神经网络-库普曼和模糊-比例积分微分框架

Enhancing gas concentration prediction and ventilation efficiency in deep coal mines: a hybrid DL-Koopman and Fuzzy-PID framework.

作者信息

Yuan Keyi, Gao Ke, Liu Yujiao

机构信息

College of Safety Science and Engineering, Liaoning Technical University, Huludao, 125105, Liaoning Province, China.

Key Laboratory of Mine Thermodynamic Disasters and Control, Ministry of Education, Liaoning Technical University, Huludao, 125105, Liaoning Province, China.

出版信息

Sci Rep. 2025 Jul 2;15(1):23630. doi: 10.1038/s41598-025-00105-3.

DOI:10.1038/s41598-025-00105-3
PMID:40603945
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12222700/
Abstract

With the increasing depth of coal mining operations, traditional ventilation systems are becoming insufficient to address the growing safety and operational challenges, particularly in dynamic underground environments. To enhance the sustainability and environmental performance of the coal mining industry, this study proposes an innovative framework that integrates deep learning with the DL-Koopman operator theory for accurate gas concentration prediction and a fuzzy adaptive PID (Fuzzy-PID) control strategy for optimized airflow regulation. The DL-Koopman-based model significantly improves prediction accuracy under fluctuating ventilation conditions, effectively addressing the challenges posed by variable wind speeds and other dynamic factors. By analyzing historical data on gas concentrations and wind speeds, the model identifies underlying patterns to develop a robust predictive framework. Furthermore, the Fuzzy-PID control strategy dynamically adjusts PID parameters in real-time, incorporating a dead zone mechanism to mitigate disturbances and enhance system stability. This dual approach not only ensures rapid adaptation to changing underground conditions but also significantly improves energy efficiency and safety. The proposed method demonstrates a practical pathway toward intelligent ventilation systems, contributing to cleaner and more sustainable mining practices. This research aligns with the global energy transition goals by reducing the environmental footprint of coal mining operations while maintaining high safety standards.

摘要

随着煤矿开采作业深度的增加,传统通风系统已不足以应对日益增长的安全和作业挑战,尤其是在动态的地下环境中。为提高煤炭行业的可持续性和环境绩效,本研究提出了一个创新框架,该框架将深度学习与DL-Koopman算子理论相结合,用于精确的瓦斯浓度预测,并采用模糊自适应PID(Fuzzy-PID)控制策略进行优化的气流调节。基于DL-Koopman的模型在波动通风条件下显著提高了预测精度,有效应对了风速变化和其他动态因素带来的挑战。通过分析瓦斯浓度和风速的历史数据,该模型识别潜在模式以建立一个强大的预测框架。此外,Fuzzy-PID控制策略实时动态调整PID参数,并入死区机制以减轻干扰并增强系统稳定性。这种双重方法不仅确保能快速适应不断变化的地下条件而且显著提高了能源效率和安全性。所提出的方法展示了通往智能通风系统的实用途径,有助于实现更清洁、更可持续的采矿作业。本研究通过减少煤矿开采作业的环境足迹同时保持高安全标准,符合全球能源转型目标。

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