Method Article

Research on a Deeply Integrated Model for Structural Optimization in Coal Spontaneous Combustion Temperature Prediction

DOI:

10.3791/69457

⸱

December 19th, 2025

In This Article

Summary

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Here, we describe a protocol for predicting the temperature of coal spontaneous combustion using an SSA-optimized CNN-LSTM-Attention framework that automatically optimizes the network structure and parameters, thereby improving accuracy, adaptability, and generalization across heterogeneous datasets and varied mining conditions.

Abstract

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Here, we propose a protocol for coal spontaneous combustion temperature prediction based on a Sparrow Search Algorithm (SSA)-optimized convolutional neural networks (CNN)-long short-term memory (LSTM)-Attention framework. This protocol addresses the limitations of fixed network architectures, restricted generalization, and poor transferability commonly encountered in conventional methods. The framework extracts spatial features using CNN and captures temporal dependencies with LSTM networks, while the attention mechanism highlights critical temperature phases and salient features. The SSA jointly optimizes network depth and hyperparameters, enabling dynamic adaptation to varying data complexities across different mining sites and experimental conditions. The protocol consists of data acquisition, feature preprocessing, model construction, parameter optimization, and validation steps. Experimental results demonstrate that the proposed model achieves significantly higher predictive accuracy on homogeneous datasets and maintains robust generalization performance across heterogeneous datasets, making it well-suited for real-time coal mine temperature monitoring and early-warning systems.

Introduction

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Coal still plays a dominant role in China's energy structure. However, during storage, transportation, and mining, spontaneous heating can occur, leading to spontaneous combustion. This often causes mine fires, seriously threatening mine safety and workers' lives1,2,3,4. Hence, accurate prediction of coal mine fire risks and their temperature variations is essential for early warning and disaster mitigation. The prediction methods for coal spontaneous combustion temperature have evolved from early empirical formulas to analysis appro....

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Protocol

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1.Coal spontaneous combustion data collection

  1. Assemble the air-type coal programmed heating oxidation system, including the gas delivery system, temperature control unit, and gas analysis instruments. Ensure that all connections are secure, temperature control settings are accurate, and the gas chromatograph and other analytical devices are fully calibrated.
  2. Weigh 1000 g of mixed coal sample (keep the original lump form), thoroughly homogenize the sample using the quartering method, and evenly place the coal blocks inside the heating chamber. Maintain consistent thickness and uniform distribution to ensure even heating.
  3. Start the air pu....

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Results

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Model stability was validated using four independent datasets, demonstrating consistent predictive performance across different geological conditions. This section presents representative results and performance evaluations of the coal spontaneous combustion experiments and the proposed SSA-CNN-LSTM-Attention model. First, the variations in multiple gas indicators collected during the programmed heating oxidation experiments are analyzed to reveal the dynamic patterns of gas concentration.......

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Discussion

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Use intact coal blocks; perform only surface cleaning after sampling and double-seal immediately to avoid prolonged exposure. Keep the gas line leak-tight with constant-flow control (MFC), execute the programmed heating exactly as specified in the protocol, and calibrate the GC with certified standards. Acquire temperature and gas signals at fixed intervals and synchronize timestamps (see protocol). From a computational standpoint, fix and record the environment (OS, Python, deep-learning framework, CUDA, etc.), set rand.......

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Disclosures

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The authors have nothing to disclose.

Acknowledgements

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This work was supported by the National Natural Science Foundation of China (Grant No. 52274206) for the project on dynamic disturbance and shear creep characteristics of deep hard rock and critical power-law behavior, and the National Natural Science Foundation of China Youth Fund (Grant No. 51904144) for the study on diffusion effects during coal seam gas migration.

....

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Materials

List of materials used in this article
NameCompanyCatalog NumberComments
6-port, 2-position gas sampling valve w/ universal actuatorVICI ValcoEUDA-2C6UWT1/16" fittings; 0.75 mm ports; RS-232; 2" standoff
Alumina sample boatMTI CorporationEQ-CA-L50W40H20>99.5% Al2O3; 50×40×20 mm
Chromatography softwareAgilent TechnologiesOpenLab CDSData acquisition/processing
Coal samples (field-collected)In-house/field-collectedN/ASource detailed in Methods
CUDA / cuDNNNVIDIAhttps://developer.nvidia.com/cuda-zoneCUDA 11.x; matching cuDNN
DAQ mainframeKeysightDAQ970A6½-digit DMM; USB/LAN
Desiccant (indicating)W.A. Hammond Drierite23001Calcium sulfate; 8 mesh; 1 lb
Diaphragm air pumpKNFhttps://www.knf.comContinuous air supply; adjustable flow
FR lab coatBulwarkKEL2 (series)NFPA 2112 compliant
Gas chromatographAgilent TechnologiesG3540A (8890 GC System)GC system; EPC; up to 2 inlets / 4 detectors
Heat-resistant glovesAnsell43-113Intermittent up to ~350 °C
High-purity airAir Liquide / Airgashttps://www.airgas.com/solutions/specialty-gases/pure-gases/alphagaz≥99.99% purity
IDEJetBrains / Microsofthttps://www.jetbrains.com/pycharm/ ; https://code.visualstudio.com/downloadPyCharm / VS Code
Inline filtersSwagelokhttps://www.swagelok.com/downloads/webcatalogs/en/ms-01-92.pdfSintered SS elements 0.5–15 µm
K-type thermocouplesOMEGAhttps://www.omega.comType K (NiCr–NiSi)
Mass flow controller (0–200 sccm)Alicat ScientificMC-200SCCM-DMC-series; ±(0.8% rdg + 0.2% FS)
Multi-component calibration gasesMesserhttps://specialtygases.messergroup.com/standard-gas-mixturesCustom concentration; certificate
Operating systemMicrosofthttps://www.microsoft.com/en-us/software-download/windows11Windows 11
Operating systemCanonicalhttps://ubuntu.com/download/desktopUbuntu LTS (22.04/24.04)
PTFE/PFA tubingSwagelokhttps://products.swagelok.com/en/all-products/hoses-flexible-tubing/ptfe-pfa-core-hose/c/716?clp=trueChemically resistant; 1/16–1/4 in OD
PythonPython Software Foundationhttps://www.python.org/downloads/Version 3.8
Quartz sample boatMTI CorporationEQ-QB-1017 (example size)~1200 °C working temp
Safety goggles3M93506P1-DC (example)Chemical splash; anti-fog options
Stainless-steel seamless tubingSwagelokhttps://www.swagelok.com/downloads/webcatalogs/en/ms-01-181.pdf316/316L; 1/16–1/4 in OD
Stainless-steel tube fittings & ferrulesSwagelokhttps://products.swagelok.com/en/all-products/fittings/tube-fittings-adapters/c/154?clp=true316/316L; double-ferrule
Temperature controllerEurotherm3216Single-loop PID; programmable ramps/alarms
TensorFlowGooglehttps://www.tensorflow.orgVersion 2.6
USB thermocouple moduleNI (National Instruments)781314-01 (USB-TC01)K/J/T; logging software
Variable area flowmeter (Visi-Float)Dwyer InstrumentsVFA-2-EC-SS (0.2–2 SCFH Air)Low-flow range; direct reading
Workstation GPUNVIDIA900-1G136-2530-000 (Founders Edition)GeForce RTX 4090, 24 GB GDDR6X (FE)

References

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  1. Zhang, J., Zhou, X., Su, J., Xiao, Y. An interpretable machine learning model for optimization of prediction index gases in coal spontaneous combustion. Alexandria Eng J. 122, 268-278 (2025).
  2. Wang, K., Huang, H., Deng, J., Zhang, Y., Wang, Q.

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Tags

Coal Spontaneous CombustionTemperature PredictionConvolutional Neural NetworksLong Short Term MemoryAttention MechanismSparrow Search AlgorithmModel OptimizationFeature PreprocessingReal Time MonitoringEarly Warning Systems

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