Influence of coal metamorphism on microstructure and pyrolysis parameters: a correlation analysis

doi:10.16265/j.cnki.issn1003-3033.2025.02.0698

Abstract

Abstract:

To reveal the impact of coal metamorphism on the self-ignition process,experimental and quantitative analysis methods was combined to analyze the pyrolysis characteristics, microstructural changes, and their correlations during coal self-ignition. First, Fourier-transform infrared spectroscopy (FTIR) was employed to determine changes in the content of active functional groups in coal samples. Then, thermogravimetric analysis (TGA) was conducted to obtain pyrolysis characteristic parameters for coal samples with varying degrees of metamorphism. Finally, Pearson correlation coefficient method was applied to quantify the relationship between microstructure and characteristic temperatures during coal self-ignition. The results indicate that as the degree of coal metamorphism increases, the content of aromatic and aliphatic hydrocarbons(Ar-CH) rises, while oxygen-containing functional groups(C-O-C) significantly decrease. Low-rank coal samples exhibit the highest proportion of oxygen-containing functional groups, whereas high-rank coal samples contain more than 50% aromatic hydrocarbons. Increased metamorphism delays weight loss curves and shifts them to higher temperature regions, leading to an increase in characteristic temperatures. Ar-CH show a significant positive correlation with characteristic temperatures, while C-O-C exhibit a negative correlation. Overall, the increase in Ar-CH and the decrease in C-O-C in coal samples are identified as the primary microstructural factors responsible for the rise in characteristic temperatures and the reduction in self-ignition propensity.

Key words: metamorphic degree, microstructur, pyrolysis parameters, correlation, spontaneous combustion of coal, functional groups

CLC Number:

X936

YE Zhengliang, GUO Ximan, SHANG Bo, HU Mian. Influence of coal metamorphism on microstructure and pyrolysis parameters: a correlation analysis[J]. China Safety Science Journal, 2025, 35(2): 57-65.

Figures/Tables 15

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煤种	水分	灰分	挥发分	固定碳含量
方家畔煤业褐煤	5.06	9.58	40.22	59.90
兴隆庄煤矿气煤	2.45	8.85	33.42	65.28
云驾岭矿无烟煤	1.88	16.56	2.35	97.12

煤种	峰面积
	羟基	脂肪烃	芳香烃			含氧官能团
	羟基	脂肪烃	Ar-CH	C=C	多种取代芳烃	-COOH	C=O	R-O-R'
方家畔煤业褐煤	107.735	75.85	14.12	21.088	15.664	5.189	8.445	61.085
兴隆庄煤矿气煤	2.376	15.295	4.585	10.915	21.388	—	3.841	6.705
云驾岭矿无烟煤	16.743	2.832	2.640	2.054	8.838	—	0.306	33.299

煤种	羟基	脂肪烃	芳香烃	含氧官能团
褐煤	29.10	10.49	13.74	46.68
气煤	25.10	14.25	20.31	40.37
无烟煤	3.65	23.49	56.66	16.20

煤样	特征温度点
	t₁	t₂	t₃	t₄	t₅	t₆	t₇
	临界温度	干裂温度	活性温度	增速温度	着火温度	速率最大温度	燃尽温度
方家畔煤业褐煤	66.25	175.25	250.00	292.25	420.25	508.75	633.75
兴隆庄煤矿气煤	69.50	174.50	334.00	365.25	511.64	643.00	787.00
云驾岭矿无烟煤	72.5	261.25	341.75	405.25	615.42	690.25	788.00