Study on the Influence of Coal Structure and Oxidation Performance by Endogenous Bacterium

IF 3 3区 农林科学 Q2 ECOLOGY Fire-Switzerland Pub Date : 2023-08-30 DOI:10.3390/fire6090339
Xuanmeng Dong, Fusheng Wang, Liwen Guo, Tiesheng Han
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引用次数: 1

Abstract

In order to solve the defects of traditional coal spontaneous combustion prevention technology in a closed goaf, a strain of aerobic endogenous bacteria was isolated from coal and used as a blocking raw material. Based on the metabolic and reproductive characteristics of microorganisms, the experimental study on the inhibition of coal spontaneous combustion by microorganisms was carried out. The colonies were isolated and purified by the dilution concentration plate method and the scribing plate method. The growth morphology of microorganisms was analyzed, and the growth curve was determined. The strains were identified by seamless cloning technology for high-throughput sequencing. The surface morphology of coal was analyzed by SEM, the differences of oxidation characteristic temperature points were analyzed by TG–DTG–DSC images, a programmed heating experiment was used to analyze the concentration of the indicator gas CO, and the changes in microscopic groups before and after microbial action were analyzed by FTIR and XPS spectra. Therefore, the inhibition of coal oxidation by endogenous bacteria was verified from macroscopic and microscopic perspectives. The results show that the coal bacteria isolated from the coal is Lysinibacilus sp. After the culture of Lysinibacilus sp., the surface of the coal demonstrated less detritus, and was relatively smooth. In the early stage of low temperature oxidation of coal spontaneous combustion, the characteristic temperature point of coal oxidation and the reaction between coal and O2 could be delayed by Lysinibacilus sp., and the total heat release was reduced in the combustion process. Not only that, Lysinibacilus sp. could also reduce the CO concentration during coal heating. After the coal was decomposed by Lysinibacilus sp., the C=C thick ring skeleton structure had little effect; however, the aromatic substitution pattern changed. This bacterium had an effect on the C-O bond, reducing the percentage of -CH2- and increasing the percentage of -CH3. It might also use the crystalline water in coal for life activities. The carboxyl carbon in coal changed the most, with a decrease of 12.03%, so it might become the carbon source required for microbial growth. The reproductive metabolism of microorganisms also affected the form of nitrogen, and the percentage of pyridine nitrogen in coal was reduced. The ratio of single-bond carbon to double-bond carbon in raw coal was about 3:2, but after this bacterial action, the ratio of the two was about 1:1. The analytical conclusions of XPS and FTIR spectra were consistent, and the results supported each other.
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内源性细菌对煤结构和氧化性能影响的研究
为了解决封闭采空区传统煤自燃防护技术的缺陷,从煤中分离出一株好氧内源性细菌,并将其用作封堵原料。根据微生物的代谢和繁殖特性,对微生物抑制煤自燃进行了实验研究。通过稀释浓缩板法和划线板法分离和纯化菌落。对微生物的生长形态进行了分析,并确定了生长曲线。菌株通过无缝克隆技术进行高通量测序鉴定。用SEM分析了煤的表面形态,用TG–DTG–DSC图像分析了氧化特征温度点的差异,用程序升温实验分析了指示气体CO的浓度,用FTIR和XPS光谱分析了微生物作用前后微观基团的变化。因此,从宏观和微观角度验证了内源性细菌对煤氧化的抑制作用。结果表明,从煤中分离出的煤细菌为赖氨酸芽孢杆菌。赖氨酸双歧杆菌培养后,煤表面碎屑较少,且相对光滑。在煤自燃低温氧化的早期阶段,赖氨菌可以延缓煤氧化的特征温度点以及煤与O2的反应,并减少燃烧过程中的总热量释放。不仅如此,赖氨菌还可以降低煤加热过程中的CO浓度。赖氨菌分解煤后,C=C厚环骨架结构对煤的分解影响不大;然而,芳香取代模式发生了变化。这种细菌对C-O键有影响,降低了-CH2-的百分比,增加了-CH3的百分比。它也可能利用煤中的结晶水进行生命活动。煤中的羧基碳变化最大,减少了12.03%,可能成为微生物生长所需的碳源。微生物的生殖代谢也影响了氮的形态,煤中吡啶氮的百分比降低。原煤中单键碳与双键碳的比例约为3:2,但经过这种细菌作用后,两者的比例约是1:1。XPS和FTIR光谱的分析结论一致,结果相互支持。
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来源期刊
Fire-Switzerland
Fire-Switzerland Multiple-
CiteScore
3.10
自引率
15.60%
发文量
182
审稿时长
11 weeks
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