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不同煤阶煤大分子煤化过程中孔隙结构演化机制的实验研究与ReaxFF模拟

Experimental investigation and ReaxFF simulation on pore structure evolution mechanism during coalification of coal macromolecules in different ranks.

作者信息

Li Wu, Cui Minrui, Li Jin, Du Zhonghua, Zhan Xingyu

机构信息

Key Laboratory of Coalbed Methane Resource and Reservoir Formation Process, Ministry of Education, China University of Mining and Technology, Xuzhou, China.

School of Resources and Earth Science, China University of Mining and Technology, Xuzhou, China.

出版信息

Sci Rep. 2024 Dec 28;14(1):30768. doi: 10.1038/s41598-024-80520-0.

DOI:10.1038/s41598-024-80520-0
PMID:39730565
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11681237/
Abstract

This analysis revealed the alterations in the pore structure of large organic molecules in coal during the process of coal pyrolysis. Nine models of macromolecular structures in coals, representing distinct coal ranks, have been built. The research results show that along with the increasing coal rank, the average microporous volume of medium rank coal is 0.0287 cm/g. The average microporous volume of high-grade coal is 0.0662 cm/g. The micropore volume and specific surface area of coal samples decrease in the order of high rank, low rank, and middle coal. The experimental measurements align with the ReaxFF pyrolysis simulation calculations, indicating a decrease in the hydrogen to carbon ratio and oxygen to carbon ratio of all coal molecules. Additionally, the pore volume and specific surface area exhibit a pattern of initially decreasing and then increasing. The simulation results of gas probes indicate that a majority of the pores with a diameter larger than that of CH molecules are found in the macromolecular structure models of low rank coal and medium to high rank coal. The conclusions are useful for us to understand the formation and development process of pores in coal reservoir. A two-dimensional representation of coal's macromolecular structure was constructed using ChemDraw software. The Forcite module in Materials Studio software was used to perform geometric optimization and annealing kinetics simulation of a two-dimensional macromolecular structure model. The ReaxFF-MD module in Amsterdam Modeling Suite (AMS) 2020 software to model the pyrolysis of XJ coal macromolecules.

摘要

该分析揭示了煤热解过程中煤中大分子有机物质孔隙结构的变化。构建了9种代表不同煤阶的煤大分子结构模型。研究结果表明,随着煤阶的升高,中阶煤的平均微孔体积为0.0287 cm/g。高阶煤的平均微孔体积为0.0662 cm/g。煤样的微孔体积和比表面积按高阶、低阶和中阶煤的顺序递减。实验测量结果与ReaxFF热解模拟计算结果一致,表明所有煤分子的氢碳比和氧碳比均降低。此外,孔隙体积和比表面积呈现出先减小后增大的趋势。气体探针的模拟结果表明,在低阶煤和中高阶煤的大分子结构模型中发现了大多数直径大于CH分子的孔隙。这些结论有助于我们理解煤储层孔隙的形成和发育过程。使用ChemDraw软件构建了煤大分子结构的二维表示。使用Materials Studio软件中的Forcite模块对二维大分子结构模型进行几何优化和退火动力学模拟。使用阿姆斯特丹建模套件(AMS)2020软件中的ReaxFF-MD模块对XJ煤大分子的热解进行建模。

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本文引用的文献

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The Chemical and Alignment Structural Properties of Coal: Insights from Raman, Solid-State C NMR, XRD, and HRTEM Techniques.煤的化学与取向结构性质:来自拉曼光谱、固态碳核磁共振、X射线衍射和高分辨透射电子显微镜技术的见解
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晋城无烟煤的分子模型构建与评估
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