三塘湖不黏煤低温氧化过程中孔隙结构的演变规律研究

doi:10. 11799/ ce202504027

摘要/Abstract

摘要：

为降低运输煤炭自燃风险，探讨了低温氧化对煤的孔隙结构影响，并采用管式炉模拟了运输煤炭低温氧化过程，通过低温氮气吸附-脱附法分析了低温氧化过程中三塘湖不黏煤孔隙结构的演变规律。结果表明：在整个低温氧化过程中三塘湖不黏煤以圆柱形或狭缝形开放孔为主，其微孔、中孔最几可孔径分别在1.8nm和9.3nm，对孔隙改变主要在微孔和中孔。氧化时间的延长有利于总孔容及比表面积增加。在氧化温度小于110℃时提升温度利于微孔、中孔体积、比表面积及分形维数D2的增加。在氧化温度110℃ 时总孔体积和比表面积达到最大值，并在2.5~4.0nm范围产生了新的孔，孔隙结构也最复杂。可推测因氧化时间影响孔道前期以坍塌、堵塞为主，后期以扩容，打通堵塞孔和产生新开放孔为主；因氧化温度影响孔道前期以扩容，打通堵塞孔为主，后期同时存在坍塌，堵塞，扩容，打通堵塞孔和产生新的开放孔。

关键词:

不黏煤 , 低温氧化 , 孔隙结构 , 分形维数

Abstract: In order to explore the mechanism of coal spontaneous combustion and reduce the risk of coal spontaneous combustion in storage and transportation,a tube furnace was used to simulate the low-temperature oxidation process of coal storage and transportation.The evolution law of pore structure of low-rank coal was analyzed by low-temperature nitrogen adsorption-desorption method.The results indicated that the most of holes of the Santanghu coal was similar to neck bottle and ink bottle. And there were also some cylindrical holes and slit flat holes.The critical pore size of Santanghu coal were around 1.8nm, 6.8nm and 9.3nm. With extending oxidation time, the pore roughness and the volume of mesopore and micropore increased. The percentage of pore volume increase was the largest.The transformation of pore structure of Sandanghu coal was be divided into three stages by oxidation temperature.The specific surface area, mesopore and micropore increased before 80℃. The specific surface area and pore volume continued to increase between 80℃-110℃. The pore volume and specific surface area of Santanghu coal reached the largest at 110℃. The pore volume of micropores increased the most.Comparing with the raw coal, the pore volume of micropores increased by 45.83 percentage points and the specific surface area increased by 61.99 percentage points.The specific surface area , micropores and mesopore decreased between 110℃-170℃.

中图分类号:

TD711 " target="_blank">
TD711

吴凡, 夏侯文奇, 许宁, 等.

三塘湖不黏煤低温氧化过程中孔隙结构的演变规律研究 [J]. 煤炭工程, 2025, 57(4): 194-201.

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