煤岩显微组分分离富集物热化学反应特性

doi:10.16085/j.issn.1000-6613.2022-0866

摘要/Abstract

摘要：

依据煤中不同类型有机质性质差异对其进行分离，进而分质利用是实现煤炭清洁高效利用的有效手段。论文利用重选法将一种低变质烟煤分质得到镜质组较原煤48.25%增加至76.02%的富镜样，惰质组较原煤43.96%增加至63.98%的富惰样，以及矿物质含量高于61.99%的富矿样。利用热重-质谱分析仪，考察了分离富集物的热解反应特性及气体逸出规律，及其燃烧和气化反应特性。结果表明，分离所得富镜样热解反应失重量及热解过程中逸出的小分子挥发分的量及组成与富惰样和富矿样均有明显差异，表明分质实现了煤中不同类型官能团的分离富集。而由分离所得富镜样、富惰样和原煤热解失重峰温基本一致则表明分质所得煤的主体官能团结构仍较为接近，但含量有明显差距。富镜、富惰与原煤的燃烧曲线整体趋势较为类似，燃烧活性差别不大。以气化反应峰值温度高低判断，富镜样气化反应活性最低，富惰样与原煤气化反应活性较为接近，富矿样气化反应活性最高。将原煤在对应热反应时的理论反应曲线与实验曲线进行对比，发现煤分质过程及煤中镜质组、惰质组和矿物质的分离与否对热解过程挥发分的逸出影响较小，但导致了其燃烧和气化反应活性有所降低。

关键词: 煤, 重选, 分质利用, 热解, 燃烧, 气化

Abstract:

Pre-separation of different macerals in coal based on the physical properties and then quality-based utilization are effective process to realize clean and efficient use of coal. According to the density difference of different macerals in coal, a sub-bituminous coal was separated by gravity separation method into maceral concentrates that was enriched in vitrinite, inertinite and mineral, respectively. Compared with the raw coal, the vitrinite increased from 48.25% to 76.02% in the vitrinite-rich sample, the inertinite increased from 43.96% to 63.98% in the inertinite-rich sample, and the minerals content increased from 10.47% to 61.99% in the mineral-rich sample. By thermogravimetry-mass spectrometry analysis, the pyrolysis behavior and the gas evolution of different maceral concentrates were investigated, and the combustion and gasification reaction characteristics were also discussed. The results show that the amount of volatiles from pyrolysis of vitrinite-rich sample is significantly higher than that of raw coal and inertinite-rich sample, indicating that the separation processes successfully separate and enrich some of the functional groups of the coal. Moreover, the pyrolysis characteristic temperatures of the maceral concentrates are basically the same, indicating that the main reaction components of the vitrinite-rich and inertinite-rich sample are similar, but the contents are different. Combustion experiments show that the overall trend of combustion curves of the vitrinite-rich, inertinite-rich sample and raw coal are similar, reflecting little difference in combustion activity. CO₂ gasification experiments show that the gasification reactivity of vitrinite-rich sample is the lowest, and the gasification reactivity of inertinite-rich sample is close to that of the raw coal gasification. Comparing the calculated reaction curve of raw coal with the experimental curve, it is found that the coal separation process and the separation of vitrinite, inertinite and minerals have little effect on the volatile liberation in the pyrolysis process, while decreasing the combustion and gasification reaction activity.

Key words: coal, gravity separation process, quality-based utilization, pyrolysis, combustion, gasification

中图分类号:

TQ529.1

张乾, 高增林, 王栋, 彭泽宇, 郝泽光, 黄伟. 煤岩显微组分分离富集物热化学反应特性[J]. 化工进展, 2022, 41(S1): 160-167.

ZHANG Qian, GAO Zenglin, WANG Dong, PENG Zeyu, HAO Zeguang, HUANG Wei. Thermal chemical reaction behavior of the coal maceral concentrates[J]. Chemical Industry and Engineering Progress, 2022, 41(S1): 160-167.

图/表 11

参考文献 16

1	谢克昌. 煤的结构与反应性[M]. 北京: 科学出版社, 2002.
	XIE Kechang. Coal structure and reactivity[M]. Beijing: Science Press, 2002.
2	GRANDA M, BLANCO C, ALVAREZ P, et al. Chemicals from coal coking[J]. Chemical Reviews, 2014, 114(3): 1608-1636.
3	相宏伟, 杨勇, 李永旺. 碳中和目标下的煤化工变革与发展[J]. 化工进展, 2022, 41(3): 1399-1408.
	XIANG Hongwei, YANG Yong, LI Yongwang. Transformation and development of coal chemical industry under the goal of carbon neutralization[J]. Chemical Industry and Engineering Progress, 2022, 41(3): 1399-1408.
4	谢和平, 任世华, 谢亚辰, 等. 碳中和目标下煤炭行业发展机遇[J]. 煤炭学报, 2021,46(7): 2197-2211.
	XIE Heping, REN Shihua, XIE Yachen, et al. Development opportunities of the coal industry towards the goal of carbon neutrality[J]. Journal of China Coal Society, 2021,46(7): 2197-2211.
5	朱之培, 高晋生. 煤化学[M]. 上海: 上海科学技术出版社, 1984.
	ZHU Zhibei, GAO Jinsheng. Coal chemisty[M]. Shanghai: Shanghai Science and Technology Press, 1984.
6	赵伟, 张晓欠, 周安宁, 等. 神府煤煤岩显微组分的浮选分离及富集物的低温热解产物特性研究[J]. 燃料化学学报, 2014, 42(5): 527-533.
	ZHAO Wei, ZHANG Xiaoqian, ZHOU Anning, et al. Flotation separation of shenfu coal macerals and low temperature pyrolysis characteristics of different maceral concentrate[J]. Journal of Fuel Chemistry and Technology, 2014, 42(5): 527-533.
7	WANG D, PENG Z, WANG J, et al. Study on pyrolysis behavior of the coal fractions based on macro maceral separation[J]. Fuel, 2021, 305(2): 121572.
8	卫小芳, 王建国, 丁云杰. 煤炭清洁高效转化技术进展及发展趋势[J]. 中国科学院院刊, 2019, 34(8): 409-416.
	WEI Xiaofang, WANG Jianguo, DING Yunjie. Progress and development trend of clean and efficient coal utilization technology[J]. Bulletin of Chinese Academy of Sciences, 2019, 34(8): 409-416.
9	XIA Y, ZHANG R, CAO Y, et al. Role of molecular simulation in understanding the mechanism of low-rank coal flotation: a review[J]. Fuel, 2020, 262: 116535.
10	桂夏辉, 邢耀文, 曹亦俊, 等. 低品质煤泥浮选过程强化研究进展及其思考[J]. 煤炭学报, 2021, 46(9): 2715-2732.
	GUI Xiahui, XING Yaowen, CAO Yijun, et al. Recent advances and thinking in process intensification of low quality coal slime flotation[J]. Journal of China Coal Society, 2021, 46(9): 2715-2732
11	孙庆雷, 李文, 李东涛, 等. 神木煤有机显微组分的结构特征与热转化性质的关系[J]. 燃料化学学报, 2003, 31(2): 97-102.
	SUN Qinglei, LI Wen, LI Dongtao, et al. Relationship between structure characteristics and thermal conversion property of Shenmu maceral concentrates[J]. Journal of Fuel Chemistry and Technology, 2003, 31(2): 97-102.
12	张乾, 向欣宁, 梁丽彤, 等. 热重分析煤焦恒温气化过程中气体切换的影响[J]. 化工进展, 2022, 41(1): 166-173.
	ZHANG Qian, XIANG Xinning, LIANG Litong, et al. Gas switch effect on the isothermal gasification reaction of coal char in thermogravimetric analyser[J]. Chemical Industry and Engineering Progress, 2022, 41(1): 166-173.
13	袁泉, 张乾, 梁丽彤, 等. 煤与催化裂化油浆共热解特性及气体逸出规律[J]. 煤炭学报, 2021, 46(8): 2690-2698.
	YUAN Quan, ZHANG Qian, LIANG Litong, et al. Characteristics of co-pyrolysis of coal and FCC slurry and the evolution behavior of the produced gases[J]. Journal of China Coal Society, 2021, 46(8): 2690-2698.
14	LIN Xiongchao, LUO Meng, LI Shouyi, et al. The evolutionary route of coal matrix during integrated cascade pyrolysis of a typical low-rank coal[J]. Applied Energy, 2017, 199: 335-346.
15	ZHANG Qian, LI Qingfeng, ZHANG Linxian, et al. Experimental and kinetic investigation of the pyrolysis, combustion, and gasification of deoiled asphalt[J]. Journal of Thermal Analysis & Calorimetry, 2014, 115(2): 1929-1938.
16	LI Changlun, YANG Sasha, CHEN Xujun, et al. The characteristic of Shengli brown coal fractions from heavy medium separation and its influence on CO₂ gasification[J]. Fuel Processing Technology, 2017, 155: 232-237.

样品	工业分析（空气干燥基）/%				元素分析（干燥无灰基）/%
样品	水分	灰分	挥发分	固定碳	碳	氢	氧^①	氮	硫
原煤	1.20	10.34	34.64	53.82	80.05	5.02	10.48	1.20	3.25
富镜	0.86	1.85	40.97	56.32	80.01	5.44	11.74	1.23	1.58
富惰	0.91	6.54	33.28	59.27	81.38	4.94	10.68	1.09	1.91
富矿	0.60	64.63	21.31	13.46	56.69	3.51	3.00	0.81	35.99

样品	工业分析（空气干燥基）/%				元素分析（干燥无灰基）/%
样品	水分	灰分	挥发分	固定碳	碳	氢	氧^①	氮	硫
原煤	1.20	10.34	34.64	53.82	80.05	5.02	10.48	1.20	3.25
富镜	0.86	1.85	40.97	56.32	80.01	5.44	11.74	1.23	1.58
富惰	0.91	6.54	33.28	59.27	81.38	4.94	10.68	1.09	1.91
富矿	0.60	64.63	21.31	13.46	56.69	3.51	3.00	0.81	35.99

样品	含矿物基/%				收率/%
样品	镜质组	惰质组	壳质组	矿物质	收率/%
原煤	48.25	43.96	1.56	6.23
富镜	76.02	21.51	1.63	0.84	36.71
富惰	32.70	63.98	0.95	2.37	56.53
富矿	16.94	20.66	0.41	61.99	6.76

样品	含矿物基/%				收率/%
样品	镜质组	惰质组	壳质组	矿物质	收率/%
原煤	48.25	43.96	1.56	6.23
富镜	76.02	21.51	1.63	0.84	36.71
富惰	32.70	63.98	0.95	2.37	56.53
富矿	16.94	20.66	0.41	61.99	6.76

样品	起始温度/℃	峰值温度/℃	峰值速率/%·min^-1	终止温度/℃
原煤	392	442	2.13	887
富镜	393	440	2.83	873
富惰	391	442	1.94	908
富矿	554	711	0.91	961