- Chinese Core Periodicals
- Chinese Core Journals of Science and Technology
- RCCSE Chinese Authoritative Academic Journals
| Citation: |
WANG Menglu, SHEN Yongxing, ZHOU Dong, et al. Experimental study on kinetic characteristics of gas adsorption of coal with different degrees of metamorphism[J]. Safety in Coal Mines, 2024, 55(1): 34−41. DOI: 10.13347/j.cnki.mkaq.20221609
|
In order to further reveal the dynamic characteristics of coal with different degrees of metamorphism under different adsorption pressures, the self-developed TQY-2 precision adsorption instrument and infrared thermal imaging device were used to conduct macroscopic adsorption tests on lignite, coking coal and anthracite coal samples with a diameter of 8.5 mm at different pressures (0.2, 0.4, 0.6, 0.8, 1.0 MPa) and the adsorption test of the mesoscopic structure of the coal body with adsorption pressures of (0.3, 0.6, 0.9, 1.2, 1.5 MPa), using quasi-primary and quasi-secondary adsorption kinetic models such as intra-particle diffusion, Elovich and double constant analyze the law and mechanism of adsorption gas. The results show that compared with five adsorption kinetics models, the quasi-secondary adsorption kinetics model is suitable for characterizing the adsorption gas process of lignite and coking coal, while the optimal model for anthracite is the intra-particle diffusion model; with the increase of adsorption pressure, the quasi-secondary adsorption rate constant k2 of lignite and coking coal gradually increased, and the intra-particle diffusion rate constant kp of anthracite coal also gradually increased, all of which were positively correlated; adsorption pressure has little effect on the dynamic model suitable for coal samples; under the macroscopic adsorption experiment and the mesoscopic structure adsorption experiment of coal body based on infrared thermography, the dynamic models suitable for different degrees of metamorphism are consistent.
| [1] |
谢和平,周宏伟,薛东杰,等. 我国煤与瓦斯共采:理论、技术与工程[J]. 煤炭学报,2014,39(8):1391−1397.
XIE Heping, ZHOU Hongwei, XUE Dongjie, et al. Theory, technology and engineering of simultaneous exploitation of coal and gas in China[J]. Journal of China Coal Society, 2014, 39(8): 1391−1397.
|
| [2] |
李树刚, 林海飞. 煤与甲烷共采学导论[M]. 北京: 科学出版社, 2014.
|
| [3] |
陈昌国,鲜晓红,杜云贵,等. 煤吸附与解吸甲烷的动力学规律[J]. 煤炭转化,1996,19(1):68−71.
CHEN Changguo, XIAN Xiaohong, DU Yungui, et al. The kinetics model of adsorption-desorption of methane on coal[J]. Coal Conversion, 1996, 19(1): 68−71.
|
| [4] |
WANG Q, LI W, ZHANG D, et al. Influence of high-pressure CO2 exposure on adsorption kinetics of methane and CO2 on coals[J]. Journal of Natural Gas Science and Engineering, 2016, 34: 811−822. doi: 10.1016/j.jngse.2016.07.042
|
| [5] |
IRFAN M F, USMAN M R, KUSAKABE K. Coal gasification in CO2 atmosphere and its kinetics since 1948 A brief review[J]. Energy, 2011, 36(1): 12−40. doi: 10.1016/j.energy.2010.10.034
|
| [6] |
HAN F, BUSCH A, KROOSS B M, et al. CH4 and CO2 sorption isotherms and kinetics for different size fractions of two coals[J]. Fuel, 2013, 108(6): 137−142.
|
| [7] |
左罗,胡志明,崔亚星,等. 页岩高温高压吸附动力学实验研究[J]. 煤炭学报,2016,41(8):2017−2023.
ZUO Luo, HU Zhiming, CUI Yaxing, et al. High temperature and pressure methane adsorption characteristics and adsorption kinetics of shale[J]. Journal of China Coal Society, 2016, 41(8): 2017−2023.
|
| [8] |
位乐. 煤的瓦斯吸附动力学机制及温度效应[J]. 煤矿安全,2020,51(8):7−11. doi: 10.13347/j.cnki.mkaq.2020.08.002
WEI Le. Kinetic mechanism and temperature effect of coal gas adsorption[J]. Safety in Coal Mines, 2020, 51(8): 7−11. doi: 10.13347/j.cnki.mkaq.2020.08.002
|
| [9] |
张哲,秦兴林. 余吾矿构造煤吸附动力学特性[J]. 煤矿安全,2020,51(8):28−31. doi: 10.13347/j.cnki.mkaq.2020.08.006
ZHANG Zhe, QIN Xinglin. Adsorption dynamics characteristic of tectonic coal in Yuwu Coal Mine[J]. Safety in Coal Mines, 2020, 51(8): 28−31. doi: 10.13347/j.cnki.mkaq.2020.08.006
|
| [10] |
周动,冯增朝,赵东,等. 煤吸附瓦斯细观特性研究[J]. 煤炭学报,2015,40(1):98−102. doi: 10.13225/j.cnki.jccs.2014.0021
ZHOU Dong, FENG Zengchao, ZHAO Dong, et al. Study on mesoscopic characteristics of methane adsorption by coal[J]. Journal of China Coal Society, 2015, 40(1): 98−102. doi: 10.13225/j.cnki.jccs.2014.0021
|
| [11] |
周动,冯增朝,王辰,等. 煤吸附甲烷结构变形的多尺度特征[J]. 煤炭学报,2019,44(7):2159−2166.
ZHOU Dong, FENG Zengchao, WANG Chen, et al. Multi-scale characteristics of coal structure deformation during methane adsorption[J]. Journal of Coal Society, 2019, 44(7): 2159−2166.
|
| [12] |
王辰,冯增朝. 基于红外成像技术的煤中甲烷分布特征研究[J]. 煤矿安全,2021,52(6):1−5. doi: 10.13347/j.cnki.mkaq.2021.06.001
WANG Chen, FENG Zengchao. Research on distribution characteristics of methane in coal based on infrared imaging technology[J]. Safety in Coal Mines, 2021, 52(6): 1−5. doi: 10.13347/j.cnki.mkaq.2021.06.001
|
| [13] |
KARACAN C O. An effective method for resolving spatial distribution of adsorption kineties in heterogeneous porous media: Application for carbon dioxide sequestration in coal[J]. Chemical Engineering Science, 2003, 58(20): 4681−4693. doi: 10.1016/j.ces.2003.05.002
|
| [14] |
HO Y S, MCKAY G. Pseudo-second order model for sorption processes[J]. Process Biochemistry, 1999, 34: 451−453. doi: 10.1016/S0032-9592(98)00112-5
|
| [15] |
WEBER W J, MORRIS J C. Proceeding of International Conference on Water Pollution Symposium[M]. Oxford: Pergamon Press, 1962: 231.
|
| [16] |
贾海红,韩宝平,马卫兴,等. 壳聚糖吸附溴酚蓝的动力学及热力学研究[J]. 环境科学与技术,2011,34(5):43−60.
JIA Haihong, HAN Baoping, MA Weixing, et al. Kinetics and thermodynamic of bromophenol blue adsorption on chitosan[J]. Environmental Science & Technology, 2011, 34(5): 43−60.
|
| [17] |
丁世敏,封享华,汪玉庭,等. 交联壳聚糖多孔微球对染料的吸附平衡及吸附动力学分析[J]. 分析科学学报,2005,21(2):127−129.
DING Shimin, FENG Xianghua, WANG Yuting, et al. Equilibrium and kinetic analysis of adsorption for dyestuff by cross-linked chitosan porous microbeads[J]. Journal of Analytical Science, 2005, 21(2): 127−129.
|
| [1] | WANG Zhengyi, HE Jiang. Mechanism of coal-rock dynamic disasters in complex geological structure areas and its prevention[J]. Safety in Coal Mines, 2021, 52(9): 204-210. |
| [2] | GAN Lintang. Coal and rock dynamic disaster analysis in Huainan Mining Area based on key stratum control principle[J]. Safety in Coal Mines, 2021, 52(7): 187-192. |
| [3] | WANG Zhen, REN Gaofeng, ZHANG Congrui, ZHANG Jianfeng. Dynamic Response Characteristics of Shock Air Wave Disaster in Gob Failure Process[J]. Safety in Coal Mines, 2019, 50(6): 45-49. |
| [4] | GAO Zhenyong, WU Guangyu, LI Yue. Influence of Low Temperature Oxidation of Coal Body on Dynamic Disasters of Coal and Rock During Coal Seam Gas Extraction[J]. Safety in Coal Mines, 2017, 48(11): 29-32. |
| [5] | WANG Zhen. Discussion on Classification and Identification Method for Dynamic Disasters of Coal and Rock[J]. Safety in Coal Mines, 2017, 48(6): 176-179. |
| [6] | CUI Feng, LAI Xingping, CAO Jiantao, SHAN Pengfei. Occurrence Mechanism and Control Strategies of Mine Dynamic Disaster[J]. Safety in Coal Mines, 2017, 48(1): 191-194,198. |
| [7] | GENG Youming. Mechanism of Compound Dynamic Disaster and Integrated Prevention Technology in Deep Mine[J]. Safety in Coal Mines, 2016, 47(11): 73-76. |
| [8] | SHI Xianfeng, QU Xiaocheng, WEI Quande, XU Yongyong, FENG Guochun, DONG Qiang, JIN Xianru. Treatment Research on Dynamic Disaster Caused by Hard Roof Multi-seam Mining[J]. Safety in Coal Mines, 2016, 47(6): 33-35,40. |
| [9] | GAO Bao-bin, MI Xiang-fan, ZHANG Rui-lin. Research Status and Prospect of Compound Dynamic Disaster of Deep Mining in Coal Mine[J]. Safety in Coal Mines, 2013, 44(11): 175-178. |
| [10] | JIN Pei-jian, WANG En-yuan, SONG Da-zhao, HUANG Ning, WANG Si-heng. Experimental Study on Coal Rock Electromagnetic Radiation Laws Under Uniaxial Cyclic Loading[J]. Safety in Coal Mines, 2013, 44(5): 46-48. |
Supported by: Beijing Renhe Information Technology Co., Ltd. 
DownLoad: