柱状煤心瓦斯径向多尺度动态表观扩散模型与实验
Experiment and radial multi-scale dynamic apparent diffusion model of gas in cylindrical coal core
-
摘要: 为了提高长钻孔瓦斯含量测定的准确性,进行了?准50 mm×100 mm柱状煤心径向和1~3 mm颗粒煤球向瓦斯解吸流动实验。实验结果表明:常系数扩散模型不能准确描述柱状煤心瓦斯的径向流动全过程;90 min前,实验值大于理论值;90 min后,实验值小于理论值,这种现象是由于煤体的多尺度孔隙结构引起的。进而提出了柱状煤心瓦斯径向多尺度动态表观扩散系数新模型。计算表明:新的径向动态表观扩散模型能精确描述瓦斯在柱状煤心中的表观扩散;相同时间内柱状煤的径向解吸比率远小于颗粒煤球向解吸比例,损失量较小;因而,进行长钻孔长时间测定瓦斯含量时,柱状煤心比颗粒煤更有优势。Abstract: In order to improve the accuracy of measuring gas content in long borehole, experiments of gas desorption flow in radial direction of ?准50 mm × 100 mm cylindrical coal and 1-3 mm granular coal were carried out. The experimental results show that the constant coefficient diffusion model can not describe the whole process of gas flow in radial direction accurately. The experimental value is larger than the theoretical value before 90 min and smaller than the theoretical value after 90 min. This phenomenon is caused by the multi-scale pore structure of coal. Furthermore, a new model of gas radial multi-scale dynamic apparent diffusion coefficient of cylindrical coal core is proposed. The calculation shows that the new radial dynamic apparent diffusion model can accurately describe the gas apparent diffusion in the cylindrical coal core. In the same time, the radial desorption ratio of cylindrical coal is much smaller than that of granular coal and the loss is smaller. Therefore, the cylindrical coal core has more advantages than the granular coal when the gas content is measured for a long time.
-
Keywords:
- methane desorption /
- diffusion coefficient /
- dynamic model /
- multi-scale /
- dynamic attenuation
-
-
[1] Richard M Barrer. Diffusion in and through solids[M]. London: Cambridge University Press, 1951. [2] Crank J. The mathematic of diffusion(second edition)[M]. Oxford: Oxford University Press, 1975. [3] Ruckenstein E, Vaidyanathan S, Youngquist GR. Sorption by solids with bidisperse pore structures[J]. Chemical Engineering Science, 1971, 26(9): 1305-1318. [4] 杨其銮,王佑安.煤屑瓦斯扩散理论及其应用[J].煤炭学报,1986(3):87-94. YANG Qiluan, WANG Youan. Theory of methane diffusion from coal cuttings and its application[J]. Journal of China Coal Society, 1986(3): 87-94.
[5] 郭勇义,吴世跃,王跃明,等.煤粒瓦斯扩散及扩散系数测定方法的研究[J].山西矿业学院学报,1997(1):17-21. GUO Yongyi, WU Shiyue, WANG Yueming, et al. Study on the measurement of coal particle gas diffusion and diffusion coefficient[J]. Shanxi Mining Institute Lea-rned Journal, 1997(1): 17-21.
[6] 聂百胜,王恩元,郭勇义,等.煤粒瓦斯扩散的数学物理模型[J].辽宁工程技术大学学报(自然科学版),1999(6):582. NIE Baisheng, WANG Enyuan, GUO Yongyi, et al.Mathematical and physical model of gas diffusion through coal particles[J]. Journal of Liaoning Technical University(Natural Science Edition), 1999(6): 582.
[7] 聂百胜,郭勇义,吴世跃,等.煤粒瓦斯扩散的理论模型及其解析解[J].中国矿业大学学报,2001,30(1):21-24. NIE Baisheng, GUO Yongyi, WU Shiyue, et al. Through coal particles and its analytical solution[J]. Journal of China University of Mining & Technology, 2001, 30(1): 21-24.
[8] 李志强,刘勇,许彦鹏,等.煤粒多尺度孔隙中瓦斯扩散机理及动扩散系数新模型[J].煤炭学报,2016,41(3):633. LI Zhiqiang, LIU Yong, XU Yanpeng, et al. Gas diffusion mechanism in multi-scale pores of coal particles and new diffusion model of dynamic diffusion coefficient[J]. Journal of China Coal Society, 2016, 41(3): 633.
[9] 李志强,王登科,宋党育.新扩散模型下温度对煤粒瓦斯动态扩散系数的影响[J].煤炭学报,2015,40(5):1055-1064. LI Zhiqiang, WANG Dengke, SONG Dangyu. Influence of temperature on dynamic diffusion coefficient of CH4 into coal particles by new diffusion model[J]. Journal of China Coal Society, 2015, 40(5): 1055-1064.
[10] 林晨.煤粒甲烷扩散系数幂函数模型研究[D].焦作:河南理工大学,2018. [11] 蔡银英,程建圣,程波.基于时变扩散系数的圆体煤屑的瓦斯放散规律研究[J].矿业安全与环保,2020, 47(3):32. CAI Yinying, CHENG Jiansheng, CHENG Bo. Study on the gas emission law of circular column cinder based on time-varying diffusion coefficient[J]. Mining Safety & Environmental Protection, 2020, 47(3): 32.
[12] 张宪尚.扩散时间对经典模型扩散系数影响研究[J].中国安全科学学报,2020,30(2):60-65. ZHANG Xianshang. Influence of time factor on diffusion coefficient based on classical model[J]. China Safety Science Journal, 2020, 30(2): 60-65.
[13] 张路路,魏建平,温志辉,等.基于动态扩散系数的煤粒瓦斯扩散模型[J].中国矿业大学学报,2020,49(1):62-68. ZHANG Lulu, WEI Jianping, WEN Zhihui, et al. Gas diffusion model of coal particle based on dynmic diffusion coefficient[J]. Journal of China University of mining & Technology, 2020, 49(1): 62-68.
[14] 张淑同.井下瓦斯含量直接法测定关键技术研究[J].采矿与安全工程学报,2014,31(2):328. ZHANG Shutong. Key technology for gas content direct determination method in underground mine[J]. Journal of Mining & Safety Engineering, 2014, 31(2): 328.
[15] Pan Z, Connell L D, Camilleri M, et al. Effect of matrix moisture on gas diffusion and flow in coal[J]. Fuel, 2010, 89(11): 3207-3217. [16] Tan Y, Pan Z, Liu J, et al. Experimental study of impact of anisotropy and heterogeneity on gas flow in coal. Part I: Diffusion and adsorption[J]. Fuel, 2018, 232(15): 444-453. [17] 李志强,成墙,刘彦伟,等.柱状煤芯瓦斯扩散模型与扩散特征实验研究[J].中国矿业大学学报,2017,46(5):1033-1040. LI Zhiqiang, CHENG Qiang, LIU Yanwei, et al. Research on gas diffusion model and experimental diffusion characteristic of cylindrical coal[J]. Journal of China University of Mining & Technology, 2017, 46(5): 1033-1040.
计量
- 文章访问数: 46
- HTML全文浏览量: 0
- PDF下载量: 29
下载:
