Characteristics of Nanometer Pore Structure in Coal Reservoir
-
摘要: 研究煤复杂发育的孔隙结构对揭示煤层气体赋存机理及扩散运移规律有重要意义.为了研究煤的纳米孔隙结构,利用SEM、液氮吸附、小角X射线研究了不同煤阶煤的纳米孔隙在形式和分布上的非均匀性.实验煤样煤基质中的孔呈多峰分布,且孔径范围主要集中在2~10 nm.煤样低温液氮吸附实验测得煤样的吸附量为3.676 cm3/g,煤样的比表面积为1.416 m2/g.以最可几孔径作为研究对象,在实验压力范围内,吸附压力越大,最可几孔径变大的越多;瓦斯气体在纳米级孔隙结构中的扩散模式以过渡型扩散为主,微孔更发达的煤样中,扩散更接近Knudsen型扩散,中孔更发达的煤样中,扩散更接近Fick型扩散;Knudsen数与温度呈负相关关系,温度高于250 K后,Knudsen数趋于稳定,与压强呈正相关关系,压强越大,扩散越容易.Abstract: In order to study the characteristics of nanometer pore structure of coal, the heterogeneous structures of nano pores of different rank coals were investigated by using SEM, liquid nitrogen adsorption and small angle X ray. It is found that the mesopore shows the multimodal division, mainly concentrated in the 2-10 aperture and nm. The adsorption capacity of coal low-temperature nitrogen adsorption experiments of coal samples is 3.676 cm3/g, and coal sample surface area is 1.416 m2/g. By analyzing the most probable aperture, the range of experimental pressure can be found out, and the most probable pore size will be increased with the adsorbent pressure. Gas diffusion model in most nanoscale pore structure model prefers coals mainly concentrated on transitional diffusion. In more developed microporous coal samples (anthracite), the diffusion type is closer to the Knudsen diffusion. In much less developed coal samples, the main diffusion type is closer to Fick diffusion. The Knudsen number is negatively related to temperature, and Knudsen number tends to be stable when the temperature is higher than 250 K, which is positively correlated with the pressure. The diffusion will be easier with the increase of pressure.
-
Key words:
- pore structure /
- diffusion model /
- Knudsen number /
- small-angle x-ray scattering
-
图 2 不同煤样的低温液氮等温吸附解吸曲线
Fig. 2. Adsorption/desorption isotherms of different coal samples
图 3 煤样电镜扫描图像
a.1#煤样;b.2#煤样;c.3#煤样;d.4#煤样;e.5#煤样
Fig. 3. SEM images of different coal samples
图 8 不同压力、温度条件下Knudsen数随孔径变化
Fig. 8. The change of Knudsen number with pore diameter in different pressures and temperatures
表 1 实验煤样煤质分析结果
Table 1. Coal quality analysis data of experimental coal samples
煤样编号 采样地点 水分含量(%) 干基挥发分(%) 干基灰分(%) 固定碳(%) 1# 润宏3# 2.015 12.510 16.965 73.615 2# 常村3# 0.730 14.670 6.180 78.580 3# 东曲9# 0.460 16.450 7.900 75.310 4# 官地3# 0.820 13.310 11.050 75.480 5# 凤凰山9# 0.915 14.550 7.265 77.600 
下载: 导出CSV
表 2 煤样比表面积和孔容及其比例、吸附能
Table 2. Specific surface area & pore volume, size distribution and adsorption energy of coal samples
煤样
编号孔容
(mL·g-1)比表面积
(m2·g-1)N2吸附量
(mL·g-1)各孔径段孔容比(%) 各孔径段比表面积比(%) 微孔平均
孔径(nm)吸附能
(kJ/mol)< 10 nm 10~30 nm >30 nm < 10 nm 10~30 nm >30 nm 1# 0.002 1.810 1.335 3.830 35.970 60.200 91.940 7.100 0.960 2.389 10.883 2# 0.002 0.580 1.083 3.520 20.930 75.500 89.640 7.390 2.970 2.759 9.425 3# 0.006 2.260 3.962 8.700 23.000 68.300 85.320 10.940 3.740 3.134 8.296 4# 0.002 0.790 1.145 3.620 18.180 78.200 86.660 9.270 4.070 2.677 9.713 5# 0.002 0.620 1.580 1.540 20.190 78.270 79.890 14.230 5.880 2.209 11.770
下载: 导出CSV
-
Alexeev, A.D., Vasilenko, T.A., Ulyanova, E.V., 1999.Closed Porosity in Possil Coals.Fuel, 78(6):635-638. doi: 10.1016/S0016-2361(98)00198-7 Chen, P., Tang, X.Y., 2001.The Research on the Adsorption of Nitrogen in Low Temperature and Micro-Pore Properties in Coal.Journal of China Coal Society, 26(5):552-556 (in Chinese with English abstract). http://en.cnki.com.cn/Article_en/CJFDTOTAL-MTXB200602006.htm He, X.Q., Nie, B.S., 2001.Diffusion Mechanism of Porous Gases in Coal Seams.Journal of China University of Mining & Technology, 30(1):1-4 (in Chinese with English abstract). http://cat.inist.fr/?aModele=afficheN&cpsidt=6980085 Kang, Y.L., Huang, F.S., You, L.J., et al., 2016.Impact of Fracturing Fluid on Multiscale Mass Transport in Coalbed Methane Reservoirs.International Journal of Coal Geology, 154-155:123-135. https://www.sciencedirect.com/science/article/pii/S0166516216300015#! Lastoskie, C., Gubbins, K.E., Quirke, N., 1993.Pore Size Heterogeneity and the Carbon Slit Pore:A Density Functional Theory Model.Langmuir, 9(10):2693-2702. doi: 10.1021/la00034a032 Li, H.Y., Ogawa, Y., Shimada, S., 2003.Mechanism of Methane Flow through Sheared Coals and Its Role on Methane Recovery.Fuel, 82(10):1271-1279. doi: 10.1016/S0016-2361(03)00020-6 Li, Z., 2013.A Program for SAXS Data Processing and Analysis.Chinese Physics C, 37(10):112-117. https://arxiv.org/pdf/1307.0358 Li, Z., Wu, Z., Mo, G., et al., 2014.Small Angle X-Ray Scattering Station at Beijing Synchrotron Radiation Facility.Instrumentation Science and Technology, 42(2):128-141. doi: 10.1080/10739149.2013.845845 Liu, Y., Wilcox, J., 2012.Molecular Simulation of CO2 Adsorption in Micro-and Mesoporous Carbons with Surface Heterogeneity.International Journal of Coal Geology, 104:83-95. doi: 10.1016/j.coal.2012.04.007 Lu, J., Shao, L.Y., Yang, M, F., et al., 2017.Depositional Model for Peat Swamp and Coal Facies Evolution Using Sedimentology, Coal Macerals, Geochemistry and Sequence Stratigraphy.Journal of Earth Science, 28(6):1163-1177. doi: 10.1007/s12583-016-0942-7 Nie, B.S., Duan, S.M., 1998.The Adsorption Essence of Gas on Coal Surface.Journal of Taiyuan University of Technology, 29(4):417-421 (in Chinese with English abstract). http://ro.uow.edu.au/cgi/viewcontent.cgi?article=2028&context=coal Nie, B.S., Liu, X.F., Guo, J.H., et al., 2015.Effect of Moisture on Gas Desorption and Diffusion in Coal Mass.Journal of China University of Mining & Technology, 44(5):781-787 (in Chinese with English abstract). https://www.deepdyve.com/lp/elsevier/effects-of-matrix-moisture-on-gas-diffusion-and-flow-in-coal-CQjRh88kJa Nie, B.S., Liu, X.F., Yuan, S.F., et al., 2016.Sorption Charateristics of Methane among Various Rank Coals:Impact of Moisture.Adsorption, 22(3):315-325. doi: 10.1007/s10450-016-9778-9 Wang, P.F., Jiang, Z.X., Li, Z., et al., 2017.Micro-Nano Pore Structure Characteristics in the Lower Cambrian Niutitang Shale, Northeast Chongqing.Earth Science, 42(7):1147-1156 (in Chinese with English abstract). https://doi.org/10.3799/dqkx.2017.093 Yang, Y.F., Wang, C.C., Yao, J., et al., 2016.A New Method for Microscopic Pore Structure Analysis in Shale Matrix.Earth Science, 41(6):1067-1073 (in Chinese with English abstract). https://doi.org/10.3799/dqkx.2016.088 Zhang, H., 2001.Genetical Type of Proes in Coal Reservoir and its Research Significance.Journal of China Coal Society, 26(1):40-44 (in Chinese with English abstract). http://en.cnki.com.cn/Article_en/CJFDTOTAL-MTXB200602006.htm 陈萍, 唐修义, 2001.低温氮吸附法与煤中微孔隙特征的研究.煤炭学报, 26(5):552-556. http://industry.wanfangdata.com.cn/yj/Detail/Periodical?id=Periodical_mtxb200105023 何学秋, 聂百胜, 2001.孔隙气体在煤层中扩散的机理.中国矿业大学学报, 30(1):1-4. http://www.cnki.com.cn/Article/CJFDTOTAL-ZGKD200101000.htm 聂百胜, 段三明, 1998.煤吸附瓦斯的本质.太原理工大学学报, 29(4):417-421. http://www.cnki.com.cn/Article/CJFDTOTAL-TYGY804.026.htm 聂百胜, 柳先锋, 郭建华, 等, 2015.水分对煤体瓦斯解吸扩散的影响.中国矿业大学学报, 44(5):781-787. https://www.researchgate.net/profile/Baisheng_Nie/publication/283765087_Effect_of_moisture_on_gas_desorption_and_diffusion_in_coal_mass/links/565edcfd08aefe619b273ffb.pdf?origin=publication_detail 王朋飞, 姜振学, 李卓, 等, 2017.渝东北下寒武统牛蹄塘组页岩微纳米孔隙结构特征.地球科学, 42(7):1147-1156. http://www.earth-science.net/WebPage/Article.aspx?id=3603 杨永飞, 王晨晨, 姚军, 等, 2016.页岩基质微观孔隙结构分析新方法.地球科学, 41(6):1067-1073. doi: 10.11764/j.issn.1672-1926.2016.06.1067 张慧, 2001.煤孔隙的成因类型及其研究.煤炭学报, 26(1):40-44. http://cdmd.cnki.com.cn/Article/CDMD-10290-1013030104.htm -
点击查看大图
图(9) / 表(2)
计量
- 文章访问数: 6409
- HTML全文浏览量: 2478
- PDF下载量: 42
- 被引次数: 0
