页岩无机孔和有机孔的渗透率计算方法

doi:10.3969/j.issn.1006-6535.2024.04.016

特种油气藏 ›› 2024, Vol. 31 ›› Issue (4): 126-132.DOI: 10.3969/j.issn.1006-6535.2024.04.016

页岩无机孔和有机孔的渗透率计算方法

李亚军, 李惊鸿, 桑茜, 董明哲, 崔传智

中国石油大学(华东),山东青岛 266580

收稿日期:2023-04-17 修回日期:2024-05-29 出版日期:2024-08-25 发布日期:2024-09-20
通讯作者: 李惊鸿(1999—),男,2022年毕业于中国石油大学(华东)石油工程专业,现为该校油气田开发工程专业在读硕士研究生,现主要从事页岩油渗流机理以及CO₂驱油埋存技术等方向的研究。
作者简介:李亚军(1984—),男,副教授,2006年毕业于中国石油大学(华东)信息与计算科学专业,2011年毕业于该校油气田开发工程专业,获博士学位,现主要从事油气田开发理论及复杂介质渗流理论方面的研究。
基金资助:
国家自然科学基金 “陆相页岩油流动机理与有效开发方式”(42090024);山东省自然科学基金“页岩油藏孔隙结构表征及微尺度效应对流动的影响机制”(ZR2019QEE037)

A Method for Calculating the Permeability of Inorganic and Organic Pores in Shale

Li Yajun, Li Jinghong, Sang Qian, Dong Mingzhe, Cui Chuanzhi

China University of Petroleum (East China), Qingdao, Shandong 266580, China

Received:2023-04-17 Revised:2024-05-29 Online:2024-08-25 Published:2024-09-20

摘要/Abstract

摘要： 针对页岩储层无机孔隙和有机孔隙共存的问题,运用双重连续介质方法,结合油相和水相在页岩无机孔隙和有机孔隙中的润湿性和渗流特征,得到油相和水相在页岩中的渗流数学模型。基于该模型拟合页岩油水自吸实验结果,分别得到了页岩的无机孔渗透率和有机孔渗透率,实现了对页岩储层含油量的准确计算,研究了页岩渗流过程的动态特征和影响规律。结果表明:无机孔渗透率为10^-8~10^-5 D,有机孔渗透率为10^-10~10^-7 D;随无机孔渗透率、有机孔渗透率的增加,页岩自吸速率加快;当有机孔渗透率与无机孔渗透率比值小于10^-3时,有机孔渗透率对自吸速率的影响不显著。研究成果对页岩储层渗透率和储量的精细评价具有重要指导意义。

关键词: 页岩, 双重连续介质, 无机孔渗透率, 有机孔渗透率, 储量评价

Abstract: In order to address the coexistence of inorganic and organic pores in shale reservoirs, a dual-continuum approach was developed to establish a percolation mathematical model for the flow of oil and water phases in shale. This model takes into consideration the wetting and flow characteristics of oil and water phases within both inorganic and organic pores in shale. By employing the proposed model, we obtained matching results from oil-water spontaneous imbibition experiments conducted on shale and determined both the inorganic and organic pore permeability, facilitating accurate calculation of oil content within shale reservoirs. Furthermore, a comprehensive study was carried out to investigate the dynamic characteristics and influential laws of the permeation process in shale. The study results indicate that the permeability of inorganic pores ranges from 10^-8 to 10^-5 D, while that of organic pores ranges from 10^-10 to 10^-7 D. As the permeability through inorganic pores increases, the rate of spontaneous imbibition in shale also increases. However, when the ratio of organic pore permeability to inorganic pore permeability is less than 10^-3, the impact of organic pore permeability on self-imbibition rate is insignificant. These findings have significant implications for a thorough assessment of permeability and reserves in shale reservoirs.

Key words: shale, dual-continuum media, inorganic pore permeability, organic pore permeability, reserve evaluation

中图分类号:

TE312

李亚军, 李惊鸿, 桑茜, 董明哲, 崔传智. 页岩无机孔和有机孔的渗透率计算方法[J]. 特种油气藏, 2024, 31(4): 126-132.

Li Yajun, Li Jinghong, Sang Qian, Dong Mingzhe, Cui Chuanzhi. A Method for Calculating the Permeability of Inorganic and Organic Pores in Shale[J]. Special Oil & Gas Reservoirs, 2024, 31(4): 126-132.

参考文献

[1] 张金川,林腊梅,李玉喜,等.页岩油分类与评价[J].地学前缘,2012,19(5):322-331.
ZHANG Jinchuan,LIN Lamei,LI Yuxi,et al.Classification and evaluation of shale oil[J].Earth Science Frontiers,2012,19(5):322-331.
[2] BUSTIN A M M,BUSTIN R M.Importance of rock properties on the producibility of gas shales[J].International Journal of Coal Geology,2012,103(1):132-147.
[3] 董明哲,李亚军,桑茜,等.页岩油流动的储层条件和机理[J].石油与天然气地质,2019,40(3):636-644.
DONG Mingzhe,LI Yajun,SANG Qian,et al.Reservoir conditions and mechanism of shale oil flow[J].Oil & Gas Geology,2019,40(3):636-644.
[4] CURTIS M E,SONDERGELD C H,AMBROSE R J,et al.Microstructural investigation of gas shales in two and three dimensions using nanometer-scale resolution imaging[J].AAPG Bulletin,2012,96(4):665-677.
[5] CHALMERS G R,BUSTIN R M,POWER I M.Characterization of gas shale pore systems by porosimetry,pycnometry,surface area,and field emission scanning electron microscopy/transmission electron microscopy image analyses:examples from the Barnett,Woodford,Haynesville,Marcellus,and Doig units[J].AAPG bulletin,2012,96(6):1099-1119.
[6] LOUCKS R G,REED R M,RUPPEL S C,et al.Spectrum of pore types and networks in mudrocks and a descriptive classification for matrix-related mudrock pores[J].AAPG Bulletin,2012,96(6):1071-1098.
[7] CAMP W K.Pore-throat sizes in sandstones,tight sandstones,and shales:discussion[J].AAPG Bulletin,2011,95(8):1443-1447.
[8] YUAN W,PAN Z,LI X, et al.Experimental study and modelling of methane adsorption and diffusion in shale[J].Fuel,2014,117:509-519.
[9] LOPEZ JIMENEZ B A,AGUILERA R.Petrophysical quantification of multiple porosities in shale-petroleum reservoirs with the use of modified pickett plots[J].SPE Reservoir Evaluation & Engineering,2018,21(1):187-201.
[10] SANG Qian,ZHANG Shaojie,LI Yajun,et al.Determination of organic and inorganic hydrocarbon saturations and effective porosities in shale using vacuum-imbibition method[J].International Journal of Coal Geology,2018,200(1):123-134.
[11] 刘毅,陆正元,戚明辉,等.渤海湾盆地沾化凹陷沙河街组页岩油微观储集特征[J].石油实验地质,2017,39(2):180-185.
LIU Yi,LU Zhengyuan,QI Minghui,et al.Microscopic characteristics of shale oil reservoirs in Shahejie Formation in Zhanhua Sag,Bohai Bay Basin[J].Petroleum Geology & Experiment,2017,39(2):180-185.
[12] ZHU C,GUO W,LI Y,et al.Effect of occurrence states of fluid and pore structures on shale oil movability[J].Fuel,2021,288:119847.
[13] BURNHAM A K.Porosity and permeability of Green River oil shale and their changes during retorting[J].Fuel,2017,203:208-213.
[14] 郑欢.自发渗吸和压力驱动作用下的双重介质模型窜流函数研究[D].合肥:中国科学技术大学,2020.
ZHENG Huan.Study on the interporosity flow function of dual porosity model under spontaneous imbibition and pressure drive[D].Hefei:University of Science and Technology of China,2020.
[15] 张建国,杜殿发.油气层渗流力学[M].东营:中国石油大学出版社,2008:44-46.
ZHANG Jianguo,DU Dianfa.Percolation mechanics of oil and gas reservoir[M].Dongying:China University of Petroleum Press,2008:44-46.
[16] 张喜淳,胡晨林,田继军,等.川南ZX向斜五峰组—龙马溪组页岩孔隙特征及差异性[J].断块油气田,2022,29(4):469-474.
ZHANG Xichun,HU Chenlin,TIAN Jijun,et al.Characteristics and differences of shale pores in Wufeng-Longmaxi Formation of ZX syncline, southern Sichuan Basin[J].Fault-Block Oil and Gas Field,2022,29(4):469-474.
[17] 刘思琦,李晓松,李金池.松辽盆地南部洼槽下白垩统泥页岩孔隙发育特征及其控制因素[J].大庆石油地质与开发,2022,41(1):23-32.
LIU Siqi,LI Xiaosong,LI Jinchi.Pore development characteristics and controlling factors of Lower Cretaceous mud shale in the troughs of south Songliao Basin[J].Petroleum Geology & Oilfield Development in Daqing,2022,41(1):23-32.

页岩无机孔和有机孔的渗透率计算方法

A Method for Calculating the Permeability of Inorganic and Organic Pores in Shale

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