川南龙马溪组页岩储层水相渗吸规律

doi:10.19596/j.cnki.1001-246x.8313

计算物理 ›› 2021, Vol. 38 ›› Issue (5): 565-572.DOI: 10.19596/j.cnki.1001-246x.8313

所属专题：多孔介质毛细动力学研究

• 专题: 多孔介质毛细动力学研究 • 上一篇下一篇

川南龙马溪组页岩储层水相渗吸规律

郭建春¹(), 陶亮²^,*(), 陈迟¹, 赵玉航¹, 何颂根³, 刘彧轩¹

1. 西南石油大学油气藏地质及开发工程国家重点实验室，四川成都 610500
2. 中石油长庆油田分公司油气工艺研究院，陕西西安 710000
3. 中石化西南油气分公司石油工程技术研究院，四川德阳 618000

收稿日期:2020-11-30 出版日期:2021-09-25 发布日期:2022-03-24
通讯作者: 陶亮
作者简介:郭建春(1970-)，男，教授, 博士生导师，主要从事油气开采与储层改造理论与技术、非常规天然气开发等教学与研究工作, E-mail：guojianchun@vip.163.com
基金资助:
国家杰出青年科学基金(51525404);中国石油科技创新基金(2019D50070203)

Water Imbibition Law of Longmaxi Formation Shale in the South of Sichuan Basin

Jianchun GUO¹(), Liang TAO²^,*(), Chi CHEN¹, Yuhang ZHAO¹, Songgen HE³, Yuxuan LIU¹

1. State Key Laboratory of Oil & Gas Reservoir Geology and Exploitation in Southwest Petroleum University, Chengdu, Sichuan 610500, China
2. Oil and Gas Technology Research Institute Changqing Oilfield Company, PetroChina Company Limited, Xi'an, Shaanxi 710000, China
3. Petroleum Engineering Technology Institute of Southwest Oil & Gas Company, SINOPEC, Deyang, Sichuan 618000, China

Received:2020-11-30 Online:2021-09-25 Published:2022-03-24
Contact: Liang TAO

摘要/Abstract

摘要：

基于川南龙马溪组页岩多重孔隙特征，建立渗吸解析模型，定量计算不同孔隙类型渗吸深度。在此基础之上，开展考虑页岩储层温度、围压、流体压力共同作用下的水相渗吸实验，分析页岩水相渗吸规律。结果表明：基于渗吸饱和度渗吸过程可分为3个阶段：渗吸扩散段、渗吸过渡段、渗吸平衡段，其中渗吸扩散段为渗吸能力主要贡献段。在焖井初期由于流体压力作用页岩渗吸能力大幅度提高，为后续自发渗吸作用提供了渗吸液体。储层围压对页岩渗吸能力有抑制作用，但仍能提高储层改造效果，孔隙度增加倍数范围为0.42倍~1.63倍，渗透率增加倍数范围为17.6倍~67.3倍。黏土孔渗吸深度远大于脆性矿物孔和有机质孔，粘土矿物为页岩水化作用诱导微裂缝主控因素。焖井有利于提高川南龙马溪组页岩储层改造效果。研究成果可为页岩气井返排制度优化提供依据。

关键词: 页岩, 龙马溪组, 多重孔隙, 渗吸能力, 渗吸深度

Abstract:

Based on characteristics of multiple pores in the shale of Longmaxi formation (LF) in the south of Sichuan Basin, an analytical model of imbibition was established. Imbibition depths of different pore types were quantitatively calculated. Water imbibition experiments under conditions of formation temperature, confining pressure, and fluid pressure were carried out. Water imbibition law in shale was analyzed. It shows that according to imbibition saturation, the shale forcible imbibition can be divided into 3 periods. They are imbibition diffusion, imbibition transition and imbibition balance periods, respectrvely. Among them, the imbibition diffusion period is the main period for imbibition capacity rise. In the early period of shut-in, the imbibition capacity of shale increases significantly under the action of fluid pressure, providing a large amount of imbibition fluid for the spontaneous imbibition later. The reservoir confining pressure has prohibition on shale imbibition, but even under reservoir confining pressure, imbibition can improve fracturing effect of reservoir, resulting in the increase of porosity of 0.42-1.63 times and increase of permeability of 17.6-67.3 times. The imbibition depth of clay pore is much greater than that of brittle mineral pore and organic pore. Clay minerals are the main controlling factor of microfractures induced by shale hydration. An appropriate shut-in treatment enhances dramatically fracturing performance in shale gas reservoirs of LF in southern Sichuan Basin. The study provides scientific basis for the optimization of flowback regime of shale gas well.

Key words: shale, Longmaxi formation, multiple porosity, imbibition capacity, imbibition depth

中图分类号:

TE37

郭建春, 陶亮, 陈迟, 赵玉航, 何颂根, 刘彧轩. 川南龙马溪组页岩储层水相渗吸规律[J]. 计算物理, 2021, 38(5): 565-572.

Jianchun GUO, Liang TAO, Chi CHEN, Yuhang ZHAO, Songgen HE, Yuxuan LIU. Water Imbibition Law of Longmaxi Formation Shale in the South of Sichuan Basin[J]. Chinese Journal of Computational Physics, 2021, 38(5): 565-572.

图/表 10

图1 页岩样品电镜扫描结果

Fig.1 SEM images of shale samples

图2 多重孔隙物理模型

Fig.2 Multiple pore physical model

图3 椭圆管内层流示意图

Fig.3 Schematic of laminar flow in an elliptical tube

表1 岩样及测试流体基础参数

Table 1 Basic parameters of rock sample and test fluid

参数	数值
参数	有机孔	脆性矿物孔	黏土孔隙
长轴a/nm	89.2	163.3	81.7
短轴b/nm	46.7	61.7	22.4
水相润湿接触角θ/(°)	80.4	16.2	11.5
渗吸液黏度μ/(mPa·s)	1
表面张力σ/(mN/m)	74.1
半透膜效率E_x/(无因次)	0.577 5
地层水相摩尔浓度C_sh/(mol/L)	0.525
压裂液水相摩尔浓度C_f/(mol/L)	0.017
气体常数R/[L·Pa/(mol·K)]	8 314.5
实验温度T/K	293

图4 不同孔隙类型渗吸深度与时间的关系

Fig.4 Relations between imbibition depth and time of different pore types

表2 页岩样品基本参数

Table 2 Basic parameters of rock samples

岩心编号	长度/cm	直径/cm	渗吸面积/cm²	渗透率/mD	孔隙度/%
S1	5.0	2.5	4.9	0.002 7	4.9
S2	5.0	2.5	4.9	0.002 4	4.6
S3	5.0	2.5	4.9	0.002 6	5.0
S4	5.0	2.5	4.9	0.003 2	5.3

表3 页岩样品水相渗吸实验设计

Table 3 Experimental design for water imbibition of shale samples

岩心编号	影响因素	流体压力/MPa	围压/MPa	温度/℃
S1		2	12	80
S2	围压	2	14	80
S3		2	16	80
S4		0	0	25

图5 不同渗吸方式渗吸能力对比

Fig.5 Comparison of imbibition capacity of different imbibition methods

图6 不同页岩样品渗吸能力与时间的关系

Fig.6 Relations between imbibition capacity and time of shale samples

图7 页岩样品渗吸前后孔隙度和渗透率变化对比

Fig.7 Comparison of porosity and permeability of shale samples before and after imbibition

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川南龙马溪组页岩储层水相渗吸规律

Water Imbibition Law of Longmaxi Formation Shale in the South of Sichuan Basin

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