基于等效介质理论的页岩声波数值模拟方法研究

doi:10.3969/j.issn.1006-6535.2023.03.008

特种油气藏 ›› 2023, Vol. 30 ›› Issue (3): 63-72.DOI: 10.3969/j.issn.1006-6535.2023.03.008

基于等效介质理论的页岩声波数值模拟方法研究

李贤胜¹, 邱小雪², 陈明江¹, 李玮³, 刘向君³, 杨孛¹

1.中国石油川庆钻探工程有限公司,四川成都 610051;
2.中国石油西南油气田分公司,四川成都 610051;
3.西南石油大学,四川成都 610500

收稿日期:2022-05-23 修回日期:2023-03-08 出版日期:2023-06-25 发布日期:2023-07-13
通讯作者: 刘向君(1969—),女,教授,博士生导师,1990年毕业于西南石油学院石油勘探专业,1995年毕业于该校地质资源与地质工程专业,获博士学位,现主要从事勘查地球物理及地质工程相关研究工作。
作者简介:李贤胜(1996—),男,助理工程师,2018年毕业于西南石油大学勘查技术与工程专业,2021年毕业于该校地质资源与地质工程专业,获硕士学位,现主要从事测井资料处理与解释工作。
基金资助:
国家自然科学基金“压敏性横观各向同性介质中超声脉冲传播机制及动态弹性刚度系数测试方法研究”(420004124)

A Numerical Simulation Method for Shale Acoustic Wave Based on Equivalent Medium Theory

Li Xiansheng¹, QiuXiaoxue², Chen Mingjiang¹, Li Wei³, Liu Xiangjun³, Yang Bei¹

1. CNPC Chuanqing Drilling Engineering Co., Ltd., Chengdu, Sichuan 610051, China;
2. PetroChina Southwest Oil & Gas Field Company, Chengdu, Sichuan 610051, China;
3. Southwest Petroleum University, Chengdu, Sichuan 610500, China

Received:2022-05-23 Revised:2023-03-08 Online:2023-06-25 Published:2023-07-13

摘要/Abstract

摘要： 声波数值模拟对于页岩各向异性特征研究及大斜度井页岩声波校正研究均有着十分重要的意义。为了研究页岩声波各向异性特征,基于等效介质理论构建了由泥质层、砂质层组成的页岩等效模型,从弹性理论出发,推导出等效页岩模型刚度系数、声波波速计算方法,分析了纹层弹性参数、纹层厚度、纹层角度、纹层密度等对等效页岩模型刚度系数和弹性波速的影响。研究表明:泥质层与砂质层厚度比会影响等效介质刚度系数;等效页岩模型刚度系数值随弹性参数比的增加而增加;泥质层的拉梅系数会影响纵波波速与纹层角度关系、横波波速极值,对SH波没有影响;声波波速随泥质层的剪切模量或弹性参数比的增加逐渐增加,且剪切模量对3种波速与纹层角度的关系均有较大影响;纹层密度一定时,随着纹层角度增加,纵波波速逐渐降低并趋于稳定,横波波速先增加后降低,SH波速逐渐降低;纹层角度一定时,3种波速均随纹层密度的增加逐渐降低。研究结果对页岩声波数值模拟方法及声波测井校正方法具有指导意义。

关键词: 等效介质理论, 页岩模型, 纹层厚度, 纹层弹性参数, 声波波速, 数值模拟

Abstract: Numerical simulation of acoustic wave is very important for the study of anisotropy characteristics of shale and the study of shale acoustic wave correction in highly inclined well. In order to study the anisotropic characteristics of shale acoustic wave, an equivalent shale model composed of argillaceous and sand layers was established on the basis of equivalent medium theory, the calculation methods of the stiffness coefficient and acoustic wave velocity of the equivalent shale model were derived from the elasticity theory, and the influences of the elastic parameter, thickness, angle and density of the lamina on the stiffness coefficient and the elastic wave velocity of the equivalent shale model were analyzed. The study shows that the thickness ratio of argillaceous layer to sandy layer affected the stiffness coefficient of equivalent medium. The stiffness coefficient of equivalent shale model increased with the increase of parameter ratio. Lamet coefficient of argillaceous layer affected the relationship between P-wave velocity and lamina angle and the extreme value of S-wave velocity, but had no effect on SH wave. The acoustic wave velocity was increased with the increase of shear modulus or parameter ratio of the argillaceous layer, and the shear modulus had a great effect on the relationship between the three wave velocities and the lamina angle. When the lamina density was constant, the P-wave velocity was decreased gradually and stabilized with the increase of lamina angle, the S-wave velocity increased first and then decreased, and the SH wave velocity decreased gradually. When the lamina angle was constant, the three wave velocities were decreased gradually with the increase of lamina density. This study plays a guiding role in the shale acoustic numerical simulation and acoustic logging correction.

Key words: equivalent medium theory, shale model, lamina thickness, lamina elastic parameters, acoustic wave velocity, numerical simulation

中图分类号:

TE132.8

李贤胜, 邱小雪, 陈明江, 李玮, 刘向君, 杨孛. 基于等效介质理论的页岩声波数值模拟方法研究[J]. 特种油气藏, 2023, 30(3): 63-72.

Li Xiansheng, QiuXiaoxue, Chen Mingjiang, Li Wei, Liu Xiangjun, Yang Bei. A Numerical Simulation Method for Shale Acoustic Wave Based on Equivalent Medium Theory[J]. Special Oil & Gas Reservoirs, 2023, 30(3): 63-72.

参考文献

[1] 王龙,张金川,唐玄.鄂尔多斯盆地下寺湾—云岩地区长7段页岩气测井评价与分布规律研究[J].中国石油勘探,2019,24(1):129-136.
WANG Long,ZHANG Jinchuan,TANG Xuan.Logging evaluation and distribution law of Chang7 shale gas in Xiasiwan-Yunyan Area,Ordos Basin[J].China Petroleum Exploration,2019,24(1):129-136.
[2] 张晋言,李淑荣,王利滨,等.页岩气测井电性解析及含气性评价——以四川盆地涪陵地区龙马溪组一段—五峰组为例[J].天然气勘探与开发,2018,41(3):33-41.
ZHANG Jinyan,LI Shurong,WANG Libin,et al.Electrical-logging analysis and evaluation on gas-bearing property of shale gas:an example from Longmaxi 1 Member-Wufeng Formation,Fuling Area,Sichuan Basin[J].Natural Gas Exploration and Development,2018,41(3):33-41.
[3] 杨小兵,齐宝权,张洪涛,等.应用测井资料聚焦海相页岩气甜点小层[J].测井技术,2020,44(3):256-261.
YANG Xiaobing,QI Baoquan,ZHANG Hongtao,et al.Application of log data to focus on sweet spots of marine shale gas[J].Well Logging Technology,2020,44(3):256-261.
[4] 舒红林,仇凯斌,李庆飞,等.页岩气地质力学特征评价方法——中国南方海相强改造区山地页岩地质力学特征[J].天然气工业,2021,41(增刊1):1-13.
SHU Honglin,QIU Kaibin,LI Qingfei,et al.A method for evaluating the geomechanical characteristics of shale gas:thegeomechanical characteristics of the mountain shale in the intensively reworked marine area of south China[J].Natural Gas Industry,2021,41(S1):1-13.
[5] SAYERS C,BOER L,DASGUPTA S,et al.Anisotropy estimate for the Horn River Basin from sonic logs in vertical and deviated wells[J].Special Section:Borehole geophysics and sonic logging,2015,34(3):296-306.
[6] HORNE S,WALSH J.Researchnote:transverse isotropy estimation from dipole sonic logs acquired in pilot and production wells[J].Geophysical Prospecting,2014,62(2):404-411.
[7] MILLER D,HORNE S,WALSH J.Precise inversion of logged slownesses for elastic parameters in a gas shale formation[J].Geophysics,2012,77(4):B197-B206.
[8] 谢剑勇,魏建新,狄帮让,等.页岩各向异性参数间关系及其影响因素分析[J].石油地球物理勘探,2015,50(6):1141-1145.
XIE Jianyong,WEI Jianxin,DI Bangrang,et al.Correlation of shale anisotropic parameters and their influence factors[J].Oil Geophysical Prospecting,2015,50(6):1141-1145.
[9] JIANG Guanghui,ZUO Jianping,LI Yulin,et al.Experimental investigation on mechanical and acoustic parameters of different depth shale under the effect of confining pressure[J].Rock Mechanics and Rock Engineering,2019,52(11):4273-4286.
[10] 伍宇明,兰恒星,黄为清.龙马溪页岩弹性各向异性与矿物分布之间的关系探讨[J].地球物理学报,2020,63(5):1856-1866.
WU Yuming,LAN Hengxing,HUANG Weiqing.Discussion on the relationship between elastic anisotropy and mineral distribution of Longmaxi shale[J].Chinese Journal of Geophysics,2020,63(5):1856-1866.
[11] 李贤胜,刘向君,熊健,等.层理对页岩纵波特性的影响[J].岩性油气藏,2019,31(3):152-160.
LI Xiansheng,LIU Xiangjun,XIONG Jian,et al.Influence of bedding on compressional wave characteristics of shales[J].Lithologic Reservoirs,2019,31(3):152-160.
[12] 熊健,梁利喜,刘向君,等.川南地区龙马溪组页岩岩石声波透射实验研究[J].地下空间与工程学报,2014,10(5):1071-1077.
XIONG Jian,LIANG Lixi,LIU Xiangjun,et al.Experimental study on acoustic penetration through the Longmaxi Formation shale rock in south region of Sichuan Basin[J].Chinese Journal of Underground Space and Engineering,2014,10(5):1071-1077.
[13] 陈乔,刘向君,刘洪,等.层理性页岩地层超声波透射实验[J].天然气工业,2013,33(8):140-144.
CHEN Qiao,LIU Xiangjun,LIU Hong,et al.An experimental study of ultrasonic penetration through bedding shale reservoirs[J].Natural Gas Industry,2013,33(8):140-144.
[14] 王小琼,葛洪魁,申颍浩.富有机质页岩波速各向异性的研究进展[J].特种油气藏, 2013, 20(6): 1-5, 39.
WANG Xiaoqiong,GE Hongkui,SHEN Yinghao.Research progress of wave velocity anisotropy in organic-rich shale[J].Special Oil & Gas Reservoirs, 2013, 20(6): 1-5, 39.
[15] WOLLNER U,MAVKO G.Brown and korringa constants for heterogeneous thinly layered poroelastic media[J]. Journal of Geophysical Research: Solid Earth, 2017, 22(2): 895-905.
[16] STOVAS A, ROGANOV Y, DUFFAUT K, et al. Low-frequency layer-induced anisotropy[J]. Geophysics, 2013, 78(5): 3-14.
[17] KOVALYSHEN Y, SAROUT J, LEBEDEV M. On the interpretation of ultrasonic laboratory measurements in anisotropic media[J]. Geophysics, 2018, 83(4):173-178.
[18] YAN F, VERNIK L, HAN D. Relationship between the anisotropy parameters for transversely isotropic mudrock[J]. Geophysics, 2019, 84(6): 195-203.
[19] 段茜,刘向君,梁利喜,等.裂缝参数对纵波各向异性影响的数值模拟[J].石油地球物理勘探,2020,55(3):575-583,590.
DUAN Xi,LIU Xiangjun,LIANG Lixi,et al.Numerical simulation to the influence of fracture parameters on P-wave anisotropy[J].Oil Geophysical Prospecting,2020,55(3):575-583,590.
[20] 李盛清,林剑松,江灿,等.随钻声波测井固井质量评价理论与数值模拟研究[J].地球物理学报,2020,63(7):2762-2773.
LI Shengqing,LIN Jiansong,JIANG Can,et al.Theoretical and numerical simulation of LWD acoustic cement logging[J].Chinese Journal of Geophysics,2020,63(7):2762-2773.
[21] 陈乔,刘向君,梁利喜,等.裂缝模型声波衰减系数的数值模拟[J].地球物理学报,2012,55(6):2044-2052.
CHEN Qiao,LIU Xiangjun,LIANG Lixi,et al.Numerical simulation of the fractured model acoustic attenuation coefficient[J].Chinese Journal of Geophysics,2012,55(6):2044-2052.
[22] 张卓,袁晓俊,饶大骞,等.页岩气多尺度渗流数值模拟技术——以昭通国家级页岩气示范区为例[J].天然气工业,2021,41(增刊1):145-151.
ZHANG Zhuo,YUAN Xiaojun,RAO Daqian,et al.A numerical simulation technology for the multi-scale flow of shale gas and its application in Zhaotong National Shale Gas Demonstration Area[J].Natural Gas Industry,2021,41(S1):145-151.
[23] 徐荣利,郭天魁,曲占庆,等.基于离散裂缝模型的页岩油储层压裂渗吸数值模拟[J].工程科学学报,2022,44(3):451-463.
XU Rongli,GUO Tiankui,QU Zhanqing,et al.Numerical simulation of fractured imbibition in a shale oil reservoir based on the discrete fracture model[J].Chinese Journal of Engineering,2022,44(3):451-463.
[24] 咸玉席,陈超峰,封猛,等.页岩油藏裂缝网络多相渗流数值模拟研究[J].石油钻探技术,2021,49(5):94-100.
XIAN Yuxi,CHEN Chaofeng,FENG Meng,et al.Numerical simulation of multiphase flow in fracture networks in shale oil reservoir[J].Petroleum Drilling Techniques,2021,49(5):94-100.
[25] 李萧,吴礼明,王丙贤,等.渝东南地区龙马溪组构造应力场数值模拟及裂缝有利区预测[J].地质科技通报,2021,40(6):24-31.
LI Xiao,WU Liming,WANG Bingxian,et al.Numerical simulation of tectonic stress field and prediction of fracture target in the Longmaxi Formation,southeastern Chongqing[J].Bulletin of Geological Science and Technology,2021,40(6):24-31.
[26] 贾庆升,钟安海,张子麟,等.济阳坳陷泥灰质纹层页岩脆性各向异性数值模拟研究[J].石油钻探技术,2021,49(4):78-84.
JIA Qingsheng,ZHONG Anhai,ZHANG Zilin,et al.Numerical simulation of the brittleness anisotropy of laminated argillaceous limestone facies shale in the Jiyang Depression[J].Petroleum Drilling Techniques,2021,49(4):78-84.
[27] 徐烽淋,陈乔,朱洪林,等.页岩层理结构对超声波特性响应分析及应用[J].石油勘探与开发,2019,46(1):79-88.
XU Fenglin,CHEN Qiao,ZHU Honglin,et al.Response analysis of shale bedding structure to ultrasonic characteristics and its application[J].Petroleum Exploration and Development,2019,46(1):79-88.
[28] 陈乔,徐烽淋,程亮,等.基于黏弹性介质波动理论的页岩超声波数值模拟[J].天然气工业,2019,39(6):63-70.
CHEN Qiao,XU Fenglin,CHENG Liang,et al.Shale ultrasonic numerical simulation based on the viscoelastic medium wave theory[J].Natural Gas Industry,2019,39(6):63-70.
[29] 胡松,王敏,刘伟男,等.页岩水平井声波时差各向异性校正方法及其应用[J].石油学报,2022,43(1):58-66.
HU Song,WANG Min,LIU Weinan,et al.Anisotropy correction method for acoustic time difference in horizontal shale wells and its application[J].ActaPetrolei Sinica,2022,43(1):58-66.
[30] 刘双莲.页理对测井响应及岩石力学参数影响分析[J].非常规油气,2019,6(4):1-5.
LIU Shuanglian.Effect analysis of shale bedding on well logging response and rock mechanics parameters[J].Unconventional Oil & Gas,2019,6(4):1-5.

基于等效介质理论的页岩声波数值模拟方法研究

A Numerical Simulation Method for Shale Acoustic Wave Based on Equivalent Medium Theory

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	程林松, 杨晨旭, 曹仁义, 贾品, 蒲保彪, 时俊杰. 注水诱导裂缝动态特征及数值模拟研究[J]. 特种油气藏, 2023, 30(5): 84-90.
[2]	张亚雄, 吕心瑞. 基于控制单元的大尺度离散裂缝降维数值模拟方法[J]. 特种油气藏, 2023, 30(5): 98-104.
[3]	崔传智, 王俊康, 吴忠维, 隋迎飞, 李静, 陆水青山. 致密油藏压驱动态裂缝模型建立及应用[J]. 特种油气藏, 2023, 30(4): 87-95.
[4]	吴建发, 朱维耀, 张德良, 陈震, 吴天鹏. 页岩气藏两相流固耦合无网格数值模拟[J]. 特种油气藏, 2023, 30(4): 96-103.
[5]	宋保建, 李景全, 孙宜丽, 张薇, 刘鹏. 致密油藏CO₂吞吐参数优化数值模拟研究[J]. 特种油气藏, 2023, 30(4): 113-121.
[6]	曹长霄, 宋兆杰, 师耀利, 高阳, 郭佳, 常旭雅. 吉木萨尔页岩油二氧化碳吞吐提高采收率技术研究[J]. 特种油气藏, 2023, 30(3): 106-114.
[7]	雷梦, 屈亚光, 万翠蓉, 杨博, 何登辉, 马国庆, 巩旭. CO₂辅助重力驱油开发效果影响因素分析[J]. 特种油气藏, 2022, 29(6): 133-140.
[8]	于雪峰. 基于数值模拟的重力火驱特征分析与调控[J]. 特种油气藏, 2022, 29(5): 88-93.
[9]	孙同文, 王芳, 王有功, 李军辉, 姚诗华, 李冰妮, 成镱娜, 刘敏华. 海拉尔盆地贝西南地区南屯组油气侧向运移路径综合确定及运移模式探讨[J]. 特种油气藏, 2022, 29(4): 38-46.
[10]	张连进, 王俊杰, 庄小菊, 陈洋, 文雯, 兰雪梅, 陶佳丽. 川西北超深层复杂构造气藏裂缝建模方法及开发潜力预测[J]. 特种油气藏, 2022, 29(3): 98-103.
[11]	唐维宇, 黄子怡, 陈超, 丁振华, 盛家平, 王秀坤, 乐平. 吉木萨尔页岩油CO₂吞吐方案优化及试验效果评价[J]. 特种油气藏, 2022, 29(3): 131-137.
[12]	万晓龙, 王思仪, 郭西峰, 兰正凯. 基于应力敏感与基质收缩效应的低渗油藏数值模拟方法及应用[J]. 特种油气藏, 2022, 29(2): 110-114.
[13]	付青春. 三元复合驱吸附滞留规律[J]. 特种油气藏, 2022, 29(2): 115-121.
[14]	翟诚, 孙可明. 天然气水合物降压分解诱发储层变形破坏正交数值模拟实验研究[J]. 特种油气藏, 2022, 29(1): 99-106.
[15]	李伟, 肖阳, 陈明鑫, 刘会锋, 范文同, 黄龙藏, 彭芬, 曹科学. 深井转向压裂暂堵剂研究及应用[J]. 特种油气藏, 2022, 29(1): 154-159.