科技导报 >

2022 , Vol. 40 >Issue 20: 83 - 92

DOI: https://doi.org/10.3981/j.issn.1000-7857.2022.20.010

专题:深部地热储层增产技

干热岩储层水力压裂改造的电磁法监测评价研究进展

  • 黄若宸 ,
  • 舒彪 ,
  • 李帝铨
展开
  • 中南大学有色金属成矿预测与地质环境监测教育部重点实验室, 地球科学与信息物理学院, 长沙 410083
黄若宸,硕士研究生,研究方向为非常规能源电磁法应用,电子信箱:205012131@csu.edu.cn

收稿日期: 2022-09-08

  修回日期: 2022-10-13

  网络出版日期: 2022-11-15

基金资助

国家自然科学基金项目(42072304);湖南省科技创新计划项目(2021RC3009);湖南省自然科学基金青年基金项目(2021JJ40726)

收起

Research progress of electromagnetic monitoring and evaluation of hot dry rock hydraulic fracturing reservoir

  • HUANG Ruochen ,
  • SHU Biao ,
  • LI Diquan
Expand
  • Key Laboratory of Metallogenic Prediction of Nonferrous Metals and Geological Environment Monitoring, Ministry of Education;School of Geosciences and Info-physics, Central South University, Changsha 410083, China

Received date: 2022-09-08

  Revised date: 2022-10-13

  Online published: 2022-11-15

Fold

摘要

从岩石受压破裂过程电阻率特性、裂缝型岩石电阻率特性、岩石电阻率与渗透率关系3个方面出发,总结了电磁法水力压裂监测评价相关的岩石物性基础研究,介绍了干热岩水力压裂现场电磁法监测应用案例。基于岩石电性基础研究总结得出:岩石在受压破裂过程中会伴随着显著的电阻率变化,且电阻率变化特征与岩石中的含水饱和度紧密相关;裂缝数量、宽度与粗糙度等都会对岩石的电阻率产生影响,影响趋势与裂缝是否含水有关;可通过修正Archie定律与Kozeny-Carman模型建立特定岩石的电阻率与渗透率关系模型。讨论了电磁法应用干热岩水力压裂监测评价所面临的难点,包括:(1)研究高温高压条件裂缝型致密岩石的电阻率性质;(2)研究高温高压条件裂缝型致密岩石渗透率与电阻率关系模型;(3)研究开发具有更高精度、更小分辨率、更强抗干扰能力及更远探测距离的电磁法探测新理论新方法、新技术新装备。

关键词: 深部干热岩; 电阻率; 渗透率; 水力压裂; 电磁法监测

本文引用格式

黄若宸 , 舒彪 , 李帝铨 . 干热岩储层水力压裂改造的电磁法监测评价研究进展[J]. 科技导报, 2022 , 40(20) : 83 -92 . DOI: 10.3981/j.issn.1000-7857.2022.20.010

Abstract

The development of the hot dry rock is one of the important ways to achieve the goal of "double carbon". In the context of monitoring the hot dry rock reservoir with the electromagnetic method and establishing a scientific and efficient hot dry rock reservoir evaluation system, this paper reviews the basic researches of the rock physical properties related to the electromagnetic hydraulic fracturing monitoring and evaluation, focusing on three aspects, namely, the electrical resistivity characteristics of the rock in the process of fracturing under pressure, the electrical resistivity characteristics of the fractured rock, and the relationship between the rock electrical resistivity and permeability. The application cases of the electromagnetic monitoring in the field of the hot dry rock hydraulic fracturing are introduced. Based on the basic researches of the rock electrical properties, it is concluded that:the pressure fracturing will be accompanied by significant electrical resistivity changes of the rock, and the characteristics of the electrical resistivity changes are closely related to the water saturation in the rock; the number, the width and the roughness of the fractures will affect the electrical resistivity of the rocks, and the influence trend is related to whether the fractures contain the water; the relationship between the electrical resistivity and permeability of specific rocks can be established by modifying the Archie's law and the Kozeny-Carman model. Finally, the tasks faced by the application of the electromagnetic method to the monitoring and the evaluation of the hot dry rock hydraulic fracturing are discussed, including:(1) the study of electrical resistivity properties of the fractured compact rocks under high temperature and high pressure; (2) the relationship model between the permeability and the electrical resistivity of the fractured compact rock under high temperature and high pressure; (3) new theories, new methods, new technologies and new equipment of electromagnetic method detection with higher accuracy, finer resolution, better anti-interference ability and longer detection distance.

Key words: hot dry rock; electrical resistivity; permeability; hydraulic fracturing; electromagnetic monitoring

参考文献

[1] 胡鞍钢.中国实现2030年前碳达峰目标及主要途径[J].北京工业大学学报(社会科学版), 2021, 21(3):1-15.
[2] 许天福, 胡子旭, 李胜涛, 等.增强型地热系统:国际研究进展与我国研究现状[J].地质学报, 2018, 92(9):1936-1947.
[3] 汪集旸, 胡圣标, 庞忠和, 等.中国大陆干热岩地热资源潜力评估[J].科技导报, 2012, 30(32):25-31.
[4] 许天福, 袁益龙, 姜振蛟, 等.干热岩资源和增强型地热工程:国际经验和我国展望[J].吉林大学学报(地球科学版), 2016, 46(4):1139-1152.
[5] 许天福, 张延军, 于子望, 等.干热岩水力压裂实验室模拟研究[J].科技导报, 2015, 33(19):35-39.
[6] 蔺文静, 刘志明, 马峰, 等.我国陆区干热岩资源潜力估算[J].地球学报, 2012, 33(5):807-811.
[7] 马峰, 孙红丽, 蔺文静, 等.中国EGS示范工程靶区选址与指标矩阵评价[J].科技导报, 2015, 33(8):41-47.
[8] 马峰, 王贵玲, 魏帅超, 等.2018年地热勘探开发热点回眸[J].科技导报, 2019, 37(1):134-143.
[9] 刘德民, 张昌生, 孙明行, 等.干热岩勘查评价指标与形成条件[J].地质科技通报, 2021, 40(3):1-11.
[10] 郭盼, 吴波, 李朋, 等.增强型地热系统储层建造及其评价[J].资源环境与工程, 2020, 34(2):256-261, 265.
[11] Gaucher E, Schoenball M, Heidbach O, et al.Induced seismicity in geothermal reservoirs:A review of forecasting approaches[J].Renewable and Sustainable Energy Reviews, 2015, 52:1473-1490.
[12] Thiel S.Electromagnetic monitoring of hydraulic fracturing:Relationship to permeability, seismicity, and stress[J].Surveys in Geophysics, 2017, 38(5):1133-1169.
[13] 陆川, 王贵玲.干热岩研究现状与展望[J].科技导报, 2015, 33(19):13-21.
[14] 柳建新, 童孝忠, 郭荣文.大地电磁测深法勘探资料处理、反演与解释[M].北京:科学出版社, 2012:260.
[15] Parkhomenko E I.Electrical resistivity of minerals and rocks at high temperature and pressure[J].Reviews of Geophysics, 1982, 20(2):193.
[16] 田瀚, 王贵文, 王克文, 等.碳酸盐岩储层孔隙结构对电阻率的影响研究[J].地球物理学报, 2020, 63(11):4232-4243.
[17] 李术才, 许新骥, 刘征宇, 等.单轴压缩条件下砂岩破坏全过程电阻率与声发射响应特征及损伤演化[J].岩石力学与工程学报, 2014, 33(1):14-23.
[18] Wang Q, Bagdassarov N, Ji S C.The Moho as a transition zone:A revisit from seismic and electrical properties of minerals and rocks[J].Tectonophysics, 2013, 609:395-422.
[19] Kolah-kaj P, Kord S, Soleymanzadeh A.The effect of pressure on electrical rock typing, formation resistivity factor, and cementation factor[J].Journal of Petroleum Science and Engineering, 2021, 204:108757.
[20] 马衍坤, 刘泽功, 成云海, 等.煤体水力压裂过程中孔壁应变及电阻率响应特征试验研究[J].岩石力学与工程学报, 2016, 35(增刊1):2862-2868.
[21] 张森琦, 文冬光, 许天福, 等.美国干热岩"地热能前沿瞭望台研究计划"与中美典型EGS场地勘查现状对比[J].地学前缘, 2019, 26(2):321-334.
[22] 谢紫霄, 黄中伟, 熊建华, 等.天然裂缝对干热岩水力压裂裂缝扩展的影响规律[J].天然气工业, 2022, 42(4):63-72.
[23] 郭亮亮, 张延军, 许天福, 等.大庆徐家围子不同储层改造的干热岩潜力评估[J].吉林大学学报(地球科学版), 2016, 46(2):525-535.
[24] Sausse J.Hydromechanical properties and alteration of natural fracture surfaces in the Soultz granite (BasRhin, France)[J].Tectonophysics, 2002, 348(1-3):169-185.
[25] Brace W F, Orange A S.Electrical resistivity changes in saturated rocks during fracture and frictional sliding[J].Journal of Geophysical Research, 1968, 73(4):1433-1445.
[26] 姜文龙, 刘英.岩石在单轴压力环境下电阻率变化的研究[J].地质学刊, 2009, 33(3):299-302.
[27] Archie G E.The electrical resistivity log as an aid in determining some reservoir characteristics[J].Transactions of the Aime, 1942, 146(1):54-62.
[28] Stesky R M.Electrical conductivity of brine-saturated fractured rock[J].Geophysics, 1986, 51(8):1585-1593.
[29] Sandler J, Li Y Z, Horne R N, et al.Effects of fracture and frequency on resistivity in different rocks[C]//71st European Association of Geoscientists and Engineers Conference and Exhibition.Amsterdam:Society of Petroleum Engineers, 2009:119872.
[30] 潘保芝, 阿茹罕, 郭宇航, 等.裂缝性岩石低频下复电阻率与饱和度关系研究[J].地球物理学报, 2021, 64(10):3774-3787.
[31] Li K W, Pan B Z, Horne R.Evaluating fractures in rocks from geothermal reservoirs using resistivity at different frequencies[J].Energy, 2015, 93:1230-1238.
[32] Kirkby A, Heinson G, Krieger L.Relating permeability and electrical resistivity in fractures using random resistor network models[J].Journal of Geophysical Research:Solid Earth, 2016, 121(3):1546-1564.
[33] Lv Y X, Yuan C, Gan Q, et al.Analysis of heat transfer based on complex Embedded Discrete Fracture Network (EDFN) for field-scale EGS[J].Geothermics, 2022, 104:102463.
[34] Pirson S J, Boatman E M.Prediction of relative permeability characteristics of intergranular reservoir rocks from electrical resistivity measurements[J].Journal of Petroleum Technology, 1964, 16(5):564-570.
[35] 关继腾, 房文静, 王玉斗.油藏储渗特性对阿尔奇饱和度指数的影响[J].测井技术, 1999, 23(6):419-423, 479.
[36] Li K W.A new method for calculating two-phase relative permeability from resistivity data in porous media[J].Transport in Porous Media, 2008, 74(1):21-33.
[37] Li K.A semianalytical method to calculate relative permeability from resistivity well logs[C]//SPE Annual Technical Conference and Exhibition.Dallas:Society of Petroleum Engineers, 2005:95575.
[38] 孙强, 冯永, 朱术云, 等.饱水岩石加载变形过程中视电阻率-渗透率的关联性[J].煤田地质与勘探, 2012, 40(2):86-90.
[39] Won J, Park J, Choo H, et al.Estimation of saturated hydraulic conductivity of coarse-grained soils using particle shape and electrical resistivity[J].Journal of Applied Geophysics, 2019, 167:19-25.
[40] 马建斌, 唐新功, 向葵.利用电阻率求取岩石渗透率的方法研究[J].长江大学学报(自然科学版), 2013, 10(10):105-106, 122.
[41] Bussian A E.Electrical conductance in a porous medium[J].Geophysics, 1983, 48(9):1258-1268.
[42] 焦乃林, 丁文龙, 尹帅, 等.通过构建基于地层岩石电导率的动态渗透率图版求取致密砂岩储层渗透率方法[J].科学技术与工程, 2016, 16(21):20-26.
[43] 尹帅, 丁文龙, 单钰铭, 等.利用致密砂岩储层电导率参数求取渗透率[J].岩性油气藏, 2016, 28(6):117-124.
[44] Waxman M H, Smits L J M.Electrical conductivities in oil-bearing shaly sands[J].Society of Petroleum Engineers Journal, 1968, 8(2):107-122.
[45] 夏培.含泥质致密砂岩储层三孔隙导电模型[J].物探与化探, 2017, 41(4):748-752.
[46] Fajana A O, Ayuk M A, Omoyegun T D.Comparison of modified Waxman-Smith algorithms and Archie models in prospectivity analysis of saturations in shaly-sand reservoirs.A case study of Pennay field, Niger-Delta[J].Earth Science Informatics, 2021, 14(3):1647-1663.
[47] 孙建国.阿尔奇(Archie)公式:提出背景与早期争论[J].地球物理学进展, 2007, 22(2):472-486.
[48] 沈金松, 苏本玉, 王智茹, 等.泥质砂岩电导率模型的分析及对比[J].测井技术, 2008, 32(5):385-393.
[49] Chelidze T L, Gueguen Y.Electrical spectroscopy of porous rocks:A review-I.Theoretical models[J].Geophysical Journal International, 1999, 137(1):1-15.
[50] Chelidze T L, Gueguen Y, Ruffet C.Electrical spectroscopy of porous rocks:A review-II.Experimental results and interpretation[J].Geophysical Journal International, 1999, 137(1):16-34.
[51] Neumann N, Sandiford M, Foden J.Regional geochemistry and continental heat flow:Implications for the origin of the South Australian heat flow anomaly[J].Earth and Planetary Science Letters, 2000, 183(1-2):107-120.
[52] Peacock J R, Thiel S, Heinson G S, et al.Time-lapse magnetotelluric monitoring of an enhanced geothermal system[J].Geophysics, 2013, 78(3):B121-B130.
[53] Rosas-Carbajal M, Linde N, Peacock J, et al.Probabilistic 3-D time-lapse inversion of magnetotelluric data:Application to an enhanced geothermal system[J].Geophysical Journal International, 2015, 203(3):1946-1960.
[54] Albaric J, Oye V, Langet N, et al.Monitoring of induced seismicity during the first geothermal reservoir stimulation at Paralana, Australia[J].Geothermics, 2014, 52:120-131.
[55] Balfour N J, Cummins P R, Pilia S, et al.Localization of intraplate deformation through fluid-assisted faulting in the lower-crust:The Flinders Ranges, South Australia[J].Tectonophysics, 2015, 655:97-106.
[56] Peacock J R, Thiel S, Reid P, et al.Magnetotelluric monitoring of a fluid injection:Example from an enhanced geothermal system[J].Geophysical Research Letters, 2012, 39(18):B121-B130.
[57] Macfarlane J, Thiel S, Pek J, et al.Characterisation of induced fracture networks within an enhanced geothermal system using anisotropic electromagnetic modelling[J].Journal of Volcanology and Geothermal Research, 2014, 288:1-7.
[58] Beardsmore G.The influence of basement on surface heat flow in the cooper basin[J].Exploration Geophysics, 2004, 35(4):223-235.
[59] Holl H G, Barton C.Habanero field:Structure and state of stress[C]//World Geothermal Congress 2015.Melbourne:International Geothermal Association, 2015:19-25.
[60] Hogarth R, Holl H, Mcmahon A.Flow testing results from the Habanero EGS project[C]//Proceedings Australian Geothermal Energy Conference 2013.Brisbane:Australian Geothermal Energy Association, 2013:21-28.
[61] Mcmahon A, Baisch S.Case study of the seismicity associated with the stimulation of the Enhanced Geothermal System at Habanero, Australia[C]//Proceedings Australian Geothermal Energy Conferences 2013.Brisbane:Australian Geothermal Energy Association, 2013:29-36.
[62] Didana Y L, Heinson G, Thiel S, et al.Magnetotelluric monitoring of permeability enhancement at enhanced geothermal system project[J].Geothermics, 2017, 66:23-38.
[63] 张炯, 黄少鹏, 傅饶, 等.大地电磁测深在火山区地热研究中的应用[J].岩石学报, 2017, 33(1):279-290.
Options
文章导航

/

联系我们

  • 地址:北京市海淀区学院南路86号科技导报社 邮编:100081
  • 电话:010-62138113 传真:010-62138113
  • E-mail:kjdbbjb@cast.org.cn

    • 访问统计

      总访问量
      今日访问
      在线人数
    科技导报官方微信公众号
    京ICP备14028469号-1 
    版权所有 © 《科技导报》编辑部