基于岩石物理与矿物组成的页岩脆性评价新方法

doi:10.11764/j.issn.1672-1926.2016.10.1924

天然气地球科学

基于岩石物理与矿物组成的页岩脆性评价新方法

秦晓艳^1,2，王震亮^1,2，于红岩^1,2，程昊^1,2，雷裕红³，罗晓容³，张丽霞⁴，姜呈馥⁴，高潮⁴

1.大陆动力学国家重点实验室(西北大学)，陕西西安710069;
2.西北大学地质学系，陕西西安 710069;
3.中国科学院地质与地球物理研究所，北京 100083;
4.陕西延长石油(集团)有限责任公司研究院，陕西西安 710075

收稿日期:2016-01-08 修回日期:2016-04-28 出版日期:2016-10-10 发布日期:2016-10-10
通讯作者: 王震亮（1966-）,男,河南内黄人,教授,博士生导师,主要从事油气地质研究和教学工作. E-mail:wangzl@nwu.edu.cn.
作者简介:秦晓艳（1984-）,女,贵州思南人,博士研究生,主要从事油气藏储层地质研究. E-mail:qinxy2005@163.com.
基金资助:
国家自然科学基金项目(编号：41172122);陕西延长石油（集团）有限责任公司研究院课题（编号：陕研X14-27）联合资助.

A new shale brittleness evaluation method based on rock physics and mineral compositions

Qin Xiao-yan^1,2，Wang Zhen-liang^1,2，Yu Hong-yan^1,2，Cheng Hao^1,2，Lei Yu-hong³，Luo Xiao-rong³，Zhang Li-xia⁴，Jiang Cheng-fu⁴，Gao Chao⁴

1.State Key Laboratory of Continental Dynamics,Northwest University,Xi’an 710069,China;2.Department of Geology,
Northwest University,Xi’an 710069,China;
3.Institute of Geology & Geophysics,CAS,Beijing 100083,China;
4.Research Institute of Shaanxi Yanchang Petroleum(Group) Co.Ltd.,Xi’an 710075,China

Received:2016-01-08 Revised:2016-04-28 Online:2016-10-10 Published:2016-10-10

摘要/Abstract

摘要： 泥页岩的脆性决定其压裂改造的效果，开展页岩的脆性评价研究，可为压裂设计提供技术支撑，压裂改造的效果对提高页岩产能意义重大。鄂尔多斯盆地东南部下寺湾地区延长组长7段张家滩页岩层系内大量发育粉砂质泥页岩条带，矿物组成复杂，岩性非均质性强，对页岩气产量影响显著。针对目前矿物脆性评价中存在的脆性矿物不明确的问题，为了明确复杂矿物组成对页岩脆性的影响，通过对21块样品(页岩15块,粉砂质泥页岩6块)分别开展页岩总有机碳、全岩矿物X-射线衍射和地层条件下的三轴压缩应力试验，系统分析矿物组成及岩石力学特征，并以实验结果为基础分析矿物与岩石物理参数表现的关系，定量模拟岩石弹性参数随矿物组分变化的特征，明确了石英和黄铁矿是张家滩页岩的脆性矿物，并提出基于岩石物理模型的陆相页岩矿物组分脆性评价新方法。以YY22井为例，应用矿物脆性评价方法，计算其页岩层段的矿物脆性指数，为高脆性有利压裂目的层的识别及增产方案设计提供了参数依据。

关键词: 矿物组成, 岩石力学, 脆性评价, 岩石物理, 页岩, 鄂尔多斯盆地

Abstract: Hydraulic fracturing effect in shale is decided by the brittleness.The research on brittleness evaluation provides technical support for stimulation treatment design,and successful hydraulic fracturing increases the wells’ production rate.Continental Zhangjiatan shale in the member 7 of Yanchang Formation in Xiasiwan area of southeast Ordos Basin,which is featured with complex mineral compositions,plenty of silty mudstone is developed,strong lithological heterogeneities make significant impact on shale gas production.Currently brittle mineral and the influence of complex mineral compositions on shale brittleness are not clear in mineral brittleness evaluation.The mineral compositions and rock mechanics characteristics of rock samples (15 shale,6 silty shale) were systematically analyzed by the TOC,XRD,and triaxial compressive stress test under formation condition.On the basis of experimental results,the relationship was analyzed between the mineral compositions and the rock physical parameters.Quartz and pyrite as brittle minerals in Zhangjiatan shale was confirmed by quantitative simulation of the rock elasticity characteristics with different mineral composition.A new brittleness evaluation method of continental shale was put forward based on rock physics model and mineral compositions.The shale mineral brittleness index was calculated by the method in Well YY22,which provided geological basis for identifying fracturing target bed in quality brittleness shale and designing stimulation treatment.

Key words: Mineral compositions, Rock mechanics, Brittleness evaluation, Rock physics, Shale, Ordos Basin

中图分类号:

TE132

秦晓艳, 王震亮, 于红岩, 程昊, 雷裕红, 罗晓容, 张丽霞, 姜呈馥, 高潮. 基于岩石物理与矿物组成的页岩脆性评价新方法[J]. 天然气地球科学, 2016, 27(10): 1924–1932.

Qin Xiao-yan, Wang Zhen-liang, Yu Hong-yan, Cheng Hao, Lei Yu-hong, Luo Xiao-rong, Zhang Li-xia, Jiang Cheng-fu, Gao Chao. A new shale brittleness evaluation method based on rock physics and mineral compositions[J]. Natural Gas Geoscience, 2016, 27(10): 1924–1932.

参考文献

[1]Er Chuang,Zhao Jingzhou,Wang Rui,et al.Controlling role of sedimentary environment on the distribution of organic-rich shale:A case study of the Chang 7 member of the Triassic Yanchang Formation,Ordos Basin[J].Natural Gas Geoscience,2015,26(5):823-832,892.[耳闯,赵靖舟,王芮,等.沉积环境对富有机质页岩分布的控制作用——以鄂尔多斯盆地三叠系延长组长７油层组为例[J].天然气地球科学,2015,26(5):823-832,892.]
[2]Lei Yuhong,Luo Xiaorong,Wang Xiangzeng,et al.Characteristics of silty laminae in Zhangjiatan shale of southeastern Ordos Basin,China:Implications for shale gas formation[J].AAPG Bulletin,2015,99(4):661-687.
[3]Cheng Ming,Luo Xiaorong,Lei Yuhong,et al.The distribution,fractal,characteristic and thickness estimation of silty laminae and beds in the Zhangjiatan shale,Ordos Basin[J].Natural Gas Geoscience,2015,26(5):845-854.[程明,罗晓容,雷裕红,等.鄂尔多斯盆地张家滩页岩粉砂质夹层/纹层分布、分形特征和估算方法研究[J].天然气地球科学,2015,26(5):845-854.][JP]
[4]Liu Guoheng,Huang Zhilong,Jiang Zhenxue,et al.The characteristic and reservoir significance of lamina in shale from Yanchang Formation of Ordos Basin[J].Natural Gas Geoscience,2015,26(3):408-417.[刘国恒,黄志龙,姜振学,等.鄂尔多斯盆地延长组湖相页岩纹层发育特征及储集意义[J].天然气地球科学,2015,26(3):408-417.]
[5]Wang Xiangzeng,Liu Guoheng,Huang Zhilong,et al.The characteristics of shale reservoir of the No.7 members in Yanchang Formation of southeast Ordos Basin[J].Natural Gas Geoscience,2015,26(7):1385-1394.[王香增,刘国恒,黄志龙,等.鄂尔多斯盆地东南部延长组长７段泥页岩储层特征[J].天然气地球科学,2015,26(7):1385-1394.]
[6]Jiang Chengfu,Cheng Yuqun,Fan Bojiang,et al.Progress in and challenges to geologic research of terrestrial shale in China:A case study from the 7th members of the Upper Triassic Yanchang Formation in the Yanchang exploration block,Ordos Basin[J].Natural Gas Industry,2014,34(2):27-33.[姜呈馥,程玉群,范柏江,等.陆相页岩气的地质研究进展及亟待解决的问题——以延长探区上三叠统延长组长７段页岩为例[J].天然气工业,2014,34(2):27-33.]
[7]Grieser W V,Bray J M.Identification of production potential in unconventional reservoirs[C].SPE,106623,the Production and Operations Symposium,31 March-3 April 2007,Oklahoma City,Oklahoma,U.S.A.1-6.
[8]Rickman R,Mullen M J,Petre J E,et al.A practical use of shale petrophysics for stimulation design optimization:All shale plays are not clones of the Barnett Shale[C].SPE 115258.SPE Annual Technical Conference and Exhibition,21-24 September 2008,Denver,Colorado,U.S.A.1-11.
[9]Tang Ying,Xing Yun,Li Lezhong,et al.Influence factors and evaluation methods of the gas shale fracability[J].Earth Science Frontiers,2012,19(5):356-363.[唐颖,邢云,李乐忠,等.页岩储层可压裂性影响因素及评价方法[J].地学前缘,2012,19(5):356-363.]
[10]Wang Chenglong,Xia Hongquan,Yang Shuangding.On fracture height and width prediction method based on rock brittleness coefficient[J].Well Logging Technology,2013,37(6):676-680.[王成龙,夏宏泉,杨双定.基于岩石脆性系数的压裂缝高度与宽度预测方法研究[J].测井技术,2013,37(6):676-680.][JP]
[11]Wang Yu,Li Xiao,Wu Yanfang,et al.Research on relationship between crack initiation stress level and brittleness indices for brittle rocks[J].Chinese Journal of Rock Mechanics and Engineering,2014,33(2):264-274.[王宇,李晓,武艳芳,等.脆性岩石起裂应力水平与脆性指标关系探讨[J].岩石力学与工程学报,2014,33(2):264-274.]
[12]Diao Haiyan.Rock mechanical properties and brittleness evaluation of shale reservoir[J].Acta Petrologica Sinica,2013,29(9):3300-3306.[刁海燕.泥页岩储层岩石力学特征及脆性评价[J].岩石学报,2013,29(9):3300-3306.]
[13]Chen Ji,Xiao Xianming.Mineral composition and brittleness of three sets of Paleozoic organic-rich shales in China South area[J].Journal of China Coal Society,2013,38(5):822-826.[陈吉,肖贤明.南方古生界3套富有机质页岩矿物组成与脆性分析[J].煤炭学报,2013,38(5):822-826.]
[14]Zhao Pei,Li Xianqing,Sun Jie,et al.Study on mineral composition and brittleness characteristics of shale gas reservoirs from the Lower Paleozoic in the southern Sichuan Basin[J].Geoscience,2014,28(2):396-403.[赵佩,李贤庆,孙杰,等.川南地区下古生界页岩气储层矿物组成与脆性特征研究[J].现代地质,2014,28(2):396-403.]
[15]Yuan Yuan,Jiang Zhenxue,Yu Chen,et al.Mineral compositions and brittleness of the middle Jurassic iacustrine shale reservoirin northern Qaidam Basin[J].Geological Journal of China Universities,,2015,21(1):117-123.[原园,姜振学,喻宸,等.柴北缘中侏罗统湖相泥页岩储层矿物组成与脆性特征[J].高校地质学报,2015,21(1):117-123.]
[16]Liu Hong,Chen Qiao,Wang Sen,et al.Experimental Study of Mineral Composition and Brittle Characteristics in Longmaxi Formation of Lower Silurian，Southeast Chongqing[J].Science Technology and Engineering,,2013,13(29):8567-8571.[刘洪,陈乔,王森,等.渝东南下志留统龙马溪组页岩矿物成分及脆性特征实验研究[J].科学技术与工程,2013,13(29):8567-8571][JP]
[17]Li Juyuan.Analysis on mineral components and frangibility of shales in Dongying Depression[J].Acta Sedimentologica Sinica,2013,31(4):616-620.[李钜源.东营凹陷泥页岩矿物组成及脆度分析[J].沉积学报,2013,31(4):616-620.]
[18]Yuan Junliang,Deng Jingen,Zhang Dingyu,et al.Fracability evaluation of shale-gas reservoirs[J].Acta Petrolei Sinica,2013,34(3):523-527.[袁俊亮,邓金根,张定宇,等.页岩气储层可压裂性评价技术[J].石油学报,2013,34(3):523-527.]
[19]Zhou Hui,Meng Fanzheng，Zhang Chuanqing,et al.Quantitative evaluation of rock brittleness based on stress-strain curve[J].Journal of Rock Mechanics and Engineering,2014,33(6):1114-1121.[周辉,孟凡震,张传庆,等.基于应力_应变曲线的岩石脆性特征定量评价方法[J].岩石力学与工程学报,2014,33(6):1114-1121.]
[20]Wu Qi,Xu Yun,Zhang Shouliang,et al.The core theories and key optimization designs of volume stimulation technology for unconventional reservoirs[J].Acta Petrolei Sinica,2014，35(4):706-714.[吴奇,胥云,张守良,等.非常规油气藏体积改造技术核心理论与优化设计关键[J].石油学报,2014,35(4):706-714.][JP]
[21]Zhong Jianhua,Liu Shengxin,Ma Yinsheng,et al.Brittle fracture characteristics and micro-fracture mechanism of shale[J].Petroleum Exploration and Development,2015,42(2):242-249.[钟建华,刘圣鑫,马寅生,等.页岩脆性破裂特征与微观破裂机理[J].石油勘探与开发,2015,42(2):242-249.]
[22]Sun Jianmeng,Han Zhilei,Qin Ruibao,et al.Log evalution method of fracturing performance in tight gas reservoir[J].Acta Petrolei Sinica,2015,36(1):74-80.[孙建孟，韩志磊，秦瑞宝，等.致密气储层可压裂性测井评价方法[J].石油学报,2015,36(1):74-80.]
[23]Evans B,Fredrich J T,Wong T F.The brittle-ductile transition in rocks:Recent experimental and theoretical progress[J].Journal of Structural Geology,2012,44(7):25-53.
[24]Makowitz A,Milliken K L.Quantification of brittle deformation in burial compation,Frio and Mount Simon formation sandstones[J].Journal of Sedimentary Research,2003,73(6):1007-1021.
[25]Miskimins J L.The importance of geophysical and petrophysical data integration for the hydraulic fracturing of unconventional reservoirs[J].The Leading Edge,2009,28(7):844-849.
[26]He Jingang,Kang Yili,You Lijun,et al.Effects of mineral composition and microstructure on stress-sensitivity of mudrocks[J].Natural Gas Geoscience,2012,23(1):129-134.[何金钢,康毅力,游利军,等.矿物成分和微结构对泥质岩储层应力敏感性的影响[J].天然气地球科学,2012,23(1):129-134.][JP]
[27]Chen Yu,Huang Tingfang.Rock Physics[M].Beijing:Peking University Press,2001.[陈颙,黄庭芳.岩石物理学[M].北京:北京大学出版社,2001.]

[28]Altindag R.Correlation of specific energy with rock brittleness concepts on rock cutting[J].The Journal of the South African Institute of Mining and Metallurgy,2003,103(3):163-171.
[29]Kahraman S,Altindag R.A brittleness index to estimate fracture toughness[J].International Journal of Rock Mechanics & Mining Sciences,2004,41(2):343-348.

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基于岩石物理与矿物组成的页岩脆性评价新方法

A new shale brittleness evaluation method based on rock physics and mineral compositions

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