中国煤层气水平井钻完井技术研究进展

doi:10.7623/syxb202311017

石油学报 ›› 2023, Vol. 44 ›› Issue (11): 1974-1992.DOI: 10.7623/syxb202311017

中国煤层气水平井钻完井技术研究进展

鲜保安¹, 高德利², 徐凤银³, 毕延森², 李贵川⁴, 王京光⁵, 张洋⁶, 韩金良⁷

1. 河南理工大学资源环境学院河南焦作 454000;
2. 中国石油大学(北京)石油工程教育部重点实验室北京 102249;
3. 中联煤层气国家工程研究中心有限责任公司北京 100095;
4. 中联煤层气(山西)有限责任公司三气共采技术创新中心山西太原 030012;
5. 中国石油集团川庆钻探工程有限公司钻采工程技术研究院陕西西安 710018;
6. 中国石油华北油田公司河北任丘 062550;
7. 中石油煤层气有限责任公司工程技术研究院陕西西安 710082

收稿日期:2023-06-30 修回日期:2023-09-25 出版日期:2023-11-25 发布日期:2023-12-08
通讯作者: 高德利,男,1958年4月生,1990年获石油大学(北京)博士学位,现为中国科学院院士、中国石油大学(北京)教授、石油工程教育部重点实验室主任,长期从事油气井力学与控制工程、定向钻井、井筒完整性、深水钻井及工程作业极限、非常规油气大型井工厂钻完井技术等方面的科学研究与技术创新工作。Email:gaodeli@cup.edu.cn;毕延森,男,1986年3月生,2020年获中国石油大学(北京)硕士学位,现为中国石油大学(北京)博士研究生,主要从事水平井钻完井工艺技术、非常规天然气完井增产等方面的科研工作。Email:biyansen2014@163.com
作者简介:鲜保安,男,1966年12月生,2006年获中国石油大学(北京)博士学位,现为河南理工大学教授、博士生导师,主要从事煤层气水平井钻完井与增产技术等方面的科研及教学工作。Email:759267753@qq.com
基金资助:
国家自然科学基金重点项目"复杂结构‘井工厂’立体设计建设基础研究"（No.52234002）和国家自然科学基金重点项目"煤层气低产储层靶向改造增产关键理论及技术基础"（No.42230814）资助。

Research progress of coalbed methane horizontal well drilling and completion technology in China

Xian Bao'an¹, Gao Deli², Xu Fengyin³, Bi Yansen², Li Guichuan⁴, Wang Jingguang⁵, Zhang Yang⁶, Han Jinliang⁷

1. School of Resources and Environment, Henan Polytechnic University, Henan Jiaozuo 454000, China;
2. MOE Key Laboratory of Petroleum Engineering, China University of Petroleum, Beijing 102249, China;
3. China United Coalbed Methane National Engineering Research Center Co., Ltd., Beijing 100095, China;
4. Innovation Center of Three-gas Co-production Technology, China United Coalbed Methane (Shanxi)Co., Ltd., Shanxi Taiyuan 030012, China;
5. Research Institute of Drilling and Production Technology, CNPC Chuanqing Drilling Engineering Co., Ltd., Shaanxi Xi'an 710018, China;
6. PetroChina Huabei Oilfield Company, Hebei Renqiu 062550, China;
7. Research Institute of Engineering Technology, PetroChina Coalbed Methane Company Limited, Shaanxi Xi'an 710082, China

Received:2023-06-30 Revised:2023-09-25 Online:2023-11-25 Published:2023-12-08

摘要/Abstract

摘要： 为了适应中国煤层复杂的地质条件与储层物性特征，水平井钻完井技术不断得以深化研究与发展，围绕"井工厂"形成了井型优化、储层保护、导向钻井和水平井适应性完井技术，逐渐成为中国煤层气高效开发的重要措施。为煤层气高效开发提供钻完井工程方面的技术支持，通过概述中国煤层气水平井钻完井技术研究进展，重点介绍了煤层气水平井完井技术3项研究成果：①形成了煤层水平井双管柱完井与增透一体化技术，在沁水盆地南部应用400余口井，并取得技术与产量突破；开展了井壁煤岩径向循环载荷实验，通过CT扫描技术检测了煤岩裂缝形成与扩展；基于煤岩双孔隙结构、非均质性和孔隙多尺度特征，修正了径向循环载荷下煤岩损伤变量计算模型。②提出了径向水平井柔性筛管液压驱动下入方法，优化设计了完井管柱结构与配套工具，建立了管柱-液压耦合计算模型，以深部煤层径向水平井为算例，计算两种完井管柱结构的最大下入长度分别达到381 m、655 m，为径向井筛管完井提供技术指导。③提出了复杂煤体结构煤层水平井分段复合完井增透方法，数值模拟了循环冲击波辅助水力压裂煤层裂缝扩展规律，通过该技术使停产井增产至2 000 m³/d。最后，概括了深部煤层气水平井钻完井发展技术要点，以大型"井工厂"为核心的配套技术将成为煤层气开发降本增效的关键技术，多约束条件轨道优化设计和控制技术是深部煤层水平井优快钻井的技术保障，水平井多元化完井增产技术将成为中国深部煤层气高效开发的新模式。

关键词: 煤层气, 水平井钻完井, 大型井工厂, 复合完井增产, 深部煤层

Abstract: In response to the complex geological conditions and physical characteristics of coal seams in China, the horizontal drilling and completion technology has been continuously studied and developed. Based on the "well factory" mode, well type optimization, reservoir protection, geosteering drilling and adaptive horizontal completion technologies have been established, gradually becoming the key measures for the efficient exploitation of coalbed methane (CBM) in China. To provide technical support for CBM horizontal drilling and completion engineering, this paper briefly reviews the research progress of domestic CBM horizontal drilling and completion technology, and focuses on the innovative research results:(1) The integrated technology of double tubular strings completion and stimulation for coal seams in horizontal wells is developed. This technology has been applied in more than 400 wells in the southern Qinshui Basin and achieved a breakthrough in technology and production; the radial cyclic load test of coal is carried out, and the formation and propagation of fractures in coal are detected by CT scanning; the calculation model of coal damage variable under radial cyclic stress is modified based on the dual pore structure, heterogeneity and multi-scale pores of coal. (2) The hydraulic driving mechanism of flexible screen pipe with inner tubing is proposed for radial horizontal completion; the tubular string structure and supporting tools are designed and optimized, and the mechanic-hydraulic coupling calculation model is established. Taking the radial horizontal well in deep coal seam as an example, the maximum install length of the two completion strings are 381 and 655 m, respectively, which provides technical guidance for screen completion of radial wells. (3) The mechanism of muti-type stimulation for horizontal well with compose liners in coal seam with complicated coal structure is expounded and the crack propagation of hydraulic fracturing with cyclic shock wave pre-cracking is numerically simulated. The production of a shut-down well is increased to 2 000 m³/d by this technology. Finally, the key development points of CBM horizontal drilling and completion technologies are summarized. The matching technology of large well factory will become the key technology to increase the efficiency of CBM exploitation and reduce the cost. The multi-constraint trajectory optimization design and control technology are the technical guarantee for safe and rapid drilling of horizontal wells in deep coal seams. The diversified completion and stimulation techniques of horizontal wells will be an innovative mode for the efficient development of deep CBM in China.

Key words: coalbed methane, horizontal well drilling and completion, large well factory, multi-type completion and stimulation, deep coal seam

中图分类号:

TE24

鲜保安, 高德利, 徐凤银, 毕延森, 李贵川, 王京光, 张洋, 韩金良. 中国煤层气水平井钻完井技术研究进展[J]. 石油学报, 2023, 44(11): 1974-1992.

Xian Bao'an, Gao Deli, Xu Fengyin, Bi Yansen, Li Guichuan, Wang Jingguang, Zhang Yang, Han Jinliang. Research progress of coalbed methane horizontal well drilling and completion technology in China[J]. Acta Petrolei Sinica, 2023, 44(11): 1974-1992.

参考文献

[1] 高德利, 毕延森, 鲜保安. 中国煤层气高效开发井型与钻完井技术进展[J].天然气工业, 2022, 42(6):1-18.
GAO Deli, BI Yansen, XIAN Bao'an.Technical advances in well types and drilling & completion for high-efficient development of coalbed methane in China[J].Natural Gas Industry, 2022, 42(6):1-18.
[2] 徐凤银, 王勃, 赵欣, 等."双碳"目标下推进中国煤层气业务高质量发展的思考与建议[J].中国石油勘探, 2021, 26(3):9-18.
XU Fengyin, WANG Bo, ZHAO Xin, et al.Thoughts and suggestions on promoting high quality development of China's CBM business under the goal of "double carbon"[J].China Petroleum Exploration, 2021, 26(3):9-18.
[3] 高德利.非常规油气井工程技术若干研究进展[J].天然气工业, 2021, 41(8):153-162.
GAO Deli.Some research advances in well engineering technology for unconventional hydrocarbon[J].Natural Gas Industry, 2021, 41(8):153-162.
[4] 张卫东, 魏韦.煤层气水平井开发技术现状及发展趋势[J].中国煤层气, 2008, 5(4):19-22.
ZHANG Weidong, WEI Wei.Status of coalbed methane horizontal well technology and trend of development[J].China Coalbed Methane, 2008, 5(4):19-22.
[5] 房娜, 姚约东, 夏朝辉, 等.中煤阶煤层气水平对接井开发效果与优化[J].新疆石油地质, 2013, 34(4):473-476.
FANG Na, YAO Yuedong, XIA Zhaohui, et al.Performance analysis and optimization of SIS well for medium coal rank CBM development[J].Xinjiang Petroleum Geology, 2013, 34(4):473-476.
[6] 丁伟, 夏朝辉, 韩学婷, 等.澳大利亚Bowen盆地M气田中煤阶煤层气水平井开发优化[J].新疆石油地质, 2014, 35(5):614-617.
DING Wei, XIA Zhaohui, HAN Xueting, et al.Optimization of medium-rank CBM development by SIS horizontal well in M gasfield of Bowen Basin in Australia[J].Xinjiang Petroleum Geology, 2014, 35(5):614-617.
[7] PACKHAM R, CINAR Y, MOREBY R.Simulation of an enhanced gas recovery field trial for coal mine gas management[J].International Journal of Coal Geology, 2011, 85(3/4):247-256.
[8] 秦勇, 申建, 沈玉林, 等.苏拉特盆地煤系气高产地质原因及启示[J].石油学报, 2019, 40(10):1147-1157.
QIN Yong, SHEN Jian, SHEN Yulin, et al.Geological causes and inspirations for high production of coal measure gas in Surat Basin[J].Acta Petrolei Sinica, 2019, 40(10):1147-1157.
[9] 鲜保安, 高德利, 王一兵, 等.多分支水平井在煤层气开发中的应用机理分析[J].煤田地质与勘探, 2005, 33(6):34-37.
XIAN Bao'an, GAO Deli, WANG Yibing, et al.Analysis on applied mechanism of multiple laterals horizontal well in developing coalbed methane[J].Coal Geology & Exploration, 2005, 33(6):34-37.
[10] 高德利, 鲜保安.煤层气多分支井身结构设计模型研究[J].石油学报, 2007, 28(6):113-117.
GAO Deli, XIAN Bao'an.Research on design models of multi-lateral well structure for coal-bed methane[J].Acta Petrolei Sinica, 2007, 28(6):113-117.
[11] 崔树清, 王风锐, 刘顺良, 等.沁水盆地南部高阶煤层多分支水平井钻井工艺[J].天然气工业, 2011, 31(11):18-21.
CUI Shuqing, WANG Fengrui, LIU Shunliang, et al.Multi-branch horizontal well drilling in the southern Qinshui Basin with high-rank coal beds[J].Natural Gas Industry, 2011, 31(11):18-21.
[12] 徐凤银, 闫霞, 林振盘, 等.我国煤层气高效开发关键技术研究进展与发展方向[J].煤田地质与勘探, 2022, 50(3):1-14.
XU Fengyin, YAN Xia, LIN Zhenpan, et al.Research progress and development direction of key technologies for efficient coalbed methane development in China[J].Coal Geology & Exploration, 2022, 50(3):1-14.
[13] 黄中伟, 李国富, 杨睿月, 等.我国煤层气开发技术现状与发展趋势[J].煤炭学报, 2022, 47(9):3212-3238.
HUANG Zhongwei, LI Guofu, YANG Ruiyue, et al.Review and development trends of coalbed methane exploitation technology in China[J].Journal of China Coal Society, 2022, 47(9):3212-3238.
[14] XIAN Baoan, LIU Gaofeng, BI Yansen, et al.Coalbed methane recovery enhanced by screen pipe completion and jet flow washing of horizontal well double tubular strings[J].Journal of Natural Gas Science and Engineering, 2022, 99:104430.
[15] 毕延森, 鲜保安, 张晓斌.煤层气水平井玻璃钢筛管完井工艺技术[J].煤炭科学技术, 2016, 44(5):106-111.
BI Yansen, XIAN Bao'an, ZHANG Xiaobin.Fiber reinforced plastic screen pipe completion technology of coalbed methane horizontal well[J].Coal Science and Technology, 2016, 44(5):106-111.
[16] 鲜保安, 张龙, 哈尔恒·吐尔松, 等.煤层气储层伤害机理与水平井双层管柱筛管完井技术[J].煤田地质与勘探, 2022, 50(9):122-129.
XIAN Bao'an, ZHANG Long, HA ERHENG·Tu'ersong, et al.Damage mechanism of CBM reservoirs and double-layered screen pipes in the horizontal well completion[J].Coal Geology & Exploration, 2022, 50(9):122-129.
[17] 申瑞臣, 时文, 徐义, 等.煤层气U型井PE筛管完井泵送方案[J].中国石油大学学报:自然科学版, 2012, 36(5):96-99.
SHEN Ruichen, SHI Wen, XU Yi, et al.PE screen completion for U-shaped coal-bed methane wells with pumping method[J].Journal of China University of Petroleum:Edition of Natural Science, 2012, 36(5):96-99.
[18] 高德利, 刁斌斌.复杂结构井磁导向钻井技术进展[J].石油钻探技术, 2016, 44(5):1-9.
GAO Deli, DIAO Binbin.Development of the magnetic guidance drilling technique in complex well engineering[J].Petroleum Drilling Techniques, 2016, 44(5):1-9.
[19] 蔡记华, 刘浩, 陈宇, 等.煤层气水平井可降解钻井液体系研究[J].煤炭学报, 2011, 36(10):1683-1688.
CAI Jihua, LIU Hao, CHEN Yu, et al.Study on degradable drilling fluid system for coalbed methane horizontal drilling[J].Journal of China Coal Society, 2011, 36(10):1683-1688.
[20] 申瑞臣, 闫立飞, 乔磊, 等.煤层气多分支井地质导向技术应用分析[J].煤炭科学技术, 2016, 44(5):43-49.
SHEN Ruichen, YAN Lifei, QIAO Lei, et al.Application and analysis on geosteering technology of coalbed methane multi branch wells[J].Coal Science and Technology, 2016, 44(5):43-49.
[21] 姚伟, 薛占新, 金国辉, 等.泵送桥塞分段压裂工艺在煤层气"二开半程固井"水平井中的应用[J].中国煤层气, 2020, 17(6):3-8.
YAO Wei, XUE Zhanxin, JIN Guohui, et al.Application of pumping bridge plug staged fracturing technology in CBM horizontal well with second spud halfway cementing[J].China Coalbed Methane, 2020, 17(6):3-8.
[22] 张群, 葛春贵, 李伟, 等.碎软低渗煤层顶板水平井分段压裂煤层气高效抽采模式[J].煤炭学报, 2018, 43(1):150-159.
ZHANG Qun, GE Chungui, LI Wei, et al.A new model and application of coalbed methane high efficiency production from broken soft and low permeable coal seam by roof strata-in horizontal well and staged hydraulic fracture[J].Journal of China Coal Society, 2018, 43(1):150-159.
[23] 庞涛, 姜在炳, 李浩哲, 等.碎软煤层顶板水平井空间位置对压裂裂缝扩展的影响[J].煤炭学报, 2022, 47(S1):196-203.
PANG Tao, JIANG Zaibing, LI Haozhe, et al.Influence of the spatial position of horizontal well in roof strata of crushed soft coal seam on the propagation of fracturing fractures[J].Journal of China Coal Society, 2022, 47(S1):196-203.
[24] 许耀波, 朱玉双, 张培河.紧邻碎软煤层的顶板岩层水平井开发煤层气技术[J].天然气工业, 2018, 38(9):70-75.
XU Yaobo, ZHU Yushuang, ZHANG Peihe.Application of CBM horizontal well development technology in the roof strata close to broken-soft coal seams[J].Natural Gas Industry, 2018, 38(9):70-75.
[25] 徐凤银, 闫霞, 李曙光, 等.鄂尔多斯盆地东缘深部(层)煤层气勘探开发理论技术难点与对策[J].煤田地质与勘探, 2023, 51(1):115-130.
XU Fengyin, YAN Xia, LI Shuguang, et al.Theoretical and technological difficulties and countermeasures of deep CBM exploration and development in the eastern edge of Ordos Basin[J].Coal Geology & Exploration, 2023, 51(1):115-130.
[26] 徐凤银, 侯伟, 熊先钺, 等.中国煤层气产业现状与发展战略[J].石油勘探与开发, 2023, 50(4):669-682.
XU Fengyin, HOU Wei, XIONG Xianyue, et al.The status and development strategy of coalbed methane industry in China[J].Petroleum Exploration and Development, 2023, 50(4):669-682.
[27] 牛小兵, 赵伟波, 史云鹤, 等.鄂尔多斯盆地本溪组天然气成藏条件及勘探潜力[J].石油学报, 2023, 44(8):1240-1257.
NIU xiaobing, ZHAO Weibo, SHI Yunhe, et al.Natural gas accumulation conditions and exploration potential of Benxi Formation in Ordos Basin [J].Acta Petrolei Sinica, 2023, 44(8):1240-1257.
[28] 鲜保安, 崔思华, 蓝海峰, 等.中国煤层气开发关键技术及综合利用[J].天然气工业, 2004, 24(5):104-106.
XIAN Bao'an, CUI Sihua, LAN Haifeng, et al.Key techniques and integrative utilization of coal-bed gas development in China[J].Natural Gas Industry, 2004, 24(5):104-106.
[29] 曹立虎, 张遂安, 石惠宁, 等.煤层气多分支水平井井身结构优化[J].石油钻采工艺, 2014, 36(03):10-14.
CAO Lihu, ZHANG Sui'an, SHI Huining, et al.Wellbore structure optimization to multi-lateral horizontal CBM well[J].Oil Drilling & Production Technology, 2014, 36(03):10-14.
[30] 鲜保安, 夏柏如, 张义, 等.应用U型井开采倾斜构造煤层气的钻采技术研究[J].探矿工程(岩土钻掘工程), 2010, 37(8):1-4.
XIAN Bao'an, XIA Bairu, ZHANG Yi, et al.Study on drilling and extraction technologies for high steep structure coalbed methane with U-shape slant well[J].Drilling Engineering, 2010, 37(8):1-4.
[31] 巫修平, 张群.碎软低渗煤层顶板水平井分段压裂裂缝扩展规律及控制机制[J].天然气地球科学, 2018, 29(2):268-276.
WU Xiuping, ZHANG Qun.Research on controlling mechanism of fracture propagation of multi-stage hydraulic fracturing horizontal well in roof of broken soft and low permeability coal seam[J].Natural Gas Geoscience, 2018, 29(2):268-276.
[32] 鲜保安, 孙平, 王一兵, 等.煤层气水平井欠平衡钻井技术研究与应用[J].中国煤层气, 2008, 5(1):5-8.
XIAN Bao'an, SUN Ping, WANG Yibing, et al.Research and application of under-balanced drilling technology in drilling horizontal CBM well[J].China Coalbed Methane, 2008, 5(1):5-8.
[33] LI Xin, GAO Deli, LU Baoping, et al.Study on the prediction model of extended-reach limit length in horizontal drilling with dual-channel drillpipe in shale formation[J].Journal of Petroleum Science and Engineering, 2019, 177:570-578.
[34] 李浩, 谭天宇, 孟振期, 等.煤层气水平井储层保护成井技术[J].中国煤层气, 2019, 16(4):19-23.
LI Hao, TAN Tianyu, MENG Zhenqi, et al.Formation damage protection well completion technology for coalbed methane horizontal well[J].China Coalbed Methane, 2019, 16(4):19-23.
[35] ZHENG Lihui, SU Guandong, LI Zhonghui, et al.The wellbore instability control mechanism of fuzzy ball drilling fluids for coalbed methane wells via bonding formation[J].Journal of Natural Gas Science and Engineering, 2018, 56:107-120.
[36] 李志勇, 李强, 孙晗森, 等.适用于煤层气钻井的微泡沫钻井液研究[J].煤炭学报, 2020, 45(2):703-711.
LI Zhiyong, LI Qiang, SUN Hansen, et al.Research on micro-foam drilling fluid suitable for coalbed methane drilling[J].Journal of China Coal Society, 2020, 45(2):703-711.
[37] 蔡记华, 袁野, 王济君, 等.纳米材料稳定的微泡沫钻井液降低煤层气储层伤害的实验研究[J].煤炭学报, 2013, 38(9):1640-1645.
CAI Jihua, YUAN Ye, WANG Jijun, et al.Experimental research on decreasing coalbed methane formation damage using micro-foam mud stabilized by nanoparticles[J].Journal of China Coal Society, 2013, 38(9):1640-1645.
[38] AHMADI M A, GALEDARZADEH M, SHADIZADEH S R.Colloidal gas aphron drilling fluid properties generated by natural surfactants:experimental investigation[J].Journal of Natural Gas Science and Engineering, 2015, 27:1109-1117.
[39] ZHENG Lihui, SU Guandong, LI Zhonghui, et al.The wellbore instability control mechanism of fuzzy ball drilling fluids for coalbed methane wells via bonding formation[J].Journal of Natural Gas Science and Engineering, 2018, 56:107-120.
[40] 郑力会, 孟尚志, 曹园, 等.绒囊钻井液控制煤层气储层伤害室内研究[J].煤炭学报, 2010, 35(3):439-442.
ZHENG Lihui, MENG Shangzhi, CAO Yuan, et al.Laboratory studies on control coal bed methane formation damage by Fuzzy-Ball based drilling fluids[J].Journal of China Coal Society, 2010, 35(3):439-442.
[41] LI Zhiyong, ZHOU Yu, QU Long, et al.Smart plugging and low-damage foam drilling fluid technology for CBM drilling[J].International Journal of Oil, Gas and Coal Technology, 2023, 32(2):103-125.
[42] 许朋琛, 陈宁, 胡景东, 等.可降解清洁钻井液的研究及现场应用[J].钻井液与完井液, 2017, 34(3):27-32.
XU Pengchen, CHEN Ning, HU Jingdong, et al.Study and field application of degradable clear drilling fluid[J].Drilling Fluid & Completion Fluid, 2017, 34(3):27-32.
[43] 齐奉忠, 于永金, 刘子帅.大宁-吉县地区煤层气水平井固井技术研究与应用[J].非常规油气, 2015, 2(1):54-60.
QI Fengzhong, YU Yongjin, LIU Zishuai.Cementing technology of horizontal coalbed methane wells in Daning-Jixian area[J].Unconventional Oil & Gas, 2015, 2(1):54-60.
[44] 张建国, 周立春, 张聪, 等.封隔式免钻半程固井工具在马必东区块的应用[J].内蒙古石油化工, 2020, 46(6):111-113.
ZHANG Jianguo, ZHOU Lichun, ZHANG Cong, et al.Application of closed drilling-free half way cementing tool in MABIDONG block-area[J].Inner Mongolia Petrochemical Industry, 2020, 46(6):111-113.
[45] 左景栾, 吴建光, 孙晗森, 等.煤层气泡沫水泥浆固井技术研究[C]//2013年煤层气学术研讨会论文集.北京:地质出版社, 2013:348-357.
ZUO Jingluan, WU Jianguang, SUN Hansen, et al.Study of foam slurry cementing technology for coalbed methane[C]//Proceedings of 2013 Coalbed Methane Symposium.Beijing:Geological Publishing House, 2013:348-357.
[46] 王楚峰, 王瑞和, 杨焕强, 等.煤层气泡沫水泥浆固井工艺技术及现场应用[J].煤田地质与勘探, 2016, 44(2):116-120.
WANG Chufeng, WANG Ruihe, YANG Huanqiang, et al.Cementing technology of foam cement slurry for coalbed methane well and its application[J].Coal Geology & Exploration, 2016, 44(2):116-120.
[47] 王楚峰, 王瑞和, 王方祥, 等.煤层气井固井泡沫水泥浆密度变化规律及应用[J].中国石油大学学报:自然科学版, 2017, 41(5):87-93.
WANG Chufeng, WANG Ruihe, WANG Fangxiang, et al.Study and application of change law of foamed cement slurry density for coalbed methane[J].Journal of China University of Petroleum:Edition of Natural Science, 2017, 41(5):87-93.
[48] 王翔, 王星星, 王成文, 等.化学充氮泡沫水泥浆制备原理与应用[J].钻井液与完井液, 2018, 35(4):97-101.
WANG Xiang, WANG Xingxing, WANG Chengwen, et al.Preparation and application of chemically nitrogen filled foamed cement slurry[J].Drilling Fluid & Completion Fluid, 2018, 35(4):97-101.
[49] 孙佃金, 孙蕾.地质导向技术在煤层气水平井施工中的应用[J].煤田地质与勘探, 2015, 43(2):106-108.
SUN Dianjin, SUN Lei.Application of geosteering technology in construction of CBM horizontal well[J].Coal Geology & Exploration, 2015, 43(2):106-108.
[50] 施斌全, 亢武臣.E-link电磁波无线随钻测量系统在煤层气钻井中的应用[J].煤田地质与勘探, 2010, 38(2):68-70.
SHI Binquan, KANG Wuchen.Application of E-link electromagnetic measurement while drilling system in drilling coal bed methane well[J].Coal Geology & Exploration, 2010, 38(2):68-70.
[51] 高德利, 黄文君, 刁斌斌, 等.复杂结构井定向钻井技术现状及展望[J].前瞻科技, 2023, 2(2):11-21.
GAO Deli, HUANG Wenjun, DIAO Binbin, et al.Current status and prospect of directional drilling technologies for complex wells[J].Science and Technology Foresight, 2023, 2(2):11-21.
[52] GAO Deli, DIAO Binbin, WU Zhiyong, et al.Research into magnetic guidance technology for directional drilling in SAGD horizontal wells[J].Petroleum Science, 2013, 10(4):500-506.
[53] XI Baobin, GAO Deli.Control technique on navigating path of intersection between two horizontal wells[J].Journal of Natural Gas Science and Engineering, 2014, 21:304-315.
[54] 高德利, 刘维, 万绪新, 等.PDC钻头钻井提速关键影响因素研究[J].石油钻探技术, 2023, 51(4):20-34.
GAO Deli, LIU Wei, WAN Xuxin, et al.Study on key factors influencing the ROP improvement of PDC bits[J].Petroleum Drilling Techniques, 2023, 51(4):20-34.
[55] 涂志民, 张亮, 吕娜, 等.韩城矿区煤层气L型水平井套管钻井技术[J].石油钻采工艺, 2019, 41(4):424-429.
TU Zhimin, ZHANG Liang, LV Na, et al.Casing drilling for L-shaped CBM horizontal wells in Hancheng mining area[J].Oil Drilling & Production Technology, 2019, 41(4):424-429.
[56] TIAN Shouceng, HUANG Zhongwei, LI Gensheng, et al.Laboratory experiments on blockage removing and stimulation of CBM reservoirs by composite pulsating hydraulic fracturing of radial horizontal wells[J].Natural Gas Industry B, 2019, 6(2):151-158.
[57] 黄中伟, 李志军, 李根生, 等.煤层气水平井定向喷射防砂压裂技术及应用[J].煤炭学报, 2022, 47(7):2687-2697.
HUANG Zhongwei, LI Zhijun, LI Gensheng, et al.Oriented and sand control hydra-jet fracturing in coalbed methane horizontal wells and field applications[J].Journal of China Coal Society, 2022, 47(7):2687-2697.
[58] 张遂安, 刘欣佳, 温庆志, 等.煤层气增产改造技术发展现状与趋势[J].石油学报, 2021, 42(1):105-118.
ZHANG Sui'an, LIU Xinjia, WEN Qingzhi, et al.Development situation and trend of stimulation and reforming technology of coalbed methane[J].Acta Petrolei Sinica, 2021, 42(1):105-118.
[59] 曹运兴, 石玢, 田林, 等.低渗低压煤层水平井密集多簇压裂高效开发技术及应用[J].煤炭学报, 2020, 45(10):3512-3521.
CAO Yunxing, SHI Bin, TIAN Lin, et al.Development and application of dense multi-cluster fracturing in horizontal wells for low permeability and low pressure coal reservoir[J].Journal of China Coal Society, 2020, 45(10):3512-3521.
[60] 王创业, 方惠军, 詹顺, 等.连续管定向喷砂射孔拖动压裂技术在煤层气水平井中的应用[J].天然气工业, 2018, 38(S1):143-147.
WANG Chuangye, FANG Huijun, ZHAN Shun, et al.Application of continuous pipe directional sand blasting perforation dragfracturing technology in CBM horizontal wells[J].Natural Gas Industry, 2018, 38(S1):143-147.
[61] 杨刚, 孟尚志, 李斌, 等.深部煤层气T型井钻井技术[J].煤炭科学技术, 2018, 46(6):189-194.
YANG Gang, MENG Shangzhi, LI Bin, et al.Drilling technology of T-shaped well in deep coalbed methane[J].Coal Science and Technology, 2018, 46(6):189-194.
[62] BI Yansen, XIAN Bao'an, SHI Xiaolei, et al.The extending length calculation of hydraulic drive non-metallic completion screen pipe running into ultra-short radius horizontal well[J].Petroleum Exploration and Development, 2022, 49(4):942-954.
[63] 毕延森, 鲜保安, 高德利.煤层气T型水平井柔性筛管泵送下入技术研究[J].煤炭科学技术, 2019, 47(11):170-175.
BI Yansen, XIAN Bao'an, GAO Deli.Study on technology of flexible screen running for T-shaped CBM wells with pumping method[J].Coa l Science and Technology, 2019, 47(11):170-175.
[64] 高德利, 刘希圣, 徐秉业.井眼轨迹控制[M].东营:石油大学出版社, 1994.
GAO Deli, LIU Xisheng, XU Bingye.Prediction and control of wellbore trajectory[M].Dongying:Petroleum University Press, 1994.
[65] JOHANCSIK C A, FRIESEN D B, DAWSON R.Torque and drag in directional wells-prediction and measurement[J].Journal of Petroleum Technology, 1984, 36(6):987-992.
[66] 樊洪海.实用钻井流体力学[M].北京:石油工业出版社, 2014.
FAN Honghai.Practical drilling fluid mechanics[M].Beijing:Petroleum Industry Press, 2014.
[67] WU J, JUVKAM-WOLD H C.The effect of wellbore curvature on tubular buckling and lockup[J].Journal of Energy Resources Technology, 1995, 117(3):214-218.
[68] WU J, JUVKAM-WOLD H C, LU R.Helical buckling of pipes in extended reach and horizontal wells-Part 1:preventing helical buckling[J].Journal of Energy Resources Technology, 1993, 115(3):190-195.
[69] WU J, JUVKAM-WOLD H C.Coiled tubing buckling implication in drilling and completing horizontal wells[J].SPE Drilling & Completion, 1995, 10(1):16-21.
[70] LEMAITRE J.Evaluation of dissipation and damage in metals submitted to dynamic loading, mechanical behavior of materials[C].Proceedings of the First International Conference.Kyoto, Japan.1972:540-549.
[71] 谢和平, 鞠杨, 董毓利.经典损伤定义中的"弹性模量法"探讨[J].力学与实践, 1997, 19(2):1-5.
XIE Heping, JU Yang, DONG Yuli.Discussing "elastic modulus method" in the classic damage definition[J].Mechanics in Engineering, 1997, 19(2):1-5.
[72] BI Yansen, GAO Deli, XIAN Baoan.Experimental study on coal damage near wellbore under cyclic alternating load[R].ARMA 0560, 2022.
[73] 张龙, 王一兵, 鲜保安, 等.新疆阜康矿区煤层气双管柱筛管完井机理与适用性研究[J].油气藏评价与开发, 2022, 12(4):633-642.
ZHANG Long, WANG Yibing, XIAN Bao'an, et al.Applicability and mechanism of dual-tubing screen completion technology for Fukang mining area in Xinjiang[J].Petroleum Reservoir Evaluation and Development, 2022, 12(4):633-642.
[74] 魏迎春, 孟涛, 张劲, 等.不同煤体结构煤储层与煤层气井产出煤粉特征的关系——以鄂尔多斯盆地东缘柳林区块为例[J].石油学报, 2023, 44(6):1000-1014.
WEI Yingchun, MENG Tao, ZHANG Jin, et al.Relationship between coal reservoirs with different coal structures and the characteristics of coal fines produced in CBM wells:a case study of Liulin block at the eastern margin of Ordos Basin[J].Acta Petrolei Sinica, 2023, 44(6):1000-1014.
[75] 肖翠, 陈贞龙, 金晓波.延川南煤层气田煤体结构模式及改造效果分析[J].煤炭科学技术, 2021, 49(11):38-46.
XIAO Cui, CHEN Zhenlong, JIN Xiaobo.Coal structure model and fracturing effect of Yanchuannan coalbed gas field[J].Coal Science and Technology, 2021, 49(11):38-46.
[76] 许耀波, 郭盛强.软硬煤复合的煤层气水平井分段压裂技术及应用[J].煤炭学报, 2019, 44(4):1169-1177.
XU Yaobo, GUO Shengqiang.Technology and application of staged fracturing in coalbed methane horizontal well of soft and hard coal composite coal seam[J].Journal of China Coal Society, 2019, 44(4):1169-1177.
[77] 边利恒, 熊先钺, 王伟, 等.韩城区块煤体结构分布规律及射孔优化方法[J].煤炭学报, 2017, 42(增刊1):209-214.
BIAN Liheng, XIONG Xianyue, WANG Wei, et al.Distribution law of coal structure and perforation optimization method in Hancheng block [J].Journal of China Coal Society, 2017, 42(S1):209-214.
[78] 秦勇, 李恒乐, 张永民, 等.基于地质-工程条件约束的可控冲击波煤层致裂行为数值分析[J].煤田地质与勘探, 2021, 49(1):108-118.
QIN Yong, LI Hengle, ZHANG Yongmin, et al.Numerical analysis on CSW fracturing behavior of coal seam under constraint of geological and engineering conditions[J].Coal Geology & Exploration, 2021, 49(1):108-118.
[79] 张永民, 邱爱慈, 秦勇.电脉冲可控冲击波煤储层增透原理与工程实践[J].煤炭科学技术, 2017, 45(9):79-85.
ZHANG Yongmin, QIU Aici, QIN Yong.Principle and engineering practices on coal reservoir permeability improved with electric pulse controllable shock waves[J].Coal Science and Technology, 2017, 45(9):79-85.
[80] 李贵川, 张锦虎, 邓拓, 等.煤层气水平井注氮增产改造技术[J].煤炭科学技术, 2016, 44(5):54-58.
LI Guichuan, ZHANG Jinhu, DENG Tuo, et al.Gas output improvement and reconstruction technology of coalbed methane horizontal well by nitrogen injection[J].Coal Science and Technology, 2016, 44(5):54-58.
[81] 毕延森.煤层气水平井筛管完井分段水力激动裂缝扩展研究[D].北京:中国石油大学(北京), 2020.
BI Yansen.Study on crack propagation by hydraulic stimulation of subsections in CBM horizontal well with screen completion[D].Beijing:China University of Petroleum, 2020.
[82] BI Yansen, GAO Deli, XIAN Bao'an, et al.Study on fracture propagation of hydraulic fracturing with cyclic shock wave pre-cracking for CBM horizontal wells[R].ARMA 0072, 2023.
[83] 毕延森, 高德利, 鲜保安, 等.复杂煤体结构煤储层水平井复合管柱完井方法研究[J/OL].煤炭科学技术, 1-10[2023-03-03].https://doi.org/10.13199/j.cnki.cst.2022-1659.
BI Yansen, GAO Deli, XIAN Bao'an.Study on horizontal completion with composite liner in coal seam with complicated coal structure[J/OL].Coal Science and Technology, 1-10[2023-03-03].https://doi.org/10.13199/j.cnki.cst.2022-1659.
[84] 高德利.大型丛式水平井工程与山区页岩气高效开发模式[J].天然气工业, 2018, 38(8):1-7.
GAO Deli.A high-efficiency development mode of shale gas reservoirs in mountainous areas based on large cluster horizontal well engineering[J].Natural Gas Industry, 2018, 38(8):1-7.
[85] 高德利.复杂结构井优化设计与钻完井控制技术[M].东营:中国石油大学出版社, 2011.
GAO Deli.Optimized design and control techniques for drilling & completion of complex-structure wells[M].Dongying:China University of Petroleum Press, 2011.
[86] 吴聿元, 陈贞龙.延川南深部煤层气勘探开发面临的挑战和对策[J].油气藏评价与开发, 2020, 10(4):1-11.
WU Yuyuan, CHEN Zhenlong.Challenges and countermeasures for exploration and development of deep CBM of South Yanchuan[J].Petroleum Reservoir Evaluation and Development, 2020, 10(4):1-11.
[87] 高德利, 刘奎, 王宴滨, 等.页岩气井井筒完整性失效力学机理与设计控制技术若干研究进展[J].石油学报, 2022, 43(12):1798-1812.
GAO Deli, LIU Kui, WANG Yanbin, et al.Some research advances in the failure mechanism and design & control technologies of shale gas well integrity[J].Acta Petrolei Sinica, 2022, 43(12):1798-1812.
[88] 徐凤银, 王成旺, 熊先钺, 等.深部(层)煤层气成藏模式与关键技术对策-以鄂尔多斯盆地东缘为例[J].中国海上油气, 2022, 34(4):30-42.
XU Fengyin, WANG Chengwang, XIONG Xianyue, et al.Deep(layer)coalbed methane reservoir forming modes and key technical countermeasures:taking the eastern margin of Ordos Basin as an example[J].China Offshore Oil and Gas, 2022, 34(4):30-42.
[89] 闫霞, 徐凤银, 聂志宏, 等.深部微构造特征及其对煤层气高产"甜点区"的控制-以鄂尔多斯盆地东缘大吉地区为例[J].煤炭学报, 2021, 46(8):2426-2439.
YAN Xia, XU Fengyin, NIE Zhihong, et al.Microstructure characteristics of Daji area in east Ordos Basin and its control over the high yield dessert of CBM[J].Journal of China Coal Society, 2021, 46(8):2426-2439.
[90] 姚红生, 肖翠, 陈贞龙, 等.延川南深部煤层气高效开发调整对策研究[J].油气藏评价与开发, 2022, 12(4):545-555.
YAO Hongsheng, XIAO Cui, CHEN Zhenlong, et al.Adjustment countermeasures for efficient development of deep coalbed methane in southern Yanchuan CBM Field[J].Petroleum Reservoir Evaluation and Development, 2022, 12(4):545-555.
[91] 姚红生, 陈贞龙, 何希鹏, 等.深部煤层气"有效支撑"理念及创新实践-以鄂尔多斯盆地延川南煤层气田为例[J].天然气工业, 2022, 42(6):97-106.
YAO Hongsheng, CHEN Zhenlong, HE Xipeng, et al."Effective support" concept and innovative practice of deep CBM in South Yanchuan gas field of the Ordos Basin[J].Natural Gas Industry, 2022, 42(6):97-106.
[92] 曹运兴, 张军胜, 田林, 等.低渗煤层定向多簇气相压裂瓦斯治理技术研究与实践[J].煤炭学报, 2017, 42(10):2631-2641.
CAO Yunxing, ZHANG Junsheng, TIAN Lin, et al.Research and application of CO₂ gas fracturing for gas control in low permeability coal seams[J].Journal of China Coal Society, 2017, 42(10):2631-2641.

中国煤层气水平井钻完井技术研究进展

Research progress of coalbed methane horizontal well drilling and completion technology in China

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