水合物储层水平井钻井井筒-储层耦合模型与井壁稳定性分析

doi:10.7623/syxb202307011

石油学报 ›› 2023, Vol. 44 ›› Issue (7): 1151-1166.DOI: 10.7623/syxb202307011

水合物储层水平井钻井井筒-储层耦合模型与井壁稳定性分析

高永海¹, 尹法领¹, 张党生², 孙小辉¹, 赵欣欣¹, 陈野^1,3, 孙宝江¹

1. 中国石油大学(华东)石油工程学院山东青岛 266580;
2. 中国石油集团渤海钻探工程有限公司井下作业分公司河北沧州 062552;
3. 中国海洋石油工程股份有限公司天津 300451

收稿日期:2022-07-09 修回日期:2023-03-25 出版日期:2023-07-25 发布日期:2023-08-08
通讯作者: 孙宝江,男,1963年11月生,1999年获北京大学流体力学专业博士学位,现为中国石油大学(华东)教授,主要从事海洋石油工程、井控、多相流动、油气井流体力学与工程研究。Email:sunbj1128@126.com
作者简介:高永海,男,1977年9月生,2008年获中国石油大学(华东)油气井工程专业博士学位,现为中国石油大学(华东)教授,主要从事海洋油气工程、井筒多相流研究。Email:upcgaoyh@126.com
基金资助:
国家自然科学基金项目（No.51876222，No.U21B2065-03）资助。

Wellbore-reservoir coupling model and borehole stability analysis of horizontal well drilling in hydrate reservoirs

Gao Yonghai¹, Yin Faling¹, Zhang Dangsheng², Sun Xiaohui¹, Zhao Xinxin¹, Chen Ye^1,3, Sun Baojiang¹

1. School of Petroleum Engineering, China University of Petroleum, Shandong Qingdao 266580, China;
2. Downhole Operation Branch, CNPC Bohai Drilling Engineering Company Limited, Hebei Cangzhou 062552, China;
3. CNOOC Offshore Oil Engineering Co., Ltd., Tianjin 300451, China

Received:2022-07-09 Revised:2023-03-25 Online:2023-07-25 Published:2023-08-08

摘要/Abstract

摘要： 在深水浅层水合物沉积层中钻探水平井是一项具有挑战性的工作。由于天然气水合物的相平衡特性，钻井液侵入引起的温度和压力扰动容易造成井周水合物分解，增加井壁失稳风险。通过考虑泥饼孔渗的动态变化、水合物相变、储层力学性质的动态变化以及井筒多相管流与储层多相渗流的热质传递耦合，提出了水合物储层钻井井筒-储层耦合模型。通过与实验数据对比表明，该模型能够有效表征水合物储层钻井液侵入引起的井周温度和压力等参数的变化。基于中国南海神狐海域SH2井位钻探数据，分析了水合物储层长水平剖面的钻井液侵入特征及井壁失稳风险。研究结果表明，随水平段长度延长，井筒环空温度和压力增大，钻井液侵入深度和井壁失稳风险增加。水平井井位部署在储层水合物饱和度高的区域有利于缓解钻井液侵入程度，并降低井壁失稳风险。进一步模拟了有无泥饼、不同钻井液入口温度和盐度对水平井趾端井壁稳定性的影响。泥饼在减小水合物饱和度低的区域钻井液侵入深度和井周屈服半径方面效果更明显。钻井液盐度的变化主要影响井周屈服情况，水合物地层钻井过程中为减小井周屈服区域和屈服程度，应采用较低盐度钻井液。在计算条件下，钻井液盐度小于4.2%比较有利于井壁稳定。在相同计算条件下，井位①和井位②趾端发生屈服的临界钻井液入口温度分别为22.39℃和22.24℃，水合物地层钻井过程中为避免井周出现屈服，钻井液入口温度应小于临界屈服温度。

关键词: 水合物储层, 无隔水管钻井, 水平井, 井筒-储层耦合, 井壁稳定性

Abstract: It is challenging to perform horizontal well drilling in deepwater shallow water hydrate sediment. Due to the phase equilibrium characteristics of natural gas hydrates, the temperature and pressure disturbance resulted from drilling fluid invasion can easily cause the decomposition of hydrates around the well, thus increasing the risk of borehole instability. To study this problem, this paper proposes a wellbore-reservoir coupling model. The model considers the dynamic changes in both mud cake porosity and permeability and reservoir mechanical properties, hydrate phase changes, and the heat-mass transfer coupling of wellbore multiphase pipe flow and reservoir multiphase seepage. The comparison with experimental data indicates that the model can effectively characterize the changes in parameters such as temperature and pressure around the well caused by the invasion of drilling fluid in hydrate reservoirs. Based on the drilling data of Well Site SH2 in Shenhu area of South China Sea, the paper analyzes the characteristics of drilling fluid invasion and the risk of borehole instability in the long horizontal section of hydrate reservoirs. The results show that with the extension of the horizontal section, the temperature and pressure in the wellbore annulus gradually go up, and the invasion depth of drilling fluid and the risk of borehole instability increase. The horizontal well location is deployed in the reservoir with high hydrate saturation, which helps alleviate the invasion degree of drilling fluid and reduce the risk of borehole instability. Further, the paper simulates the effect of mud cake, different drilling fluid inlet temperatures and salinities on the borehole stability at the toe of horizontal well. The results demonstrate that mud cake has a more obvious effect on reducing the drilling fluid invasion depth and the yield radius around the well in the low hydrate saturation area. The changes in drilling fluid salinity mainly affect the yield conditions around the well. It is suggested to use the drilling fluid with lower salinity, so as to reduce the yield area and yield degree around the well in the drilling process of hydrate formations. Under the calculation conditions in this study, the salinity of the drilling fluid lower than 4.2% is more conducive to borehole stability. Under the same calculation conditions, the critical drilling fluid inlet temperatures at the toe of well locations ① and ② are 22.39℃ and 22.24℃, respectively. To avoid yield around the well in the drilling process of hydrate formation, the drilling fluid inlet temperature should be lower than the critical yield temperature.

Key words: hydrate reservoir, riserless drilling, horizontal well, wellbore-reservoir coupling, borehole stability

中图分类号:

TE21

高永海, 尹法领, 张党生, 孙小辉, 赵欣欣, 陈野, 孙宝江. 水合物储层水平井钻井井筒-储层耦合模型与井壁稳定性分析[J]. 石油学报, 2023, 44(7): 1151-1166.

Gao Yonghai, Yin Faling, Zhang Dangsheng, Sun Xiaohui, Zhao Xinxin, Chen Ye, Sun Baojiang. Wellbore-reservoir coupling model and borehole stability analysis of horizontal well drilling in hydrate reservoirs[J]. Acta Petrolei Sinica, 2023, 44(7): 1151-1166.

参考文献

[1] 徐立涛, 何玉林, 石万忠, 等.琼东南盆地深水区天然气水合物成藏主控因素及模式[J].石油学报, 2021, 42(5):598-610.
XU Litao, HE Yulin, SHI Wanzhong, et al.Main controlling factors and patterns of gas hydrate accumulation in the deep water area of Qiongdongnan Basin[J].Acta Petrolei Sinica, 2021, 42(5):598-610.
[2] 卢海龙, 尚世龙, 陈雪君, 等.天然气水合物开发数值模拟器研究进展及发展趋势[J].石油学报, 2021, 42(11):1516-1530.
LU Hailong, SHANG Shilong, CHEN Xuejun, et al.Research progress and development direction of numerical simulator for natural gas hydrate development[J].Acta Petrolei Sinica, 2021, 42(11):1516-1530.
[3] 张智, 赵苑瑾, 张喆, 等.深水井开采制度对天然气水合物分解的影响[J].石油学报, 2022, 43(2):281-292.
ZHANG Zhi, ZHAO Yuanjin, ZHANG Zhe, et al.Influence of deep-water well production system on natural gas hydrate decomposition[J].Acta Petrolei Sinica, 2022, 43(2):281-292.
[4] MAKOGON Y F, HOLDITCH S A, MAKOGON T Y.Natural gas-hydrates-A potential energy source for the 21st Century[J].Journal of Petroleum Science and Engineering, 2007, 56(1/3):14-31.
[5] 刘争, 孙宝江, 王志远, 等.海域天然气水合物降压开采压力控制及气液流动特性[J].石油学报, 2022, 43(8):1173-1184.
LIU Zheng, SUN Baojiang, WANG Zhiyuan, et al.Pressure control and gas-liquid flow characteristics of offshore natural gas hydrate extraction by depressurization[J].Acta Petrolei Sinica, 2022, 43(8):1173-1184.
[6] YIN Faling, GAO Yonghai, CHEN Ye, et al.Numerical investigation on the long-term production behavior of horizontal well at the gas hydrate production site in South China Sea[J].Applied Energy, 2022, 311:118603.
[7] 孙嘉鑫, 张凌, 宁伏龙, 等.天然气水合物藏增产研究现状与展望[J].石油学报, 2021, 42(4):523-540.
SUN Jiaxin, ZHANG Ling, NING Fulong, et al.Research status and prospects of increasing production from gas hydrate reservoirs[J].Acta Petrolei Sinica, 2021, 42(4):523-540.
[8] YIN Faling, GAO Yonghai, ZHANG Heen, et al.Comprehensive evaluation of gas production efficiency and reservoir stability of horizontal well with different depressurization methods in low permeability hydrate reservoir[J].Energy, 2022, 239:122422.
[9] 杨进, 傅超, 刘书杰, 等.超深水浅层建井关键技术创新与实践[J].石油学报, 2022, 43(10):1500-1508.
YANG Jin, FU Chao, LIU Shujie, et al.Key technological innovation and practice of well construction in ultra-deepwater shallow Formations[J].Acta Petrolei Sinica, 2022, 43(10):1500-1508.
[10] 周世琛, 周博, 薛世峰, 等.基于离散元法的天然气水合物沉积物剪切带演化机理[J].石油学报, 2022, 43(1):101-111.
ZHOU Shichen, ZHOU Bo, XUE Shifeng, et al.Mechanisms of shear band propagation in gas hydrate-bearing sediments based on DEM[J].Acta Petrolei Sinica, 2022, 43(1):101-111.
[11] 高永海, 孙宝江, 赵欣欣, 等.水合物钻探井筒多相流动及井底压力变化规律[J].石油学报, 2012, 33(5):881-886.
GAO Yonghai, SUN Baojiang, ZHAO Xinxin, et al.Multiphase flow in wellbores and variation laws of the bottom hole pressure in gas hydrate drilling[J].Acta Petrolei Sinica, 2012, 33(5):881-886.
[12] 叶建良, 秦绪文, 谢文卫, 等.中国南海天然气水合物第二次试采主要进展[J].中国地质, 2020, 47(3):557-568.
YE Jianliang, QIN Xuwen, XIE Wenwei, et al.Main progress of the second gas hydrate trial production in the South China Sea[J].Geology in China, 2020, 47(3):557-568.
[13] FREIJ-AYOUB R, TAN C, CLENNELL B, et al.A wellbore stability model for hydrate bearing sediments[J].Journal of Petroleum Science and Engineering, 2007, 57(1/2):209-220.
[14] 李庆超, 程远方, 鲁钟强, 等.钻井液特性对近井地带水合物分解的影响[J].大庆石油地质与开发, 2019, 38(3):59-64.
LI Qingchao, CHENG Yuanfang, LU Zhongqiang, et al.Influences of the drilling fluid properties on the hydrate dissociation nearby the wellbore[J].Petroleum Geology & Oilfield Development in Daqing, 2019, 38(3):59-64.
[15] 郑明明, 蒋国盛, 刘天乐, 等.钻井液侵入时水合物近井壁地层物性响应特征[J].地球科学, 2017, 42(3):453-461.
ZHENG Mingming, JIANG Guosheng, LIU Tianle, et al.Physical properties response of hydrate bearing sediments near wellbore during drilling fluid invasion[J].Earth Science, 2017, 42(3):453-461.
[16] SUN Jiaxin, NING Fulong, LEI Hongwu, et al.Wellbore stability analysis during drilling through marine gas hydrate-bearing sediments in Shenhu area:a case study[J].Journal of Petroleum Science and Engineering, 2018, 170:345-367.
[17] SUN Jiaxin, NING Fulong, LIU Tianle, et al.Numerical analysis of horizontal wellbore state during drilling at the first offshore hydrate production test site in Shenhu area of the South China Sea[J].Ocean Engineering, 2021, 238:109614.
[18] LIAO Youqiang, WANG Zhiyuan, CHAO Mingzhe, et al.Coupled wellbore-reservoir heat and mass transfer model for horizontal drilling through hydrate reservoir and application in wellbore stability analysis[J].Journal of Natural Gas Science and Engineering, 2021, 95:104216.
[19] GAO Yonghai, SUN Baojiang, XU Boyue, et al.A wellbore/formation-coupled heat-transfer model in deepwater drilling and its application in the prediction of hydrate-reservoir dissociation[J].SPE Journal, 2017, 22(3):756-766.
[20] CHENG Wan, NING Fulong, SUN Jiaxin, et al.A porothermoelastic wellbore stability model for riserless drilling through gas hydrate-bearing sediments in the Shenhu area of the South China Sea[J].Journal of Natural Gas Science and Engineering, 2019, 72:103036.
[21] 张杰, 毛葛振, 李鑫, 等.无隔水管钻井液回收系统环空压力影响因素研究[J].石油机械, 2020, 48(12):60-66.
ZHANG Jie, MAO Gezhen, LI Xin, et al.Study on influencing factors of annular pressure in riser-free drilling fluid recovery system[J].China Petroleum Machinery, 2020, 48(12):60-66.
[22] 程远方, 沈海超, 李令东, 等.天然气水合物藏物性参数综合动态模型的建立及应用[J].石油学报, 2011, 32(2):320-323.
CHENG Yuanfang, SHEN Haichao, LI Lingdong, et al.Comprehensive and dynamical modeling for physical parameters of natural gas hydrate reservoirs and its application[J].Acta Petrolei Sinica, 2011, 32(2):320-323.
[23] LIAO Youqiang, SUN Xiaohui, SUN Baojiang, et al.Transient gas-liquid-solid flow model with heat and mass transfer for hydrate reservoir drilling[J].International Journal of Heat and Mass Transfer, 2019, 141:476-486.
[24] 吴俊晨, 范宜仁, 曹军涛, 等.基于大尺寸地层模型的砂岩储层油基钻井液侵入模拟[J].石油学报, 2019, 40(11):1407-1414.
WU Junchen, FAN Yiren, CAO Juntao, et al.Simulation of oil-based mud invasion in sandstone reservoir based on a large-sized Formation model[J].Acta Petrolei Sinica, 2019, 40(11):1407-1414.
[25] 范宜仁, 巫振观, 吴飞, 等.地层模块尺度钻井液侵入模拟与储集层电阻率剖面特征[J].石油勘探与开发, 2017, 44(6):989-996.
FAN Yiren, WU Zhenguan, WU Fei, et al.Simulation of mud invasion and analysis of resistivity profile in sandstone Formation module[J].Petroleum Exploration and Development, 2017, 44(6):989-996.
[26] 陈鹏, 王新海, 董樱花, 等.泥饼形成预测模型及影响因素分析[J].断块油气田, 2012, 19(4):522-525.
CHEN Peng, WANG Xinhai, DONG Yinghua, et al.Prediction model of filter cake buildup and its influential factor[J].Fault-Block Oil & Gas Field, 2012, 19(4):522-525.
[27] MORIDIS G J, KOWALSKY M B, PRUESS K.TOUGH+HYDRATE v1.2 user's manual:a code for the simulation of system behavior in hydrate-bearing geologic media[R].Berkeley:Lawrence Berkeley National Laboratory, 2012.
[28] DONG Lin, WAN Yizhao, LI Yanlong, et al.3D numerical simulation on drilling fluid invasion into natural gas hydrate reservoirs[J].Energy, 2022, 241:122932.
[29] KIM H C, BISHNOI P R, HEIDEMANN R A, et al.Kinetics of methane hydrate decomposition[J].Chemical Engineering Science, 1987, 42(7):1645-1653.
[30] SUN Xiang, LUO Tingting, WANG Lei, et al.Numerical simulation of gas recovery from a low-permeability hydrate reservoir by depressurization[J].Applied Energy, 2019, 250:7-18.
[31] SONG Benjian, CHENG Yuanfang, YAN Chuanliang, et al.Seafloor subsidence response and submarine slope stability evaluation in response to hydrate dissociation[J].Journal of Natural Gas Science and Engineering, 2019, 65:197-211.
[32] GAO Yonghai, CHEN Ye, WANG Zhiyuan, et al.Experimental study on heat transfer in hydrate-bearing reservoirs during drilling processes[J].Ocean Engineering, 2019, 183:262-269.
[33] CHEN Ye, SUN Baojiang, GAO Yonghai, et al.Pressure effects on heat transfer in hydrate-bearing deposit with drilling fluid invasion by lab simulation[J].International Journal of Green Energy, 2019, 16(10):770-777.
[34] 董胜伟, 王子健, 曹飞, 等.深水浅部水合物储层水平井井筒温度计算模型[J].特种油气藏, 2020, 27(5):157-161.
DONG Shengwei, WANG Zijian, CAO Fei, et al.Wellbore temperature calculation model for horizontal wells in shallow hydrate reservoirs in deep water[J].Special Oil and Gas Reservoirs, 2020, 27(5):157-161.
[35] 万义钊, 吴能友, 胡高伟, 等.南海神狐海域天然气水合物降压开采过程中储层的稳定性[J].天然气工业, 2018, 38(4):117-128.
WAN Yizhao, WU Nengyou, HU Gaowei, et al.Reservoir stability in the process of natural gas hydrate production by depressurization in the Shenhu area of the South China Sea[J].Natural Gas Industry, 2018, 38(4):117-128.
[36] WU Nengyou, ZHANG Haiqi, YANG Shengxiong, et al.Gas hydrate system of Shenhu area, Northern South China Sea:geochemical results[J].Journal of Geological Research, 2011, 2011:370298.

水合物储层水平井钻井井筒-储层耦合模型与井壁稳定性分析

Wellbore-reservoir coupling model and borehole stability analysis of horizontal well drilling in hydrate reservoirs

PDF

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]	杨立红, 朱超凡, 曾皓, 苏建政, 王益维, 武俊文, 陈旭东, 郭威. 油页岩自生热原位转化直井与水平井开发效果数值模拟——以鄂尔多斯盆地旬邑地区油页岩为例[J]. 石油学报, 2023, 44(8): 1333-1343.
[2]	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.
[3]	陈志明, Yu Wei, 石璐铭, 胡连博, 廖新维. 压裂水平井的多模式裂缝网络试井模型及参数评价——以吉木萨尔页岩油为例[J]. 石油学报, 2023, 44(10): 1706-1726.
[4]	李宁, 冯周, 武宏亮, 田瀚, 刘鹏, 刘英明, 刘忠华, 王克文, 徐彬森. 中国陆相页岩油测井评价技术方法新进展[J]. 石油学报, 2023, 44(1): 28-44.
[5]	唐雪平, 洪迪峰, 高文凯, 彭烈新, 杨宝斌. 七段制恒工具面角三维水平井轨道设计方法[J]. 石油学报, 2022, 43(9): 1315-1324.
[6]	史晓东, 孙灵辉, 战剑飞, 李斌会, 韩雪, 陆慧敏, 蒋成刚. 松辽盆地北部致密油水平井二氧化碳吞吐技术及其应用[J]. 石油学报, 2022, 43(7): 998-1006.
[7]	柳军, 杜智刚, 郭晓强, 殷腾, 俞海, 曹大勇. 水平井裸眼分段压裂完井管柱下入屈曲磨损预测模型及规律[J]. 石油学报, 2022, 43(11): 1632-1641.
[8]	胡松, 王敏, 刘伟男, 王兵. 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.
[9]	罗红文, 李海涛, 李颖, 汪凤, 向雨行, 蒋贝贝, 于皓. 低渗透气藏压裂水平井产出剖面与裂缝参数反演解释[J]. 石油学报, 2021, 42(7): 936-947.
[10]	郜益华, 张迎春, 杨宝泉, 李珂, 苑志旺, 康博韬, 张昕, 张旭, 陈国宁. 复杂断块油田跨断层水平井产能预测及分段长度优化方法——以西非A深水油田为例[J]. 石油学报, 2021, 42(7): 948-961.
[11]	李国欣, 吴志宇, 李桢, 陈强, 鲜成刚, 刘合. 陆相源内非常规石油甜点优选与水平井立体开发技术实践 ——以鄂尔多斯盆地延长组7段为例[J]. 石油学报, 2021, 42(6): 736-750.
[12]	张家强, 李士祥, 李宏伟, 周新平, 刘江艳, 郭睿良, 陈俊霖, 李树同. 鄂尔多斯盆地延长组7油层组湖盆远端重力流沉积与深水油气勘探——以城页水平井区长7₃小层为例[J]. 石油学报, 2021, 42(5): 570-587.
[13]	张胜飞, 孙新革, 苟燕, 张忠义, 王红庄, 周晓义, 解阳波, 吕柏林. 流量控制器在SAGD技术中的应用现状及思考[J]. 石油学报, 2021, 42(10): 1395-1404.
[14]	刘合, 匡立春, 李国欣, 王峰, 金旭, 陶嘉平, 孟思炜. 中国陆相页岩油完井方式优选的思考与建议[J]. 石油学报, 2020, 41(4): 489-496.
[15]	林日亿, 李端, 王新伟, 杨正大, 张立强. 水平井配汽三维物理模拟实验[J]. 石油学报, 2020, 41(12): 1649-1656.