超深高温高盐油藏膨胀乳液调驱技术研究与应用

doi:10.3969/j.issn.1006-6535.2024.06.016

特种油气藏 ›› 2024, Vol. 31 ›› Issue (6): 130-136.DOI: 10.3969/j.issn.1006-6535.2024.06.016

超深高温高盐油藏膨胀乳液调驱技术研究与应用

王雷^1,2,3, 叶荣俊⁴, 陈德瑞⁵, 许文俊^1,2,3, 张健鹏^1,2,3

1.长江大学石油工程学院,湖北武汉 430100;
2.低碳催化与二氧化碳利用全国重点实验室(筹),湖北武汉 430100;
3.油气钻采工程湖北省重点实验室,湖北武汉 430100;
4.中国石油塔里木油田分公司,新疆库尔勒 841000;
5.中国石油新疆油田分公司,新疆昌吉 831511

收稿日期:2023-07-06 修回日期:2024-09-05 出版日期:2024-12-25 发布日期:2025-01-22
通讯作者: 叶荣俊(1999—),男,助理工程师,2022年毕业于长江大学海洋油气工程专业,2024年毕业于该校油气田开发工程专业,获硕士学位,现从事提高采收率方面研究工作。
作者简介:王雷(1976—),男,教授,2000年毕业于西南石油学院石油工程专业,2005年毕业于西南石油大学石油工程专业,获博士学位,现从事非常规油藏增产、提高采收率技术方面的科研与教学工作。
基金资助:
国家自然科学基金面上项目“热敏聚合物纳米流体高温触变机制研究”(52074038 )

Research and Application of Expansion Lotion Profile Control and Flooding Technology for Ultra-deep High-temperature High-salinity Reservoirs

Wang Lei^1,2,3, Ye Rongjun^1,2,3, Chen Derui⁴, Xu Wenjun^1,2,3, Zhang Jianpeng^1,2,3

1. School of Petroleum Engineering,Yangtze University,Wuhan,Hubei 430100,China;
2. National Key Laboratory for Low-Carbon Catalysis and Carbon Dioxide Utilization (Preparatory),Wuhan,Hubei 430100,China;
3. Hubei Key Laboratory of Drilling and Production Engineering for Oil and Gas,Yangtze University,Wuhan,Hubei 430100,China;
4. PetroChina Xinjiang Oilfield Company,Changji,Xinjiang 831511,China

Received:2023-07-06 Revised:2024-09-05 Online:2024-12-25 Published:2025-01-22

摘要/Abstract

摘要： 塔里木盆地河道砂油藏属于超深高温高盐油藏,储层非均质性强,注入水易沿物性较好的河道中央窜进。针对该问题,利用可视化微观模型与非均质长岩心模型开展膨胀乳液调驱物理模拟研究,分析调驱特征与机理,优选调驱参数与段塞组合方式,并进行了现场应用。结果表明:河道砂油藏水驱后剩余油分布类型主要包括多分支式簇状、并联式喉道状、角隅式凹状、分散式孤滴状、连片式成块状等类型。膨胀乳液的调驱机理为深部运移+增黏提压、膨胀封堵+变形运移、剥离油膜+推拉拖拽。优化调驱参数为:注入量为0.30倍孔隙体积,质量分数为8%,乳液粒径为微米级,注入速度为0.52 mL/min,注入段塞组合为0.15倍孔隙体积小粒径乳液颗粒+0.15倍孔隙体积大粒径乳液颗粒。现场应用表明调驱效果显著,调驱井组日产油量最高升至26.4 t,含水率最低降至32.1%。该研究成果对具有强非均质性的超深高温高盐河道砂油藏剩余油挖潜具有重要意义。

关键词: 膨胀乳液, 调驱, 超深油藏, 高温, 高盐, 非均质, 河道砂

Abstract: The channel sand reservoirs in the Tarim Basin are categorized as ultra-deep,high-temperature,and high-salt reservoirs,characterized by strong reservoir heterogeneity.Injected water tends to channel along the central part of the channel with better physical properties.To address this issue,physical simulation studies on swelling emulsion flooding were conducted using visualized micro-models and heterogeneous long-core models.The study analyzed the characteristics and mechanisms of flooding,optimized the flooding parameters and slug combination methods,and implemented in-situ applications.The results indicate that the remaining oil distribution types after water flooding in channel sand reservoirs mainly include multi-branch cluster,parallel throat,corner concave,dispersed isolated droplet,and contiguous blocky types.The flooding mechanism of the swelling emulsion involves deep migration+viscosity increase and pressure enhancement,swelling plugging+deformation migration and stripping oil film+push-pull dragging.The optimized flooding parameters are as follows:injection volume is 0.30 times the pore volume,mass fraction is 8%,emulsion particle size is in the micrometer range,injection rate is 0.52 mL/min,and the injection slug combination is 0.15 times the pore volume of small-particle-size lotion particles+0.15 times the pore volume of large-particle-size emulsion particles.In-situ applications demonstrate significant flooding effects,with the daily oil production of the flooding well group increasing to a maximum of 26.4 t and the water content decreasing to a minimum of 32.1%.The research achievement is of great significance for tapping the remaining oil potential in ultra-deep,high-temperature,high-salt channel sand reservoirs with strong heterogeneity.

Key words: swellingemulsion, profile control and flooding, ultra-deep reservoir, high temperature, high salinity, heterogeneity, channel sand

中图分类号:

TE357

王雷, 叶荣俊, 陈德瑞, 许文俊, 张健鹏. 超深高温高盐油藏膨胀乳液调驱技术研究与应用[J]. 特种油气藏, 2024, 31(6): 130-136.

Wang Lei, Ye Rongjun, Chen Derui, Xu Wenjun, Zhang Jianpeng. Research and Application of Expansion Lotion Profile Control and Flooding Technology for Ultra-deep High-temperature High-salinity Reservoirs[J]. Special Oil & Gas Reservoirs, 2024, 31(6): 130-136.

参考文献

[1] 马新平.塔河油田YT2井区三叠系阿三段河道砂油藏描述[D].青岛:中国石油大学(华东),2015.
MA Xinping.Description of channel sand reservoir in A3 Member of Triassic in YT2 Well Area of Tahe Oilfield[D].Qingdao:China University of Petroleum (East China),2015.
[2] 梁宏刚,先伟,李文平.塔河油田超深层、薄储层、窄河道砂体识别与描述技术[J].地质科技情报,2015,34(5):180-183.
LIANG Honggang,XIAN Wei,LI Wenping.Identification and description technique for ultra-deep,thin reservoir,narrow channel sand,Tahe Oilfield[J].Geological Science and Technology Information,2015,34(5):180-183.
[3] 周海燕,张运来,何逸凡,等.新型交联聚合物微球调驱性能研究[J].西南石油大学学报(自然科学版),2022,44(6):175-182.
ZHOU Haiyan,ZHANG Yunlai,HE Yifan,et al.A study on profile control and flooding performance of new crosslinked polymer microspheres[J].Journal of Southwest Petroleum University (Science & Technology Edition),2022,44(6):175-182.
[4] 邹龙庆,何怀银,杨亚东,等.页岩气水平井暂堵球运移特性数值模拟研究[J].石油钻探技术,2023,51(5):156-166.
ZOU Longqing,HE Huaiyin,YANG Yadong,et al.Numerical simulation study on the migration characteristics of ball sealers in horizontal shale gas wells[J].Petroleum Drilling Techniques,2023,51(5):156-166.
[5] 葛罗.大庆油田萨北区块中渗透砂岩油藏凝胶调剖剂运移吸附实验研究[J].石油钻探技术,2023,51(3):119-125.
GE Luo.Experimental study on the migration and adsorption of gel profile control agent in medium-permeability sandstone in the Sabei Block of Daqing Oilfield[J].Petroleum Drilling Techniques,2023,51(3):119-125.
[6] 秦山.E31油藏二次开发阶段深部调驱技术研究[D].成都:西南石油大学,2017.
QIN Shan.Research on deep profile control and flooding technology in the secondary development stage of E31 Reservoir[D].Chengdu:SouthWest Petroleum University,2017.
[7] 李子豪.耐温耐盐自组装深部调驱体系流动机理研究[D].北京:中国石油大学(北京),2016.
LI Zihao.Study on flow mechanism of self-assembly deep profile control system with temperature and salt tolerance[D].Beijing:China University of Petroleum(Beijing),2016.
[8] 马珍福,邵现振,李刚,等.低渗油藏扩容压驱工艺技术在渤南油田的应用[J].非常规油气,2023,10(4):58-66.
MA Zhenfu,SHAO Xianzhen,LI Gang,et al.Application of dilatant pressure flooding technology in low permeability reservoir in Bonan Oilfield[J].Unconventional Oil & Gas,2023,10(4):58-66.
[9] 王金铸,龚雪峰,刘发根,等.高效自适应纳米乳液调驱技术在东北油田的应用[J].中国石油大学胜利学院学报,2021,35(4):50-57.
WANG Jinzhu,GONG Xuefeng,LIU Fagen,et al.Application of efficient adaptive nanoemulsion profile control technology in Northeast Oilfield[J].Journal of Shengli College China University of Petroleum,2021,35(4):50-57.
[10] 冯洋,杨国旗,李颖涛,等.基于砂岩岩心模型的微观水驱油渗流规律和剩余油赋存状态实验[J].非常规油气,2022,9(4):98-106.
FENG Yang,YANG Guoqi,LI Yingtao,et al.Experiment of microscopic water flooding seepage law and remaining oil occurrence state based on sandstone core model[J].Unconventional Oil & Gas,2022,9(4):98-106.
[11] 赵光,戴彩丽,由庆.冻胶分散体软体非均相复合驱油体系特征及驱替机理[J].石油勘探与开发,2018,45(3):464-473.
ZHAO Guang,DAI Caili,YOU Qing.Characteristics and displacement mechanisms of the dispersed particle gel soft heterogeneous compound flooding system[J].Petroleum Exploration and Development,2018,45(3):464-473.
[12] 王瑜.葡北油田纳微米微球深部调驱实验研究[D].大庆:东北石油大学,2013.
WANG Yu.Experimental study on deep profile control and flooding of nano-micron microspheres in Pubei Oilfield[D].Daqing:Northeast Petroleum University,2013.
[13] 张莉娜,任建华,胡春锋.常压页岩气立体开发特征及缝网干扰规律研究[J].石油钻探技术,2023,51(5):149-155.
ZHANG Lina,REN Jianhua,HU Chunfeng.Three-dimensional development characteristics and rracture network interference of atmospheric shale gas reservoir[J].Petroleum Drilling Techniques,2023,51(5):149-155.
[14] WEN Yiping,LAI Nanjun,DU Zhaofeng,et al.Application of orthogonal experiment method in foam flooding system composition and injection parameter optimization[J].Journal of Petroleum Science and Engineering,2021,204:108663.
[15] 吕杭,刘向斌,王庆国,等.黏度可控凝胶体系注入参数优化[J].新疆石油地质,2018,39(6):708-712.
LYU Hang,LIU Xiangbin,WANG Qingguo,et al.Injection parameter optimization of aviscosity-controlled gel system[J].Xinjiang Petroleum Geology,2018,39(6):708-712.

超深高温高盐油藏膨胀乳液调驱技术研究与应用

Research and Application of Expansion Lotion Profile Control and Flooding Technology for Ultra-deep High-temperature High-salinity Reservoirs

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]	吴鑫涛, 刘丽, 葛家旺, 冯潇飞, 胡成军, 肖尧, 宋林珂. 川中地区沙二一段古地貌对河道砂体发育的控制作用[J]. 特种油气藏, 2024, 31(6): 57-66.
[2]	任海鹰, 温书鹏, 侯建军, 孔令飞, 周泽妮, 郭志军. 基于低场核磁共振技术的煤储层孔裂隙分形模型适用性分析[J]. 特种油气藏, 2024, 31(5): 85-94.
[3]	张翔宇, 于田田, 李爱芬, 张仲平, 郑万刚, 初伟, 马爱青, 冯海顺. 低渗透夹层分布对正韵律非均质储层渗流规律的影响[J]. 特种油气藏, 2024, 31(5): 102-109.
[4]	丁伟俊, 张颖, 余维初, 丁飞, 杨世楚, 蒲洪兵, 段文博. 无黏土水基钻井液用超支化聚合物降滤失剂的合成及性能评价[J]. 特种油气藏, 2024, 31(4): 169-174.
[5]	熊钰, 熊锋, 冯棚鑫, 雷婷婷, 王羚鸿. 南海高温高压凝析气藏凝析水产出机理及产量预测方法[J]. 特种油气藏, 2024, 31(3): 116-122.
[6]	陈登亚, 游红娟, 陈昂, 郭文轩, 陈龙, 王旭生, 郭勇. 环烷基稠油火驱开发中焦炭生成规律及物理化学特征[J]. 特种油气藏, 2024, 31(3): 136-142.
[7]	程涛, 张祎, 宋颖智, 党杨斌, 贾志伟, 朱秀雨, 濮兰天, 邵黎明. 尕斯区块高温高盐油藏减氧空气驱泡沫体系配方优化[J]. 特种油气藏, 2023, 30(5): 121-126.
[8]	钟红利, 卓自敏, 张凤奇, 张佩, 陈玲玲. 鄂尔多斯盆地甘泉地区长7页岩油储层非均质性及其控油规律[J]. 特种油气藏, 2023, 30(4): 10-18.
[9]	刘刚, 曹涵, 朱爱国, 李宜强, 岳航. 稠油油藏多相协同蒸汽驱物理模拟实验[J]. 特种油气藏, 2023, 30(3): 131-136.
[10]	宋甲邦, 于海洋, 王崧臣, 刘进博, 胡疆, 汪洋, 赵力彬. 地层油气高温相态实验一致性检验方法[J]. 特种油气藏, 2023, 30(1): 93-99.
[11]	罗强, 李明, 李凯, 宁朦, 贺伟, 杜代军. 砂砾岩油藏原位乳化提高采收率实验研究[J]. 特种油气藏, 2023, 30(1): 100-106.
[12]	陈建勋. 深层高压碳酸盐岩气藏孔隙结构特征及衰竭开发规律[J]. 特种油气藏, 2022, 29(5): 80-87.
[13]	段波龙, 李垚银, 孙志雄, 常志勇, 党思思, 马艳清. 夏盐11井区剩余油分布特征与挖潜对策研究[J]. 特种油气藏, 2022, 29(4): 114-119.
[14]	李佳琦, 杨海彤, 葛兵, 杨笑, 姜汉桥, 孙明波. 一种耐高温交联淀粉钻井液降滤失剂的制备与评价[J]. 特种油气藏, 2022, 29(4): 164-168.
[15]	刘其成, 闫红星, 杨俊印, 程海清, 董晓东. 稠油油藏火驱取心井高温氧化区带识别方法[J]. 特种油气藏, 2022, 29(3): 76-83.