CO2响应型预交联凝胶颗粒的研制及性能评价

doi:10.3969/j.issn.1006-6535.2025.02.014

特种油气藏 ›› 2025, Vol. 32 ›› Issue (2): 110-116.DOI: 10.3969/j.issn.1006-6535.2025.02.014

CO₂响应型预交联凝胶颗粒的研制及性能评价

邓佳男¹, 郑昊¹, 高源鲜¹, 毕文良¹, 赵鸿浩¹, 贺甲元², 卢贵武¹, 张潇¹

1.中国石油大学(北京)理学院,北京 102249;
2.中国石化石油勘探开发研究院,北京 102206

收稿日期:2024-05-10 修回日期:2025-02-13 出版日期:2025-04-25 发布日期:2025-06-16
通讯作者: 张潇(1984—),女,副教授,博士生导师,2007年毕业于大连理工大学应用化学专业,2012年毕业于该校应用化学专业,获博士学位,现主要从事非常规油气开采化学药剂、工艺的研发,以及二氧化碳吸附分离封存和利用方面的研究工作。
作者简介:邓佳男(1995—),男,2018年毕业于北京化工大学高分子材料与工程专业,现为中国石油大学(北京)能源物理科学与技术专业在读博士研究生,主要从事油田化学及提高采收率方面的研究工作。
基金资助:
国家自然科学基金企业创新发展联合基金集成项目“复杂环境下水泥环全生命周期密封理论与控制方法”(U22B6003-01)

Development and performance evaluation of CO₂-responsive preformed particle gel

DENG Jia′nan¹, ZHENG Hao¹, GAO Yuanxian¹, BI Wenliang¹, ZHAO Honghao¹, HE Jiayuan², LU Guiwu¹, ZHANG Xiao¹

1. College of Science of China University of Petroleum (Beijing), Beijing 102249, China;
2. Sinopec Petroleum Exploration and Production Research Institute, Beijing 102206, China

Received:2024-05-10 Revised:2025-02-13 Online:2025-04-25 Published:2025-06-16

摘要/Abstract

摘要： 针对在CO₂驱替过程中,地层水形成酸性环境后导致凝胶颗粒(PPG)降解脱水的问题,以N,N-二甲基丙烯酰胺(DMAA)、乙烯基咪唑(VIZ)和N-乙烯基吡咯烷酮(NVP)3种CO₂响应型单体为主要原料,添加有机交联剂N,N-亚甲基双丙烯酰胺(MBA)和纳米交联剂VSNPs,通过水溶液聚合的方法制备了一种具有三重交联网络的CO₂响应型凝胶颗粒(CR-PPG),并开展了体系优化、CO₂响应性测试、电导率测试、流变测试和岩心驱替实验。研究表明:单体DMAA、VIZ、NVP的最佳配比为2∶2∶1;CR-PPG具有优异的CO₂响应特性和力学强度,其在CO₂驱替过程中具有高效的封堵调剖能力;CR-PPG的CO₂响应机理为其结构中叔胺基团在CO₂酸性环境下的质子化效应。该研究为CO₂驱替过程中的调堵作业提供了重要依据。

关键词: CO₂驱, 非均质储层, 三重交联, 预交联凝胶颗粒, 纳米交联剂

Abstract: In response to the issue of preformed particle gel (PPG) degradation and dehydration caused by the acidic environment formed during CO₂ flooding,a CO₂-responsive preformed particle gel (CR-PPG) with a triple crosslinked network was prepared using N,N-dimethylacrylamide (DMAA),vinylimidazole (VIZ),and N-vinylpyrrolidone (NVP) as the main raw materials,along with the organic crosslinking agent N,N′-methylenebisacrylamide (MBA) and the nano-crosslinking agent vinyl silica nanoparticles (VSNPs),through aqueous solution polymerization.System optimization,CO₂ responsiveness testing,conductivity testing,rheological testing,and core displacement experiments were conducted.The study shows that the optimal ratio of the monomers DMAA,VIZ,and NVP was found to be 2∶2∶1.The CR-PPG exhibited excellent CO₂ responsiveness and mechanical strength,demonstrating efficient plugging and profile control capabilities during CO₂ flooding.The CO₂ responsiveness mechanism of CR-PPG is attributed to the protonation effect of the tertiary amine groups in its structure under CO₂ acidic conditions.This study provides an important basis for plugging and profile control operations during CO₂ flooding.

Key words: CO₂ flooding, non-homogeneous reservoir, triple crosslinking, preformed particle gel, nano-crosslinking agent

中图分类号:

TE39

邓佳男, 郑昊, 高源鲜, 毕文良, 赵鸿浩, 贺甲元, 卢贵武, 张潇. CO₂响应型预交联凝胶颗粒的研制及性能评价[J]. 特种油气藏, 2025, 32(2): 110-116.

DENG Jia′nan, ZHENG Hao, GAO Yuanxian, BI Wenliang, ZHAO Honghao, HE Jiayuan, LU Guiwu, ZHANG Xiao. Development and performance evaluation of CO₂-responsive preformed particle gel[J]. Special Oil & Gas Reservoirs, 2025, 32(2): 110-116.

参考文献

[1] LIU Dexin,XU Jiaju,ZHAO Han,et al.Nanoemulsions stabilized by anionic and non-ionic surfactants for enhanced oil recovery in ultra-low permeability reservoirs:performance evaluation and mechanism study[J].Colloids and Surfaces A:Physicochemical and Engineering Aspects,2022,637(1):128235
[2] WEI Zijian,SHENG Jiaping.Study of thermally-induced enhancement in nanopores,microcracks,porosity and permeability of rocks from different ultra-low permeability reservoirs[J].Journal of Petroleum Science and Engineering,2022,209(1):109896.
[3] 王达.堵水调剖在低效水驱油藏中的发展与应用[J].化工设计通讯,2024,50(5):33-38.
WANG Da.Development and application of water shutoff and profile control in low efficiency water drive reservoir[J].Chemical Engineering Design Communications,2024,50(5):33-38.
[4] 唐子翔,周莅康,杜若彤,等.现阶段油藏堵水调剖剂研究现状[J].山东化工,2024,53(2):97-98.
TANG Zixiang,ZHOU Linkang,DU Ruotong,et al.Research status of reservoir water plugging and profile control agents at the current stage[J].Shandong Chemical Industry,2024,53(2),97-98.
[5] 张换果,李岸涛,李希元,等.低渗透砂岩油藏水驱规律及稳产对策研究[J].石油化工应用,2023,42(3):81-84.
ZHANG Huanguo,LI Antao,LI Xiyuan,et al.Study on the water flooding laws and stable production strategies of low-permeability sandstone reservoirs[J].Petrochemical Industry Application,2023,42(3):81-84.
[6] 夏惠芬,徐勇.低渗透油藏CO₂驱油机理及应用现状研究[J].当代化工,2017,46(3):471-474.
XIA Huifen,XU Yong.Study on the mechanism and application of CO₂ flooding in low permeability reservoirs[J].Contemporary Chemical Industry,2017,46(3):471-474.
[7] 罗二辉,胡永乐,李保柱,等.中国油气田注CO₂提高采收率实践[J].特种油气藏,2013,20(2):142-151.
LUO Erhui,HU Yongle,LI Baozhu,et al.Practices of CO₂ EOR in China[J].Special Oil & Gas Reservoirs,2013,20(2):142-151.
[8] 于洪敏,王友启,黄凯,等.低渗透砂岩油藏水驱微观剩余油评价方法与发展方向[J].油气与新能源,2024,36(5):17-27.
YU Hongmin,WANG Youqi,HUANG Kai,et al.Evaluation methods and development directions of microscopic remaining oil in water-flooded low-permeability sandstone reservoirs[J].Petroleum and New Energy,2024,36(5):17-27.
[9] 陈祖华,孙雷,杨正茂,等.苏北低渗透油藏CO₂驱油开发模式探讨[J].西南石油大学学报(自然科学版),2020,42(3):97-106.
CHEN Zuhua,SUN Lei,YANG Zhengmao,et al.Development model of CO₂ flooding in Subei low-permeability reservoirs[J].Journal of Southwest Petroleum University (Natural Science Edition),2020,42(3):97-106.
[10] 王振川,钱钰,折印楠,等.CO₂化学驱在提高传统天然气采收率中的应用与优化[J].当代化工,2025,54(2):270-274.
WANG Zhenchuan,QIAN Yu,ZHE Yinnan,et al.Application and optimization of CO₂ chemical flooding in enhanced conventional natural gas recovery[J].Contemporary Chemical Industry,2025,54(2):270-274.
[11] 汤瑞佳,陈龙龙,江绍静,等.低渗透油藏强化CO₂/水交替注入驱油效果实验研究[J].非常规油气,2024,11(4):70-78.
TANG Ruijia,CHEN Longlong,JIANG Shaojing,et al.Experimental study on enhanced oil recovery by CO₂/water alternating injection in low-permeability reservoirs[J].Unconventional Oil & Gas,2024,11(4):70-78.
[12] 李阳,黄文欢,金勇,等.双碳愿景下中国石化不同油藏类型CO₂驱提高采收率技术发展与应用[J].油气藏评价与开发,2021,11(6):793-804.
LI Yang,HUANG Wenhuan,JIN Yong,et al.Different reservoir types of CO₂ flooding in Sinopec EOR technology development and application under "dual carbon"vision[J].Reservoir Evaluation and Development,2021,11(6):793-804.
[13] 樊康杰,王健,魏峰,等.陆相砂岩油藏高含水阶段驱油效率再认识[J].油气地质与采收率,2023,30(3):128-135.
FAN Kangjie,WANG Jian,WEI Feng,et al.Re-understanding of oil displacement efficiency of continental sandstone reservoir at high water cut stage[J].Petroleum Geology and Recovery Efficiency,2023,30(3):128-135.
[14] 李恋,吴亚红,种珊,等.地层各向异性对CO₂在含水层中迁移转化的影响[J].科学技术与工程,2022,8(2):22-26.
LI Lian,WU Yahong,ZHONG Shan,et al.Effect of formation anisotropy on CO₂ migration and transformation in shallow aquifers[J].Science Technology and Engineering,2022,8(2):22-26.
[15] 张蒙,赵凤兰,吕广忠,等.气水交替改善CO₂驱油效果的适应界限[J].油田化学,2020,37(2):279-286.
ZHANG Meng,ZHAO Fenglan,LYU Guangzhong,et al.Experimental study on the adaptation limit of WAG to improve CO₂ flooding effect[J].Oilfield Chemistry,2020,37(2):279-286.
[16] ZHAO Guang,DAI Caili,ZHANG Yanhui,et al.Enhanced foam stability by adding comb polymer gel for in-depth profile control in high temperature reservoirs[J].Colloid Surface A,2015,482(1):115-124.
[17] 刘斌,王彦玲,梁雷.超临界二氧化碳增稠剂研究现状与展望[J].应用化工,2020,49(12):3120-3125.
LIU Bin,WANG Yanling,LIANG Lei.Current status and prospects of supercritical carbon dioxide thickeners[J].Applied Chemical Industry,2020,49(12):3120-3125.
[18] 李宛珊,王健,任振宇,等.低渗透油藏二氧化碳气溶性泡沫控制气窜实验研究[J].特种油气藏,2019,26(5):136-141.
LI Wanshan,WANG Jian,REN Zhenyu,et al.Gas-channeling control experiment with carbon dioxide gas-soluble foam in low-permeability oil reservoir[J].Special Oil & Gas Reservoirs,2019,26(5):136-141.
[19] 李松岩,马芮,党法强.基于高干度泡沫实验的非均质咸水层CO₂封存能力分析[J].天然气工业,2024,44(4):46-55.
LI Songyan,MA Rui,DANG Faqiang.Experimental study on CO₂ storage capacity of high-dryness foam in heterogeneous saline aquifers[J].Natural Gas Industry,2024,44(4):46-55.
[20] SUN Xindi,LONG Yifu,BAI Baojun,et al.Evaluation and plugging performance of carbon dioxide-resistant particle gels for conformance control[J].SPE Journal,2020,25(4):1745-1760.
[21] SUN Xindi,BAI Baojun.Dehydration of polyacrylamide-based super-absorbent polymer swollen in different concentrations of brine under CO₂ conditions[J].Fuel,2017,210:32-40.
[22] JIANG Haizhuang,YANG Hongbin,PAN Ruosheng,et al.Performance and enhanced oil recovery efficiency of an acid-resistant polymer microspheres of anti-CO₂ channeling in low-permeability reservoirs[J].Petroleum Science,2024,21(4):2420-2432.
[23] MOUSAVI Moghadam Asefe,SEFTI Mohsen Vafaie,SALEHI Mahsa Baghban,et al.Preformed particle gel:evaluation and optimization of salinity and pH on equilibrium swelling ratio[J].Journal of Petroleum Exploration and Production Technology,2012,2(1):85-91.
[24] BRATTEKÅS Bergit,SERIGHT Randall.A review of polymer gel utilization in carbon dioxide flow control at the core and field scale[J].SPE journal,2023,28(6):3291-3307.
[25] PU Wanfen,DU Daijun,FAN Huancai,et al.CO₂-responsive preformed gel particles with interpenetrating networks for controlling CO₂ breakthrough in tight reservoirs[J].Colloids and Surfaces A:Physicochemical and Engineering Aspects,2021,613(1):126065.
[26] DENG Jianan,LIAN Haoyu,ZHUANG Yuan,et al.Synthesis and performance evaluation of multi-crosslinked preformed particle gels with ultra-high strength and high-temperature and high-salinity resistance for conformance control[J].Fuel,2024,357:130027.
[27] CIPRIANO B H,BANIK S J,SHARMA R,et al.Superabsorbent hydrogels that are robust and highly stretchable[J].Macromolecules,2014,47(13):4445-4452.

CO₂响应型预交联凝胶颗粒的研制及性能评价

Development and performance evaluation of CO₂-responsive preformed particle gel

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]	孟庆春, 何刚, 郭发军, 李华斌, 王莉. 支化预交联凝胶颗粒提高采收率机理实验[J]. 特种油气藏, 2023, 30(5): 105-112.
[2]	孙挺, 史海东, 郑建军, 钟小刚, Watheq J, Al-Mudhafar. 页岩储层CO₂驱沥青质沉淀特征及影响因素分析[J]. 特种油气藏, 2022, 29(2): 83-90.
[3]	孙大龙, 张广东, 彭旭, 敬豪, 吕华, 任超峰, 王宁. CO₂驱气溶性降混剂提高采收率机理实验[J]. 特种油气藏, 2022, 29(1): 134-140.
[4]	周翔, 周丹, 邓家胜, 邓靖译, Ray Rui, 姜哲人. 超临界CO₂驱提高致密油藏采收率实验研究[J]. 特种油气藏, 2021, 28(3): 118-123.
[5]	石立华, 王维波, 王成俊, 陈龙龙. 基于裂缝径向流物理模型的CO₂驱注入方式研究[J]. 特种油气藏, 2021, 28(3): 112-117.
[6]	高冉, 吕成远, 伦增珉, 王锐. 二氧化碳驱替与埋存一体化数值模拟[J]. 特种油气藏, 2021, 28(2): 102-107.
[7]	雷欣慧, 郑自刚, 余光明, 张康. 特低渗油藏水驱后二氧化碳气水交替驱见效特征[J]. 特种油气藏, 2020, 27(5): 113-117.
[8]	李承龙, 迟博. 一种新型二氧化碳驱特征曲线的建立与应用 [J]. 特种油气藏, 2020, 27(2): 98-102.
[9]	李承龙. 特低渗透油藏二氧化碳驱气窜影响因素及规律[J]. 特种油气藏, 2018, 25(3): 82-.
[10]	王雅春，赵振铎. 压力对二氧化碳驱油效果影响的实验研究[J]. 特种油气藏, 2017, 24(4): 132-.
[11]	李志鹏，卜丽侠. 二氧化碳驱油及封存过程中的地质安全界限体系[J]. 特种油气藏, 2017, 24(2): 141-.
[12]	程杰成，刘春林，汪艳勇，白文广，牟广山. 特低渗透油藏二氧化碳近混相驱试验研究[J]. 特种油气藏, 2016, 23(6): 64-.
[13]	李军，张军华，谭明友，曲志鹏，崔世凌. 高89-4井区二氧化碳驱波及面地震预测[J]. 特种油气藏, 2016, 23(6): 40-.
[14]	江绍静，王维波，黄春霞，杨红，余华贵. 改性淀粉凝胶体系控制CO₂窜逸技术研究[J]. 特种油气藏, 2016, 23(4): 136-.
[15]	蒲万芬，孙波帅，李一波，郭臣，刘元爽. 塔河缝洞型超稠油油藏二氧化碳驱实验研究[J]. 特种油气藏, 2016, 23(4): 123-.