高碳气置换高烃气实验及机理评价

doi:10.3969/j.issn.1006-6535.2023.06.015

特种油气藏 ›› 2023, Vol. 30 ›› Issue (6): 114-119.DOI: 10.3969/j.issn.1006-6535.2023.06.015

高碳气置换高烃气实验及机理评价

崔书姮^1,2, 孔杰¹, 鲁瑞彬³, 郭敏灵^1,2, 王誉钧¹, 钟鸿鹏¹

1.中海油能源发展股份有限公司工程技术湛江分公司,广东湛江 524057;
2.广东省海上高温高压油气藏勘探开发企业重点实验室,广东湛江 524057;
3.中海石油(中国)有限公司湛江分公司,广东湛江 524057

收稿日期:2022-11-30 修回日期:2023-09-05 出版日期:2023-12-25 发布日期:2024-01-19
作者简介:崔书姮(1982—),女,高级工程师,2005年毕业于大庆石油学院石油工程专业,2008年毕业于中国石油大学(北京)油气田开发专业,获硕士学位,现主要从事油气田开发实验评价工作。
基金资助:
国家自然科学基金“海上高温高压低渗透储层渗流流固耦合机理及表征方法研究”(U22B2073)

Experiment on Replacement of High Carbon Gas with High Hydrocarbon Gas and Its Mechanism Evaluation

Cui Shuheng^1,2, Kong Jie¹, Lu Ruibin³, Guo Minling^1,2, Wang Yujun¹, Zhong Hongpeng¹

1. Zhanjiang Engineering and Technology Branch, CNOOC Energy Development Co., Ltd., Zhanjiang, Guangdong 524057, China;
2. Guangdong Provincial Key Laboratory of Offshore High Temperature and High Pressure Oil and Gas Reservoir Exploration and Development Enterprise, Zhanjiang, Guangdong 524057, China;
3. CNOOC (China) Zhanjiang Company, Zhanjiang, Guangdong 524057, China

Received:2022-11-30 Revised:2023-09-05 Online:2023-12-25 Published:2024-01-19

摘要/Abstract

摘要： 中国南海西部某气田深层气组为高碳气藏,浅层气组为高烃气藏。为有效提高高烃气藏采收率,增大经济效益,开展高碳气置换高烃气机理室内实验,研究高碳气置换高烃气后气体组分及溶解度变化情况,以及置换后高烃气藏提高采收率的效果及影响因素结果表明:使用高碳气替换高烃气后,高碳气能够置换地层束缚水中的高烃气,游离CH₄增加,在低注高采、倾角较大和岩心高渗透率等储层条件下进行长岩心驱替,CH₄累计采出程度更高,采出程度可提高4.5%。该研究可对中国高烃气藏高效开发、高碳气藏中CO₂埋存方式评价提供理论参考。

关键词: 高烃气藏, 高烃气提高采收率, 溶解度, 置换机理, 南海西部气田

Abstract: The deep gas group of a certain gas field in the western part of South China Sea is a high-carbon gas reservoir, and the shallow gas group is a high-hydrocarbon gas reservoir. In order to effectively improve the recovery rate of high-hydrocarbon gas reservoirs and increase the economic benefits, the indoor experiments of replacing high-hydrocarbon gas with high-carbon gas were carried out, and the mechanism evaluation method was adopted, to obtain the changes of gas components and solubility after the replacement of high-hydrocarbon gas with high-carbon gas, as well as the effect of the high-hydrocarbon reservoirs on the recovery rate after the replacement and the influencing factors, and the study results were applied to the evaluation of the mine pilot experiments and the prediction of the effect of CO₂ storage in high-carbon gas reservoirs of a certain gas field in western part of South China Sea. The results show that after the replacement of the high-hydrocarbon gas with the high-carbon gas, the high-carbon gas can displace the high-hydrocarbon gas in formation irreducible water, free CH₄ increases, and the long core replacement was carried out under reservoir conditions such as low-injection and high-production, large dip and high permeability of the core, with a higher cumulative CH₄ recovery degree of up to 4.5%. This study provides theoretical references for the efficient development of high-hydrocarbon gas reservoirs in China , and the evaluation of CO₂ storage mode in high-carbon gas reservoirs.

Key words: high-hydrocarbon gas reservoirs, high-hydrocarbon gas enhanced recovery, solubility, replacement mechanism, gas field in the western part of South China Sea

中图分类号:

TE377

崔书姮, 孔杰, 鲁瑞彬, 郭敏灵, 王誉钧, 钟鸿鹏. 高碳气置换高烃气实验及机理评价[J]. 特种油气藏, 2023, 30(6): 114-119.

Cui Shuheng, Kong Jie, Lu Ruibin, Guo Minling, Wang Yujun, Zhong Hongpeng. Experiment on Replacement of High Carbon Gas with High Hydrocarbon Gas and Its Mechanism Evaluation[J]. Special Oil & Gas Reservoirs, 2023, 30(6): 114-119.

参考文献

[1] 范鸿澈,黄志龙,袁剑,等.高温高压条件下甲烷和二氧化碳溶解度实验[J].中国石油大学学报(自然科学版),2011,35(2):5-7.
FAN Hongche,HUANG Zhilong,YUAN Jian,et al.Methane and carbon dioxide solubility test under high temperature and high pressure conditions[J].Journal of China University of Petroleum(Edition of Natural Sciences),2011,35(2):5-7.
[2] 付晓泰,卢双舫,王振平,等.天然气组分的溶解特征及其意义[J].地球化学,1997,26(3):60-61.
FU Xiaotai,LU Shuangfang,WANG Zhenping,et al.Dissolving character for the components of natural gas and its significance[J].Geochimica,1997,26(3):60-61.
[3] 高军,郑大庆,郭天民.高温高压下气体在电解质水溶液中的溶解度[J].化工学报,2000,51(4):540-541.
GAO Jun,ZHENG Daqing,GUO Tianmin.Gas solubility in aqueous electrolyte under high pressure and high temperature[J].CIESC Journal,2000,51(4):540-541.
[4] SIM S S K,TURTA A T,SINGHAL A K,et al.Enhanced gas recovery:factors affecting gas-gas displacement efficiency[J].Journal of Candian Petroleum Techology,2009,48(8):49-55.
[5] TURTA A T,SIM S S,SINGHAL A K,et al.Basic investigations on enhanced gas recovery by gas-gas displacement[J].Journal of Canadian Petroleum Technology,2008,47(10):39-44.
[6] 汤勇,张超,杜志敏,等.CO₂驱提高气藏采收率及埋存实验[J].油气藏评价与开发,2015,5(5):34-40.
TANG Yong,ZHANG Chao,DU Zhimin,et al.Experiments on enhancing gas recovery and sequestration by CO₂ displacement[J].Reservoir Evaluation and Development,2015,5(5):34-40.
[7] 史云清,贾英,潘伟义,等.低渗致密气藏注超临界CO₂驱替机理[J].石油与天然气地质,2017,38(3):610-616.
SHI Yunqing,JIA Ying,PAN Weiyi,et al.Mechanism of supercritical CO₂ flooding in low-permeability tight gas reservoirs[J].Oil & Gas Geology,2017,38(3):610-616.
[8] 申永良,李维芳.系统总压力对气相反应平衡组成的影响[J].化学工程师,1998,68(5):36-37.
SHEN Yongliang,LI Weifang.Influence of total system pressure on the equilibrium composition of gas-phase reactions[J].Chemical Engineer,1998,68(5):36-37.
[9] 程付启,金强,林会喜,等.天然气溶解过程中组分分馏模型及其应用[J].高校地质学报,2008,14(1):123-124.
CHENG Fuqi,JIN Qiang,LIN Huixi,et al.Dissolution fractionation model of natural gas components and its application[J].Geological Journal of China Universities,2008,14(1):123-124.
[10] 傅献彩,沈文霞,姚天扬,等.物理化学[M].北京:高等教育出版社,2005:18-19,225-226.
FU Xiancai,SHEN Wenxia,YAO Tianyang,et al.Physical chemistry[M].Beijing:Higher Education Press,2005:18-19,225-226.
[11] 付晓泰,王振平,卢双舫.气体在水中的溶解机理及溶解度方程[J].中国科学 B辑:化学,1996,26(2):127-129.
FU Xiaotai,WANG Zhenping,LU Shuangfang.Mechanism of gas dissolution in water and solubility equation[J].Science in China Series B:Chemistry,1996,26(2):127-129.
[12] 中华人民共和国国家质量监督检验检疫总局.油气藏流体物性分析方法:GB/T 26981—2021 [S].北京:中国标准出版社,2021:9-13.
General Administration of Quality Supervision,Inspection and Quarantine of the People's Republic of China.Analysis method for reservoir fluid physical properties:GB/T 26981-2021[S].Beijing:Standards Press of China,2021:9-13.
[13] 郝石生,张振英.天然气在地层水中的溶解度变化特征及地质意义[J].石油学报,1993,14(2):16-18.
HAO Shisheng,ZHANG Zhenying.The characteristic of the solubility of natural gas in formation waters and it's geological significance[J].Acta Petrolei Sinica,1993,14(2):16-18.
[14] 薛海涛,刘灵芝,周丽华,等.天然气在大庆原油中的溶解度[J].大庆石油学院学报,2001,25(2):12-15.
XUE Haitao,LIU Lingzhi,ZHOU Lihua,et al.Solubility of natural gas in Daqing crude oil[J].Journal of Daqing Petroleum Institute,2001,25(2):12-15.
[15] 张燕玉,何鲁平.天然气驱长岩心室内实验研究[J].实验力学,2007,22(2):162-163.
ZHANG Yanyu,HE Luping.A study on long-core experiment of natural gas driving[J].Journal of Experimental Mechanics,2007,22(2):162-163.
[16] 张鹏豹,李凡异,杨童,等.AVO技术在二连盆地吉尔嘎朗图凹陷低煤阶煤层气预测中的应用[J].大庆石油地质与开发,2021,40(1):129-136.
ZHANG Pengbao,LI Fanyi,YANG Tong,et al.Application of AVO technique in the prediction of low-rank CBM in Jiergalangtu Sag of Erlian Basin[J].Petroleum Geology & Oilfield Development in Daqing,2021,40(1):129-136.
[17] 薛辉,韩春元,朱萍,等.金坛储气库阜宁组四段含盐层系沉积特征及成盐模式[J].吉林大学学报(地球科学版), 2022, 52(2):363-381.
Xue Hui,Han Chunyuan,Zhu Ping,et al.Sedimentary characteristics and salt-forming model of salt-bearing Sequence of Member 4 of Funing Formation in Jintan Gas Storage[J].Journal of Jilin University(Earth Science Edition),2022,52(2):363-381.
[18] 毛永强.孤家子气田储气库关键指标设计优化技术[J].大庆石油地质与开发,2021,40(1):96-102.
MAO Yongqiang.Design optimization technology of key indicators for the gas storage in Gujiazi Gas Field[J]. Petroleum Geology & Oilfield Development in Daqing,2021,40(1):96-102.
[19] 李云,文孟刚,高秀峰,等.多因素影响下多孔介质中气体突破渗透率衰减模型[J].天然气工业,2021,41(9):75-86.
LI Yun,WEN Menggang,GAO Xiufeng,et al.Attenuation model of gas breakthrough permeability in porous media under the influence of multiple factors[J].Natural Gas Industry,2021,41(9):75-86.
[20] 王奥,李菊花,郑斌.多孔介质中凝析气相态特征[J].大庆石油地质与开发,2021,40(1):61-67.
WANG Ao,LI Juhua,ZHENG Bin.Study on the phase behaviors of the condensate gas in porous media[J].Petroleum Geology & Oilfield Development in Daqing,2021,40(1):61-67.
[21] 齐桂雪,李中超,刘平,等.凝析气藏气驱二维填砂物理模型实验研究[J].断块油气田,2022,29(2):164-170.
QI Guixue,LI Zhongchao,LIU Ping,et al.An experimental study of two-dimensional sand filling physical model for gas flooding in condensate gas reservoir[J].Fault-Block Oil & Gas Field,2022,29(2):164-170.
[22] 江同文,王锦芳,王正茂,等.地下储气库与天然气驱油协同建设实践与认识[J].天然气工业,2021,41(9):66-74.
JIANG Tongwen, WANG Jinfang, WANG Zhengmao,et al.Practice and understanding of collaborative construction of underground gas storage and natural gas flooding[J]. Natural Gas Industry,2021,41(9):66-74.
[23] 马新华,窦立荣,王红岩,等.天然气驱动可持续发展的未来——第28届世界天然气大会综述[J].天然气工业,2022,42(7):1-6.
MA Xinhua,DOU Lirong,WANG Hongyan,et al.A sustainable future—powered by gas: a brief summary from the 28th World Gas Conference (WGC)[J].Natural Gas Industry,2022,42(7):1-6.

高碳气置换高烃气实验及机理评价

Experiment on Replacement of High Carbon Gas with High Hydrocarbon Gas and Its Mechanism Evaluation

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