Experimental study on influence of non-condensable gas on steam quality

doi:10.7623/syxb202512009

Acta Petrolei Sinica ›› 2025, Vol. 46 ›› Issue (12): 2332-2342,2426.DOI: 10.7623/syxb202512009

• OIL FIELD DEVELOPMENT • Previous Articles Next Articles

Experimental study on influence of non-condensable gas on steam quality

Guo Erpeng^1,2, Mao Xiaopeng³, He Jitao⁴, Jiang Xu⁴, Zhang Kanyi⁴, Liu Zongjian³, Ren Shuowen³, Wang Xinwei³

1. PetroChina Research Institute of Petroleum Exploration and Development, Beijing 100083, China;
2. State Key Laboratory of Enhanced Oil Recovery, Beijing 100083, China;
3. College of New Energy, China University of Petroleum, Shandong Qingdao 266580, China;
4. PetroChina (Xinjiang)Petroleum Engineering Co., Ltd., Xinjiang Karamay 834000, China

Received:2025-06-23 Revised:2025-09-30 Online:2025-12-25 Published:2026-01-09

非凝结气体掺混对蒸汽干度影响实验

郭二鹏^1,2, 毛晓鹏³, 贺吉涛⁴, 蒋旭⁴, 张侃毅⁴, 刘宗建³, 任铄文³, 王新伟³

1. 中国石油勘探开发研究院北京 100083;
2. 提高油气采收率全国重点实验室北京 100083;
3. 中国石油大学(华东)新能源学院山东青岛 266580;
4. 中油(新疆)石油工程有限公司新疆克拉玛依 834000

通讯作者: 王新伟,男,1984年1月生,2019年获中国科学院工程热物理研究所博士学位,现为中国石油大学(华东)高级实验师,主要从事热力采油、能源高效清洁利用研究工作。Email:wangxw@upc.edu.cn
作者简介:郭二鹏,男,1983年8月生,2008年获中国石油勘探开发研究院硕士学位,现为中国石油勘探开发研究院高级工程师,主要从事注气提高采收率技术和稠油提高采收率技术研究工作。Email:guoerpeng@petrochina.com.cn
基金资助:
中国石油天然气股份有限公司前瞻性基础性项目"稠油绿色低碳大幅度提高采收率新机理与新方法研究"(2023ZZ0405)和新型油气勘探开发国家科技重大专项"油气田生产系统再造技术与装备"(2025ZD1406700)资助。

Abstract

Abstract: Steam quality is a critical factor influencing the effectiveness and economic efficiency of steam injection for enhanced oil recovery. In the later stage of conventional steam injection, the oil steam ratio is low, and different kinds of gas such as carbon dioxide and flue gas are often employed to reduce steam consumption. However, the unclear mechanism by which non-condensable gas admixture affects steam quality remains a significant limitation in the advancement of gas-assisted steam injection technologies. This study utilizes a high-temperature, high-pressure visual PVT experimental system to set up two experiments including constant-volume cooling and constant-temperature volume reduction. The experiment was conducted under conditions of steam temperatures ranging from 90 ℃ to 150 ℃ and pressures between 0 MPa and 0.451 MPa. It probes into the effect of blending varying proportions of four non-condensable gases, i.e., carbon dioxide, methane, ethane, and ammonia, on steam quality. The findings reveal that the gas admixture such as carbon dioxide and ammonia enhances steam quality, with ammonia exhibiting a more significant effect than carbon dioxide. In contrast, the admixture of gases like methane and ethane decreases steam quality, with methane showing a stronger reduction effect than ethane. This research elucidates the fundamental principles governing the impact of mixing four non-condensable gases on steam quality, providing valuable guidance for the selection of gas types in the gas-assisted steam thermal recovery of heavy oil.

Key words: heavy oil, steam quality, non-condensable gas, methane, carbon dioxide

摘要： 蒸汽干度是影响注汽热采开发效果和经济性的关键因素之一,常规注蒸汽开发后期油汽比低,为减少蒸汽用量常采用二氧化碳、烟道气等辅助开发。但非凝结气体的掺混对注入过程蒸汽干度的影响机理不清是制约气体辅助蒸汽开发技术的重要问题。通过高温高压可视化PVT实验系统,在蒸汽温度为90~150 ℃、压力为0~0.451 MPa的工况下,设置定容降温与定温降容两组实验,深入探讨了掺混不同比例的二氧化碳、甲烷、乙烷、氨气4种非凝结气体对蒸汽干度的影响。研究结果表明,二氧化碳、氨气等气体掺混可提高蒸汽干度,且氨气的提高效果强于二氧化碳,而甲烷、乙烷等气体掺混会降低蒸汽干度,且甲烷的降低效果强于乙烷。揭示了4种非凝结气体掺混对蒸汽干度影响的基础规律,可为气体辅助蒸汽热采稠油的气体种类选择提供借鉴与参考。

关键词: 稠油, 蒸汽干度, 非凝结气体, 甲烷, 二氧化碳

CLC Number:

TE357

Guo Erpeng, Mao Xiaopeng, He Jitao, Jiang Xu, Zhang Kanyi, Liu Zongjian, Ren Shuowen, Wang Xinwei. Experimental study on influence of non-condensable gas on steam quality[J]. Acta Petrolei Sinica, 2025, 46(12): 2332-2342,2426.

郭二鹏, 毛晓鹏, 贺吉涛, 蒋旭, 张侃毅, 刘宗建, 任铄文, 王新伟. 非凝结气体掺混对蒸汽干度影响实验[J]. 石油学报, 2025, 46(12): 2332-2342,2426.

References

[1] 袁士义,王强. 中国油田开发主体技术新进展与展望[J].石油勘探与开发,2018,45(4):657-668.
YUAN Shiyi,WANG Qiang.New progress and prospect of oilfields development technologies in China[J].Petroleum Exploration and Development,2018,45(4):657-668.
[2] 孙焕泉,刘慧卿,王海涛,等.中国稠油热采开发技术与发展方向[J].石油学报,2022,43(11):1664-1674.
SUN Huanquan,LIU Huiqing,WANG Haitao,et al.Development technology and direction of thermal recovery of heavy oil in China[J].Acta Petrolei Sinica,2022,43(11):1664-1674.
[3] 张义堂,李秀峦,张霞.稠油蒸汽驱方案设计及跟踪调整四项基本准则[J].石油勘探与开发,2008,35(6):715-719.
ZHANG Yitang,LI Xiuluan,ZHANG Xia.Four fundamental principles for design and follow-up of steam flooding in heavy oil reservoirs[J] .Petroleum Exploration and Development,2008,35(6):715-719.
[4] 张锐.稠油热采技术[M].北京:石油工业出版社,1999:292-293.
ZHANG Rui.Thermal recovery technology for heavy oil[M].Beijing:Petroleum Industry Press,1999:292-293.
[5] 曹嫣镔,刘冬青,王善堂,等.中深层稠油油藏化学辅助蒸汽驱三维物理模拟与应用[J].石油学报,2014,35(4):739-744.
CAO Yanbin,LIU Dongqing,WANG Shantang,et al.Three-dimensional physical simulation and application of chemistry assistant steam flooding on middle and deep heavy oil reservoir[J].Acta Petrolei Sinica,2014,35(4):739-744.
[6] 王成建.烟道气辅助蒸汽驱驱油特征及参数优化[D].青岛:中国石油大学(华东),2021.
WANG Chengjian.Characteristics and parameter optimization of flue gas-assisted steam-drive oil recovery[D].Qingdao:China University of Petroleum,2021.
[7] 李博良,李宾飞,冀延民,等.烟道气辅助注蒸汽开采稠油增效机理及应用[J].石油学报,2024,45(3):574-585.
LI Boliang,LI Binfei,JI Yanmin,et al.Mechanism and application of flue gas-assisted steam injection for heavy oil recovery[J].Acta Petrolei Sinica,2024,45(3):574-585.
[8] 高永荣,刘尚奇,沈德煌,等.氮气辅助SAGD开采技术优化研究[J].石油学报,2009,30(5):717-721.
GAO Yongrong,LIU Shangqi,SHEN Dehuang,et al.Optimization of N₂ injection technology during steam assisted gravity drainage process[J].Acta Petrolei Sinica,2009,30(5):717-721.
[9] 许鑫.多介质辅助蒸汽驱提高稠油采收率技术研究[D].大庆:东北石油大学,2022.
XU Xin.Research on steam flooding assisted bymulti-media injection for enhancing heavy oil recovery[D].Daqing:Northeast Petroleum University,2022.
[10] 鹿腾,班晓春,李兆敏,等.烟道气辅助SAGD蒸汽腔扩展机理[J].石油学报,2021,42(8):1072-1080.
LU Teng,BAN Xiaochun,LI Zhaomin,et al.Mechanisms on expansion of SAGD steam chamber assisted by flue gas[J].Acta Petrolei Sinica,2021,42(8):1072-1080.
[11] 林日亿,李魏,李兆敏,等.烟气-蒸汽辅助重力泄油模拟技术[J].中国石油大学学报(自然科学版),2012,36(5):136-140.
LIN Riyi,LI Wei,LI Zhaomin,et al.Numerical simulation technology of flue gas-steam assisted gravity drainage[J].Journal of China University of Petroleum(Edition of Natural Science),2012,36(5):136-140.
[12] 张运军,沈德煌,高永荣,等.二氧化碳气体辅助SAGD物理模拟实验[J].石油学报,2014,35(6):1147-1152.
ZHANG Yunjun,SHEN Dehuang,GAO Yongrong,et al.Physical simulation experiments on CO₂ injection technology during steam assisted gravity drainage process[J].Acta Petrolei Sinica,2014,35(6):1147-1152.
[13] 石兰香,彭栋梁,席长丰,等.丙烷与二甲醚辅助SAGD开采规律二维物理模拟实验[J].石油学报,2024,45(6):999-1008.
SHI Lanxiang,PENG Dongliang,XI Changfeng,et al.Two-dimensional physical simulation experiment of propane and dimethyl ether assisted SAGD[J].Acta Petrolei Sinica,2024,45(6):999-1008.
[14] 王晓燕,章杨,张杰,等.稠油油藏注CO₂吞吐提高采收率机制[J].中国石油大学学报(自然科学版),2021,45(6):102-111.
WANG Xiaoyan,ZHANG Yang,ZHANG Jie,et al.EOR mechanisms of CO₂ huff and puff process for heavy oil recovery[J].Journal of China University of Petroleum(Edition of Natural Science),2021,45(6):102-111.
[15] 王敬,张洪权,姬泽敏,等.低渗-致密油藏注气吞吐CO₂—原油相互作用与传质规律[J].石油学报,2025,46(1):265-278.
WANG Jing,ZHANG Hongquan,JI Zemin,et al.Law of interaction and mass transfer of CO₂ and crude oil during gas injection huff and puff in low permeability tight reservoirs[J].Acta Petrolei Sinica,2025,46(1):265-278.
[16] 李宾飞,赵希芮,郑磊,等.CO₂压驱高速注入对基质驱油特征的影响[J].石油学报,2025,46(5):926-937.
LI Binfei,ZHAO Xirui,ZHENG Lei,et al.Effects of high-speed fracturing-flooding CO₂ injection on matrix oil displacement characteristics[J].Acta Petrolei Sinica,2025,46(5):926-937.
[17] 陈超,张晶晨,董海海,等.低渗透砾岩油藏CO₂驱孔隙和剩余油动用机理及驱替效率[J].石油学报,2025,46(7):1434-1446.
CHEN Chao,ZHANG Jingchen,DONG Haihai,et al.Mechanisms of pore-scale oil production and displacement efficiency for CO₂ flooding in low-permeability conglomerate reservoirs[J].Acta Petrolei Sinica,2025,46(7):1434-1446.
[18] 东晓虎,刘慧卿,侯吉瑞,等.非凝析气与蒸汽混注水平井井筒流动传热特征[J].中国石油大学学报(自然科学版),2016,40(2):105-114.
DONG Xiaohu,LIU Huiqing,HOU Jirui,et al.Transient fluid flow and heat transfer characteristics during co-injection of steam and non- condensable gases in horizontal wells[J].Journal of China University of Petroleum(Edition of Natural Science),2016,40(2):105-114.
[19] J AMSHID-NEZHAD M.Steam alternating non-condensable gas injection for more heavy oil recovery[J].Energy,2022,240:122476.
[20] PRASAD S K,SANGWAI J S,BYUN H S.A review of the supercritical CO₂ fluid applications for improved oil and gas production and associated carbon storage[J].Journal of CO₂ Utilization,2023,72:102479.
[21] SUN Xiaofei,CAI Jiaming,LI Xiaoyu,et al.Experimental investigation of a novel method for heavy oil recovery using supercritical multithermal fluid flooding[J].Applied Thermal Engineering,2021,185:116330.
[22] 窦立荣,孙龙德,吕伟峰,等.全球二氧化碳捕集、利用与封存产业发展趋势及中国面临的挑战与对策[J].石油勘探与开发,2023,50(5):1083-1096.
DOU Lirong,SUN Longde,LV Weifeng,et al.Trend of global carbon dioxide capture,utilization and storage industry and challenges and countermeasures in China[J].Petroleum Exploration and Development,2023,50(5):1083-1096.
[23] 杨勇.中国碳捕集、驱油与封存技术进展及发展方向[J].石油学报,2024,45(1):325-338.
YANG Yong.Technology progress and development direction of carbon capture,oil-flooding and storage in China[J].Acta Petrolei Sinica,2024,45(1):325-338.
[24] ZHANG Dandi,LI Shu,TONG Lili,et al.Research on heat transfer characteristics of steam condensation with non-condensable gas at low steam mass flux[J].Applied Thermal Engineering,2024,256:124039.
[25] LU Junhui,CAO Haishan,LI Junming.Condensation heat and mass transfer of steam with non-condensable gases outside a horizontal tube under free convection[J].International Journal of Heat and Mass Transfer,2019,139:564-576.
[26] MA Xizhen,XIAO Xiu,JIA Haijun,et al.Experimental research on steam condensation in presence of non-condensable gas under high pressure[J].Annals of Nuclear Energy,2021,158:108282.
[27] YI Qiujie,TIAN Maocheng,YAN Weijie,et al.Visualization study of the influence of non-condensable gas on steam condensation heat transfer[J].Applied Thermal Engineering,2016,106:13-21.
[28] AHN T,MOON J,KANG J,et al.Steam condensation in the presence of non-condensable gas inside a nearly horizontal tube under separated flow[J].International Journal of Heat and Mass Transfer,2022,197:123351.
[29] CHEN Xianbing,YANG Luopeng,ZHANG Wenke,et al.Effect of non-condensable gas on submerged steam jet condensation in a narrow pipe[J].Applied Thermal Engineering,2023,219:119598.
[30] HUANG Jian,ZHANG Junxia,WANG Li.Review of vapor condensation heat and mass transfer in the presence of non-condensable gas[J].Applied Thermal Engineering,2015,89:469-484.
[31] LU Junhui,CAO Haishan,LI Junming.Diffusion layer model for condensation of vapor with the presence of noncondensable gas under natural convective condensation[J].Progress in Nuclear Energy,2020,118:103078.
[32] CHEN Xianbing,ZHOU Tao,ZHANG Wenke,et al.Numerical simulation on the effect of non-condensable gas on direct contact condensation of steam jet in a narrow pipe[J].International Communications in Heat and Mass Transfer,2024,152:107328.
[33] XU Zhengxiao,LI Zhaomin,LI Binfei,et al.Investigation of the heat transfer mechanism of CO₂-assisted steam injection via experimental and simulation evaluation[J].Frontiers in Energy Research,2020,8:592142.
[34] RAVEENDRAN P,IKUSHIMA Y,WALLEN S L.Polar attributes of supercritical carbon dioxide[J].Accounts of Chemical Research,2005,38(6):478-485.
[35] WEN Rongfu,ZHOU Xingdong,PENG Benli,et al.Falling-droplet-enhanced filmwise condensation in the presence of non-condensable gas[J].International Journal of Heat and Mass Transfer,2019,140:173-186.

Experimental study on influence of non-condensable gas on steam quality

非凝结气体掺混对蒸汽干度影响实验

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