摘要
准噶尔盆地吉木萨尔凹陷二叠系芦草沟组是中国混积型陆相页岩油的典型代表。经过十余年的勘探与开发,虽然已取得重大突破,但现行衰竭式开发仍面临地层能量衰减快、产量递减快、采收率低等问题,后期提高采收率的关键技术方向尚不明确。为此,基于吉木萨尔凹陷下甜点某平台井实际地质模型,建立了水力裂缝—页岩基质耦合数值模拟模型,通过优化关键参数完成生产动态历史拟合,设计了衰竭开发后中间井注气、两侧井采油的3口水平井间注气驱替工程方法。结果表明,针对吉木萨尔页岩油基质致密、天然裂缝不发育特征,水平井间水力裂缝沟通程度决定了注气驱替开发效果,通过对比注入气体种类、注气时机、注气压力影响,提出了注入气突破后产出气循环回注方式,与衰竭开发相比,注气驱替累计增油量提高约45%,换油率提升近一倍。进一步提出的产出气循环回注方式,可在保证提高原油采出程度的同时有效利用注入的CO_(2) ,实现驱油增产与高效碳利用。本研究结果对陆相页岩油后期注气驱替开发及CO_(2) 地质封存具有重要参考意义。
The Lucaogou formation of the Permian System in the Jimsar Sag,Junggar Basin,represents a typical example of mixed siliciclastic–carbonate continental shale oil in China.After more than a decade of exploration and pilot development,remarkable technological and production breakthroughs have been achieved,confirming its substantial resource potential.Nevertheless,the current depletion-based development mode continues to face critical challenges such as rapid formation energy loss,sharp production decline rates,and persistently low recovery factors.The key technical direction for improving oil recovery at the later stage of development therefore remains unclear and urgently requires systematic investigation.To address these issues,a coupled numerical model of hydraulic fractures and the shale matrix was established based on the actual geological model of a well platform located in the lower sweet-spot interval of the Jimsar Sag.The model was validated through history matching by optimizing key reservoir and fracture parameters.On this basis,an inter-well gas injection displacement scheme involving three horizontal wells was designed,in which gas is injected through the central well and oil is produced from the two adjacent wells following an initial depletion phase.Simulation results show that,for Jimsar shale oil characterized by an ultra-tight matrix and poorly developed natural fractures,the degree of communication between horizontal wells through hydraulic fractures is the key factor determining the effectiveness of gas injection development.Comparative analyses of different injected gases(CO_(2) and CH4),injection timing,and injection pressure were performed to clarify their influence on the displacement process.Based on these results,an optimized operation strategy was proposed,involving cyclic reinjection of produced gas after the initial breakthrough of the injected gas at the production wells.Compared with depletion development,the designed inter-well gas injection scheme increases the cumulative oil production by approximately 45%,while the oil utilization ratio-an indicator of carbon and energy efficiency-nearly doubles.The proposed cyclic reinjection of produced gas further enhances carbon utilization efficiency and reduces the external CO_(2) supply demand,thereby achieving a dual objective of improving oil recovery and promoting effective carbon recycling.Overall,the developed coupled model and the derived optimization strategy provide a technically feasible and scientifically grounded approach for enhancing oil recovery in continental shale oil reservoirs.The findings clarify the mechanisms and governing parameters of inter-well gas displacement under ultra-tight conditions,and the proposed cyclic reinjection mode offers a practical pathway for synergistic oil production enhancement and CO_(2) geological utilization.This study provides important theoretical support and engineering reference for large-scale application of gas injection displacement and CO_(2) sequestration in the late-stage development of continental shale oil fields in China.
作者
葛琛琦
雷征东
纪东奇
张原
刘一杉
阎逸群
惠钢
陈掌星
GE Chenqi;LEI Zhengdong;JI Dongqi;ZHANG Yuan;LIU Yishan;YAN Yiqun;HUI Gang;CHEN Zhangxing(College of Petroleum Engineering,China University of Petroleum,Beijing 102249,China;Research Institute of Petroleum Exploration and Development,PetroChina,Beijing 100083,China;College of Petroleum Engineering,China University of Petroleum-Beijing at Karamay,Karamay 834000,China;State Key Laboratory of Continental Shale Oil,Daqing 163712,China)
出处
《石油科学通报》
2026年第1期239-256,共18页
Petroleum Science Bulletin
基金
国家自然科学基金项目(U22B2075、52204053)
中国石油天然气股份有限公司(2023ZZ08)联合资助。
关键词
页岩油
气驱
数值模拟
提高采收率
碳埋存
shale oil
gas displacement
numerical simulation
enhanced oil recovery
carbon sequestration
