基于全油气系统理论预测深层—超深层油气资源最大埋深#br#

doi:10.3969/j.issn.1672-7703.2025.03.009

中国石油勘探 ›› 2025, Vol. 30 ›› Issue (3): 126-139.DOI: 10.3969/j.issn.1672-7703.2025.03.009

基于全油气系统理论预测深层—超深层油气资源最大埋深#br#

庞雄奇^1,2,李才俊^1,2,贾承造^1,3,陈雨萱^1,2,黎茂稳⁴,姜林⁵,肖惠译 ^1,2,姜福杰^1,2,曹鹏^1,2,6,陈冬霞^1,2,徐帜^1,2,林会喜⁴,胡涛^1,2,郑定业⁴,王雷^1,2

1 中国石油大学（北京）油气资源与工程全国重点实验室；2 中国石油大学（北京）地球科学学院；3 中国石油天然气集团有限公司；4 中国石化石油勘探开发研究院；5 中国石油勘探开发研究院；6 中国石油杭州地质研究院

出版日期:2025-05-15 发布日期:2025-05-15
作者简介:庞雄奇（1961-），男，湖北崇阳人，博士，1991年毕业于中国地质大学（北京），中国石油大学（北京）教授，博士生导师，主要从事油气成藏机理和油气资源评价等方面的科研和教学工作。地址：北京市昌平区府学路18号中国石油大学（北京）地球科学学院，邮政编码：102249。
基金资助:
国家自然科学基金企业联合基金项目“深层碳酸盐岩油气成藏动力机制与潜在发育区预测方法”（19B6003-02-04）；中国石油前瞻性基础研究项目“非常规油气自封闭与成藏机理研究”（2021DJ0101）。

Prediction of the maximum depth of deep to ultra-deep resources based on the theory of whole petroleum system

Pang Xiongqi^1,2,Li Caijun^1,2,Jia Chengzao^1,3,Chen Yuxuan^1,2,Li Maowen⁴,Jiang Lin⁵,Xiao Huiyi^1,2,Jiang Fujie^1,2,Cao Peng^1,2,6,Chen Dongxia^1,2,Xu Zhi^1,2,Lin Huixi⁴,Hu Tao^1,2,Zheng Dingye⁴,Wang Lei^1,2

1 State Key Laboratory of Petroleum Resources and Engineering, China University of Petroleum (Beijing); 2 College of Geosciences, China University of Petroleum (Beijing); 3 China National Petroleum Corporation; 4 Sinopec Petroleum Exploration and Production Research Institute; 5 PetroChina Research Institute of Petroleum Exploration & Development; 6 PetroChina Hangzhou Research Institute of Geology

Online:2025-05-15 Published:2025-05-15

摘要/Abstract

摘要： 深层—超深层由于其蕴藏的丰富油气资源成为当前国内外油气勘探和研究的重点领域，揭示深层—超深层油气藏最大埋深对深层油气资源评价、超深钻井部署、勘探风险认识等具有重要的现实意义。本文基于全油气系统理论提出了一种预测深层—超深层油气藏最大埋深的方法和流程，该方法能够对含油气盆地内常规、致密和页岩油气藏的最大埋深进行定量预测。研究以已经发现的油气藏和钻井资料为例，分别对我国塔里木、准噶尔、四川、鄂尔多斯、松辽、渤海湾等含油气盆地油气藏最大埋深进行了预测。结果显示，中国六大含油气盆地常规油气藏、致密油气藏和页岩油气藏对应的最大埋深通常情况下分别介于800～4400m、5050～7990m和5400～9300m。油气藏的最大埋深随着大地热流减小、含有机母质类型变好、储层亲油性增强而增大，随着钻探技术和预测水平提升发现油气资源的领域将不断扩大。此外，构造变动也会改变实际地质条件下油气成藏的最大埋深，研究依据浅—中—深油气实际钻探结果，预测出塔里木盆地寒武系—奥陶系碳酸盐岩超深层油藏的最大埋深超（9500±50)m，气藏最大埋深超(10500±100)m。

关键词: 自然资源, 化石能源, 全油气系统, 深层—超深层, 油气成藏底限, 油气勘探下限, 油气资源, 常规和非常规油气

Abstract: The deep to ultra-deep formations have abundant resources, which is currently a key field for petroleum exploration and research both domestically and internationally. The study on the maximum depth of oil and gas reservoirs has important practical significance for assessing deep oil and gas resources, deploying ultra-deep wells, and understanding exploration risks. Based on the theory of whole petroleum system (WPS), the method and process have been proposed to quantitatively predict the maximum depth of conventional, tight, and shale oil and gas reservoirs in petroliferous basins. Some cases of discovered oil and gas reservoirs and well drilling data have been studied to predict the maximum depth of oil and gas reservoirs in petroliferous basins such as Tarim, Junggar, Sichuan, Ordos, Songliao, and Bohai Bay in China. The study results show that the maximum depths of conventional, tight, and shale oil and gas reservoirs in the six major petroliferous basins are usually in the range of 800–4400 m, 5050–7990 m, and 5400–9300 m, which increase with decreasing geothermal gradient, better organic matter types, and higher oil wet property of the reservoir. With advancements in drilling technology and predictive capabilities, the scope of discovering oil and gas resources will continue to expand. In addition, the maximum depth of oil and gas reservoirs is influenced by tectonic movements in the context of in-situ geological conditions. Finally, based on the actual drilling results of shallow–medium–deep oil and gas in Tarim Basin, the predicted maximum depths of ultra-deep carbonate oil and gas reservoirs in the Cambrian–Ordovician exceed (9500±50) m
and (10500±100) m, respectively.

Key words: natural resources, fossil energy, whole petroleum system, deep to ultra-deep formations, lower depth limit for hydrocarbon accumulation, lower depth limit for petroleum exploration, oil and gas resources, conventional and unconventional oil and gas

中图分类号:

TE112

庞雄奇, 李才俊, 贾承造, 陈雨萱, 黎茂稳, 姜林, 肖惠译, 姜福杰, 曹鹏, 陈冬霞, 徐帜, 林会喜, 胡涛, 郑定业, 王雷. 基于全油气系统理论预测深层—超深层油气资源最大埋深#br#[J]. 中国石油勘探, 2025, 30(3): 126-139.

Pang Xiongqi, Li Caijun, Jia Chengzao, Chen Yuxuan, Li Maowen, Jiang Lin, Xiao Huiyi, Jiang Fujie, Cao Peng, Chen Dongxia, Xu Zhi, Lin Huixi, Hu Tao, Zheng Dingye, Wang Lei. Prediction of the maximum depth of deep to ultra-deep resources based on the theory of whole petroleum system[J]. China Petroleum Exploration, 2025, 30(3): 126-139.

参考文献

[1] 马永生，蔡勋育，赵培荣.深层、超深层碳酸盐岩油气储层形成机理研究综述[J].地学前缘，2011,18(4):181-192.
Ma Yongsheng, Cai Xunyu, Zhao Peirong. The research status and advances in porosity evolution and diagenesis of deep carbonate reservoir [J]. Earth Science Frontiers, 2011,18(4): 181-192.
[2] Appert O. Production of reservoir fluids in frontier conditions[J]. Revue de L’Institut Francais du Petrole, 1998, 53(3):249-252.
[3] Bloch S, Robert H Lander, Linda Bonnell. Anomalously high porosity and permeability in deeply buried sandstone reservoirs: origin and predictability [J]. AAPG Bulletin, 2002,86(2):301-328.
[4] Barker C, Takach N E. Prediction of natural gas composition in ultradeep sandstone reservoirs [J]. AAPG Bulletin, 1992, 76(12): 1859-1873.
[5] 赵文智，张光亚，王红军.石油地质理论新进展及其在拓展勘探领域中的意义[J].石油学报，2005,26(1):1-7,12.
Zhao Wenzhi, Zhang Guangya, Wang Hongjun. New achievements of petroleum geology theory and its significances on expanding oil and gas exploration field [J]. Acta Petrolei Sinica, 2005, 26(1):1-7,12.
[6] П Г 迈哈蒂耶夫，史斗.深埋层含油气性的地温前提条件[J].天然气地球科学，2001,12(专刊2):56-60.
П Г Makhatiev, Shi Dou. Geothermal prerequisites for hydrocarbon content in deep buried layers [J]. Natural Gas Geoscience, 2001,12(Z2):56-60.
[7] 朱光有，张水昌.中国深层油气成藏条件与勘探潜力[J].石油学报，2009,30(6):793-802.
Zhu Guangyou, Zhang Shuichang. Hydrocarbon accumulation conditions and exploration potential of deep reservoirs in China [J]. Acta Petrolei Sinica, 2009,30(6):793-802.
[8] 孙龙德，邹才能，朱如凯，等.中国深层油气形成、分布与潜力分析[J].石油勘探与开发，2013,40(6):641-649.
Sun Longde, Zou Caineng, Zhu Rukai, et al. Formation, distribution and potential of deep hydrocarbon resources in China [J]. Petroleum Exploration and Development, 2013,40(6): 641-649.
[9] 李阳，薛兆杰，程喆，等.中国深层油气勘探开发进展与发展方向[J]. 中国石油勘探，2020,25(1):45-57.
Li Yang, Xue Zhaojie, Cheng Zhe, et al. Progress and development directions of deep oil and gas exploration and development in China [J]. China Petroleum Exploration, 2020, 25(1):45-57.
[10] 中国国家标准化管理委员会.石油天然气钻进工程术语：GB/T 28911—2012[S].北京：中国标准出版社，2012.
Standardization Administration of China. Vocabulary of drilling engineering for petroleum and natural gas: GB/T 28911—2012 [S]. Beijing: China Standards Press, 2012.
[11] 何登发，贾承造，赵文智，等.中国超深层油气勘探领域研究进展与关键问题[J].石油勘探与开发，2023,50(6):1162-1172.
He Dengfa, Jia Chengzao, Zhao Wenzhi, et al. Research progress and key issues of ultra-deep oil and gas exploration in China [J]. Petroleum Exploration and Development, 2023,50(6): 1162-1172.
[12] 朱光有，杨海军，苏劲，等.塔里木盆地海相石油的真实勘探潜力[J].岩石学报，2012,28(4):1333-1347.
Zhu Guangyou, Yang Haijun, Su Jin, et al. True exploration potential of marine oils in the Tarim Basin [J]. Acta Petrologica Sinica, 2012,28(4):1333-1347.
[13] 汪泽成，江青春，王居峰，等.基岩油气成藏特征与中国陆上深层基岩油气勘探方向[J].石油勘探与开发，2024,51(1):28-38.
Wang Zecheng, Jiang Qingchun, Wang Jufeng, et al. Hydrocarbon accumulation characteristics in basement reservoirs and exploration targets of deep basement reservoirs in onshore China [J]. Petroleum Exploration and Development, 2024,51(1): 28-38.
[14] 马永生，黎茂稳，蔡勋育，等.中国海相深层油气富集机理与勘探开发：研究现状、关键技术瓶颈与基础科学问题[J].石油与天然气地质，2020,41(4):655-672,683.
Ma Yongsheng, Li Maowen, Cai Xunyu, et al. Mechanisms and exploitation of deep marine petroleum accumulations in China: advances, technological bottlenecks and basic scientific problems [J]. Oil & Gas Geology, 2020,41(4):655-672,683.
[15] Tissot B P, Welte D H. Petroleum formation and occurrence[M]. New York: Springer-Verlag, 1978.
[16] Price L C. Thermal stability of hydrocarbons in nature: limits, evidence, characteristics and possible controls [J]. Geochimica et Cosmochimica Acta, 1993,57(14):3261-3280.
[17] Williams K E, Redhead R, Standifird W. Geopressure analysis in the subsalt Knotty Head field: deep water Gulf of Mexico [J]. Gulf Coast Association of Geological Societies Transactions, 2008,58:905-912.
[18] 杨海军，陈永权，田军，等.塔里木盆地轮探1井超深层油气勘探重大发现与意义[J].中国石油勘探, 2020,25(2):62-72.
Yang Haijun, Chen Yongquan, Tian Jun, et al. Great discovery and its significance of ultra-deep oil and gas exploration in well Luntan-1 of the Tarim Basin [J]. China Petroleum Exploration, 2020,25(2):62-72.
[19] Waples D W.The kinetics of in-reservoir oil destruction and gas formation: constraints from experimental and empirical data, and from thermodynamics[J]. Organic Geochemistry, 2000,31(6):553-575.
[20] Hill R J, Tang Y, Kaplan I R. Insights into oil cracking based on laboratory experiments [J]. Organic Geochemistry, 2003,34(12):1651-1672.
[21] Schenk C J, Pollastro R M. Natural gas production in the United States [R]. Reston: U. S. Geological Survey, 2001,FS-113-01.
[22] 闫磊，朱光有，王珊，等.塔里木盆地震旦系—寒武系万米超深层天然气成藏条件与有利区带优选[J].石油学报，2021,42(11): 1446-1457.
Yan Lei, Zhu Guangyou, Wang Shan, et al. Accumulation conditions and favorable areas for natural gas accumulation in 10000 meters ultra-deep Sinian-Cambrian in Tarim Basin [J]. Acta Petrolei Sinica, 2021,42(11):1446-1457.
[23] 李建忠，陶小晚，白斌，等.中国海相超深层油气地质条件、成藏演化及有利勘探方向[J].石油勘探与开发，2021,48(1):52-67.
Li Jianzhong, Tao Xiaowan, Bai Bin, et al. Geological conditions, reservoir evolution and favorable exploration directions of marine ultra-deep oil and gas in China [J]. Petroleum Exploration and Development, 2021,48(1):52-67.
[24] 庞雄奇，贾承造，郭秋麟，等.全油气系统理论用于常规和非常规油气资源评价的地模拟技术原理及应用[J].石油学报，2023, 44(9):1417-1433.
Pang Xiongqi, Jia Chengzao, Guo Qiulin, et al. Principle and application of basin modeling technology for evaluation of conventional and unconventional oil-gas resource based on whole petroleum system theory [J]. Acta Petrolei Sinica, 2023, 44(9):1417-1433.
[25] 贾承造，庞雄奇，宋岩.全油气系统理论基本原理[J].石油勘探与开发，2024,51(4):679-691.
Jia Chengzao, Pang Xiongqi, Song Yan. Basic principles of the whole petroleum system [J]. Petroleum Exploration and Development,2024,51(4):679-691.
[26] Pang X Q, Hu T, Larter S, et al. Hydrocarbon accumulation depth limit and implications for potential resources prediction[J]. Gondwana Research, 2021,103:389-400.
[27] 贾承造.论非常规油气对经典石油天然气地质学理论的突破及意义[J].石油勘探与开发，2017,44(1):1-11.
Jia Chengzao. Breakthrough and significance of unconventional oil and gas to classical petroleum geological theory [J]. Petroleum Exploration and Development, 2017,44(1):1-11.
[28] Jia C Z, Pang X Q, Song Y. Whole petroleum system and ordered distribution pattern of conventional and unconventional oil and gas reservoirs[J]. Petroleum Science, 2023,20(1):1-19.
[29] Pang X, Liu K, Ma Z, et al. Dynamic field division of hydrocarbon migration, accumulation and hydrocarbon enrichment rules in sedimentary basins [J]. Acta Geologica Sinica, 2012,86(6):1559-1592.
[30] Pang X Q, Jia C Z, Wang W Y, et al. Buoyance-driven hydrocarbon accumulation depth and its implication for unconventional resource prediction [J]. Geoscience Frontiers, 2021,12(4):97-113.
[31] Pang X Q, Jia C Z, Zhang K, et al. The dead line for oil and gas and implication for fossil resource prediction [J]. Earth System Science Data, 2020,12(1):577-590.
[32] 庞雄奇，姜振学，黄捍东，等.叠复连续油气藏成因机制、发育模式及分布预测[J].石油学报，2014,35(5):795-828.
Pang Xiongqi, Jiang Zhenxue, Huang Handong, et al. Formation mechanisms, distribution models, and prediction of superimposed, continuous hydrocarbon reserviors [J]. Acta Petrolei Sinica, 2014,35(5):795-828.
[33] Pang X Q, Shao X H, Li M W, et al. Correlation and difference between conventional and unconventional reservoirs and their unified genetic classification [J]. Gondwana Research, 2021,97(6):73-100.
[34] 庞雄奇，贾承造，宋岩，等.全油气系统定量评价：方法原理与实际应用[J].石油学报，2022,43(6):727-759.
Pang Xiongqi, Jia Chengzao, Song Yan, et al. Quantitative evaluation of whole petroleum system: principle and application [J]. Acta Petrolei Sinica, 2022,43(6):727-759.
[35] Pang X Q. Quantitative evaluation of the whole petroleum system: hydrocarbon thresholds and their application [M]. Berlin: Springer, 2023.
[36] IHS Energy Group. International petroleum exploration and production database [R]. Englewood, Colorado: IHS Energy Group, 2020.
[37] Worden R H, Armitage P J, Butcher A R, et al. Petroleum reservoir quality prediction: overview and contrasting approaches from sandstone and carbonate communities [C]. London: Reservoir Quality of Clastic and Carbonate Rocks-Analysis, Modelling and Prediction, 2018,435:1-31.
[38] 寿建峰，张惠良，沈扬，等.中国油气盆地砂岩储层的成岩压实机制分析[J].岩石学报，2006,22(8):2165-2170.
Shou Jianfeng, Zhang Huiliang, Shen Yang, et al. Diagenetic mechanisms of sandstone reservoirs in China oil and gas-bearing basins [J]. Acta Petrologica Sinica, 2006,22(8):2165-2170.
[39] 谢武仁，文龙，汪泽成，等.四川盆地深层—超深层碳酸盐岩油气成藏条件与勘探潜力[J].中国石油勘探，2024,29(5):61-76.
Xie Wuren, Wen Long, Wang Zecheng, et al. Hydrocarbon accumulation conditions and exploration potential of deep-ultradeep carbonate rocks in Sichuan Basin [J]. China Petroleum Exploration, 2024,29(5):61-76.
[40] 陈旋，刘俊田，张华，等.吐哈盆地台北凹陷深层致密砂岩气成藏特征及跃探1H井勘探发现的意义[J].中国石油勘探，2024, 29(6):1-16.
Chen Xuan, Liu Juntian, Zhang Hua, et al. Accumulation conditions of deep tight sandstone gas in Taipei Sag and enlightenment and significance of exploration and discovery of Yuetan 1H Well [J]. China Petroleum Exploration, 2024,29(6): 1-16.
[41] 黄福喜，汪少勇，李明鹏，等.中国石油深层、超深层油气勘探进展与启示[J].天然气工业，2024,44(1):86-96.
Huang Fuxi, Wang Shaoyong, Li Mingpeng, et al. Progress and implications of deep and ultra-deep oil and gas exploration in PetroChina [J]. Natural Gas Industry, 2024,44(1):86-96.
[42] 贾爱林，闫海军，唐海发，等.中国深层、超深层气藏开发关键技术与对策建议[J].天然气工业，2024,44(1):119-127.
Jia Ailin, Yan Haijun, Tang Haifa, et al. Key technologies and countermeasures for deep and ultra-deep gas reservoir development in China [J]. Natural Gas Industry, 2024,44(1): 119-127.

基于全油气系统理论预测深层—超深层油气资源最大埋深#br#

Prediction of the maximum depth of deep to ultra-deep resources based on the theory of whole petroleum system

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