收稿日期: 2003-07-24
修回日期: 2003-08-26
网络出版日期: 2003-10-20
ECOGNITION ON RESERVOIR-FORMING MECHANISM OF KELA 2 GAS FIELD IN TARIM BASIN
Received date: 2003-07-24
Revised date: 2003-08-26
Online published: 2003-10-20
克拉2气田是一个大型、特高丰度、高产、超高压优质气田。该气田出现在南天山山前逆冲带,成藏机制十分特殊。运用近代石油地质学理论,特别是油气系统和流体封存箱的概念、方法对克拉2气田的成藏机制进行研究后认为:位于库车富气油气系统中心地带和活跃的气源补给、卓越的封盖层、良好的储层、比较完整的背斜圈闭、畅顺的油气充注通道(主要是断裂)等成藏要素的有序耦合以及晚近期至今源岩处于生气高峰阶段(\"活气源\")和异常流体压力封存箱内载气水循环对流作用是该气田天然气聚集成藏的主要有利条件。
关键词: 塔里木盆地; 克拉2气田; 载气水循环对流形成机制; 油气系统; 流体封存箱
周兴熙 . 塔里木盆地克拉2气田成藏机制再认识[J]. 天然气地球科学, 2003 , 14(5) : 354 -361 . DOI: 10.11764/j.issn.1672-1926.2003.05.354
Kela 2 gas field——a grant, abundant, super-overpressure,larger producer,high quality gas field distributing in the southern!Tianshan Thrusting zone,has been with quietly special reservoir-forming mechanism. The reservoir-forming mechanism of Kela 2 gas field was researched, Used the recent petroleum geological theory, emphasizing the concept and method of petroleum system and fluid compartment. Its excellent forming conditions of Kela 2 gas field were that located in the center of Kuqe rich-gas petroleum system, and coupled of five factors-active gas replenishment, predominant cap rock, favorable reservoir rock, rather integrated anticline trap and smooth charging-pathway, and the late-stage enrichment and reservoir forming. Its reservoir-forming circumstance was the supercharging-high impedance petroleum system. High speed sediment fill and intense extrusion of Tianshan mountain southerly in the late stage of the Himalaya cycle resulted in the super-over pressure gas pool of Kela 2 gas field. The over-pressure affect become stronger as a result of the rapid tectonic uplifting in shore time in recent stage. The reservoir forming mechanism of convection reservoir forming from water carried gas in overpressure compartment would be reservoir forming mechanism.
[1] 胡见义.含油气地质单元序列划分及其意义[A].中国石油地质学会地质专业委员会. 中国含油气系统的应用与进展[C].北京:石油工业出版社. 1997.3-8.
[2] 赵重远.论含油气盆地的整体动态综合分析[A].赵重远,刘池洋,姚远.含油气盆地地质学研究进展[C].西安:西北大学出版社. 1995.21-28.
[3] Bradley J S. Abnomal formation pressure[J]. AAPG Bulletin. 1975, 59(6):957-973.
[4] Bradley J S, Powley D E. Pressure compartments in sedimentary basin: A review of basin compartment and seal[J]. AAPG Memoir,1994,61:3-26.
[5] Powley D E. Pressures and hydrogeology in petroleum basins. Earth Science Reviews[J]. 1990.29:215-226.
[6] Gerard Demaison, Bradley Huizinga J. Genetic classification of petroleum system using three factors: Charge, migration and entrapment[J]. AAPG Memoir 60.1994. 73-89.
[7] Hunt J M. Generation and migration of petroleum from abnormal pressure fluid compartment[J]. AAPG Bull., 1990: 1-12.
[8] 张义纲, 陈彦华, 陆嘉炎. 油气运移及其聚集成藏模式[M]. 南京: 河海大学出版社, 1997.69-84.
[9] 贾承造, 顾家裕, 张光亚. 库车坳陷大中型气田形成的地质条件[J].科学通报. 2002.47(增刊) :49-55.
[10] 戴金星. 中国大、中型气田形成主要控制因素[A]. 戴金星.中国大中型气田形成条件与分布规律[C].北京:科学出版社.1997.184-198.
[11] 周兴熙. 库车油气系统第三系盐膏质盖层特征及其对油气成藏的控制作用[J]. 古地理学报. 2000.2(4):51-57.
[12] 周兴熙. 源盖共控论述要[J]. 石油勘探与开发. 1997, 24(60):4-7.〖LL〗
[13] Marlan W,Downey油气藏盖层含油气系统——从源岩到圈闭[M].张祈译.北京:石油工业出版社. 1998.184-190.
[14] 周兴熙. 库车油气系统新生代构造格局演变及油气成藏作用[J].古地理学报, 2002, 4(1):75-82.
[15] 周兴熙. 库车油气系统成藏作用与成藏模式[J]. 石油勘探与开发, 2001, 28(2):8-10.
[16] 周兴熙. 库车油气系统中新生界压力结构和成藏机制[J]. 地学前缘, 2001, 8(4):351-361.
[17] 周兴熙,张光亚,李洪辉,等. 塔里木盆地库车油气系统的成藏作用[M]. 北京:石油工业出版社,2002.
[18] 梁狄刚, 张水昌, 赵孟军, 等. 库车坳陷的油气成藏期[J]. 科学通报, 2002, 47(增刊):56-63.
[19] 张启明. 强超压储层天然气成藏条件[J]. 科学通报, 2002, 47(增刊):77-83.
[20] 宋岩, 贾承造, 赵孟军, 等. 库车煤成烃前陆盆地冲断带大气田的控制因素[J]. 科学通报, 2002, 47(增刊):64-69.[21] 赵孟军, 卢双舫, 王廷栋, 等. 克拉2气田天然气地球化学特征与成藏过程[J]. 科学通报, 2002, 47(增刊):109-115.
[22] Rooney M A, Claypool G E, Chung H M. Modeling themogenic gas generating using carbon isotope ratios of natural gas hydrocarbons[J]. Chem Geol, 1995, 123(3-4): 219-232.
[23] 周兴熙, 王红军. 略论天然气甲烷碳同位素的累积效应[J].石油勘探与开发, 1999, 26(1):10-12.
[24] 陶士振, 秦胜飞. 塔里木盆地克依构造带包裹体油气地质研究[J]. 石油学报, 2001,22(5):16-22.
[25] 陶士振, 秦胜飞, 张宝民. 库车前陆盆地油气运移的物理化学条件[J]. 地质科学, 2002, 37(增刊):129-140.
[26] 王红军, 胡见义. 库车油气系统白垩系含油气系统与高压气藏的形成[J]. 天然气工业, 2002, 22(1):5-8.
[27] 皮学军, 谢会文, 张存, 等. 库车前陆逆冲带异常高压成因机制及其对油气藏形成的作用[J]. 科学通报, 2002, 47(增刊):84-90.
[28] 夏新宇, 宋岩, 房得权. 构造抬升对地层压力的影响及克拉2气田异常压力成因[J]. 天然气工业, 2001, 21(1):35-41.
[29] 宋岩, 夏新宇, 洪峰, 等. 前陆盆地异常压力特征与天然气成藏模式[J]. 科学通报, 2002, 47(增刊):70-76.
[30] 周兴熙. 库车油气系统北带中、新生界主要储层孔隙流体超压成因探讨[J]. 古地理学报, 2003, 5(1):110-119.
[31] Barker C. Calculated volume and pressure change during the thermal cracking of oil to gas in reservoir[J]. AAPG Bulletin, 1990: 1254-1261.
[32] 马启富, 陈斯忠, 张启明, 等. 超压盆地与油气分布[M]. 北京:地质出版社, 2000.2-4.
[33] 张厚福, 方朝亮, 高先志, 等. 石油地质学[M]. 北京:石油工业出版社, 1999.176-178.
[34] 李亮. 墨西哥湾油气的运移和补给[J]. 石油知识,1994, (4):14-16.
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