川中古隆起寒武系超压形成与保存

doi:10.11764/j.issn.1672-1926.2016.08.1439

天然气地球科学

川中古隆起寒武系超压形成与保存

刘一锋^1,2,3，邱楠生^1,2，谢增业⁴，姚倩颖⁵，刘雯^1,2

1.中国石油大学油气资源与探测国家重点实验室，北京 102249；
2.中国石油大学盆地与油藏研究中心，北京 102249；
3.南京大学地球科学与工程学院，江苏南京 210023；
4.中国石油勘探开发研究院廊坊分院，河北廊坊 065007；
5.中国石油杭州地质研究院，浙江杭州 310023

收稿日期:2015-10-19 修回日期:2016-03-06 出版日期:2016-08-10 发布日期:2016-08-10
通讯作者: 邱楠生(1968-),男,福建连城人，教授,博士生导师，主要从事沉积盆地温压场和盆地热体制和热历史研究. E-mail:qiunsh@cup.edu.cn.
作者简介:刘一锋(1987-),男，重庆人，博士后，主要从事含油气盆地温压场和油气成藏机理研究. E-mail:liuyf1103@foxmail.com.
基金资助:
国家“973”项目(编号：2012CB214703) ；国家杰出青年基金项目“石油与天然气地质”（编号：41125010）；国家科技重大专项研究专题“典型大气田形成的温压条件研究”（编号：2011ZX05007-002）联合资助.

The formation and preservation of overpressure in old formations:#br# Taking the Cambrian in the central of Sichuan Basin as an instance

Liu Yi-feng^1,2,3，Qiu Nan-sheng^1,2，Xie Zeng-ye⁴，Yao Qian-ying⁵，Liu Wen^1,2

1.State Key Laboratory of Petroleum Resource and Prospecting,China University of Petroleum,Beijing 102249,China;
2.Research Center for Basin and Reservoir,China University of Petroleum,Beijing 102249,China;
3.School of Earth Sciences and Engineering,Nanjing University,Nanjing 210023,China;
4.Langfang Branch,Research Institute of Petroleum Exploration and Development,Langfang 065007,China;
5.PetroChina Hangzhou Research Institute of Geology,Hangzhou 310023,China

Received:2015-10-19 Revised:2016-03-06 Online:2016-08-10 Published:2016-08-10

摘要/Abstract

摘要： 我国西部古老海相地层经历了复杂的地质演化过程，深入研究古老地层超压的成因机制和保存条件将有助于分析压力演化、完善油气成藏理论和提高勘探效率。以川中地区为例，利用多种压力数据并结合封隔层分布特征，将磨溪_高石梯地区纵向上划分为5个压力系统，其中包括3个超压系统；各超压系统的成因机制不同，寒武系超压主要是晚期原油裂解生气引起的流体膨胀所致，上三叠统须家河组和二叠系都具有明显的泥岩欠压实特征；下三叠统强超压应该是原油裂解作用附加了石膏脱水作用，膏岩良好的封隔能力是该套强超压保存的关键。良好的封隔层和晚期增压机制是川中古隆起寒武系发育超压的有利条件；后期构造抬升将造成地层压力下降，威远地区因此恢复至常压，磨溪_高石梯地区仍有超压保留。

关键词: 超压, 成因机制, 保存条件, 川中地区, 古老地层

Abstract: As old marine formations in the west of China experienced complex geologic evolution,deep studies on the mechanisms and preservation of overpressure in old formations would help for analyzing the fluid pressure evolution,improving the oil and gas accumulation theory and increasing the exploration efficiency.Taking the central of Sichuan Basin as an example,five pressure systems including three overpressure systems in the Moxi-Gaoshiti area have been identified in vertical,based on multiple pressure data and seals distribution characteristics.Mechanisms for various overpressure systems are different.The Cambrian overpressure system is predominantly associated with fluid expansion which was mainly resulted from late gas generation through oil cracking;the Upper Triassic Xujiahe Formation and the Permian are obvious disequilibrium compaction overpressures.The high-overpressure in the marine carbonate rocks of Lower Triassic was caused by oil cracking and gypsum dehydration mechanisms,and the good sealing capacity of the gypsolyte is the key factor for preservation of the high-overpressure.Effective seals and late pressurization are advantages for overpressure developing in old marine formations.Tectonic uplift could decrease the fluid pressure,and for this reason,hydrostatic pressure is reverted in the Weiyuan area,and overpressures are remained in the Moxi-Gaoshiti area.

Key words: Overpressure, Overpressure mechanism, Overpressure preservation, Central of Sichuan Basin, Old formation

中图分类号:

TE121

刘一锋, 邱楠生, 谢增业, 姚倩颖, 刘雯. 川中古隆起寒武系超压形成与保存[J]. 天然气地球科学, 2016, 27(8): 1439–1446.

Liu Yi-feng, Qiu Nan-sheng, Xie Zeng-ye, Yao Qian-ying, Liu Wen. The formation and preservation of overpressure in old formations:#br# Taking the Cambrian in the central of Sichuan Basin as an instance[J]. Natural Gas Geoscience, 2016, 27(8): 1439–1446.

参考文献

[1]Bowers G L.Pore pressure estimation from velocity data:Accounting from overpressure mechanisms besides undercompaction[J].SPE Drilling & Completion,1995,10(2):89-95.
[2]Osborne M J,Swarbrick R E.Mechanisms for generating overpressure in sedimentary basins:A reevaluation[J].AAPG Bulletin,1997,81(6):1023-1041.
[3]Tingay M R P,Hillis R R,Swarbrick R E,et al.'Vertically transferred' overpressures in Brunei:Evidence for a new mechanism for the formation of high-magnitude overpressure[J].Geology,2007,35(11):1023-1026.
[4]Wei G,Chen G,Du S,et al.Petroleum systems of the oldest gas field in China:Neoproterozoic gas pools in the Weiyuan Gasfield,Sichuan Basin[J].Marine and Petroleum Geology,2008,25(4):371-386.
[5]Liu S,Wang H,Sun W,et al.Energy field adjustment and hydrocarbon phase evolution in Sinian-Lower Paleozoic Sichuan Basin[J].Journal of China University of Geosciences,2008,19(6):700-706.
[6]Xu Guosheng,Meng Yuzhang,Zhao Yihua,et al.The study of accumulation mechanism of natural gas in Jialingjiang Formation,Moxi-Longnüsi area in the middle of Sichuan Basin[J].Petroleum Geology & Experiment,2009,31(6):576-582.[徐国盛,孟昱璋,赵异华,等.川中磨溪_龙女寺构造带嘉陵江组天然气成藏机理研究[J].石油实验地质,2009,31(6):576-582.]
[7]Hao Guoli,Liu Guangdi,Xie Zengye,et al.Distribution and origin of abnormal pressure in Upper Triassic Xujiahe Formation reservoir in central and southern Sichuan[J].Global Geology,2010,29(2):298-304.[郝国丽,柳广弟,谢增业,等.川中_川南地区上三叠统须家河组气藏异常压力分布及成因[J].世界地质,2010,29(2):298-304.]
[8]Ma Dewen,Qiu Nansheng,Xie Zengye,et al.Analysis on evolution of abnormal high formation pressure in gas fields of Upper Triassic Xujiahe Formation,central Sichuan Basin[J].Acta Sedimentologica Sinica,2011,29(5):593-561.[马德文,邱楠生,谢增业,等.川中地区上三叠统须家河组气田异常高压演化研究[J].沉积学报,2011,29(5):953-961.]
[9]Hunt J M.Generation and migration of petroleum from abnormally pressured fluid compartments[J].AAPG Bulletin,1990,74(1):1-12.
[10]Muggeridge A,Abacioglu Y,England W,et al.The rate of pressure dissipation from abnormally pressured compartments[J].AAPG Bulletin,2005,89(1):61-80.
[11]Ruth P V,Hillis R,Tingate P.The origin of overpressure in the Carnarvon Basin,Western Australia:implications for pore pressure prediction[J].Petroleum Geoscience,2004,10(3):247-257.
[12]Tingay M R P,Morley C K,Laird A,et al.Evidence for overpressure generation by kerogen-to-gas maturation in the northern Malay Basin[J].AAPG Bulletin,2013,97(4):639-672.
[13]Tingay M R P,Hillis R R,Swarbrick R E,et al.Origin of overpressure and pore-pressure prediction in the Baram Province,Brunei[J].AAPG Bulletin,2009,93(1):51-74.
[14]Lahann R W,Swarbrick R E.Overpressure generation by load transfer following shale framework weakening due to smectitediagenesis[J].Geofluids,2011,11(4):362-375.
[15]Zhang J.Effective stress,porosity,velocity and abnormal pore pressure prediction accounting for compaction disequilibrium and unloading[J].Marine and Petroleum Geology,2013,45:2-11.
[16]Luo X,Vasseur G.Contributions of compaction and aquathermal pressuring to geopressure and the influence of environmental conditions[J].AAPG Bulletin,1992,76(10):1550-1559.
[17]Deming D,Cranganu C,Lee Y.Self-sealing in sedimentary basins[J].Journal of Geophysical Research,2002,107(B12):2329.
[18]Fu Xiaodong,Qin Jianzhong,Tenger,et al.Mineral components of source rocks and their petroleum significance:A case from Paleozoic marine source rocks in the Middle-Upper Yangtze region[J].Petroleum Exploration and Development，2011,38(6):671-684.[付小东,秦建中,滕格尔,等.烃源岩矿物组成特征及油气地质意义__以中上扬子古生界海相优质烃源岩为例[J].石油勘探与开发,2011,38(6):671-684.]
[19]Yardley G S,Swarbrick R E.Lateral transfer:A source of additional overpressure?[J].Marine and Petroleum Geology,2000,17(4):523-537.
[20]Guo Zhengwu,Deng Kangling,Han Yonghui,et al.The Formation and Evolution of Sichuan Basin[M].Beijing:Geological Publishing House,1996.[郭正吾,邓康岭,韩永辉,等.四川盆地形成与演化[M].北京:地质出版社,1996.]
[21]Wei Guoqi,Liu Delai,Zhang Lin,et al.The exploration region and natural gas accumulation in Sichuan Basin[J].Natural Gas Geoscience,2005,16(4):437-442.[魏国齐,刘德来,张林,等.四川盆地天然气分布规律与有利勘探领域[J].天然气地球科学,2005,16(4):437-442.]
[22]Mao Qiong,Zou Guangfu,Zhang Hongmao,et al.Discussion on geodynamic evolution and oil/gas prospect of the Sichuan Basin[J].Natural Gas Industry,2006,26(11):7-10.[毛琼,邹光富,张洪茂,等.四川盆地动力学演化与油气前景探讨[J].天然气工业,2006,26(11):7-10.]
[23]Sun Wei,Liu Shugen,Ma Yongsheng,et al.Determination and quantitative simulation of gas pool formation process of Sinian cracked gas in Weiyuan-Ziyang area,Sichuan Basin[J].Acta Geologica Sinica,2007,81(8):1153-1159.[孙玮,刘树根,马永生,等.四川盆地威远_资阳地区震旦系油裂解气判定及成藏过程定量模拟[J].地质学报,2007,81(8):1153-1159.]
[24]Huang Wenming,Liu Shugen,Wang Guozhi,et al.Geological conditions and gas reservoir features in Lower Paleozoic in Sichuan Basin[J].Natural Gas Geoscience,2011,22(3):465-476.[黄文明,刘树根,王国芝,等.四川盆地下古生界油气地质条件及气藏特征[J].天然气地球科学,2011,22(3):465-476.]
[25]Liu Yifeng,Qiu Nansheng,Xie Zengye,et al.Characteristics and effects on gas accumulation of the Sinian-Lower Cambrian temperature-pressure field in the Central Paleo-Uplift,Sichuan Basin[J].Acta Sedimentologica Sinica,2014,32(3):601-610.[刘一锋,邱楠生,谢增业,等.川中古隆起震旦系_下寒武统温压演化及其对天然气成藏的影响[J].沉积学报,2014,32(3):601-610.]
[26]Zhang Lu,Xie Zengye,Wang Zhihong,et al.Caprock characteristics and sealing ability evaluation of Sinian-Cambrian gas reservoirs in Gaoshit-Moxi area,Sichuan Basin[J].Natural Gas Geoscience,2015,26(5):796-804.[张璐,谢增业,王志宏,等.四川盆地高石梯_磨溪地区震旦系_寒武系气藏盖层特征及封闭能力评价[J].天然气地球科学,2015,26(5):796-804.]
[27]Dai Jinxing.Pool-forming periods and gas sources of Weiyuan Gasfield[J].Petroleum Geology & Experiment,2003,25(5):473-480.[戴金星.威远气田成藏期与气源[J].石油实验地质,2003,25(5):473-480.]
[28]Huang Xianping,Wang ShiQian,Luo Qihou,et al.Oil and Gas Resource Evaluation in Sichuan Basin[R].Chengdu:PetroChina Southwest Oil & Gasfield Company,2002.[黄先平,王世谦,罗启后,等.四川盆地油气资源评价[R].成都:中国石油西南油气田分公司,2002.]
[29]Lü Yanfang,Fu Guang,Zhang Faqiang,et al.Quantitative Study on Sealing Ability of Ultra-Pressure Caprock[J].Acta Sedimentologica Sinica,2000,18(3):465-468.[吕延防,付广,张发强,等.超压盖层封烃能力的定量研究[J].沉积学报,2000,18(3):465-468.]
[30]Liu S,Deng B,Li Z,et al.Architecture of basin-mountain systems and their influences on gas distribution:A case study from the Sichuan basin,South China[J].Journal of Asian Earth Sciences,2012,47(1):204-215.
[31]Xia Xinyu,Song Yan.Temperature effects on geopressure during deposition and erosion[J].Petroleum Exploration and Development,2001,28(3):8-11.[夏新宇,宋岩.沉降及抬升过程中温度对流体压力的影响[J].石油勘探与开发,2001,28(3):8-11.]
[32]Xia Xinyu,Zeng Fangang,Song Yan.Is tectonic uplifting the genesis of abnormal highpressure?[J].Petroleum Geology & Experiment,2002,24(6):496-500.[夏新宇,曾凡刚,宋岩.构造抬升是异常高压的成因吗?[J].石油实验地质,2002,24(6):496-500.]
[33]Katahara K W,Corrigan J D.Effect of Gas on Poroelastic Response to Burial or Erosion[C]//Huffman A R,Bowers G L.Pressure Regimes in Sedimentary Basins and Their Prediction.
Houston:AAPG Memoir 76, 2002:73-78.
[34]Bao Youshu.Relationship between tectonic uplifting& erosion andformation of abnormal pressure[J].Oil & Gas Geology,2009,30(6):684-688.[包友书.构造抬升剥蚀与异常压力形成[J].石油与天然气地质,2009,30(6):684-688.]

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川中古隆起寒武系超压形成与保存

The formation and preservation of overpressure in old formations:#br# Taking the Cambrian in the central of Sichuan Basin as an instance

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