珠江口盆地深水区白云凹陷超压成因机制及其勘探意义

doi:10.7623/syxb202201004

石油学报 ›› 2022, Vol. 43 ›› Issue (1): 41-57.DOI: 10.7623/syxb202201004

珠江口盆地深水区白云凹陷超压成因机制及其勘探意义

张向涛¹, 李军², 向绪洪¹, 赵靖舟²

1. 中海石油深海开发有限公司广东深圳 518054;
2. 西安石油大学地球科学与工程学院陕西省油气成藏地质学重点实验室陕西西安 710065

收稿日期:2021-03-22 修回日期:2021-10-03 出版日期:2022-01-25 发布日期:2022-02-10
通讯作者: 李军,男,1982年12月生,2012年获中国石油大学(北京)博士学位,现为西安石油大学地球科学与工程学院副教授,主要从事油气成藏地质学、非常规油气地质与勘探方面的教学与科研工作。Email:lijun@xsyu.edu.cn
作者简介:张向涛,男,1969年10月生,1996年获中国石油大学(华东)硕士学位,现为中海石油深海开发有限公司教授级高级工程师,主要从事珠江口盆地(东部)油气勘探与地质研究工作。Email:zhangxt1@cnooc.com.cn
基金资助:
中海石油（中国）有限公司"十三五"科技重点项目（CNOOC-KJ135ZDXM37SZ01SHENHAI）资助。

Genetic mechanism of overpressure and its significance on petroleum exploration in Baiyun sag in the deep water zone of Pearl River Mouth Basin

Zhang Xiangtao¹, Li Jun², Xiang Xuhong¹, Zhao Jingzhou²

1. CNOOC Deepwater Development Limited, Guangdong Shenzhen 518054, China;
2. School of Earth Sciences and Engineering, Xi'an Shiyou University;Shaanxi Key Lab of Petroleum Accumulation Geology, Shaanxi Xi'an 710065, China

Received:2021-03-22 Revised:2021-10-03 Online:2022-01-25 Published:2022-02-10

摘要/Abstract

摘要： 珠江口盆地深水区白云凹陷珠海组—文昌组油气勘探近期取得重要突破，在超压层段见砂即见油气，揭示超压可能是此类油气藏形成与分布的重要控制因素之一，但目前超压成因及其与油气成藏的关系尚缺乏深入研究。选取凹陷内3口典型超压井进行全井段泥页岩系统取样，并开展场发射扫描电镜、N₂/CO₂吸附和X射线衍射等实验，明确了白云凹陷主洼及北坡和白云东两个地区泥页岩成岩作用及超压测井响应差异的原因。同时，基于钻井和Bowers法预测压力结果，在明确超压分布特征的基础上，采用多方法深入分析了超压成因机制，并探讨了超压的成藏效应及下一步的油气勘探领域。研究结果表明，白云凹陷超压段的测井响应模式存在地区差异，白云主洼及北坡表现为声波时差、密度基本保持恒定，电阻率增加；白云东地区表现为随深度增加声波时差、电阻率出现明显反转，密度先增加后小幅反转。造成这种差异的原因为两个地区的泥页岩矿物组成存在差异，导致其孔隙结构和压实模式不同。白云凹陷珠海组—文昌组的超压为非欠压实成因，超压源主要为生烃导致的流体膨胀，白云东地区的超压亦可能与黏土矿物转化有关，储层超压为压力传导成因。超压是油气成藏的动力，油气藏的形成与分布与古今超压的分布密切相关，据此可划分超压封存箱箱缘及箱外常压油气藏和箱内超压油气藏两大油气勘探领域，前者主要受控于泄压通道与优质圈闭等成藏要素的有效耦合，后者则与良好的生烃及滞烃条件、超压强度和优质储层及储层甜点等因素密切相关。

关键词: 生烃增压, 压力传导, 超压成因, 勘探领域, 珠海组—文昌组, 白云凹陷, 珠江口盆地

Abstract: Recently, an important breakthrough has been made in the oil-gas exploration of Zhuhai Formation and Wenchang Formation of Baiyun sag in the deep water zone of Pearl River Mouth Basin, and the sandbody, i.e., oil and gas, was found in overpressure section, revealing that overpressure might be one of the key controlling factors for the formation and distribution of this type of oil-gas reservoirs. However, there are still few stuies on the overpressure genesis and the relationship between it and oil-gas reservoir formation. Therefore, three typical overpressure wells in the sag were selected for systematic shale sampling throughout the well section, and the experiments such as field emission scanning electron microscopy, N₂/CO₂ absorption and X-ray diffraction were carried out, clarifying the shale diagenesis in the main depression, north slope and the east of Baiyun sag, as well as the causes for the difference in overpressure logging response. Meanwhile, based on the determination of overpressure distribution characteristics according to the pressure prediction results obtained by drilling and Bowers method, multiple methods were adopted to this paper thoroughly analyzes the overpressure genesis mechanism using multiple methods and explores the hydrocarbon accumulation effect under overpressure and the oil-gas exploration fields in the near future. The research results show that there is a regional difference in the logging response model of overpressure section in Baiyun sag; the sonic transit time and density remain constant and the electrical resistivity is increased in the main depression and north slope of Baiyun sag; in the east of Baiyun sag, the sonic transit time and resistivity show an obvious reversal with the increasing of depth, while the density first increases and then is slightly reversed. The reason for such a difference is that there are differences in mineral composition of the shale in the two regions, thus resulting in various pore structures and compaction modes. The overpressure in Zhuhai Formation-Wenchang Formation of Baiyun sag is not caused by undercompaction, and the source of overpressure primarily lies in fluid expansion caused by hydrocarbon generation; the overpressure in the east of Baiyun sag may also be related to clay mineral transformation, and reservoir overpressure is resulted from pressure transfer. As overpressure is the driving force for hydrocarbon accumulation, and the formation and distribution of oil-gas reservoirs are closely related to the distribution of overpressure in ancient and modern times. On this basis, the oil-gas exploration fields can be divided into the atmospheric pressure oil-gas reservoir at the edge of overpressure sealing compartment or outside the compartment and the overpressure oil-gas reservoir inside the compartment. Specifically, the former is mainly controlled by the effective coupling of reservoir-forming elements, such as pressure releasing pathway and high-quality trap, while the latter is closely related to such factors as good hydrocarbon generation and hysteresis conditions, overpressure strength and high-quality reservoirs and sweet spots.

Key words: hydrocarbon generation overpressure, pressure transfer, overpressure genesis, exploration fields, Zhuhai Formation to Wenchang Formation, Baiyun sag, Pearl River Mouth Basin

中图分类号:

TE122.3

张向涛, 李军, 向绪洪, 赵靖舟. 珠江口盆地深水区白云凹陷超压成因机制及其勘探意义[J]. 石油学报, 2022, 43(1): 41-57.

Zhang Xiangtao, Li Jun, Xiang Xuhong, Zhao Jingzhou. Genetic mechanism of overpressure and its significance on petroleum exploration in Baiyun sag in the deep water zone of Pearl River Mouth Basin[J]. Acta Petrolei Sinica, 2022, 43(1): 41-57.

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珠江口盆地深水区白云凹陷超压成因机制及其勘探意义

Genetic mechanism of overpressure and its significance on petroleum exploration in Baiyun sag in the deep water zone of Pearl River Mouth Basin

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