摘要
伊通盆地莫里青断陷具多物源、多期次走滑断陷盆地的特征,其断裂复杂,物源期次、储层展布认识不足。文章应用高分辨率层序地层学原理,岩—电—震相结合,通过对莫里青油田双阳组二段层序主要界面的识别与对比,首次将研究区双阳组二段划分为4个四级层序(对应基准面中期旋回)和13个基准面短期旋回,建立了莫里青油田高分辨率层序格架。结合粒度分析、地震属性和地震相分析等方法进行沉积微相划分,进而利用相控随机建模的方法,拟合开发程度较高的A、B区块的储层展布特征,选取最优模型,实现对开发程度较低的C、D区块进行储层预测的目的。该方法成功在莫里青油田C区块南部双二段预测出6个有利含油储层,实现储层定性分析向半定量、定量化分析的转变。
With multiple sources and multiple stages for strike-slip,the Moliqing Fault Basin has a complicated fracture pattern,and the source stage and reserve distribution still remain discussing.By means of high-resolution sequence stratigraphy,combining lithologic,electric and seismic data together,the 2nd member of the Shuangyang Formation in the Moliqing Oilfield has been divided into 4 4th-grade sequences(equivalent to mid-term base-level cycles) and 13 short-term base-level cycles.A high-resolution sequence stratigraphy framework of the Moliqing Oilfield has been established.Grain size,seismic attribute and facies analyses have been applied to study sediment-ary micro-facies.Using facies-constrained stochastic modeling method,the reservoir distributing features of high-exploitation blocks A and B have been fitted and the optimal parameters and models have been selected.Then these parameters are applied to the reservoir prediction in blocks C and D which are in low exploitation degree.Six oil-bearing reservoirs in the 2nd member of the Shuangyang Formation in the south of block C have been predicted with this method.The change from qualitative analysis to semi-quantitative and quantitative analyses in reservoir research provides more reliable foundation for the exploration and development of lithologic reservoirs.
引文
[1]徐翔军.伊通地堑古近系层序地层学分析及重点区岩性地层圈闭分布规律[D].长春:吉林大学,2007:76-113.
[2]李本才.伊通地堑岔路河断陷古近系层序地层学研究及非构造圈闭预测[D].北京:中国地质大学,2006:38-40.
[3]马良,周江羽,王旭丽,等.伊通盆地岔路河断陷始新统地层对比[J].石油实验地质,2008,30(3):260-269.
[4]王永春.伊通地堑含油气系统与油气成藏[M].北京:石油工业出版社,2001:10-21.
[5]Van Wagoner J C,Mitchum R M,Campion K M,et al.Siliciclas-tic sequence stratigraphy in well logs,cores and outcrops:Con-cepts for high resolution correlation of time and facies[J].AAPGMethods in Exploration,1990(7):55.
[6]Mitchum Jr R M,Van Wagoner J C.High-frequency sequencesand their stacking patterns:sequence stratigraphic evidence ofhigh-frequency eustatic cycles[J].Sedimentary Geology,1991,70:131-160.
[7]Cross T A.High-resolutions stratigraphic correlation from the per-spective of base-level cycles and sediment accommodations[C].Proceedings of Northwestern European Sequence StratigraphyCongress,1994:105-123.
[8]威尔格斯C K.层序地层学原理:海平面变化综合分析[M].徐怀大,等译.北京:石油工业出版社,1993:155-183.
[9]邓宏文.高分辨率层序地层学:原理及应用[M].北京:地质出版社,2002:16-22.
[10]Escalona A,Mann P.Sequence-stratigraphic analysis of Eoceneclastic foreland basin deposits in central Lake Maracaibo usinghigh-resolution well correlation and 3-D seismic data[J].AAPG Bulletin,2006,90:581-623.
[11]郑荣才,彭军,吴朝容.陆相盆地基准面旋回的级次划分和研究意义[J].沉积学报,2001,19(2):249-255.
[12]陆永潮,任建业,李思田,等.伊通地堑的沉积充填序列及其对转换—伸展过程的响应[J].石油实验地质,1999,21(3):233-236.
[13]唐大卿,何生,陈红汉,等.伊通盆地断裂体系特征及其演化历史[J].吉林大学学报:地球科学版,2009,39(3):386-396.
[14]林畅松.沉积盆地的层序和沉积充填结构及过程响应[J].沉积学报,2009,27(5):849-862.
[15]秦雁群,邓宏文,侯秀林,等.海拉尔盆地乌尔逊凹陷北部高分辨率层序地层与储层预测[J].石油与天然气地质,2011,32(2):214-221.
[16]郑荣才,吴朝容,叶茂才.浅淡陆相盆地高分辨率层序地层研究思路[J].成都理工学院学报,2000,27(3):241-244.
[17]肖朝辉,王招明,吴金才,等.塔里木盆地石炭系层序地层划分及演化[J].石油实验地质,2011,33(3):244-254.
[18]朱红涛,Liu Keyu,杨香华.陆相湖盆层序构型及其岩性预测意义:以珠江口盆地惠州凹陷为例[J].地学前缘,2012,19(1):32-39.
[19]吴胜和,金振奎.储层建模[M].北京:石油工业出版社,1999:9-24.
[20]李少华,尹艳树,张昌民.储层随机建模系列技术[M].北京:石油工业出版社,2007:60-69.
[21]韩登林,张昌民,李忠,等.油气田开发中后期的储层三步建模法:以赵凹油田为例[J].地质科技情报,2007,26(5):109-112.