|
|
- 2018
基于分频融合地震属性的曲流带预测与点坝识别:以渤海湾盆地埕岛油田馆陶组为例*
|
Abstract:
埕岛油田馆陶组发育典型的高弯度曲流河沉积。通过分频融合地震属性提取与优选、储层构型模式指导、动态响应特征约束等手段,对研究区海上稀井网条件下曲流带和点坝进行精细刻画。研究表明: (1)分频融合地震属性的储层预测方法提高了曲流带的预测精度,振幅类属性与砂体厚度相关性最好,以最大峰值振幅为最佳,相比原始地震属性,分频融合得到的最大峰值振幅属性更好地刻画了曲流带砂体边界与砂体厚度分布;(2)复合正韵律、砂体厚度大、紧邻废弃河道分布为点坝三大重要识别标志,与此相对应,点坝表现为高最大峰值振幅、高反演属性的地震响应特征,而废弃河道呈弯月状低振幅属性、“顶平底凸”的低反演属性特征;(3)在应用地震属性确定点坝位置的基础上,通过经验公式推算点坝跨度,可认知研究区点坝的规模,有效指导地下点坝识别,动态信息的约束也为点坝识别提供了依据。井震结合的曲流带及点坝识别方法可为相似油田构型分析提供借鉴。
Sedimentary environment of the Guantao Formation in Chengdao Oilfield is meandering river. With the methods including the extraction and optimization of spectral-decomposed and fused seismic attributes,the guidance of reservoir architecture model,and dynamic response characteristics constraints,meandering belts and point bars under the condition of offshore sparse well network are characterized in detail. The result shows that: (1)the reservoir prediction method of spectral-decomposed seismic attributes improves the prediction accuracy of the meandering belt. The correlation between amplitude properties and sand thickness is the best,especially the maximum peak amplitude. Compared to the original seismic attributes,the maximum peak amplitude derived from the spectral-decomposed seismic attributes can characterize the boundary and thickness of the meandering sand-bodies much better. (2)The three important symbols of point bar are composite positive rhythms,thick sand-bodies,and being adjacent to abandoned channels. Corresponding to these features,point bars show the characteristics of seismic response with high maximum peak amplitude and high inversion properties,while abandoned channels show low amplitude attributes and low inversion properties with the characteristics of flat top and convex bottom. (3)Based on location prediction of the point bar by using seismic attributes,the span of the point bar is calculated through empirical formula,the scale of point bar is recognized,and the identification of subsurface point bar is effectively guided. The constraint of dynamic data also provides a basis for point bar identification. The methods proposed in this paper can provide implications to the oilfield with similar sedimentary characteristics and data condition
| [1] | 郭太现,杨庆红,黄凯,张建民. 2013. 海上河流相油田高效开发技术. 石油勘探与开发, 40(6): 708-714. [Guo T X,Yang Q H,Huang K,Zhang J M.2013. Techniques for high-efficient development of offshore fluvial oilfields. Petroleum Exploration and Development, 40(6): 708-714] [2] 姜秀清. 2006. 储集层地震属性优化及属性体综合解释. 中国科学院广州地球化学研究所博士论文, 50-74. [Jiang X Q.2006. The optimization of reservoir seismic attributes and the comprehensive interpretation of attribute-body. Doctoral Dissertation of Guangzhou Institute of Geochemistry,Chinese Academy of Sciences,50-74] [3] 马世忠,杨清彦. 2000. 曲流点坝沉积模式、三维构形及其非均质模型. 沉积学报, 18(2): 241-247. [Ma S Z,Yang Q Y.2000. The depositional model,3-D architecture and heterogeneous model of point bar in meandering channels. Acta Sedimentolgica Sinica, 18(2): 241-247] [4] 王海峰,范廷恩,宋来明,胡光义,梁旭,王帅,刘向南. 2017. 高弯度曲流河砂体规模定量表征研究. 沉积学报, 35(2): 279-289. [Wang H F,Fan T E,Song L M,Hu G Y,Liang X,Wang S,Liu X N.2017. Quantitative characterization study on sand body scale in high sinuosity meandering river. Acta Sedimentolgica Sinica, 35(2): 279-289] [5] 吴胜和,岳大力,刘建民,束青林,范峥,李宇鹏. 2008. 地下古河道储集层构型的层次建模研究. 中国科学: D 辑: 地球科学,38(增刊Ⅰ): 111-121. [Wu S H,Yue D L,Liu J M,Shu Q L,Fan Z,Li Y P.2008. Hierarchy modeling of subsurface palaeochannel reservoir architecture. Science in China: Series D: Earth Sciences,38(Supp.Ⅰ): 111-121] [6] 徐安娜,穆龙新,裘怿楠. 1998. 中国不同沉积类型储集层中的储量和可动剩余油分布规律. 石油勘探与开发, 25(5): 57-60. [Xu A N,Mu L X,Qiu Y N.1998. Distribution pattern of OOIP and remaining mobile oil in different types of sedimentary reservoir of China. Petroleum Exploration and Development, 25(5): 57-60] [7] 岳大力,吴胜和,刘建民. 2007. 曲流河点坝地下储集层构型精细解剖方法. 石油学报, 28(4): 99-103. [Yue D L,Wu S H,Liu J M.2007. An accurate method for anatomizing architecture of subsurface reservoir in point bar of meandering river. Acta Petrolei Sinica, 28(4): 99-103] [8] 曾洪流,朱筱敏,朱如凯,陈庆石. 2012. 陆相坳陷型盆地地震沉积学研究规范. 石油勘探与开发, 39(3): 275-284. [Zeng H L,Zhu X M,Zhu R K,Chen Q S.2012. Guidelines for seismic sedimentologic study in non-marine postrift basins. Petroleum Exploration and Development, 39(3): 275-284] [9] Chopra S,Marfurt K J.2012. Seismic attribute expression of differential compaction. The Leading Edge, 31(12): 1418-1422. [10] Hart B S.2008. Channel detection in 3-D seismic data using sweetness. AAPG, 92(6): 733-742. [11] Jiao Y,Yan J,Li S,Yang R,Lang F.2005. Architectural units and heterogeneity of channel reservoirs in Karamay Formation,outcrop area of Karamay oilfield,Junggar Basin,northwest of China. AAPG Bulletin, 89(4): 529-545. [12] Leeder M R.1973. Fluviatile fining-upwards cycles and the magnitude of palaeochannels. Geological Magazine, 110(3): 265-276. [13] Lorenz J C,Heinze D M,Clark J A,Searls C A.1985. Determination of width of meander-bel t sandstone reservoirs from vertical downhole data,Mesaverde Group,Piceance Greek Basin,Colorado. AAPG Bulletin, 69(5): 710-721. [14] Mirza N A, Philip R.2012. Application of spectral decomposition and seismic attributes to understand the structure and distribution of sand reservoirs within Tertiary rift basins of the Gulf of Thailand. The Leading Edge, 31(6): 630-634. [15] Schumm S A.1963. Sinuosity of alluvial rivers on the great plains. Geological Society of America Bulletin, 74: 1089-1100. [16] Widess M B.1973. How thin is a thin bed. Geophysics, 38(6): 1176-1180. |
