Hierarchical Modeling of Multi-Scale Flow Barriers in Channelized Reservoirs
Channelized reservoirs often show multi-scale architectures such as large-scale channel belts, middle-scale single channels and small-scale channel infill facies. These architectural elements are defined between bounding surfaces. Along these hierarchical bounding surfaces, thin shale drapes may be present as flow barriers that compartmentalize the reservoirs. Characterizing the distribution of these multi-scale flow barriers calls for a hierarchical modeling approach in which the large-scale reservoir architecture is modeled first, the shale drapes are then simulated within this architecture framework. The reservoir architecture modeling in this paper involves defining channel deposition fairways (valleys) based on seismic data, modeling long sinuous channels and placing them into defined fairways such that all data are matched. This paper adopts a stratigraphic-based modeling approach. In this stratigraphic-based approach, individual channels are simulated using the YACS method (Alapetite et al., 2005). This method is fast and conditions to well data under the assumption that channel sand can be identified in the well data. To put multiple channels together reproducing desirable stacking patterns, the overlap ratio and migration ratio are simulated. Once the large-scale reservoir architecture is modeled, the corresponding bounding surfaces are recorded; next the shale drapes are simulated along these surfaces using multiple-point statistics techniques.
Hongmei Li Jef Caers
Energy Resources Engineering Department, Stanford University, USA
国际会议
The 12th Conference of the International Association for Mathematical Geology(第12届国际数学地质大会)
北京
英文
381-385
2007-08-26(万方平台首次上网日期,不代表论文的发表时间)