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用于模拟研究的非均质各向异性油藏的合成分形建模:对其烃类采收率预测的影响

Synthetic Fractal Modelling of Heterogeneous and Anisotropic Reservoirs for Use in Simulation Studies: Implications on Their Hydrocarbon Recovery Prediction.

作者信息

Al-Zainaldin Saud, Glover Paul W J, Lorinczi Piroska

机构信息

School of Earth and Environment, University of Leeds, Leeds, LS2 9JT UK.

出版信息

Transp Porous Media. 2017;116(1):181-212. doi: 10.1007/s11242-016-0770-3. Epub 2016 Oct 1.

DOI:10.1007/s11242-016-0770-3
PMID:32269403
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7115096/
Abstract

Optimising production from heterogeneous and anisotropic reservoirs challenges the modern hydrocarbon industry because such reservoirs exhibit extreme inter-well variability making them very hard to model. Reasonable reservoir models can be obtained using modern geostatistical techniques, but all of them rely on significant variability in the reservoir only occurring at a scale at or larger than the inter-well spacing. In this paper we take a different, generic approach. We have developed a method for constructing realistic synthetic heterogeneous and anisotropic reservoirs which can be made to represent the reservoir under test. The main physical properties of these synthetic reservoirs are distributed fractally. The models are fully controlled and reproducible and can be extended to model multiple facies reservoir types. This paper shows how the models can be constructed and how they have been tested. Reservoir simulation results of a number of generated 3-D heterogeneous and anisotropic models show that heterogeneity, in terms of only the geometric distribution of reservoir properties, has a little effect on oil production from high and moderate quality reservoirs. However, if the effect of heterogeneity on capillary pressure is taken into account, the effect becomes striking, where varying the heterogeneity of reservoirs properties can lead to a 70 % change in the predicted oil production rate and a significant early shift of water breakthrough time. Hence, it is the heterogeneity consequences that are really substantial if not taken into account. These are very significant uncertainties for a hydrocarbon company if the heterogeneity of their reservoir is not well defined.

摘要

优化非均质和各向异性油藏的产量给现代油气行业带来了挑战,因为这类油藏具有极大的井间变异性,很难对其进行建模。利用现代地质统计学技术可以获得合理的油藏模型,但所有这些模型都依赖于油藏中仅在等于或大于井间距的尺度上才出现的显著变异性。在本文中,我们采用了一种不同的通用方法。我们开发了一种构建逼真的合成非均质和各向异性油藏的方法,该方法可用于表征被测油藏。这些合成油藏的主要物理性质呈分形分布。这些模型完全可控且可重复,并且可以扩展到对多相油藏类型进行建模。本文展示了如何构建这些模型以及如何对它们进行测试。对多个生成的三维非均质和各向异性模型进行油藏模拟的结果表明,仅就油藏性质的几何分布而言,非均质性对高质量和中等质量油藏的产油量影响较小。然而,如果考虑非均质性对毛管压力的影响,这种影响就会变得显著,改变油藏性质的非均质性会导致预测产油率变化70%,并使水突破时间显著提前。因此,如果不考虑非均质性的影响,其后果实际上是相当严重的。对于油气公司来说,如果其油藏的非均质性没有得到很好的界定,这些都是非常重大的不确定性因素。

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