利用网络拓扑约束裂缝网络渗透率

R. Hansberry, S. Holford, R. King, N. Debenham
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引用次数: 0

摘要

预测任何尺度裂缝的连通性和渗透率仍然是构造地质学的一个基本挑战。根据与应力场的关系来预测裂缝打开可能性的模型可以应用于数百米到公里的尺度。然而,对最小尺度(亚地震级至毫米级)天然裂缝网络如何允许地下流体流动的理解日益成为预测和开发这些途径的关键。在这里,我们将网络拓扑的新兴方法应用于Otway盆地的一个化石断层破坏带的天然裂缝网络。网络连通性和潜在的渗透流体已被证明与拓扑结构和压裂强度直接相关。该技术相对简单,提供了一系列参数来定义裂缝网络的各个方面(例如强度、连通性),并且与感兴趣的结构的规模和几何形状无关。我们将该技术与传统的构造分析相结合,以说明区域尺度断层周围的压裂规模,并约束与裂缝网络相关的渗透率的空间变化。我们还说明了如何将这种技术的元素应用于现有的地下数据。
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Using network topology to constrain fracture network permeability
Summary Predicting the interconnectivity and permeability of fractures at any scale remains a fundamental challenge in structural geology. Models which predict the likelihood of fracture opening based on their relation to the stress field can be applied at scales of 100s of metres to kilometres. Increasingly however, an understanding of how networks of the smallest-scale (sub-seismic to mm) natural fractures permit fluid flow in the subsurface appears key to predicting and exploiting these pathways. Here, we apply the nascent method of network topology to natural fracture networks to a fossilised fault damage zone in the Otway Basin. Network connectivity and the potential to percolate fluids has been shown to be directly related to the topology, and intensity of fracturing. This technique is relatively straightforward, provides a range of parameters to define various aspects of a fracture network (e.g. intensity, connectivity), and is independent of the scale and geometry of the structures of interest. We integrate this technique with traditional structural analysis to illustrate the scale of fracturing around a region-scale fault and constrain spatial variation in permeability associated with the fracture network. We also illustrate how elements of this technique might be applied to existing sub-surface data.
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