A simple dilation-recompaction model for hydraulic fracturing

Xuemin Huang, Jingyi Wang, Shengnan (Nancy) Chen, Ian D. Gates
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引用次数: 8

Abstract

Production of unconventional oil and gas resources has played a significant role on the global energy supply, of which tight oil and gas reservoirs are drawing greater focus. The key enabler behind tight oil and gas production has been multi-stage hydraulic fracturing along extended reach horizontal wells. Despite many advances in multistage fracturing, it still remains unclear how to model the hydraulic fracturing process to provide the basis to optimize and predict the properties of fracture networks and associated enhancement of fluid production. In typical reservoir simulation practice, the conventional way to represent the hydraulic fracture is to place high permeability planes around the horizontal well – this means that the user has prescribed the orientation and length scale of the fracture before the simulation has started. In the research documented here, we explore a dynamic fracturing approach that uses a dilation-recompaction model in a reservoir simulator to model hydraulic fracturing. The key strength of the approach is that the geometry and length scale of the fracture is not prescribed a priori. The results of the simulation show that dilation-recompaction model is capable of modeling the hydraulic fracturing process prior to the flow-back and production. The oil, gas, and water rates of the model are well matched to the field data and the extent of the fractured zone predicted by the model is reasonable.

水力压裂的简单膨胀-再压实模型
非常规油气资源的开发在全球能源供应中发挥着重要作用,其中致密油气日益受到人们的关注。致密油气生产的关键推动因素是大位移水平井的多级水力压裂。尽管在多级压裂方面取得了许多进展,但如何对水力压裂过程进行建模,从而为优化和预测裂缝网络的性质以及相关的流体产量提高提供依据,目前仍不清楚。在典型的油藏模拟实践中,传统的表示水力裂缝的方法是在水平井周围放置高渗透平面,这意味着在模拟开始之前,用户已经规定了裂缝的方向和长度尺度。在本文的研究中,我们探索了一种动态压裂方法,该方法使用油藏模拟器中的膨胀-再压实模型来模拟水力压裂。该方法的关键强度在于,裂缝的几何形状和长度尺度不是预先规定的。模拟结果表明,膨胀-再压实模型能够较好地模拟反排生产前的水力压裂过程。模型的油、气、水速率与现场数据吻合较好,预测的裂缝带范围合理。
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