Predictive Model for Relative Permeability Using Physically-Constrained Artificial Neural Networks

IF 3.2 3区工程技术 Q1 ENGINEERING, PETROLEUM

SPE Journal Pub Date : 2023-10-01 DOI:10.2118/209420-pa

Hanif F. Yoga, Russell T. Johns, Prakash Purswani

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引用次数: 0

Abstract

Summary Hysteresis of transport properties like relative permeability (kr) can lead to computational problems and inaccuracies for various applications including CO2 sequestration and chemical enhanced oil recovery (EOR). Computational problems in multiphase numerical simulation include phase labeling issues and path dependencies that can create discontinuities. To mitigate hysteresis, modeling kr as a state function that honors changes in physical parameters like wettability is a promising solution. In this research, we apply the state function concept to develop a physics-informed data-driven approach for predicting kr in the space of its state parameters. We extend the development of the relative permeability equation-of-state (kr-EoS) to create a predictive physically-constrained model using artificial neural networks (ANNs). We predict kr as a function of phase saturation (S) and phase connectivity (χ^), as well as the specific S-χ^ path taken during the displacement while maintaining other state parameters constant such as wettability, pore structure, and capillary number. We use numerical data generated from pore-network modeling (PNM) simulations to test the predictive capability of the EoS. Physical limits within S-χ^ space are used to constrain the model and improve its predictability outside of the region of measured data. We find that the predicted relative permeabilities result in a smooth and physically consistent estimate. Our results show that ANN can more accurately estimate kr surface compared to using a high-order polynomial response surface. With only a limited amount of drainage and imbibition data with an initial phase saturation greater than 0.7, we provide a good prediction of kr from ANN for all other initial conditions, over the entire S-χ^ space. Finally, we show that we can predict the specific path taken in the S-χ^ space along with the corresponding kr for any initial condition and flow direction, making the approach practical when phase connectivity information is unavailable. This research demonstrates the first application of a physics-informed data-driven approach for the prediction of relative permeability using ANN.

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基于物理约束人工神经网络的相对渗透率预测模型

相对渗透率(kr)等输运性质的滞后性可能会导致计算问题和各种应用的不准确性，包括二氧化碳封存和化学提高采收率(EOR)。多相数值模拟中的计算问题包括相位标记问题和可能产生不连续的路径依赖。为了减轻迟滞，将kr建模为一个状态函数，该函数遵循物理参数(如润湿性)的变化，这是一个很有前途的解决方案。在本研究中，我们应用状态函数概念开发了一种物理知情的数据驱动方法，用于预测其状态参数空间中的kr。我们扩展了相对渗透率状态方程(kr-EoS)的发展，使用人工神经网络(ann)创建了一个预测的物理约束模型。我们预测kr是相饱和度(S)和相连通性(χ^)的函数，以及位移过程中采取的特定S-χ^路径，同时保持其他状态参数恒定，如润湿性，孔隙结构和毛细数。我们使用孔隙网络建模(PNM)模拟生成的数值数据来测试EoS的预测能力。S-χ^空间内的物理限制用于约束模型并提高其在测量数据区域外的可预测性。我们发现预测的相对渗透率结果是一个平滑和物理一致的估计。我们的结果表明，与使用高阶多项式响应面相比，人工神经网络可以更准确地估计kr表面。只有少量的排水和渗吸数据，初始相饱和度大于0.7，在整个S-χ^空间内，我们可以很好地预测所有其他初始条件下的kr。最后，我们证明了我们可以预测任何初始条件和流动方向下的S-χ^空间中的特定路径以及相应的kr，使得该方法在相位连通性信息不可用的情况下实用。该研究首次展示了利用人工神经网络预测相对渗透率的物理数据驱动方法的应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

SPE Journal 工程技术-工程：石油

CiteScore

7.20

自引率

11.10%

发文量

229

审稿时长

4.5 months

期刊介绍： Covers theories and emerging concepts spanning all aspects of engineering for oil and gas exploration and production, including reservoir characterization, multiphase flow, drilling dynamics, well architecture, gas well deliverability, numerical simulation, enhanced oil recovery, CO2 sequestration, and benchmarking and performance indicators.