Reduced-Order Modeling for Multiphase Flow Using a Physics-Based Deep Learning

T. Alsulaimani, M. Wheeler
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引用次数: 1

Abstract

Reservoir simulation is the most widely used tool for oil and gas production forecasting and reservoir management. Solving a large-scale system of nonlinear differential equations every timestep can be computationally expensive. In this work, we present a two-phase physics-constrained deep-learning reduced-order model as a surrogate model for subsurface flow production forecast. The implemented deep learning model is a physics-guided encoder-decoder, constructed based on the Embed-to-Control (E2C) framework. In our implementation, the E2C works in a way analogous to Proper Orthogonal Decomposition combined with Discrete Empirical Interpolation Method (POD-DEIM) or Trajectory Piece-Wise Linearization approach (POD-TPWL). The E2C-Reduced-order model (ROM) involves projecting the system from a high-dimensional space into a low-dimensional subspace using the encoder-decoder, approximating the progression of the system from one timestep to the next using a linear transition model, and finally projecting the system back to high-dimensional space using the encoder-decoder. To guarantee mass conservation, we adopt the Finite Elements Mixed Formulation in the neural network's loss function combined with the original data-based loss function. Training simulations are generated using a full-physics reservoir simulator (IPARS). High-fidelity pressure, velocity, and saturation solution snapshot at constant time intervals are taken as training input to the neural network. After training, the model is tested over large variations of well control settings. Accurate pressure and saturation solutions are predicted along with the injection and production well quantities using the proposed approach. Errors in the predicted quantities of interest are reduced with the increase in the number of training simulations used. Although it required a large number of training simulations for the offline (training) step, the model achieved a significant speedup in the online stage compared to the full physics model. Considering the overall computational cost, this ROM model is proper for cases when a large number of simulations are required like in the case of production optimization and uncertainty assessments. The proposed approach shows the capability of the deep-learning reduced-order model to accurately predict multiphase flow behavior such as well quantities, and global pressure and saturation fields. The model honors mass conservation and the underlying physics laws, which many existing approaches don't take into direct consideration.
基于物理的深度学习多相流的降阶建模
油藏模拟是油气生产预测和油藏管理中应用最广泛的工具。求解一个大型非线性微分方程系统的每一个时间步可能是计算昂贵的。在这项工作中,我们提出了一个两阶段物理约束的深度学习降阶模型,作为地下流体产量预测的替代模型。实现的深度学习模型是一个物理引导的编码器-解码器,基于嵌入式到控制(E2C)框架构建。在我们的实现中,E2C的工作方式类似于结合离散经验插值方法(POD-DEIM)或轨迹分段线性化方法(POD-TPWL)的适当正交分解。e2c -降阶模型(ROM)涉及使用编码器-解码器将系统从高维空间投影到低维子空间,使用线性过渡模型近似系统从一个时间步到下一个时间步的进展,最后使用编码器-解码器将系统投影回高维空间。为了保证质量守恒,我们将神经网络损失函数中的有限元混合公式与原始的基于数据的损失函数相结合。训练模拟是使用全物理油藏模拟器(IPARS)生成的。以恒定时间间隔的高保真压力、速度和饱和度溶液快照作为神经网络的训练输入。经过训练后,该模型将在各种井控环境下进行测试。使用该方法可以预测准确的压力和饱和度解以及注入和生产井的数量。随着使用的训练模拟次数的增加,兴趣预测量的误差减少。尽管在离线(训练)阶段需要大量的训练模拟,但与全物理模型相比,该模型在在线阶段实现了显著的加速。考虑到总体计算成本,该模型适用于生产优化和不确定性评估等需要大量模拟的情况。该方法显示了深度学习降阶模型准确预测多相流行为(如井数量、整体压力和饱和度场)的能力。该模型尊重质量守恒和潜在的物理定律,而许多现有的方法并没有直接考虑到这一点。
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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