基于动态模态分解的生产控制优化混合建模方法

Hardikkumar Zalavadia, S. Sankaran, M. Kara, Wenyue Sun, E. Gildin
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引用次数: 7

摘要

基于模型的油田开发规划和优化通常需要计算密集型油藏模拟,其中模型需要在输入不确定性或寻求最佳结果的情况下多次运行。降阶建模(ROM)方法是一类应用于油藏模拟的技术,用于降低模型复杂性和加快计算速度,特别是对于大规模或复杂的模型,这可能对此类优化问题非常有用。虽然侵入式ROM方法(如适当正交分解(POD)及其扩展、轨迹分段线性化(TPWL)、离散经验插值方法(DEIM)等)已被提出用于油藏模拟问题,但这些方法在使用商业模拟器的大量实际应用中仍然无法实现或无法使用。在本文中,我们描述了一种非侵入式ROM方法的新应用,即动态模式分解(DMD)。我们特别关注降低井控优化问题涉及的时间复杂性,使用DMD的一种变体,称为DMD(带控制的DMD)。我们提出了一个工作流程,使用井的训练数据集,并预测优化运行过程中遇到的一组新的井底压力剖面的状态解(压力和饱和度)。我们使用了一种新的策略来选择基维以防止不稳定解。由于优化问题的目标函数通常基于流体产量曲线,因此我们提出了一种使用机器学习技术从DMDc的预测状态预测流体产量的策略。该机器学习问题的特征是基于流体通过射孔的物理特性设计的,因此可以非常准确地预测产量。我们将提出的方法与DMD的另一种变体进行比较,称为ioDMD(输入-输出DMD),用于系统识别以预测输出生产流速。该方法在一个基准案例和墨西哥湾深水油田中得到了验证,结果表明,与精细模拟相比,使用所提出的DMDc工作流可以显著减少生产控制优化问题的时间,速度提高了约30 - 40倍,同时保持了解决方案的准确性。本文提出的降低模型复杂性的“非侵入式”方法可以大大增加ROM方法在实际油田开发和油藏管理中的应用范围。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Hybrid Modeling Approach to Production Control Optimization Using Dynamic Mode Decomposition
Model-based field development planning and optimization often require computationally intensive reservoir simulations, where the models need to be run several times in the context of input uncertainty or seeking optimal results. Reduced Order Modeling (ROM) methods are a class of techniques that are applied to reservoir simulation to reduce model complexity and speed up computations, especially for large scale or complex models that may be quite useful for such optimization problems. While intrusive ROM methods (such as proper orthogonal decomposition (POD) and its extensions, trajectory piece-wise linearization (TPWL), Discrete Empirical Interpolation Method (DEIM) etc.) have been proposed for application to reservoir simulation problems, these remain inaccessible or unusable for a large number of practical applications that use commercial simulators. In this paper, we describe a novel application of a non-intrusive ROM method, namely dynamic mode decomposition (DMD). We specifically look at reducing the time complexity involved in well control optimization problem, using a variant of DMD called DMDc (DMD with control). We propose a workflow using a training dataset of the wells and predict the state solution (pressure and saturation) for a new set of bottomhole pressure profiles encountered during the optimization runs. We use a novel strategy to select the basis dimensions to prevent unstable solutions. Since the objective function of the optimization problem is usually based on fluid production profiles, we propose a strategy to predict the fluid production rates from the predicted states from DMDc using machine learning techniques. The features for this machine learning problem are designed based on the physics of fluid flow through well perforations, which result in very accurate rate predictions. We compare the proposed methodology using another variant of DMD called ioDMD (input-ouput DMD) for system identification to predict output production flow rates. The methodology is demonstrated on a benchmark case and a Gulf of Mexico deepwater field that shows significant time reduction in production control optimization problem with about 30 – 40 times speedup using the proposed DMDc workflow as compared to fine scale simulations, while preserving the accuracy of the solutions. The proposed "non-intrusive" method in this paper to reduce model complexity can substantially increase the range of application of ROM methods for practical field development and reservoir management.
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