Well control optimization in waterflooding using genetic algorithm coupled with Artificial Neural Networks

IF 2.6 Q3 ENERGY & FUELS Upstream Oil and Gas Technology Pub Date : 2022-09-01 DOI:10.1016/j.upstre.2022.100071
Muhammad Gibran Alfarizi , Milan Stanko , Timur Bikmukhametov
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引用次数: 10

Abstract

Optimum well controls to maximize net present value (NPV) in a waterflooding operation are often obtained from an iterative process of employing numerical reservoir simulation and optimization algorithms. It is often challenging to implement gradient-based optimization algorithms because of the large number of variables and the complexities to embed the optimization algorithm in the simulator solving workflow. Approaches based on repeated model evaluation are easier to implement but are often time-consuming and computationally expensive.

This work proposes the use of Artificial Neural Networks (ANN) to replicate the numerical reservoir simulation outputs. The ANN model is used to estimate cumulative oil production, cumulative water injection, and cumulative water production based on sets of well control values, i.e. flowing bottom-hole pressure. Then, the ANN model is combined with the genetic algorithm (GA) optimization (a derivative-free optimization) to find the optimum well controls that maximize the NPV of a synthetic reservoir model. The optimization results of this ANN-GA model were compared against the results of using the traditional approach of applying the genetic algorithm directly on the numerical reservoir model.

The ANN model successfully reproduces the results of the numerical reservoir model with a low average error of 1.89%. The ANN-GA model successfully finds optimal operational conditions that are identical to those found by using GA and the original reservoir model. However, the running time was lowered by 96% (43 h faster) when compared to the optimization scheme using the original reservoir model. The optimal solution increases the NPV by 22.2% when compared to the base case.

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基于遗传算法和人工神经网络的水驱井控优化
在注水作业中,实现净现值(NPV)最大化的最佳井控通常是通过采用数值油藏模拟和优化算法的迭代过程获得的。基于梯度的优化算法的实现往往具有挑战性,因为它包含大量的变量和将优化算法嵌入到模拟器求解工作流程中的复杂性。基于重复模型评估的方法更容易实现,但通常耗时且计算成本高。这项工作提出使用人工神经网络(ANN)来复制数值油藏模拟输出。人工神经网络模型用于根据井控值(即井底流动压力)来估计累计产油量、累计注水量和累计产水量。然后,将人工神经网络模型与遗传算法(GA)优化(一种无导数优化)相结合,找到使合成油藏模型的NPV最大化的最佳井控。将该ANN-GA模型的优化结果与直接应用遗传算法求解油藏数值模型的传统方法进行了比较。人工神经网络模型成功地再现了油藏数值模型的结果,平均误差较低,为1.89%。ANN-GA模型成功地找到了与遗传算法和原始油藏模型相同的最优运行条件。然而,与使用原始油藏模型的优化方案相比,运行时间缩短了96%(缩短了43 h)。与基本情况相比,最优解决方案使NPV增加22.2%。
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