Dilayne Santos Oliveira, B. Horowitz, J. R. Rojas Tueros
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引用次数: 4
Abstract
Proxy models are widely used to estimate parameters such as interwell connectivity in the development and management of petroleum fields due to their low computational cost and not require prior knowledge of reservoir properties. In this work, we propose a proxy model to determine both oil and water production to maximize reservoir profitability. The approach uses production history and the Capacitance and Resistance Model based on Producer wells (CRMP), together with the combination of two fractional flow models, Koval [Cao (2014) Development of a Two-phase Flow Coupled Capacitance Resistance Model. PhD Dissertation, The University of Texas at Austin, USA] and Gentil [(2005) The use of Multilinear Regression Models in patterned waterfloods: physical meaning of the regression coefficient. Master’s Thesis, The University of Texas at Austin, USA]. The proposed combined fractional flow model is called Kogen. The combined fractional flow model can be formulated as a constrained nonlinear function fitting. The objective function to be minimized is a measure of the difference between calculated and observed Water cut (Wcut) values or Net Present Values (NPV). The constraint limits the difference in water cuts of the Koval and Gentil models at the time of transition between the two. The problem can be solved using the Sequential Quadratic Programming (SQP) algorithm. The parameters of the CRMP model are the connectivity between wells, time constant and productivity index. These parameters can be found using a Nonlinear Least Squares (NLS) algorithm. With these parameters, it is possible to predict the liquid rate of the wells. The Koval and Gentil models are used to calculate the Wcut in each producer well over the concession period which in turn allows to determine the accumulated oil and water productions. To verify the quality of Kogen model to forecast oil and water productions, we formulated an optimization problem to maximize the reservoir profitability where the objective function is the NPV. The design variables are the injector and producer well controls (liquid rate or bottom hole pressure). In this work the optimization problem is solved using a gradient-based method, SQP. Gradients are approximated using an ensemble-based method. To validate the proposed workflow, we used two realistic reservoirs models, Brush Canyon Outcrop and Brugge field. The results are shown into three stages. In the first stage, we analyze the ensemble size for the gradient computation. Second, we compare the solutions obtained with the three fractional flow models (Koval, Gentil and Kogen) with results achieved directly from the simulator. Third, we use the solutions calculated with the proxy models as starting points for a new high-fidelity optimization process, using exclusively the simulator to calculate the functions involved. This study shows that the proposed combined model, Kogen, consistently generated more accurate results. Also, CRMP/Kogen proxy model has demonstrated its applicability, especially when the available data for model construction is limited, always producing satisfactory results for production forecasting with low computational cost. In addition, it generates a good warm start for high fidelity optimization processes, decreasing the number of simulations by approximately 65%.
由于代理模型计算成本低,且不需要事先了解油藏性质,因此被广泛用于油田开发和管理中估计井间连通性等参数。在这项工作中,我们提出了一个代理模型来确定油和水的产量,以最大限度地提高油藏的盈利能力。该方法使用生产历史和基于生产井的电容和电阻模型(CRMP),以及两种分流模型的结合,Koval [Cao(2014)开发了两相流耦合电容电阻模型。dr . Dissertation, University of Texas at Austin, USA] and Gentil [(2005) Multilinear Regression Models在模式水驱中的应用:回归系数的物理意义。硕士论文,德克萨斯大学奥斯汀分校,美国]。提出的组合分流模型被称为Kogen。组合式分流模型可表述为约束非线性函数拟合。要最小化的目标函数是测量计算和观测到的含水率(Wcut)值或净现值(NPV)之间的差异。这一约束限制了Koval模型和Gentil模型在两者过渡时含水率的差异。该问题可以用序列二次规划(SQP)算法求解。CRMP模型的参数为井间连通性、时间常数和产能指数。这些参数可以使用非线性最小二乘(NLS)算法找到。有了这些参数,就可以预测井的产液率。Koval和Gentil模型用于计算特许期内每口生产井的Wcut,从而可以确定累积的油水产量。为了验证Kogen模型预测油水产量的质量,提出了以NPV为目标函数的油藏盈利能力最大化优化问题。设计变量是注入井和生产井控制(液量或井底压力)。在本工作中,采用基于梯度的方法SQP来解决优化问题。梯度近似使用基于集成的方法。为了验证提出的工作流程,我们使用了两个真实的油藏模型,即Brush Canyon露头和Brugge油田。研究结果分为三个阶段。在第一阶段,我们分析了梯度计算的集合大小。其次,我们将三种分数阶流动模型(Koval, Gentil和Kogen)的解与直接从模拟器获得的结果进行了比较。第三,我们使用代理模型计算的解决方案作为新的高保真优化过程的起点,专门使用模拟器计算所涉及的函数。本研究表明,所提出的组合模型Kogen始终产生更准确的结果。此外,CRMP/Kogen代理模型也证明了它的适用性,特别是在模型构建可用数据有限的情况下,总能以较低的计算成本获得令人满意的生产预测结果。此外,它为高保真优化过程产生了良好的热启动,将模拟次数减少了约65%。
期刊介绍:
OGST - Revue d''IFP Energies nouvelles is a journal concerning all disciplines and fields relevant to exploration, production, refining, petrochemicals, and the use and economics of petroleum, natural gas, and other sources of energy, in particular alternative energies with in view of the energy transition.
OGST - Revue d''IFP Energies nouvelles has an Editorial Committee made up of 15 leading European personalities from universities and from industry, and is indexed in the major international bibliographical databases.
The journal publishes review articles, in English or in French, and topical issues, giving an overview of the contributions of complementary disciplines in tackling contemporary problems. Each article includes a detailed abstract in English. However, a French translation of the summaries can be provided to readers on request. Summaries of all papers published in the revue from 1974 can be consulted on this site. Over 1 000 papers that have been published since 1997 are freely available in full text form (as pdf files). Currently, over 10 000 downloads are recorded per month.
Researchers in the above fields are invited to submit an article. Rigorous selection of the articles is ensured by a review process that involves IFPEN and external experts as well as the members of the editorial committee. It is preferable to submit the articles in English, either as independent papers or in association with one of the upcoming topical issues.