利用机器学习辅助工作流程优化水-交变co2注入现场作业

You Junyu, Ampomah William, Sun Qian
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引用次数: 0

摘要

本文将提出一个强大的工作流来解决具有大量操作控制参数的二氧化碳- eor封存项目的多目标优化(MOO)。Farnsworth Unit (FWU)油田是一个成熟的油藏,正在进行二氧化碳交替注水(CO2- wag)提高采收率(EOR),将作为现场案例来验证所提出的优化方案。这项工作的预期结果将是一个多目标函数的帕累托最优解库,包括石油采收率、碳储量和项目经济性。采用FWU的数值模型对所提出的优化流程进行了验证。由于使用MOO需要计算密集型的过程,因此引入了基于机器学习的代理来替代高保真模型,从而减少了总计算开销。利用向量机回归与高斯核(Gaussian -SVR)相结合的方法构建代理。迭代的自调整过程使训练知识库能够开发健壮的代理并最大限度地减少计算时间。采用贝叶斯优化方法对代理的超参数进行优化设计,以获得更好的泛化性能。将训练好的代理与多目标粒子群优化(MOPSO)协议相结合,构建Pareto-front解库。该工作流的结果将是一个存储库,其中包含CO2-WAG项目中考虑的多个目标的帕累托最优解。将提出的优化工作流程与另一种采用多层神经网络的方法进行比较,以验证其在处理具有大量参数控制的MOO时的可行性。所使用的优化参数包括可用于控制CO2-WAG过程的操作变量,例如注水/注气周期的持续时间、生产井底压力(BHP)控制以及数值模型中包含的每口井的注水速度。结果表明,耦合高斯-SVR代理和迭代自调整协议的工作流计算效率更高。通过压缩所需训练知识库的大小,使mooo过程更加快速,同时保持优化结果的高准确性。优化研究结果表明,在成功建立考虑多目标函数的解决方案库方面取得了良好的效果。利用得到的优化控制参数,将Pareto front与仿真结果进行了验证。这项工作的结果可以为油田运营商提供一个机会,利用尽可能多的油藏模型输入来设计CO2-WAG项目。本文提出了一种新的概念,将高斯-SVR代理与自调整协议相结合,以提高所提出工作流的计算效率,并保证所获得的优化结果的高准确性。更重要的是,该工作流可以优化复杂CO2-WAG过程中使用的大量控制参数,这大大扩展了其在解决具有相似期望结果的各种项目中的大规模多目标优化问题方面的实用性。
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Optimization of Water-Alternating-CO2 Injection Field Operations Using a Machine-Learning-Assisted Workflow
This paper will present a robust workflow to address multi-objective optimization (MOO) of CO2-EOR-sequestration projects with a large number of operational control parameters. Farnsworth Unit (FWU) field, a mature oil reservoir undergoing CO2 alternating water injection (CO2-WAG) enhanced oil recovery (EOR), will be used as a field case to validate the proposed optimization protocol. The expected outcome of this work would be a repository of Pareto-optimal solutions of multiple objective functions, including oil recovery, carbon storage volume, and project economics. FWU's numerical model is employed to demonstrate the proposed optimization workflow. Since using MOO requires computationally intensive procedures, machine-learning-based proxies are introduced to substitute for the high-fidelity model, thus reducing the total computation overhead. The vector machine regression combined with the Gaussian kernel (Gaussian -SVR) is utilized to construct proxies. An iterative self-adjusting process prepares the training knowledgebase to develop robust proxies and minimizes computational time. The proxies’ hyperparameters will be optimally designed using Bayesian Optimization to achieve better generalization performance. Trained proxies will be coupled with Multi-objective Particle Swarm Optimization (MOPSO) protocol to construct the Pareto-front solution repository. The outcomes of this workflow will be a repository containing Pareto-optimal solutions of multiple objectives considered in the CO2-WAG project. The proposed optimization workflow will be compared with another established methodology employing a multi-layer neural network to validate its feasibility in handling MOO with a large number of parameters to control. Optimization parameters used include operational variables that might be used to control the CO2-WAG process, such as the duration of the water/gas injection period, producer bottomhole pressure (BHP) control, and water injection rate of each well included in the numerical model. It is proven that the workflow coupling Gaussian -SVR proxies and the iterative self-adjusting protocol is more computationally efficient. The MOO process is made more rapid by squeezing the size of the required training knowledgebase while maintaining the high accuracy of the optimized results. The outcomes of the optimization study show promising results in successfully establishing the solution repository considering multiple objective functions. Results are also verified by validating the Pareto fronts with simulation results using obtained optimized control parameters. The outcome from this work could provide field operators an opportunity to design a CO2-WAG project using as many inputs as possible from the reservoir models. The proposed work introduces a novel concept that couples Gaussian -SVR proxies with a self-adjusting protocol to increase the computational efficiency of the proposed workflow and to guarantee the high accuracy of the obtained optimized results. More importantly, the workflow can optimize a large number of control parameters used in a complex CO2-WAG process, which greatly extends its utility in solving large-scale multi-objective optimization problems in various projects with similar desired outcomes.
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