基于组合的综合历史匹配方法的应用——海上油田案例研究

U. Aslam, Luis Hernando Perez Cardenas, Andrey Klimushin
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引用次数: 0

摘要

物联网普及了数字孪生的概念——物理系统的虚拟表示。设计油田开发计划存在很大的风险,多年来,油气行业一直在利用油藏模型(数字孪生模型)来改进决策过程。随着计算资源可用性的增加,行业正在转向基于集成的工作流程,以评估油田开发计划中的风险。在本文中,我们展示了使用基于集成的方法来评估油藏模型中的不确定性,并量化其对决策过程的影响。数字孪生的一个重要特征是它能够使用传感器数据来更新虚拟模型,更常见的是历史匹配或数据同化。我们演示了如何使用生产数据来识别和约束油藏模型中的不确定性。利用贝叶斯统计和最先进的监督机器学习技术,将生产数据结合起来,创建一个模型集合,以捕获油藏模型中的不确定性范围。这种具有改进预测能力的校准模型集合提供了与生产预测相关的不确定性的现实评估。通过在北海海上油田的应用,验证了基于集成的方法。在解释和深度转换后,该油田具有高度的分区性和高度的结构不确定性。建立了一个集成的跨域模型,将断层传递率、孔隙体积、流体接触、饱和度和相对渗透率端点等动态参数中的不确定性及其依赖关系纳入到通常被忽略的结构不确定性中。模型历史匹配集合的结果显示,这些参数和预测产量的不确定性显著降低。该技术的一个优点是自动化的、可重复的、可审计的基于集成的工作流可以在任何时候将新获得的测量数据吸收到油藏模型中,使模型保持最新和常绿。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Application of an Integrated Ensemble-Based History Matching Approach - An Offshore Field Case Study
The Internet of Things has popularized the notion of a digital twin - a virtual representation of a physical system. There are substantial risks associated with designing a development plan for an oilfield and the industry has been making use of reservoir models - digital twins - to improve the decision-making process for many years. With an increase in the availability of computational resources, the industry is moving towards ensemble-based workflows to estimate risk in field development plans. In this paper, we demonstrate the use of an integrated ensemble-based approach to assess uncertainties in the reservoir models and quantify their impact on the decision-making process. An important feature of a digital twin is its ability to use sensor data to update the virtual model, more commonly known as history matching or data assimilation. We demonstrate how production data can be used to identify and constrain the uncertainties in the reservoir model. Production data is incorporated using Bayesian statistics and state-of-the-art supervised machine learning techniques to create an ensemble of models that capture the range of uncertainties in the reservoir model. This ensemble of calibrated models with an improved predictive ability provides a realistic assessment of the uncertainty associated with production forecasts. The ensemble-based approach is demonstrated through its application on an offshore oilfield located in the North Sea. The field is highly compartmentalized and has high structural uncertainty following the interpretation and depth conversion. An integrated cross-domain model is set up to incorporate typically ignored structural uncertainty in addition to the uncertainties and their dependencies in the dynamic parameters, including fault transmissibility, pore-volume, fluid contacts, saturation, and relative permeability endpoints, etc. Results from the history matched ensemble of models show a significa nt reduction in uncertainty in these parameters and the predicted production. An advantage of the proposed technique is that the automated, repeatable, and auditable ensemble-based workflow can assimilate the newly acquired measured data into the reservoir model at any time, keeping the model up-to-date and evergreen.
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