非常规油田地质驱动的EUR预测

C. Temizel, C. H. Canbaz, Hasanain Alsaheib, Kirill Yanidis, Karthik Balaji, Nouf Alsulaiman, Mustafa A. Basri, Nayif Jama
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引用次数: 2

摘要

非常规油田的EUR(估计最终采收率)预测一直是一个艰难的过程,因为非常规油田的生产机制涉及到其物理特性,因此很难建模或预测。由于操作问题和历史生产数据的质量问题,基于机器学习(ML)的欧元预测变得非常具有挑战性。地质驱动的EUR预测一旦建立,就可以提供不受关闭等操作问题影响的EUR预测解决方案。该研究展示了智能油田的整体方法,通过实时数据流和模型更新,除了对单井进行EUR预测外,还可以优化井位。一个综合但真实的模型可以展示物理特性,用于生成训练ML模型的输入数据,其中空间分布的地质参数(包括但不限于孔隙度、渗透率、饱和度)被用来描述产量和最终的EUR。在油田地层特征不同的情况下进行完井,导致生产性能依赖于位置,从而根据地质参数的EUR预测进行井位优化。该算法不仅可以预测单井的EUR,还可以确定最佳的井位。由于训练模型中包含了干扰井的数据,因此该模型能够捕捉井干扰中的模式。即使构建了一个综合的、真实的油藏模型来生成数据,以辅助ML模型,但在实践中,(1)获取输入参数来建立一个鲁棒的油藏模拟模型并不是一件容易的事情;(2)理解和建模非常规油藏流体流动和生产的物理特性是建立真实模型的一项复杂而耗时的任务。因此,与数值模型和解决方案相比,像这样的数据驱动方法有助于通过合理的近似来加快油藏管理和开发决策。还解释了机器学习在智能领域的应用,其中模型是动态更新的,并使用新数据进行训练。地质驱动的EUR预测已经被应用,并且在行业中相对较新。在。在这项研究中,我们将其扩展到非常规智能油田的优化井位,超越了文献中的其他现有研究。
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Geology-Driven EUR Forecasting in Unconventional Fields
EUR (Estimated Ultimate Recovery) forecasting in unconventional fields has been a tough process sourced by its physics involved in the production mechanism of such systems which makes it hard to model or forecast. Machine learning (ML) based EUR prediction becomes very challenging because of the operational issues and the quality of the data in historical production. Geology-driven EUR forecasting, once established, offers EUR forecasting solutions that is not affected by operational issues such as shut-ins. This study illustrates the overall methodology in intelligent fields with real-time data flow and model update that enables optimization of well placement in addition to EUR forecasting for individual wells. A synthetic but realistic model which demonstrates the physics is utilized to generate input data for training the ML model where the spatially-distributed geological parameters including but not limited to porosity, permeability, saturation have been used to describe the production values and ultimately the EUR. The completion is given where the formation characteristics vary in the field that lead to location-dependent production performance leading to well placement optimization based on EUR forecasting from the geological parameters. The algorithm not only predicts the EUR of an individual well and makes decision for the optimum well locations. As the training model includes data of interfering wells, the model is capable of capturing the pattern in the well interference. Even though a synthetic but realistic reservoir model is constructed to generate the data for the aim of assisting the ML model, in practice, it is not an easy task to (1) obtain the input parameters to build a robust reservoir simulation model and (2) understanding and modeling of physics of fluid flow and production in unconventionals is a complex and time-consuming task to build real models. Thus, data-driven approaches like this help to speed up reservoir management and development decisions with reasonable approximations compared to numerical models and solutions. Application of machine learning in intelligent fields is also explained where the models are dynamically-updated and trained with the new data. Geology-driven EUR forecasting has been applied and relatively-new in the industry. In. this study, we are extending it to optimize well placement in intelligent fields in unconventionals beyond other existing studies in the literature.
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