使用增强型物理数据驱动模拟器进行历史匹配和预测产量和井底压力数据

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2023-01-10 DOI:10.2118/210102-pa
Ying Li, Faruk Omer Alpak, Vivek Jain, Ranran Lu, Mustafa Onur
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引用次数: 0

摘要

在这项研究中,我们介绍了新开发的基于物理的数据驱动井间数值模拟器(INSIM)的一种新应用,即INSIM-BHP,用于对具有底水驱动机制的油藏生产的多射孔井中每天获得的高可变实际(振荡)产油量和井底压力(BHP)数据进行历史匹配。INSIM-BHP提供快速、准确的井速和bhp计算,用于历史匹配、预测和生产优化。它可以在有限含水层驱动机制的影响下提供精确的BHP计算。我们的新版本通过结合谐波平均透射率计算协议和在压力方程中包含算术平均重力项,更真实地代表了两相油水流动的物理特性。由于本研究中考虑的特定数据集包含一系列高度可变的油率和BHP数据,因此数据密度要求INSIM-BHP采取比通常更小的时间步长,并对使用INSIM-BHP作为正演模型的集成-平滑多数据同化(ES-MDA)历史匹配算法施加压力。该模拟器的另一个新功能是在模拟器的井模型中使用时变井指数和表皮因子,以解释井事件对油藏响应的影响,如结垢、出砂和基质酸化。另一项对井口周期计算的新颖修改,可以更好地模拟产量较低或井被关井时井筒内的流动物理。我们比较了INSIM-BHP与高保真商业油藏模拟器的历史匹配产油量和BHP数据和预测结果的准确性,以及历史匹配和未来预测的计算效率。结果表明,INSIM-BHP即使在振荡速率计划和操作条件变化的影响下,也能准确预测油井的产油量和bhp。此外,它还可以帮助诊断模拟运行中BHP测量的异常。针对本文研究的真实数据集,对INSIM-BHP和高保真商用模拟器的计算成本进行了评估。据观察,在单次正演模拟中,我们基于物理的数据驱动模拟器比传统的高保真油藏模拟器快两个数量级。具体的现场应用结果表明,在所研究的有限体积含水层驱动开发中,INSIM-BHP具有成为历史匹配和预测工作流快速近似能力的巨大潜力。
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History-Matching and Forecasting Production Rate and Bottomhole Pressure Data Using an Enhanced Physics-Based Data-Driven Simulator
Summary In this study, we present a novel application of our newly developed physics-based data-driven interwell numerical simulator (INSIM) referred to as INSIM-BHP to history match highly variable real-life (oscillatory) oil rate and bottomhole pressure (BHP) data acquired daily in multiperforated wells produced from an oil reservoir with bottomwater drive mechanism. INSIM-BHP provides rapid and accurate computation of well rates and BHPs for history matching, forecasting, and production optimization purposes. It delivers precise BHP calculations under the influence of a limited aquifer drive mechanism. Our new version represents the physics of two-phase oil-water flow more authentically by incorporating a harmonic-mean transmissibility computation protocol and including an arithmetic-mean gravity term in the pressure equation. As the specific data set considered in this study contains a sequence of highly variable oil rate and BHP data, the data density requires INSIM-BHP to take smaller than usual timesteps and places a strain on the ensemble-smoother multiple data assimilation (ES-MDA) history-matching algorithm, which utilizes INSIM-BHP as the forward model. Another new feature of our simulator is the use of time-variant well indices and skin factors within the simulator’s well model to account for the effects of well events on reservoir responses such as scaling, sand production, and matrix acidizing. Another novel modification has been made to the wellhead term calculation to better mimic the physics of flow in the wellbore when the production rate is low, or the well(s) is(are) shut in. We compare the accuracy of the history-matched oil rate and BHP data and forecasted results as well as computational efficiency for history matching and future prediction by INSIM-BHP with those from a high-fidelity commercial reservoir simulator. Results show that INSIM-BHP yields accurate forecasting of wells' oil rates and BHPs on a daily level even under the influence of oscillatory rate schedules and changing operational conditions reflected as skin effects at the wells. Besides, it can help diagnose abnormal BHP measurements within simulation runs. Computational costs incurred by INSIM-BHP and a high-fidelity commercial simulator are evaluated for the real data set investigated in this paper. It has been observed that our physics-based, data-driven simulator is about two orders of magnitude faster than a conventional high-fidelity reservoir simulator for a single forward simulation. The specific field application results demonstrate that INSIM-BHP has great potential to be a rapid approximate capability for history matching and forecasting workflow in the investigated limited-volume aquifer-driven development.
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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