集成动态资产建模在海上设施生产不稳定性预测和解决中的应用,案例研究,墨西哥

O. Espinola, R. Mehranfar, J. Álvarez, J. Villanueva, L. Vazquez
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引用次数: 0

摘要

集成资产建模在过去十年中得到了广泛的应用,涵盖了从油田开发到生产优化的各种挑战。除了支持feed和FEL研究的不同目的。此外,该技术在集成和动态或瞬态仿真方面已经发展,作为一个额外的元素,扩展了覆盖不同挑战和工作流程的可能性。本文的目的是展示如何将这种动态集成(动态集成资产建模)应用于在不同动态机制(注入、含水层和气顶)下产生水和气的几个储层的共同问题,从储层的角度理解气和水对整个生产系统的影响。所采用的方法是使用经过数值模拟的精细扇区模型,结合瞬态多相流模拟器,根据岩石物理性质和不同的生产场景,观察压降对接触面水平和形状的影响,并生成不同的图形来观察这种现象的表现。此外,还与文献中用于识别气和水窜流的所有最具分析性的相关性进行了比较,以了解它们之间的差异,并使用这种动态综合方法。另一方面,对于生产端,该耦合模型应用于海上设施,以观察这些储层对输送系统的影响,以及它们如何影响管道和立管,因为气体和水的突然进入改变了流动条件、流动模式、压降,并在严重段塞流引起的分离器中造成了一些不稳定。该分析的结果对于了解总产量系统(储层-地表)的动态、预测气侵和水侵、建立避免这些问题的临界速率以及了解在某些情况下与常用分析相关性的结果有何不同非常有用。建立了管道和立管中的特定条件,以量化段塞问题,并通过提出不同的方案(例如立管注气、顶部堵塞等)来评估消除不稳定性的不同方案。这种综合方法的应用对于识别问题的根源,在开发和运营阶段提供适当和可行的解决方案非常有益。此外,验证和减少相关文献相关性的不确定性,为生产和油藏工程师提供了一种快速可靠的方法来了解临界速率,从而支持决策过程。
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 Integrated Dynamic Asset Modeling to Predict and Resolve Production Instabilities in an Offshore Facility, A Case Study, Mexico
Integrated asset modeling has been used for the last decade with a wide technical application covering different challenges from field development to production optimization. Besides supporting the FEEDS and FEL studies for different purposes. Moreover, the technology has evolved in terms of integration and dynamic or transient simulation has been added as an extra element expanding the possibility to cover different challenges and workflows. The objective of this paper is to show how this dynamic integration (Dynamic integrated asset modeling) was applied to a common problem of several reservoirs that produce water and gas under different dynamic mechanisms (injection, aquifer and gas cap) to understand, from the reservoir perspective, the effects of gas and water conning over the entire production system. The methodology applied was using a refined sector model solved with numerical simulation and coupled with a transient multiphase flow simulator to see how pressure drop affect the contacts level and shape based on the petrophysical properties and under different production scenarios and generate different graphics to see how this phenomenon behaves. Besides a comparison with all the most analytical correlations used in the literature to identify gas and water conning was performed to see the differences among them and with this dynamic integrated approach. On the other hand, for the production side this coupled model was applied to an offshore facility to see these reservoir effects in the transport system and how they impact in the pipeline and riser due to this abrupt entrance of gas and water changing the flow conditions, flow patterns, pressure drop and creating some instabilities in the separators caused by severe slugging. The results of this analysis were very useful to understand the total production systems (reservoir-surface) behavior, predict the gas and water breakthrough, establish the critical rates to avoid these problems and see how the results differ in some cases with the common analytical correlations. Specific conditions in the pipeline and riser were established to quantify the slugging problems and evaluate different alternatives to eliminate the instabilities through proposing different scenarios such as gas injection in the riser, top side choking, etc. Application of this integrated approach has been very beneficial in recognizing the source of the problem, offer proper and feasible solutions in development and operational phases. In addition, validating and reducing uncertainty of related literature correlations and give to the production and reservoir engineers a quick and reliable way to know the critical rates that can support the decision-making process.
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