油田套管失效分析中大规模储层压实与小规模套管稳定模型的有效集成方法

Kenta Yamada, K. Furui
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引用次数: 2

摘要

在世界各地的油气田中,已经报道了许多套管失效事件。这些套管损坏事件不仅可能发生在储层内,也可能发生在周围地层中。在钻井和完井时,工程师必须评估套管损坏的风险,特别是在高度压实的油藏中。然而,在套管破坏风险评估过程中遇到的挑战之一是,在进行套管稳定性分析时,必须适当地考虑到钻井和从储层开采油气所导致的现场应力变化和位移。本研究的目的是建立一种大规模储层压实和小规模套管稳定性分析的有效集成方法,以评估套管变形和破坏。本文所建立的数值模型是基于三维弹塑性有限元法的。储层压实和沉降采用考虑详细地质环境的大尺度有限元模型分析,套管稳定性采用小尺度有限元模型单独分析。通过对大尺度模型计算的位移进行插值,并对小尺度套管稳定性分析模型的边界赋值,将两种有限元模型整合在一起。文中还对所提出的积分方法进行了验证。我们的研究结果表明,本文提出的集成方法的计算效率比传统的模拟方法快5倍,传统的模拟方法需要大量的油藏、周围地层、水泥和套管的有限元。结果表明,该综合模型可以应用于高度非均质地层的斜井,并具有足够的精度。现场实例研究还表明,套管变形的风险在很大程度上取决于其倾角和相对于压实地层的位置。本研究开发的小型和大型耦合方法有助于工程师有效地评估油藏和周围地层中不同位置的套管变形和破坏,并制定安全高效的钻井和完井方案,以降低套管机械问题的风险。
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Efficient Integration Method of Large-Scale Reservoir Compaction and Small-Scale Casing Stability Models for Oilfield Casing Failure Analysis
Many casing failure incidents have been reported in oil and gas fields around the world. These casing failure events can occur not only within reservoirs but also in surrounding formations. Engineers must evaluate risks of casing failure when drilling and completing wells especially in highly compacting reservoirs. However, one of the challenges encountered during the evaluation of casing failure risks is that field-scale stress changes and displacements as a result of drilling wells and producing hydrocarbon from reservoirs must be properly taken into account for casing stability analysis. The objective of this study is to develop an efficient integration method for large-scale reservoir compaction and small-scale casing stability analyses for the evaluation of casing deformation and failure. The numerical model developed in this work is based on 3D elasto-plastic finite element method (FEM). Reservoir compaction and subsidence are analyzed using a large-scale FEM model considering details of geological settings while casing stability is analyzed separately by a small-scale FEM model. The two FEM models are integrated by interpolating displacements calculated by the large-scale model and assigning resultant displacements for boundaries of the small-scale casing stability analysis model. The validation of the proposed integration method is also presented in the paper. Our study results indicate that the integration method presented in this paper significantly improves computational efficiencies on an order of 5 times faster than the conventional simulation method that requires a large number of finite elements for reservoir, surrounding formations, cement, and casing. Also it is demonstrated that the integrated model can be applied to inclined wells completed in highly heterogeneous formations at sufficient accuracy. The field case study also indicates that the risk of casing deformation highly depends on its inclination and the position relative to the compacting formation. The small and large scale coupling method developed in this work helps engineers evaluate casing deformation and failure in various locations in reservoir and surrounding formations in an efficient manner and also develop safe and efficient drilling and completion programs to reduce risk of casing mechanical problems.
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