Field Trial Results for New Sand Control Technology for Water Injectors

Day 4 Thu, November 15, 2018 Pub Date : 2018-11-12 DOI:10.2118/192840-MS

S. Fipke, J. E. Charles, Annabel Green

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引用次数: 1

Abstract

In 2014, an R&D project was intitiated to develop an innovative technological solution to improve the performance and reliability of Deepwater Gulf of Mexico assets. The objective was to increase the life expectancy of Miocene and Lower Tertiary water injection (WI) wells, several of which had suffered a severe loss of injectivity within only a few years of completion. Before scoping out the project, an internal study was conducted to compile and analyse the available data. The root problem was identified as an accumulation of formation solids inside the lower completion; principally fine matrix sand that had been pulled in from the reservoir. These formation solids are normally stationary during steady injection, but can be mobilized during shut-ins (maintenance, pump problems, environmental conditions, etc.) due to powerful transient flow effects such as back-flow, cross-flow and even water-hammer. Eventually, enough solid fill can accumulate inside the lower completion as to diminish the injection rates. At this point the operator must consider some very expensive options such as to sidetrack or re-drill a new injector well. The obvious solution to this problem was to find a way to prevent the fine material from getting inside the completion. The challenge was to do so while sustaining high injection rates, with no loss of injection pressure or requirement for additional horsepower. Therefore, the goal of the project was to find a practical, efficient method of stopping the formation material from entering the lower completion during a shut-in cycle. To achieve this, a new flow control device (FCD) and completion system was developed with intrinsic non-return valves (NRV) that are designed to prevent any back-flow or cross-flow during the shut-ins. Also, depending on well conditions, the system will minimize the damaging effects of water-hammer: rapid, high-amplitude pressure cycles that can occur during a sudden stoppage of flow.

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注水井防砂新技术的现场试验结果

2014年，公司启动了一个研发项目，旨在开发一种创新的技术解决方案，以提高墨西哥湾深水资产的性能和可靠性。目的是提高中新世和下第三纪注水井的预期寿命，其中几口井在完井后的几年内就遭受了严重的注入能力损失。在确定项目范围之前，进行了一项内部研究，以汇编和分析现有数据。问题的根源在于下部完井内地层固体的堆积;主要是从储层中取出的细基质砂。在稳定注入过程中，这些地层固体通常是静止的，但在关井(维修、泵问题、环境条件等)期间，由于强大的瞬态流动效应(如回流、交叉流动甚至水锤)，这些固体可能会被调动起来。最终，下部完井段内会积聚足够的固体充填物，从而降低注入速度。此时，作业者必须考虑一些非常昂贵的选择，如侧钻或重新钻一口新的注入井。解决这个问题的明显方法是找到一种方法来防止细小的材料进入完井。挑战在于，在保持高注入速度的同时，不损失注入压力，也不需要额外的马力。因此，该项目的目标是找到一种实用、有效的方法，在关井周期内阻止地层材料进入下部完井段。为了实现这一目标，开发了一种新的流量控制装置(FCD)和完井系统，其内置止回阀(NRV)可以防止关井期间发生倒流或过流。此外，根据井况，该系统将最大限度地减少水锤的破坏性影响:在突然停止流动时可能发生的快速、高振幅压力循环。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Day 4 Thu, November 15, 2018

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