Development and Testing of a Wireline-Deployed Positive-Displacement Pump for Late-Life Wells

IF 16.4 1区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Accounts of Chemical Research Pub Date : 2020-10-01 DOI:10.2118/201163-pa

Michael C. Romer, M. Spiecker, T. Hall, R. Dieudonne, François Porel, Laurent Jerzak, D OrtizSantos, King George, Kartikkumar Jaysingbhai Gohil, W. Tapie, Michael Peters, Brandon Alexander Curkan

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引用次数: 1

Abstract

What do you do after plunger lifting? What if lift gas is not readily available or your liquid level is around a bend? What can you do with a well that has low reservoir pressure, liquid-loading trouble, and fragile economics? Do you give up on the remaining reserves and advance to plugging and abandonment? These questions were considered, and the answers were found to be unsatisfactory. This paper will describe the development and testing of a novel wireline-deployed positive-displacement pump (WLPDP) that was invented to address these challenges. Artificial-lift (AL) pumps have historically been developed with high-producing oil wells in mind. Pumps for late-life wells have mostly been repurposed from these applications and optimized for reduced liquids production. The WLPDP development began with the constraints of late-life wells with the goal of addressing reserves that conventional AL methods would struggle to produce profitably. Internal and industry-wide data were first reviewed to determine what WLPDP specifications would address the majority of late-life wells. The primary target was gas wells, although “stripper” oil wells were also considered. The resulting goal was a pump that could deliver 30 BFPD from 10,000-ft true vertical depth (TVD). The pumping system must be cost-effective to be a viable solution, which led to several design boundaries. Pumps fail and replacement costs can drive economics, so the system must be deployable/retrievable through tubing. The majority of new onshore wells have tortuous geometries, so the system must be able to function at the desired depth despite them—without damaging associated downhole components. The system should use as many off-the-shelf components and known technologies as possible to reduce development costs and encourage integration. Finally, the pump should be able to handle a variety of wellbore liquids, produced gases, and limited solids. The WLPDP was designed to meet the established specifications and boundary conditions. The 2.25-in.-outer-diameter (OD) pump is deployed through tubing. and powered with a standard wireline (WL) logging cable. The cable powers a direct-current (DC) motor that drives an axial piston pump. The piston pump circulates a dielectric oil between two bladders by means of a switching valve. When each bladder expands, it pressurizes inlet-wellbore liquids, pushing them out of the well. Produced gas flows in the annulus between the tubing and production casing. The intake/discharge check valves and bladders are the only internal pump components that contact the wellbore fluids. The WLPDP system was able to meet the design-volume/pressure specifications in all orientations, as confirmed through laboratory and integration testing. Targeted studies were conducted to verify/improve check-valve reliability, gas handling, elastomer suitability, and cable-corrosion resistance. The results of these and related studies will be discussed in the paper.

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一种适用于晚期油井的钢丝绳式正排量泵的开发与测试

柱塞提升后你会做什么？如果举升气不可用，或者您的液位在弯道附近，该怎么办？对于一口储层压力低、装液困难且经济性脆弱的井，你能做些什么？你是否放弃了剩余的储量，转而进行封堵和废弃？对这些问题进行了审议，结果发现答案并不令人满意。本文将描述一种新型电缆部署正排量泵（WLPDP）的开发和测试，该泵是为了应对这些挑战而发明的。人工举升（AL）泵在历史上一直是在考虑高产油井的情况下开发的。用于晚期油井的泵大多已从这些应用中重新调整用途，并针对减少液体产量进行了优化。WLPDP的开发始于晚期油井的限制，目的是解决传统AL方法难以盈利的储量问题。首先审查了内部和整个行业的数据，以确定WLPDP规范将适用于大多数晚期油井。主要目标是气井，尽管也考虑了“汽提塔”油井。由此产生的目标是一个可以从10000英尺的真实垂直深度（TVD）输送30 BFPD的泵。泵送系统必须具有成本效益，才能成为可行的解决方案，这导致了几个设计边界。泵故障和更换成本可能会带来经济效益，因此系统必须能够通过管道进行部署/回收。大多数新的陆上油井都有曲折的几何形状，因此系统必须能够在不损坏相关井下组件的情况下，在所需深度下发挥作用。该系统应使用尽可能多的现成组件和已知技术，以降低开发成本并鼓励集成。最后，该泵应能够处理各种井筒液体、产生的气体和有限的固体。WLPDP的设计符合既定规范和边界条件。2.25英寸外径（OD）泵通过卡套管展开。并且由标准有线（WL）测井电缆供电。电缆为驱动轴向活塞泵的直流电机供电。活塞泵通过开关阀在两个内胆之间循环介质油。当每个囊状物膨胀时，它会对入口井筒液体加压，将它们推出井外。采出的气体在油管和生产套管之间的环空中流动。进气/排气止回阀和气囊是唯一接触井筒流体的内部泵部件。WLPDP系统能够在所有方向上满足设计体积/压力规范，这通过实验室和集成测试得到了证实。进行了有针对性的研究，以验证/提高止回阀的可靠性、气体处理、弹性体的适用性和电缆的耐腐蚀性。本文将讨论这些研究和相关研究的结果。

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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来源期刊

Accounts of Chemical Research 化学-化学综合

CiteScore

31.40

自引率

1.10%

发文量

312

审稿时长

2 months

期刊介绍： Accounts of Chemical Research presents short, concise and critical articles offering easy-to-read overviews of basic research and applications in all areas of chemistry and biochemistry. These short reviews focus on research from the author’s own laboratory and are designed to teach the reader about a research project. In addition, Accounts of Chemical Research publishes commentaries that give an informed opinion on a current research problem. Special Issues online are devoted to a single topic of unusual activity and significance. Accounts of Chemical Research replaces the traditional article abstract with an article "Conspectus." These entries synopsize the research affording the reader a closer look at the content and significance of an article. Through this provision of a more detailed description of the article contents, the Conspectus enhances the article's discoverability by search engines and the exposure for the research.