Experimental Investigation of the Effects of Fluid Viscosity on Electrical Submersible Pumps Performance

SPE Production & Operations Pub Date : 2022-08-01 DOI:10.2118/210603-pa

W. Monte Verde, E. Kindermann, J. L. Biazussi, V. Estevam, B. P. Foresti, A. Bannwart

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引用次数: 2

Abstract

Electrical submersible pumps (ESPs) are an important artificial lift method used in oil production. ESPs can provide high production flow rate, are flexible, and can be installed in highly deviated wells, subsea deepwater wells, or on the seabed. ESP performance is generally characterized by manufacturers using only water as fluid. However, oil properties are very different from water and significantly alter the pump’s performance. Operating ESPs with viscous fluids leads to degraded pump performance. Therefore, knowing the ESP’s performance when pumping viscous fluid is essential to properly design the production system. In this work, we present an experimental study of ESP performance operating with viscous flow. A total of six ESP models were tested, operating at four different rotational speeds and 11 viscosities, resulting in a comprehensive database of more than 5,800 operating conditions. This database contributes to the literature given the lack of available data. We also perform a phenomenological analysis on the influence of operational parameters, such as viscosity, rotational speed, specific speed, and rotational Reynolds number. The database and analyses performed are central for future models predicting the viscous performance of ESPs. The results from our investigation and tests showed that the increase in viscosity causes (1) a reduction in the head and (2) an increase in drive power, resulting in (3) a sharp decrease in efficiency. However, increasing rotational speed tends to mitigate this performance degradation. Efficiency and flow rate correction factors are virtually independent of the flow rate within the recommended operating region. This is not true for the head correction factor, which is not constant. The pump geometry seems to influence its performance as ESPs with higher specific speed are less impaired by viscous effects. The database obtained in the present work is available in the data repository of the University of Campinas, at the address presented by Monte Verde et al. (2022).

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流体粘度对电潜泵性能影响的实验研究

电潜泵(esp)是一种重要的人工举升方式。esp可以提供高生产流量，具有灵活性，可以安装在大斜度井、海底深井或海底。ESP性能的特点通常是制造商只使用水作为流体。然而，油的性质与水有很大的不同，这极大地改变了泵的性能。在粘性流体中使用esp会导致泵的性能下降。因此，了解ESP在泵送粘性流体时的性能对于合理设计生产系统至关重要。在本工作中，我们对ESP在粘性流体下的性能进行了实验研究。总共测试了6种ESP模型，在4种不同的转速和11种粘度下运行，形成了超过5800种运行工况的综合数据库。由于缺乏可用数据，该数据库有助于文献。我们还对粘度、转速、比转速和旋转雷诺数等操作参数的影响进行了现象学分析。所进行的数据库和分析对于预测esp粘性性能的未来模型至关重要。我们的调查和测试结果表明，粘度的增加导致(1)压头减小，(2)驱动功率增加，导致(3)效率急剧下降。然而，增加转速往往会减轻这种性能下降。效率和流量校正系数实际上与推荐操作区域内的流量无关。对于不是常数的水头校正系数来说，情况并非如此。泵的几何形状似乎会影响其性能，因为具有较高比速的esp受粘性效应的影响较小。在本工作中获得的数据库可在坎皮纳斯大学的数据存储库中获得，地址由Monte Verde等人提供(2022年)。

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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SPE Production & Operations

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