Abstract
The working capability of multi-stage pumps, such as electrical submersible pumps (ESPs) handling multiphase flow, has always been a big challenge for petroleum industries. The major problem is associated with the agglomeration of gas bubbles inside ESP-impellers, causing pump performance degradation ranging from mild to severe deterioration (surging/gas pockets). Previous literature showed that the two-phase performance of ESPs is greatly affected by gas involvement, rotational speed, bubble size, and fluid viscosity. Thus, it is necessary to understand which parameter is actually accountable for performance degradation and different flow patterns in ESP, and how it can be controlled. The present study is mainly focused on (1) the main parameters that impede two-phase performance of different ESPs; (2) comparison of existing empirical models (established for two-phase performance prediction and surging initiation) with our single-stage centrifugal pump results to determine their validity and working-range; (3) gas-handling techniques applied to enhance the multiphase performance of ESPs. Firstly, it aims at understanding the internal flow mechanism in different ESP designs, followed by test studies based on empirical models, visualization techniques, bubble-size measurements, and viscosity analysis. The CFD-based (computational fluid dynamics) numerical analysis concerning multiphase flow is described as well. Furthermore, gas-handling design methods are discussed that are helpful in developing the petroleum industry by enhancing the multiphase performance of ESPs.
Highlights
Introduction iationsThe submersible pump, since its inception in 1910 by Russian engineer, ArmaisArutunoff [1,2], has had a great impact in oil and gas industries
This review provides a better understanding of the complex flow behavior inside the rotating impeller of electrical submersible pumps (ESPs), and reports some design methods that have increased the gas–liquid two-phase flow-handling ability of ESP
The recent experimental analysis on ESPs handling multiphase flow has helped in identifying some major parameters and difficulties that are accountable for pump performance degradation
Summary
Arutunoff [1,2], has had a great impact in oil and gas industries. These downhole pumps are used to convert kinetic energy into hydraulic pressure head and exhibit high efficiency. The electrical submersible pump (ESP) systems are the second most extensively applied for artificial lift and are used in more than 90 percent of the oil production wells and high-volume production [3–5]. ESP performance is affected by many factors including gas involvement, rotational speed, bubble size, fluid density and viscosity [6,7]. When handling two-phase flow—gas and liquid—the involvement of gas and bubble size distribution can cause pump performance degradation, ranging from mild deterioration to severe deterioration (surging and gas-pocket formation), and may result in complete flow blocking (gas locking) [8,9]. The surging, which is related to gas-pocket formation [10,11], Licensee MDPI, Basel, Switzerland
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