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Abstract

Assembled in series with multistage, Electrical Submersible Pumps (ESP) are widely used in offshore petroleum production due to the high production rate and efficiency. The hydraulic performance of ESPs is subjected to the fluid viscosity. High oil viscosity leads to the degradation of ESP boosting pressure compared to the catalog curves under water flow. In this paper, the influence of fluid viscosity on the performance of a 14-stage radial-type ESP under varying operational conditions, e.g. rotational speeds 1800–3500 r/min, viscosities 25–520 cP, was investigated. Numerical simulations were conducted on the same ESP model using a commercial Computational Fluid Dynamics (CFD) software. The simulated average pump head is comparable to the corresponding experimental data under different viscosities and rotational speeds with less than ±20% prediction error. A mechanistic model accounting for the viscosity effect on ESP boosting pressure is proposed based on the Euler head in a centrifugal pump. A conceptual best-match flowrate Q_BM is introduced, at which the impeller outlet flow direction matches the designed flow direction. The recirculation losses caused by the mismatch of velocity triangles and other head losses resulted from the flow direction change, friction loss and leakage flow etc., are included in the model. The comparison of model predicted pump head versus experimental measurements under viscous fluid flow conditions demonstrates good agreement. The overall prediction error is less than ±10%.

Keywords

Electrical submersible pump head losses viscosity effect mechanistic model pump performance

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References

Zhu

Zhang

HQ.

A review of experiments and modeling of gas-liquid flow in electrical submersible pumps. Energies 2018; 11: 180.

Augusto

Bulgarelli

Biazussi

, et al. Experimental investigation on the performance of electrical submersible pump (ESP) operating with unstable water/oil emulsions. J Pet Sci Eng 2021; 197: 107900.

Daugherty

RL.

A further investigation of the performance of centrifugal pumps when pumping oils. Goulds Pumps, Inc., 1926, p.130.

Ippen

AT.

The influence of viscosity on centrifugal pump performance. Fritz Engineering laboratory reports. Trans ASME 1946. 68: 823–848.

William

Jorge

Antonio

, et al. Gas and viscous effects on the ESPs performance. In: SPE artificial lift conference, Cartagena, Colombia, USA, 2013.

Hydraulic

Effects of liquid viscosity on rotor dynamic pump performance. ANSI-HI 9.6.7, 2010.

Banjar

Gamboa

Zhang

HQ.

Experimental study of liquid viscosity effect on two-phase stage performance of electrical submersible pumps. In: SPE annual technical conference and exhibition, New Orleans, Louisiana, USA, 2013.

Biazussi

Estrada

Verde

WM.

Experimental study and modeling of heating effect in electrical submersible pump operating with ultra-heavy oil. In: Proceedings of the ASME international conference on ocean, offshore and arctic engineering, Madrid, Spain, 2018.

WG.

Effects of flow rate and viscosity on slip factor of centrifugal pump handling viscous oils. Int J Rotat Mach 2013; 2013: 1–12.

10.

WG.

Mechanism for onset of sudden-rising head effect in centrifugal pump when handling viscous oils. J Fluid Eng 2014; 136: 074501.

11.

Stel

Sirino

Ponce

, et al. Numerical investigation of the flow in a multistage electric submersible pump. J Pet Sci Eng 2015; 136: 41–54.

12.

Zhu

Banjar

Xia

, et al. CFD simulation and experimental study of oil viscosity effect on multi-stage electrical submersible pump (ESP) performance. J Pet Sci Eng 2016; 146: 735–745.

13.

Ofuchi

Stel

Sirino

, et al. Numerical investigation of the effect of viscosity in a multistage electric submersible pump. Eng Appl Comput Fluid Mech 2017; 11: 258–272.

14.

Hydraulic

Tentative standards of hydraulic institute: charts for the determination of pump performance when handling viscous liquids. New York, NY: The Institute, 1948.

15.

Hydraulic I. Determination of pump performance when handling viscous liquid. In: Hydraulic institute standards. 20th ed. Parsippany, NJ: Hydraulic Institute, 1969.

16.

Turzo

Takacs

Zsuga

Equations correct centrifugal pump curves for viscosity. Oil Gas J 2000; 98: 57–67.

17.

Gülich

JF.

Effect of Reynolds number and surface roughness on the efficiency of centrifugal pump. J Fluids Eng 2003; 125: 670–679.

18.

Solano

EA.

Viscous effects on the performance of electro submersible pumps (ESP’s). MS Thesis, The University of Tulsa, Tulsa, OK, 2009.

19.

Tatiane

José

André

DB.

Analytical study of pressure losses and fluid viscosity effects on pump performance during monophase flow inside an ESP stage. J Pet Sci Eng 2015; 127: 245–258.

20.

Morrison

Yin

Agarwal

Development of modified affinity law for centrifugal pump to predict the effect of viscosity. J Energy Resour Technol 2018; 140(9): 092005.

21.

Mohammadzaheri

AlQallaf

Ghodsi

, et al. Development of a fuzzy model to estimate the head of gaseous petroleum fluids driven by electrical submersible pumps. Fuzzy Inf Eng 2018; 10: 99–106.

22.

Mohammadzaheri

Tafreshi

Khan

, et al. Modelling of petroleum multiphase flow in electrical submersible pumps with shallow artificial neural networks. Ships Offshore Struct 2020; 15: 174–183.

23.

El-Abd

Wahba

Adam

IG.

Viscous flow simulations through multi-lobe progressive cavity pumps. Pet Sci 2020; 17: 768–780.

24.

Jafari

Hasani

Hosseini

, et al. Application of CFD technique to simulate enhanced oil recovery processes: current status and future opportunities. Pet Sci 2020; 17: 434–456.

25.

ANSYS Inc. ANSYS Academic Research, Release 17.2, Help System, CFX Documentation. 2016.

26.

Stepanoff

AJ.

Centrifugal and axial flow pumps. 3rd ed. New York, NY: Wiley, 1964.

27.

Takács

Electrical submersible pumps manual: design, operations, and maintenance. Burlington, VT: Gulf Professional Publishing, 2009.

28.

Zhu

Cao

GQ.

A new mechanistic model to predict boosting pressure of electrical submersible pumps ESPs under high-viscosity fluid flow with validations by experimental data. In: SPE gulf coast section electric submersible pumps symposium, Woodlands, Texas, USA. 2019.

29.

Zhang

Experiments, CFD simulation and modeling of ESP performance under viscous fluid flow conditions. Master thesis, The University of Tulsa, Oklahoma, USA, 2017.

30.

Tuzson

Centrifugal pump design. New York, NY: Wiley, 2000.

31.

White

FM.

Fluid mechanics. 7th ed. New York, NY: McGraw-Hill, 2011.

32.

Churchill

SW.

Friction-factor equation spans all fluid-flow regimes. Chem Eng J 1977; 84: 91–92.

33.

Wiesner

FJ.

A review of slip factors for centrifugal impellers. J. Eng Power 1967; 89: 558–572.

34.

Sun

Prado

MG.

Single-phase model for electric submersible pump (ESP) head performance. SPE J 2006; 11: 80–88.

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Experiments and mechanistic modeling of viscosity effect on a multistage ESP performance under viscous fluid flow

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