A Computational Model for Analysis of Fluid-Structure Interaction within Elastomeric Progressing Cavity Pumps

Paladino, Emilio E.; Almeida, Rairam F.C.; Assmann, Benno Waldemar; Lima, João Alberto Lins de; Medeiros, Philippe E.

doi:10.2118/165650-ms

Cited by 2 publications

(2 citation statements)

References 9 publications

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“…Thus, to accomplish such simulation, a fluid-structure interaction model is needed that is beyond the scope of this paper. An application of this model to an elastomeric-stator pump, for singlephase flow condition, is presented by Lima et al (2013).…”

Section: Computational Modelmentioning

confidence: 99%

“…This research group continued to develop experimental studies, so that works of Martin et al (1999), Suarez (2002), , Olivet et al (2002), and Gamboa et al (2002) presented an extensive experimental study in PCPs for single-and twophase flow conditions and obtained characteristic curves and transient-pressure profiles within cavities in metallic (rigid) stator pumps. Some of these studies Gamboa et al 2002) focused effects such as the rotor speed and liquid viscosity, and presented some important results such as longitudinal pressure distribution and pump power, which were used in this paper for model validation.…”

Section: Introductionmentioning

confidence: 99%

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A 3D Transient Model for the Multiphase Flow in a Progressing-Cavity Pump

2016

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This paper presents the development of a computational-fluiddynamics (CFD) model for the 3D transient two-phase flow within a progressing-cavity pump (PCP). The model implementation was only possible because of the meticulous mesh-generation and mesh-motion algorithm, previously published by the authors, which is briefly described herein. In this algorithm, a structured mesh was generated by defining all nodes' positions and connectivities, for each rotor position by means of FORTRAN subroutines, which were embodied into ANSYS CFX software. The model is capable of predicting accurately the volumetric efficiency and the viscous losses, and it provides detailed information of pressure and velocity fields and void distribution along the pump. Such information could be of fundamental importance for product development and/or optimization for field operation. In field applications, the common situation is that in which the oil comes into the pump accompanied with free gas, which characterizes a multiphase flow. Simplified models on the basis of the calculation of the backflow or "slippage," which is subtracted from the displaced flow rate, fail to characterize the PCP performance under multiphase conditions because the slip is variable along the pump. In this model, the governing equations were solved with an element-based finite-volume method in a moving mesh. The Eulerian-Eulerian approach, considering the homogeneous model, is used to model the flow of the gas/liquid mixture. The compressibility of the gas is taken into account, which is one of the main shortcomings in positive/constant displacement pumps. The effects of the different gas-volume fractions (GVFs) in pump volumetric efficiency, pressure distribution, power, slippage flow rate, and volumetric flow rate were analyzed, and some new insights are presented about the slippage in PCPs operating in multiphase conditions. The results show that the developed model is capable of reproducing pump dynamic behavior under multiphase-flow conditions performed early in experimental works.

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Section: Computational Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A 3D Transient Model for the Multiphase Flow in a Progressing-Cavity Pump

2016

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Analysis and Prediction of Fluid Flow Behavior in Progressing Cavity Pumps

Al-Safran

Aql

Nguyen

2017

Journal of Fluids Engineering

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A progressing cavity pump (PCP) is a positive displacement pump with an eccentric screw movement, which is used as an artificial lift method in oil wells. Downhole PCP systems provide an efficient lifting method for heavy oil wells producing under cold production, with or without sand. Newer PCP designs are also being used to produce wells operating under thermal recovery. The objective of this study is to develop a set of theoretical operational, fluid property, and pump geometry dimensionless groups that govern fluid flow behavior in a PCP. A further objective is to correlate these dimensionless groups to develop a simple model to predict flow rate (or pressure drop) along a PCP. Four PCP dimensionless groups, namely, Euler number, inverse Reynolds number, specific capacity number, and Knudsen number were derived from continuity, Navier–Stokes equations, and appropriate boundary conditions. For simplification, the specific capacity and Knudsen dimensionless groups were combined in a new dimensionless group named the PCP number. Using the developed dimensionless groups, nonlinear regression modeling was carried out using large PCP experimental database to develop dimensionless empirical models of both single- and two-phase flow in a PCP. The developed single-phase model was validated against an independent single-phase experimental database. The validation study results show that the developed model is capable of predicting pressure drop across a PCP for different pump speeds with 85% accuracy.

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A Computational Model for Analysis of Fluid-Structure Interaction within Elastomeric Progressing Cavity Pumps

Cited by 2 publications

References 9 publications

A 3D Transient Model for the Multiphase Flow in a Progressing-Cavity Pump

A 3D Transient Model for the Multiphase Flow in a Progressing-Cavity Pump

Analysis and Prediction of Fluid Flow Behavior in Progressing Cavity Pumps

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