Comparison between eulerian and vof models for two-phase flow assessment in vertical pipes

Guerrero, E.T.; Muñoz, Felipe; Ratkovich, Nicolás Ríos

doi:10.29047/01225383.66

Cited by 34 publications

(12 citation statements)

References 15 publications

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“…And the VOF multi-phase model which presents an adequate detail of the bubbles in the two phases, solves the interface by means of the continuity of the equation as a function of the volume fraction and predicts the flow pattern. (Gelves et al, 2013, Guerrero et al, 2017.…”

Section: Hydrodynamic Studymentioning

confidence: 99%

Entropy and Hurst analysis for the determination of two-phase flow time series complexity

Rodrígurez¹,

Vizguerra²,

Corona³

et al. 2023

RMIQ

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Section: Hydrodynamic Studymentioning

confidence: 99%

Entropy and Hurst analysis for the determination of two-phase flow time series complexity

Rodrígurez¹,

Vizguerra²,

Corona³

et al. 2023

RMIQ

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“…A two-phase Volume of Fluid (VOF) model was applied for nitrogen and user-defined galinstan in an isothermal system. This type of model was chosen based on previous studies and the capabilities to more accurately predict the two-phase flow patterns occurring in a vertical riser pipe [12]. The standard K-ε turbulence model was applied due to its ability to accurately represent a wide range of turbulent flows [13].…”

Section: Cfd Modelmentioning

confidence: 99%

Nitrogen-Galinstan Two Phase Pumping for MHD Power Generation Systems

Rosettani¹,

Geddis²,

Clements³

et al. 2020

World Congress on Momentum, Heat and Mass Transfer

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The continuous demand for energy has open many pathways to develop new sustainable power generation processes. Magnetohydrodynamics (MHD) power generation is an alternative process being investigated to recover energy from low temperature sources but is not limited to low temperatures. Liquid Metal MHD (LMMHD) power generation is the process of circulating liquid metal through an MHD generator using gas injection. The need to design a low energy two-phase gas-lift pump and evaluate its performance as well as the two-phase dynamics in this energy recovering process are crucial components to develop the system. In this study, a preliminary analysis utilizing ANSYS Fluent ® for pumping two-phase flow mixture of nitrogen and galinstan is performed. These numerical results along with the analytical model based on drift flux assumptions are used to understand the performance of the gas-lift two-phase flow pump in this system. Reasonable agreement between the numerical and analytical results were obtained. The CFD results were used to describe the void fraction of the two phases in the pipe riser and considered to be the first step to understand the performance of LMMHD power generation loop.

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“…Selecting CFD models is usually an act of balancing accuracy and efficiency. Using a single set of transport equations for all phases reduces the computational cost of the model significantly and increases its robustness and stability compared to the Eulerian Multiphase model, which models a separate transport equation for each phase (Guerrero et al, 2017). However, it may also reduce the accuracy of the model.…”

Section: Multiphase Modelmentioning

confidence: 99%

“…Considering the simplifications assumed by the VOF method, which are related to its computational efficiency, the 20% error for the liquid holdup and 12% for the pressure drop was considered acceptable. This was also based on the fact that in CFD studies, especially of multiphase flow or gas modeling, an error of up to 20% or even 30% is not unusual (Guerrero et al, 2017;Fatima and Chaudhry, 2017;Rivas et al, 2019).…”

Section: Experimental Comparisonmentioning

confidence: 99%

CFD study and experimental validation of low liquid-loading flow assurance in oil and gas transport: studying the effect of fluid properties and operating conditions on flow variables

Martínez

Pereyra

Ratkovich

2020

Heliyon

Self Cite

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Low liquid-loading flow frequently occurs during the transport of gas products in various industries, such as in the Oil & Gas, the Food, and the Pharmaceutical Industries. Even small amounts of liquid can have a significant effect on the flow conditions inside the pipeline, such as increased pressure loss, pipe wall stresses and corrosion, and liquid holdup along the pipeline. However, most studies that analyze this type of flow only use atmospheric pressures and horizontal 1-in or 2-in pipes, which do not accurately represent the range of operating conditions present in industrial applications. Therefore, this study focused on modeling low liquid-loading flow in mediumsized (6-10 in) pipes, using CFD simulations and experimental data from the University of Tulsa, and then applying it to real operating conditions from a Colombian gas pipeline. An acceptable difference was observed between experimental and CFD data, both for the liquid holdup (18%) and for the pressure drop (12%). Variables like pressure drop and wall shear stress increase with phase velocity, operating pressure, and pipe inclination. Liquid holdup increases with liquid velocity but decreases with all other factors. The relation of flow variables with phase velocities is of particular interest: Doubling the gas velocity decreased holdup 70% and increased pressure drop tenfold. On the other hand, the presence of the liquid phase seems to be more influential on process variables than its exact flowrate; the introduction of the liquid phase to a single-phase gas causes an increase in pressure loss by a factor of three, but doubling the liquid velocity only increases the pressure loss by a further 30%.

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Comparison between eulerian and vof models for two-phase flow assessment in vertical pipes

Cited by 34 publications

References 15 publications

Entropy and Hurst analysis for the determination of two-phase flow time series complexity

Entropy and Hurst analysis for the determination of two-phase flow time series complexity

Nitrogen-Galinstan Two Phase Pumping for MHD Power Generation Systems

CFD study and experimental validation of low liquid-loading flow assurance in oil and gas transport: studying the effect of fluid properties and operating conditions on flow variables

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