Experimental Study on the Interfacial Evolution of Taylor Bubble at Inception of an Annulus

Rohilla, Lokesh; Das, Arup Kumar

doi:10.1021/acs.iecr.8b05964

Cited by 9 publications

(7 citation statements)

References 40 publications

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“…6 In recent years, a number of investigations have sought to provide insight into these bubbles in tubular pipes, 5,[7][8][9][10] but the understanding of their behavior in annular conduits is still limited. 11,12 The importance of this piping configuration has increased, for example, with the unconventional extraction techniques used to maintain supply of natural gas among the depletion of conventional reservoirs. 13 Determining the pressure gradient through conduits in the presence of multiphase flow is often addressed using empirical and/or mechanistic models.…”

Section: Introductionmentioning

confidence: 99%

Development of closure relations for the motion of Taylor bubbles in vertical and inclined annular pipes using high-fidelity numerical modeling

Mitchell

Leonardi

2020

Physics of Fluids

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This study analyses the flow of Taylor bubbles through vertical and inclined annular pipes using high-fidelity numerical modeling. A recently developed phase-field lattice Boltzmann method is employed for the investigation. This approach resolves the two-phase flow behavior by coupling the conservative Allen-Cahn equation to the Navier-Stokes hydrodynamics. This paper makes contributions in three fundamental areas relating to the flow of Taylor bubbles. First, the model is used to determine the relationship between the dimensionless parameters (Eötvös and Morton numbers) and the bubble rise velocity (Froude number). There currently exists no surrogate model for the rise of a Taylor bubble in an annular pipe that accounts for fluid properties. Instead, relations generally include the diameter of the outer and inner pipes only. This study covered Eötvös numbers between 10 and 700 and Morton numbers between 10 −6 and 10 0 . As such, the proposed correlation is applicable to concentric annular pipes within this range of parameters. An assessment of the correlation to parameters outside of this range was made; however, this was not the primary scope for the investigation. Following this, the effect of pipe inclination was introduced with the impact on rise velocity measured. A correlation between the inclination angle and the rise velocity was proposed and its performance quantified against the limited experimental data available. Finally, the high-fidelity numerical results were analyzed to provide key insights into the physical mechanisms associated with annular Taylor bubbles and the shape they form. To extend this work, future studies on the effect of pipe eccentricity, diameter ratios, and pipe fittings (e.g., elbows and risers) on the flow of Taylor bubbles will be conducted.

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Section: Introductionmentioning

confidence: 99%

Development of closure relations for the motion of Taylor bubbles in vertical and inclined annular pipes using high-fidelity numerical modeling

Mitchell

Leonardi

2020

Physics of Fluids

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“…In comparison to the body of literature available on Taylor bubbles in tubular conduits, research into the dynamics associated with flow in an annulus is limited [226,227]. The primary variation between the two flow confinements comes from the shape of the bubble nose that develops and the breakdown of symmetry observed in the annular configuration.…”

Section: Annular Taylor Bubblesmentioning

confidence: 99%

“…Due to the potential flow techniques employed in the early stages of Taylor bubble analysis, understanding the shape and governing forces in these different bubble regions became critical to the analysis. A limited number of studies look to investigate this problem in detail, with recent investigations by the likes of Rohilla and Das [227], finding novel conclusions about the nature of the annular Taylor bubble shape. From the previous chapter, it is clear that high resolution data is obtainable with the proposed PFLBM, and as such the aim of this chapter is to demonstrate the capability of the model and present a methodology for which the behaviour of Taylor bubbles can be further understood.…”

Section: Annular Taylor Bubblesmentioning

confidence: 99%

“…They were able to determine correction terms for small, D 2 ≤ 0.0254 m, and large, D 2 ≥ 0.247 m, pipe configurations, with which accurate predictions were obtained for their own and existing experimental data in the literature. From this study, the rise velocity of a Taylor bubble in pipe sizing applicable to natural gas wells can be predicted as, = 0.322 × 0.765 g(D 1 + D 2 ) , D 2 ≤ 0.0254 m u T B = 0.323 g(D 1 + D 2 ) , 0.0254 m < D 2 < 0.247 m.This correlation was further validated by Agarwal et al[228], where it was used to make conclusions about the practicality of extending the analysis from a circular annulus to a square shaped conduit.Rohilla and Das[227] more recently made use of it when analysing the effects of eccentricity as well as investigating the transition from a tubular to annular Taylor bubble as it passed over a cylindrical insert. These few findings represent the main body of research existing for annular Taylor bubbles, "despite being a widely observed phenomenon"[227].…”

mentioning

confidence: 99%

“…The methodology applied for these three simulations provides a means with which one can analyse Taylor bubble dynamics in vertical annular pipes. This could replace the use of physical experiments in correlating dimensionless flow parameters with the bubble rise behaviour, and as such gives a potential method for developing a unified rise velocity correlation.7.3 Effect of pipe inclinationWith the limited literature available on the flow of Taylor bubbles in annular piping[226,227], it is not surprising that their flow in inclined annuli is also remiss. The general problem of two-phase flow in a deviated annulus has seen more focused research interest in the past than the particulars of the slug flow regime.…”

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confidence: 99%

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Development of a multiphase lattice Boltzmann model for high-density and viscosity ratio flows in unconventional gas wells

Mitchell¹

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The confined flow of multiphase fluids is relevant in a range of applications in both science and engineering. For example, the two-phase flow of gas and liquid can commonly be observed in boilers used for power production, nuclear reactors (particularly in a loss-of-coolant accident) as well as in the transportation of hydrocarbons in the oil and gas industry. The optimal design and operation of these systems relies on an understanding of how the phases interact and the behaviour emergent from these interactions. This thesis studies multiphase flows in the field of natural gas extraction from unconventional reservoirs, with a focus on coal seam gas (CSG). In this context, the bottom hole pressure (BHP) in a natural gas well is an important parameter in the effective design of well completions and artificial lifting systems. Poor estimation of this can lead to liquid loading in the wellbore and reduced efficiency of the extraction process. The complex interaction of production gas and the associated water can increase the uncertainty in pressure gradients and ultimately impact the BHP estimation. A significant body of research has explored pressure gradients in the co-current multiphase flows found in conventional gas extraction, but these are not expected to hold for the counter-current regimes present in CSG production. Therefore, this research aimed to develop a fully resolved-numerical model for the simulation of simultaneous gas and liquid transport in scenarios applicable to CSG extraction. When two-phases flow in a confined environment such as a pipe or conduit, the topology of the interface is described by commonly observed flow regimes. When the pipe is in a vertical configuration, the typical regimes include bubble, slug, churn and annular flow. The models that describe the liquidgas interactions are typically dependent on the flow regime and can significantly impact the accuracy of pressure predictions. As a result, knowledge of the flow regime is required a priori to predicting the pressure gradient. Once this has been determined, the uncertainty associated with the phase interaction models can still deteriorate the practical use of predictive tools. The rise velocity of elongated bubbles in the slug flow regime has recently been identified in the literature as impacting greatly on the estimation of liquid hold up and pressure gradients in a piping system. Understanding the behaviour of these bubbles, termed Taylor bubbles, allows operators to reduce pressure oscillations in the wellbore and more accurately forecast production over the life of the well. This work seeks to capture the behaviour of these bubbles in flow configurations applicable to CSG extraction. This involves modelling annular pipe systems at a range of inclinations as well as with fluids propagating in co-and counter-current directions. This thesis presents the development, verification and validation of a phase-field lattice Boltzmann method (PFLBM) that allows for the simulation of dynamic liquid-gas flows with density ratios on th...

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Numerical analysis of velocity field and energy transformation, and prediction model for Taylor bubbles in annular slug flow of static power law fluid

Lou

Wang

Guo³

et al. 2022

Chemical Engineering Science

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Experimental Study on the Interfacial Evolution of Taylor Bubble at Inception of an Annulus

Cited by 9 publications

References 40 publications

Development of closure relations for the motion of Taylor bubbles in vertical and inclined annular pipes using high-fidelity numerical modeling

Development of closure relations for the motion of Taylor bubbles in vertical and inclined annular pipes using high-fidelity numerical modeling

Development of a multiphase lattice Boltzmann model for high-density and viscosity ratio flows in unconventional gas wells

Numerical analysis of velocity field and energy transformation, and prediction model for Taylor bubbles in annular slug flow of static power law fluid

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