Particle image velocimetry measurements of stratified gas-liquid flow in horizontal and inclined pipes

Vestøl, Sondre; Kumara, W.A.S.; Melaaen, Morten C.

doi:10.2495/cmem-v6-n2-411-422

Cited by 2 publications

(2 citation statements)

References 14 publications

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“…The interfacial shear, pressure fluctuations, turbulent fluid motion, and other effects observed in gas‐liquid flows produce interfacial instabilities and wave structure formation. A number of the PIV studies for gas‐liquid flows have reported difficulty in defining the precise position of the interface and in taking measurements close to pipe walls due to reflection at the interface and wall respectively . Various techniques have been employed to improve PIV measurements at the interface such as camera orientation, optical filters, fluorescent seeding, and the use of complementary measurement instrumentations such as pulsed shadow technique (PST) and planar laser‐induced fluorescence (PLIF) among others .…”

Section: Piv Measurements Of Two‐phase Flow Characteristics Of Gas‐limentioning

confidence: 99%

Turbulence statistics and flow structure in fluid flow using particle image velocimetry technique: A review

Ayegba

Edomwonyi‐Otu

2020

Engineering Reports

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Particle image velocimetry (PIV) measurement technique provides an excellent opportunity for investigating instantaneous spatial structures which are not always possible with point measurements techniques like laser Doppler velocimetry. In this review, it was shown that PIV technique provides an effective means of visualizing important structures of Newtonian and drag‐reducing fluid flows. Such structures include large‐scale‐events that constitute an important portion of the Reynolds stress tensor; shear layers of drag‐reducing flows, which have been suggested to constitute the mechanism of drag reduction (DR); and near wall vortices/low speed streaks which constitute the mechanism of turbulence production. PIV investigations of turbulence statistics in Newtonian and drag‐reducing fluid flows were reviewed with the view of providing explanation to DR by additives. Results of turbulence statistics, for Newtonian fluid flow, showed that streamwise velocity fluctuations and turbulence intensity had peak values close to the wall, in a region of high mean velocity gradient, while radial fluctuating velocity and Reynolds stress tensor had peaks further from the wall and at approximately the same detachment from the wall. In single‐ and two‐phase flows in horizontal channels, the velocity profile of polymer solution, in the turbulent regime, show asymmetric behavior. This review highlighted important interfacial characteristics in gas‐liquid flows such as S‐shaped velocity profile as well as the turbulences statistics in each phase and across the interface region. Drag‐reducing agents (DRAs)‐imposed changes on turbulence statistics and flow structures were also examined. PIV studies of drag‐reducing flows showed that DRAs act to dampen wall‐normal‐, streamwise fluctuating velocity, and Reynolds stress tensor. The reduction in Reynolds stress tensor is higher than the reduction of both wall‐normal and streamwise velocity fluctuations and this discrepancy has been associated with the decorrelation of the component of fluctuating velocity. Furthermore, the addition of DRA produces a shift of the peak of wall‐normal velocity fluctuations further from the wall due to increased buffer layer thickness. DRAs do not only act to reduce drag but also to modify the flow structure. The major influence of DRAs on flow structures is seen in the reduced strength and population of vortices close to the wall, increased spacing between low‐speed streaks, reduced frequency of large‐scale events and reduced concentration of small eddies. Effect of DRAs on flow structures depends not only on the level of DR but also on the concentration and molecular weight. The effect of concentration is linked to the elastic properties of the DRA. The influence of DRA on oil‐water flows in similar to its effect on single phase water flow with regards to changes in near wall structures and turbulence statistics. A few research gaps and limitations of the PIV techniques were also highlighted.

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Section: Piv Measurements Of Two‐phase Flow Characteristics Of Gas‐limentioning

confidence: 99%

Turbulence statistics and flow structure in fluid flow using particle image velocimetry technique: A review

Ayegba

Edomwonyi‐Otu

2020

Engineering Reports

View full text Add to dashboard Cite

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“…The two-phase flow measurements indicated expected behaviour for low flow rates, and very interesting features related to the turbulence structure at higher flow rates that led to wavy interfaces. Inspired by ongoing approach, Vestøl et al [24] produced detailed velocity profile measurements over a range of operating conditions of two phase gas/liquid flow with low liquid fractions in horizontal and inclined pipes. The experiments were implemented in a 15 long stainless steel pipe with internal diameter of 56 at room temperature and atmospheric outlet pressure.…”

Section: Introductionmentioning

confidence: 99%

Numerical 3D simulation of developing turbulent stratified gas-liquid flow in curved pipes consisting of entrained particles through this type of flow

et al. 2018

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Since curved pipes are widely used in industrial equipment, predicting multiphase flows in these geometries is of great importance. In the present study, a computational model for predicting the velocity profile is developed and used to study the developing turbulent gas-liquid flows in curved pipes. In order to discretize and solve the three-dimensional steady-state momentum equations, the finite volume scheme on staggered grids besides central difference and QUICK scheme have been used. Moreover, the k-ε model is employed to reflect the nature of turbulence in the flow. In order to address the needs for sooner convergence and convenient mapping of the physical domain, the computations have been performed in a new toroidal coordinate system. Particle tracking has been done using Lagrangian approach in which two-way coupling regime is considered. In terms of validation, the numerical simulation results for the straight duct (infinite curvature), have been compared with the analytical solution and previous experimental results. Moreover, injection of particles through the flow indicates that, in each section of the bend, trade-off between centrifugal and pressure gradient forces plays a key role on particles motion. In last section, the effects of particle diameter and bend curvature on particle motion have been examined.

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Particle image velocimetry measurements of stratified gas-liquid flow in horizontal and inclined pipes

Cited by 2 publications

References 14 publications

Turbulence statistics and flow structure in fluid flow using particle image velocimetry technique: A review

Turbulence statistics and flow structure in fluid flow using particle image velocimetry technique: A review

Numerical 3D simulation of developing turbulent stratified gas-liquid flow in curved pipes consisting of entrained particles through this type of flow

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