Analysis of Oil/Water-Flow Tests in Horizontal, Hilly Terrain, and Vertical Pipes

Abduvayt, Polat; Manabe, Ryo; Watanabe, Tomoko; Arihara, Norio

doi:10.2118/90096-pa

Cited by 22 publications

(32 citation statements)

References 4 publications

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“…Cox (1985) and Alkaya (2000) observed that the transition from separated to dispersed flow occurs at lower velocities in downwardly inclined flows than in horizontal flow. In contrast to the current work stratified wavy flow pattern has been observed in downwardly inclined flows by other investigators (Cox, 1985;Alkaya, 2000;Oddie et al, 2003;Abduvayt et al, 2004;Rodriguez et al, 2006). This could be due to the different ranges of velocities, fluid properties and pipe geometries used in their experiments.…”

Section: Flow Pattern Mapscontrasting

confidence: 95%

“…Alkaya (2000) reported that downward inclination enhance the dispersed water-in-oil flow pattern slightly so that it appears at lower mixture velocities at -5º. Stratified wavy flow pattern has been observed by Abduvayt et al (2004) and Rodriguez et al (2006). For two-phase oil-water pipe flow the pressure drop behavior with respect to oil-water ratio has been presented in a number of publications starting with the work of Charles et al (1961).…”

Section: Introductionmentioning

confidence: 99%

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Pressure drop, flow pattern and local water volume fraction measurements of oil–water flow in pipes

Kumara¹,

Halvorsen²,

Melaaen³

2009

Meas. Sci. Technol.

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Abstract. Oil-water flow in horizontal and slightly inclined pipes was investigated. The experimental activities were performed using the multiphase flow loop at Telemark University College, Porsgrunn, Norway. The experiments were conducted in a 15 m long, 56 mm diameter, inclinable steel pipe using Exxsol D60 oil (density of 790 kg/m 3 and viscosity of 1.64 mPa s) and water (density of 996 kg/m 3 and viscosity of 1.00 mPa s) as test fluids. The test pipe inclination was changed in the range from 5° upward to 5° downward. Mixture velocity and inlet water cut varies up to 1.50 m/s and 0.975, respectively. The time averaged cross sectional distributions of oil and water were measured with a single-beam gamma densitometer. The pressure drop along the test section of the pipe was also measured. The characterization of flow patterns and identification of their boundaries are achieved via visual observations and by analysis of local water volume fraction measurements. The observed flow patterns were presented in terms of flow pattern maps for different pipe inclinations. In inclined flows dispersions appear at lower mixture velocities compared to the horizontal flows. Smoothly stratified flows observed in the horizontal pipe disappeared in upwardly inclined pipes and new flow patterns, plug flow and stratified wavy flow were observed. The water-inoil dispersed flow regime slightly shrinks as the pipe inclination increases. In inclined flows the dispersed oil-in-water flow regime extended to lower mixture velocities and lower inlet water cuts. The present experimental data were compared with results of a flow pattern dependent prediction model, which uses the area averaged steady state two-fluid model for stratified flow and the homogeneous model for dispersed flow. The two-fluid model was able to predict the pressure drop and water hold-up for stratified flow. The homogeneous model was not able to predict the pressure profile of dispersed oil-water flow at higher water cuts. The two-fluid model and homogeneous model over-predicts the pressure drop for dual continuous flow.

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Section: Flow Pattern Mapscontrasting

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Pressure drop, flow pattern and local water volume fraction measurements of oil–water flow in pipes

Kumara¹,

Halvorsen²,

Melaaen³

2009

Meas. Sci. Technol.

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“…Previous studies indicate that at low upward inclination generally results in higher water hold-up than in horizontal flow giving higher slip ratios [5][6][7]. The relevant systems are described by Scott [5] at +15º and +30º, Lum et al [6] at +5º and Abduvayt et al [7] at +0.5º and +3º. The reported S values are in general above one, for upwardly inclined oilwater flows and show a good agreement with present observations.…”

Section: Water Hold-up and Slip Ratio Measurementssupporting

confidence: 89%

“…At low inlet water fraction (λ w =0.25), the oil, as the less dense phase, travels at a considerably higher velocity than the water, so that S is always above one for upwardly inclined flows. Previous studies indicate that at low upward inclination generally results in higher water hold-up than in horizontal flow giving higher slip ratios [5][6][7]. The relevant systems are described by Scott [5] at +15º and +30º, Lum et al [6] at +5º and Abduvayt et al [7] at +0.5º and +3º.…”

Section: Water Hold-up and Slip Ratio Measurementsmentioning

confidence: 99%

Velocity and turbulence measurements of oil-water flow in horizontal and slightly inclined pipes using PIV

Kumara

Halvorsen

Melaaen

2009

Computational Methods in Multiphase Flow V

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Oil-water flows in horizontal and slightly inclined pipes are investigated using Particle Image Velocimetry (PIV). PIV offers a powerful non-invasive tool to study such flow fields. The experiments are conducted in a 15 m long, 56 mm diameter, inclinable steel pipe using Exxsol D60 oil (viscosity 1.64 mPa s, density 790 kg/m 3 ) and water (viscosity 1.0 mPa s, density 996 kg/m 3 ) as test fluids. The test pipe inclination is changed in the range from 5° upward to 5° downward. The experiments are performed at mixture velocity 0.25 m/s and inlet water volume fraction 0.25. The instantaneous local velocities are measured using PIV, and based on the instantaneous local velocities mean velocities and turbulence profiles (U-rms, V-rms and Reynolds stresses) are calculated. The time averaged cross sectional distributions of oil and water phases are measured with a traversable gamma densitometer. The flow regimes are determined based on visual observations. The measured flow regimes, water hold-up, slip ratio and velocity and turbulence profiles show a strong dependency with pipe inclination.

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“…Effects of the mixture flow velocity on the slip velocity ratio and water holdup at a constant input water fraction (b W ¼ 0.5) in the small inclined flows from À58 to 58 (data from Kumar et al [6] ). Abduvayt et al [4] 8.1 14.0 20.5 116 Atmaca et al [5] 3.8 11.6 15.8 83 Flores et al [1] À8.0 8.3 10.0 89 Kumara et al [6] 1.6 15.5 31.5 22 Lum et al [7,8] À0.3 10.3 22.0 121 Mukherjee et al [2] À2.6 8.0 15.1 228 Oddie et al [23] À1.6 6.3 7.1 8 Rodriguez and Oliemans [9] 14.1 19.6 24.1 19 Rodriguez and Baldani [24] 36.2 38.7 25.1 17 Vigneaux et al [3] À11.0 11.1 6. 5 25 can give a reasonable performance with 98 % of the data having an average absolute error less than 20 %.…”

Section: Inclined Flowmentioning

confidence: 99%

Characteristics of water holdup for oil and water mixture flows in horizontal, vertical, and inclined pipes

Liu

Zhang

et al. 2016

Can J Chem Eng

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In this work, the water holdup and slippage for oil and water mixture flows in horizontal, vertical, and inclined pipes have been investigated. A large group of experimental data was collected from 21 different sources covering the whole range of inclination angles from À908 to 908 to reveal the holdup characteristics and develop the drift velocity model. The results show that in horizontal flows the water holdup is dependent to the flow pattern, and yet in vertical flows the water holdup is similar to the input one and the flow direction shows a few influences on the holdup. In inclined flows, the Froude numbers are relatively independent of inclination angles when the angles are greater than 308. Therefore, the changes of water holdup in the pipe with small inclination angles are more severe than those with large inclination angles. In addition, a satisfactory agreement between predicted and experimental holdups substantiates the general validity of the proposed drift velocity correlation for oil and water flows, especially for those with large inclination angles.

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Analysis of Oil/Water-Flow Tests in Horizontal, Hilly Terrain, and Vertical Pipes

Cited by 22 publications

References 4 publications

Pressure drop, flow pattern and local water volume fraction measurements of oil–water flow in pipes

Pressure drop, flow pattern and local water volume fraction measurements of oil–water flow in pipes

Velocity and turbulence measurements of oil-water flow in horizontal and slightly inclined pipes using PIV

Characteristics of water holdup for oil and water mixture flows in horizontal, vertical, and inclined pipes

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