Your search keyword '"V. Hernandez-Perez"' showing total 14 results

1. Insights into the transition from plug to slug flow in a horizontal pipe: An experimental study

Author

Lokman A. Abdulkareem, M. Abdulkadir, V. Hernandez-Perez, D. Zhao, and N.O. Asikolaye

Subjects

Work (thermodynamics), Materials science, General Chemical Engineering, Flux, Wave growth, 02 engineering and technology, General Chemistry, Mechanics, Electrical capacitance tomography, 021001 nanoscience & nanotechnology, Slug flow, law.invention, Vibration, 020401 chemical engineering, law, 0204 chemical engineering, 0210 nano-technology, Spark plug, Pressure gradient

Abstract

A thorough understanding of the behaviour of the transition from plug to slug flow is imperative based on the fact that the transition can trigger an abrupt radial pressure variation. This can bring about major vibrations to the pipeline and also lead to big differences in pressure gradient and wall temperature. Unfortunately, the transition from plug to slug flow is poorly understood due to the scarce availability of experimental data. Furthermore, a considerable amount of research on the transition from plug to slug flow in the literature is based on an air–water system. In this work, the transition behaviour from plug to slug flow in a horizontal pipeline was experimentally investigated using electrical capacitance tomography (ECT). Working fluids are air–silicone oil. The work was carried out over a range of liquid and gas superficial velocities of 0.05–0.47 m/s and 0.05–4.7 m/s, respectively. Wave growth and wave characteristics mechanisms were observed to be responsible for the transition from plug to slug flow based on the obtained experimental results. Both liquid and gas superficial velocities have a major influence also on these mechanisms. The drift flux parameters for the transition from plug to slug flow was determined. A reasonably good agreement was observed from the comparison between present experimental data against hitherto published empirical models and correlations.

Published

2020

2. Annular liquid film thickness prediction in a vertical 180° return bend

Author

V. Hernandez-Perez, D.U. Okhiria, M. Abdulkadir, J.N. Samson, and D. Zhao

Subjects

Fluid Flow and Transfer Processes, Work (thermodynamics), Range (particle radiation), Inertial frame of reference, Materials science, Mechanical Engineering, General Chemical Engineering, Flow (psychology), Aerospace Engineering, 02 engineering and technology, Mechanics, 01 natural sciences, 010305 fluids & plasmas, Physics::Fluid Dynamics, Surface tension, symbols.namesake, Liquid film, 020401 chemical engineering, Nuclear Energy and Engineering, 0103 physical sciences, Froude number, symbols, 0204 chemical engineering, Dimensionless quantity

Abstract

Annular flow is predominant in gas wells. Liquid may be present in form of entrained droplets as well as in the liquid film on pipe wall. The knowledge of the average liquid film thickness is vital for detailed mechanistic modelling of churn–annular flow in engineering applications. So far, the models for liquid film thickness prediction are limited to vertical and horizontal pipes. These models were based on limited ranges of experimental data. In addition, exhaustive iterations are needed when these models are used to estimate liquid film thickness. In this work, a new correlation to predict liquid film thickness in a 180o bend under gas–liquid annular conditions was successfully proposed. The correlation was based on dimensionless numbers (modified gas and liquid Weber numbers and gas Froude number) which reflect the underlined physics governing gas–liquid interaction in the bend. The Weber numbers capture the two important forces (inertial and surface tension forces) which govern the formation of the liquid film thickness within the system while gas Froude number quantifies the interaction of two important forces (centrifugal and gravitational forces) which determines the distribution of the phases across a bend. The proposed liquid film thickness correlation was based on the experimental data obtained from a wide range of operating conditions. The liquid superficial velocities ranges from 0.02 to 0.2 m/s and gas superficial velocities from 3.5 to 16 m/s at different measurement locations of 45o, 90o and 135o of the bend with a diameter of 127 mm. The liquid film thickness in air–water and helium–water annular flow can be predicted by . The validation of the proposed correlation used to predict liquid film thickness in gas–liquid annular systems with different pipe diameters were examined against the available data in the literature. Good agreement was found between the predicted values of liquid film thickness with the experimental data at different measuring locations of the bend.

Published

2018

3. Interrogating flow development and phase distribution in vertical and horizontal pipes using advanced instrumentation

Author

M. Abdulkadir, Barry J. Azzopardi, V. Hernandez-Perez, and C.A. Kwatia

Subjects

Drift velocity, Superficial velocity, Applied Mathematics, General Chemical Engineering, Instrumentation, Flow (psychology), Spherical cap, 02 engineering and technology, General Chemistry, Electrical capacitance tomography, Mechanics, 01 natural sciences, Industrial and Manufacturing Engineering, 010305 fluids & plasmas, 020401 chemical engineering, 0103 physical sciences, Two-phase flow, 0204 chemical engineering, Porosity, Geology

Abstract

The characterization of two-phase flow in both vertical and horizontal pipes is important in oil/gas transportation. As the pipe orientation may change from well to well, it is also important to understand the characteristic responses expected of a two-phase mixture to a change in pipe inclination. This study concerns the changes in the void fraction, structure frequency and structure velocity that occur within an air–silicone oil mixture as a function of the pipe orientation. Experimental data were obtained from the combined use of electrical capacitance tomography (ECT) and wire mesh sensors (WMS), which allow the 3D visualization of the flow patterns. The reported experiments were performed on a 67 mm diameter pipe, in a flow loop, in which a pipe section may be inclined at angles of between −5 or 90° to the horizontal. For this study, the inclined pipe was either set at an angle of 0 or 90 to the horizontal, which correspond to a horizontal or vertical pipe setting, respectively. The results of flow development using the PDF of void fraction obtained at 3 measurement locations; ECT 1, ECT 2 and WMS at 4.4, 4.489 and 4.92 m, respectively, showed that the flow is fully developed and statistically stable for the vertical two-phase flow. While on the other hand, the flow is in rapid development for the horizontal two-phase flow scenario at same liquid and gas superficial velocities. The processed data reveal the differences in flow distribution produced by the pipe inclination. Within the vertical pipe configuration spherical cap bubbles, slug and churn two phase flow patterns were observed, whilst plug, slug and stratified wavy two-phase flows were identified in the horizontal configuration of the pipe. It is concluded that a plot of mixture superficial velocity against average void fraction may be used to provide a qualitative assessment of the flow patterns observed, regardless of pipe inclination. The two-phase flow variables that are concluded to significantly influence the distribution coefficient, C0, and drift velocity, VD, are the pipe orientation and flow patterns.

Published

2018

4. Experimental investigation of the characteristics of the transition from spherical cap bubble to slug flow in a vertical pipe

Author

V. Hernandez-Perez, B. Ugwoke, Lokman A. Abdulkareem, D. Zhao, and M. Abdulkadir

Subjects

Fluid Flow and Transfer Processes, Materials science, Terminal velocity, business.industry, Mechanical Engineering, General Chemical Engineering, Bubble, Flow (psychology), Aerospace Engineering, Spherical cap, 02 engineering and technology, Mechanics, Computational fluid dynamics, Slug flow, 01 natural sciences, 010305 fluids & plasmas, Physics::Fluid Dynamics, 020401 chemical engineering, Nuclear Energy and Engineering, 0103 physical sciences, 0204 chemical engineering, Porosity, business, Pressure gradient

Abstract

Reliable and accurate prediction of the transition from spherical cap bubble to slug flow is crucial not only to the operation of industrial facilities such as the crude oil pipelines, bubble column, and nuclear reactors but also for model development for computational fluid dynamics (CFD) studies. The present paper presents a review of the transition mechanics from spherical cap bubble flow to slug flow in vertical pipes. The bubble flow was split into sub-regions, bubbles and spherical cap bubbles and the mechanisms to classify them (i.e., bubble terminal velocity and cap bubble velocity) was analysed. For now, the literature review does not present some important previous works. This paper presents an original data set of gas–silicone oil in vertical pipes to support the new findings. The experimental two-phase data classifies the flow patterns using the probability density function (PDF) and shows the important flow variables such as average void fraction, pressure gradient, slug body void fraction, liquid slug, Taylor bubble and slug unit lengths, structural velocity and frequency obtained by electrical capacitance tomography (ECT) and a wire mesh sensor (WMS).

Published

2021

5. Experimental study of the hydrodynamic behaviour of slug flow in a horizontal pipe

Author

M. Abdulkadir, E. Sam-Mbomah, V. Hernandez-Perez, Barry J. Azzopardi, and Ian Lowndes

Subjects

Pressure drop, animal structures, Materials science, biology, Slug, Applied Mathematics, General Chemical Engineering, fungi, Flow (psychology), 02 engineering and technology, General Chemistry, Mechanics, biology.organism_classification, Slug flow, 01 natural sciences, Pressure sensor, Industrial and Manufacturing Engineering, 010305 fluids & plasmas, 020401 chemical engineering, embryonic structures, 0103 physical sciences, Geotechnical engineering, 0204 chemical engineering, Current (fluid), Porosity

Abstract

This paper investigates the unsteady hydrodynamic behaviour of slug flow occurring within an air–silicone oil mixture, within a horizontal 67 mm internal diameter pipe. A series of slug flow regime experiments were performed for a range of injected air superficial velocities (0.29–1.4 m s−1) and for liquid flows with superficial velocities of between 0.05–0.47 m s−1. A pair of Electrical Capacitance Tomography (ECT) probes was used to determine: the slug translational velocities of the elongated bubbles and liquid slugs, the slug frequencies, the lengths of elongated bubbles and the liquid slugs, the void fractions within the elongated bubbles and liquid slugs. The pressure drop experienced along the pipe was measured using a differential pressure transducer cell (DP cell). A comparative analysis of the current experimental data and that previously published experimental confirms good agreement.

Published

2016

6. Detailed analysis of phase distributions in a vertical riser using wire mesh sensor (WMS)

Author

Ian Lowndes, V. Hernandez-Perez, M. Abdulkadir, Barry J. Azzopardi, and E.T. Brantson

Subjects

Fluid Flow and Transfer Processes, Superficial velocity, Materials science, Mechanical Engineering, General Chemical Engineering, Flow (psychology), Aerospace Engineering, Mechanics, Silicone oil, Pipe flow, Root mean square, chemistry.chemical_compound, Nuclear Energy and Engineering, chemistry, Approximation error, Phase (matter), Porosity

Abstract

This paper looks into the results of an experimental study concerned with the phase distributions of gas–liquid multiphase flows experienced in a vertical riser. Scale experiments were carried out using a mixture of air and silicone oil in a 6 m long riser pipe with an internal diameter pipe of 67 mm. A series of pipe flow experiments were performed for a range of injected air superficial velocities over the range 0.05–4.73 m/s, whilst the liquid superficial velocities ranged from 0.05 to 0.38 m/s. Measurements of cross-sectional void fraction and radial time averaged void fraction across a pipe section located 4.92 m from the pipe flow injection were obtained using a capacitance wire mesh sensor (WMS). The data were recorded at a frequency of 1000 Hz over an interval of 60 s. For the range of flow conditions studied, the average void fraction was observed to vary between 0.1 and 0.83. An analysis of the data collected concluded that the observed void fraction was strongly affected by the gas superficial velocity, whereby the higher the gas superficial velocity, the higher was the observed average void fraction. The average void fraction distributions observed were in good agreement with the results obtained by other researchers. The accuracy and performance of void fraction correlations were carried out in terms of percentage error and Root Mean Square (RMS) error. Reasonably symmetric radial void fraction profiles were obtained when the air–silicone oil was fully developed, and the shape of the symmetry profile was strongly dependent on the gas superficial velocity. The data for air/water and air/silicone oil systems showed reasonably good agreement except at gas superficial velocity of 0.05 m/s. A comparison of the experimental data was performed against a published model to investigate the flow structure of air–water mixtures in a bubble column. A satisfactory report was observed for radial void fraction profile (mean relative error is within 5.7%) at the higher gas superficial velocities.

Published

2014

7. Comparison of Experimental and Computational Fluid Dynamics (CFD) Studies of Slug Flow in a Vertical 90° Bend

Author

M. Abdulkadir, V. Hernandez-Perez, S. Lo, I. S. Lowndes, and B. J. Azzopardi

Subjects

General Engineering, General Physics and Astronomy, lcsh:TA170-171, lcsh:Environmental engineering

Abstract

This paper presents the results of comparison of experimental and CFD studies of slug flow in a vertical 90° bend using validated models. For the experimental part, Electrical Capacitance Tomography (ECT), Wire Mesh Tomography (WMS), and high-speed videos were used to monitor an air-silicone oil mixture flowing in a vertical 90o bend. The ECT probes were mounted before the bend whilst the WMS was positioned either immediately upstream or immediately downstream of the bend. The downstream pipe was maintained horizontal whilst the upstream pipe was maintained vertical. The bend (R/D = 2.3) was made of transparent acrylic resin. Parallel to the experiments, simulations were carried out for same experiment set-up using the commercial software package Star-CD and Star-CCM+. The condition was simulated with the Volume of Fluid (VOF) model. The simulation predictions were validated against the experimental data. A reasonably good agreement was observed for the results of the experiment and CFD.

Published

2013

8. Grid Generation Issues in the CFD Modelling of Two-Phase Flow in a Pipe

Author

Barry J. Azzopardi, V. Hernandez-Perez, and M. Abdulkadir

Subjects

Continuum mechanics, Computer simulation, business.industry, Computer science, Turbulence, General Engineering, General Physics and Astronomy, Mechanics, Computational fluid dynamics, Grid, lcsh:Environmental engineering, Physics::Fluid Dynamics, Mesh generation, Volume of fluid method, Two-phase flow, lcsh:TA170-171, business, ComputingMethodologies_COMPUTERGRAPHICS

Abstract

The grid generation issues found in the 3D simulation of two-phase flow in a pipe using Computational Fluid Dynamics (CFD) are discussed in this paper. Special attention is given to the effect of the element type and structure of the mesh. The simulations were carried out using the commercial software package STAR-CCM+, which is designed for numerical simulation of continuum mechanics problems. The model consisted of a cylindrical vertical pipe. Different mesh structures were employed in the computational domain. The condition of two-phase flow was simulated with the Volume of Fluid (VOF) model, taking into consideration turbulence effects using the k-e model. The results showed that there is a strong dependency of the flow behaviour on the mesh employed. The best result was obtained with the grid known as butterfly grid, while the cylindrical mesh produced misleading results. The simulation was validated against experimental results.

Published

2011

9. Wisp-like structures in vertical gas–liquid pipe flow revealed by wire mesh sensor studies

Author

Uwe Hampel, V. Hernandez Perez, M. J. da Silva, Barry J. Azzopardi, R. Kaji, and Matthias Beyer

Subjects

Fluid Flow and Transfer Processes, Materials science, Flow (mathematics), Wire mesh, Mechanical Engineering, General Physics and Astronomy, Conductance, Two-phase flow, Mechanics, Phase velocity, Flow pattern, Porosity, Pipe flow

Abstract

A conductance wire mesh sensor system has been employed on a vertical 67 mm diameter pipe with the up flow of air and water mixtures. The measuring system provides time and cross-sectionally resolved information about the spatial distribution of the phases. Statistical information can be extracted and used to identify flow patterns. The fully resolved data has revealed a hitherto unreported structure has been seen in churn flow which could be linked to the wisps in wispy-annular flow.

Published

2010

10. Comparative study of gas–oil and gas–water two-phase flow in a vertical pipe

Author

V. Hernandez Perez, Barry J. Azzopardi, Dirk Lucas, M. J. da Silva, Uwe Hampel, Lokman A. Abdulkareem, Matthias Beyer, Lutz Szalinski, and S. Thiele

Subjects

Multiphase flow meter, Materials science, Plug flow, Mass flow meter, Water flow, Applied Mathematics, General Chemical Engineering, Analytical chemistry, General Chemistry, Mechanics, Industrial and Manufacturing Engineering, Flow measurement, Physics::Fluid Dynamics, Thermal mass flow meter, Flow coefficient, Two-phase flow

Abstract

A wire-mesh sensor has been employed to study air/water and air/silicone oil two-phase flow in a vertical pipe of 67 mm diameter and 6 m length. The sensor was operated with a conductivity-measuring electronics for air/water flow and a permittivity-measuring one for air/silicone oil flow. The experimental setup enabled a direct comparison of both two-phase flow types for the given pipe geometry and volumetric flow rates of the flow constituents. The data have been interrogated at a number of levels. The time series of cross-sectionally averaged void fraction was used to determine characteristics in amplitude and frequency space. In a more three-dimensional examination, radial gas volume fraction profiles and bubble size distributions were processed from the wire-mesh sensor data and compared for both flow types. Information from time series and bubble size distribution data was used to identify flow patterns for each of the flow rates studied.

Published

2010

11. Comparison of experimental and Computational Fluid Dynamics (CFD) studies of slug flow in a vertical riser

Author

M. Abdulkadir, Barry J. Azzopardi, S. Lo, Ian Lowndes, and V. Hernandez-Perez

Subjects

Fluid Flow and Transfer Processes, Void (astronomy), Materials science, business.industry, Mechanical Engineering, General Chemical Engineering, Bubble, Aerospace Engineering, Spectral density, Probability density function, Mechanics, Computational fluid dynamics, CFD, ECT, VOF, Slug Flow, Air-silicone Oil, Riser, PDF, Void Fraction, PSD, Taylor Bubble Length, Velocity, Slug flow, Physics::Fluid Dynamics, Nuclear Energy and Engineering, Volume of fluid method, Porosity, business

Abstract

This paper presents a comparison of the results obtained from experiments and CFD studies of slug flow in a vertical riser. A series of two experimental investigations were carried out on a 6 m vertical pipe with a 0.067 m internal diameter charged with an air–silicone oil mixture. For the first set of experiments, the riser was initially full of air, and then liquid and gas flows set to liquid and gas superficial velocities = 0.05 and 0.344 m/s, respectively, electrical capacitance tomography (ECT) and wire mesh sensor (WMS) transducers were employed. In the second one, the riser was initially full of (static) liquid, and then liquid and gas flows set to liquid and gas superficial velocities = 0.05 and 0.344 m/s, respectively, only ECT was used. A characterisation of the observed slug flow regimes was carried out. This includes the evaluation of the instantaneous distribution of the phases over the pipe cross-section, the Probability Density Function (PDF) of void fraction, time series of cross-sectional void fraction, Power Spectral Density (PSD), structure velocity of the Taylor bubble, lengths of the liquid slug and Taylor bubble and void fractions in the liquid slug and Taylor bubble. The simulation results were validated both qualitatively and quantitatively against experimental data. A reasonably good agreement was observed between the results of the experiment and CFD.

Published

2015

12. Experimental study of the hydrodynamic behaviour of slug flow in a vertical riser

Author

Barry J. Azzopardi, M. Abdulkadir, V. Hernandez-Perez, Ian Lowndes, and S. Dzomeku

Subjects

Pressure drop, Superficial velocity, animal structures, Chemistry, Applied Mathematics, General Chemical Engineering, Drop (liquid), Bubble, fungi, General Chemistry, Mechanics, Slug flow, Pressure sensor, Industrial and Manufacturing Engineering, law.invention, Physics::Fluid Dynamics, law, embryonic structures, ECT, Taylor Bubble, Liquid Slug, Slug Unit, Frequency, Void Fraction, Geotechnical engineering, Total pressure, Hydrostatic equilibrium

Abstract

This paper presents an investigation of the hydrodynamics of slug flow in a vertical 67 mm internal diameter riser. The slug flow regime was generated using a multiphase air–silicone oil mixture over a range of gas (0.42

Published

2014

13. The control and maintenance of desired flow patterns in bends of different orientations

Author

Buddhika N. Hewakandamby, Abdelwahid Azzi, Faiza Saidj, Barry J. Azzopardi, Lokman A. Abdulkareem, Rajab Omar, D. Zhao, V. Hernandez Perez, and M. Abdulkadir

Subjects

Flow (psychology), Phase (waves), Void fraction, 02 engineering and technology, Classification of discontinuities, 01 natural sciences, 010305 fluids & plasmas, Electrical tomography, 020401 chemical engineering, Position (vector), Orientation (geometry), Modelling and Simulation, 0103 physical sciences, Point (geometry), 0204 chemical engineering, Electrical and Electronic Engineering, Instrumentation, Mechanics, Flow pattern, Bends, Computer Science Applications, Modeling and Simulation, Conductance, Heat transfer, Gas-liquid, Geology

Abstract

Multiphase flows are common in industrial settings and bends in pipe lines cannot be avoided due to space limitations. Gas-liquid two phase flows could form material discontinuities that could have adverse effect on productivity and the pipe network due to sudden variations resulting due to the rapid momentum flux variations at fittings such as bends. Research into gas-liquid flow and bends can be motivated by the effect of the bend on the flow downstream of it which could alter the flow pattern occurring and the performance of downstream equipment. Alternatively, the interest might come from what occurs in the bend itself, there could be dryout of the film on the walls and consequent damage to the heat transfer equipment. Here we present measurements made with a number of accurate and fast responding sensors on three cases, two on the effect of the bend and one considering effects in the bend. The results show that the flow transformations occur in two phase flows depending on the orientation of the bend and the change could be captured using fast sweeping measurement techniques. We present the evidence of effectiveness of several types of measurement techniques that could fit into various combinations of phases. The results, point to how to achieve certain flow patterns. Also recommendations are provided regarding the position of any sensor installed to determine flow pattern.

14. Applications of Artificial Neural Network (ANN) method for performance prediction of the effect of a vertical 90° bend on an air-silicone oil flow

Author

V. Hernandez-Perez, Barry J. Azzopardi, Ian Lowndes, M. Abdulkadir, and P.O. Ayegba

Subjects

Superficial velocity, Mean squared error, General Chemical Engineering, Flow (psychology), Multiphase flow, void fraction, Probability density function, 02 engineering and technology, General Chemistry, Mechanics, 01 natural sciences, PDF, 010305 fluids & plasmas, 90o bend, modelling, air–silicone oil, 020401 chemical engineering, Approximation error, 0103 physical sciences, Performance prediction, 0204 chemical engineering, Porosity, ANN, Mathematics

Abstract

Knowledge of how the presence of a bend can change the flow patterns of a gas–liquid mixture is important for the design of multiphase flow systems, particularly to prevent burn-out and erosion–corrosion. Burn-out and erosion–corrosion both have serious implications for heat and mass transfer. The objective of this work therefore is to train an artificial neural network (ANN), a powerful interpolation technique, to predict the effect of a vertical 90o bend on an air–silicone oil mixture over a wide range of flow rates. Experimental data for training, validation, testing and final prediction were obtained using advanced instrumentation, wire mesh sensor (WMS) and high speed camera. The performance of the models were evaluated using the mean square error (MSE), average absolute relative error (MAE), Chi square test (X2) and cross correlation coefficients (R). The performance discriminator X2 for prediction of average void fraction is 2.57e-5 and that for probability density function (PDF) of void fraction MAE is 0.0028 for best performing models. The well trained ANN is then used to predict the effects of the two input parameters individually. The predicted results show that for the before the bend scenario, the most effective input parameter that reflects a change in flow pattern is the gas superficial velocity. On the other hand, the most unfavourable output parameter to measure after the bend is the average void fraction based on the fact that the flow near the bend is a developing one.