Your search keyword '"Albeirutty M"' showing total 19 results

1. An experimental study for the characterization of fluid dynamics and heat transport within the spacer-filled channels of membrane distillation modules

Author

Albeirutty, M., Turkmen, N., Al-Sharif, S., Bouguecha, S., Malik, A., Faruki, O., Cipollina, A., Ciofalo, M., and Micale, G.

Published

2018

2. Dynamic behavior of micrometric single water droplets impacting onto heated surfaces with TiO2 hydrophilic coating

Author

Negeed, El-Sayed R., Albeirutty, M., and Takata, Y.

Published

2014

3. Water and salts recovery from desalination brines: An exergy evaluation

Author

Macedonio, F., primary, Criscuoli, A., additional, Gzara, L., additional, Albeirutty, M., additional, and Drioli, E., additional

Published

2021

4. A tool for modelling spacer-filled MD channels based on open source CFD code

Author

Al Sharif, S., Albeirutty, M., CIPOLLINA, Andrea, MICALE, Giorgio Domenico Maria, Al-Sharif, S., Albeirutty, M., Cipollina, A., and Micale, G.

Subjects

CFD, spacer, membrane distillation, open foam

Published

2011

5. Dynamic Behavior of a Small Water Droplet Impact Onto a Heated Hydrophilic Surface

Author

Negeed, El-Sayed R., primary, Albeirutty, M., additional, AL-Sharif, Sharaf F., additional, Hidaka, S., additional, and Takata, Y., additional

Published

2016

6. Assessment of temperature polarization in membrane distillation channels by liquid crystal thermography

Author

Tamburini, A., primary, Cipollina, A., additional, Al-Sharif, S., additional, Albeirutty, M., additional, Gurreri, L., additional, Micale, G., additional, and Ciofalo, M., additional

Published

2014

7. Assessment of temperature polarization in membrane distillation channels by liquid crystal thermography.

Author

Tamburini, A., Cipollina, A., Al-Sharif, S., Albeirutty, M., Gurreri, L., Micale, G., and Ciofalo, M.

Subjects

MEMBRANE distillation, TEMPERATURE distribution, THERMAL efficiency, LIQUID crystals, IMAGE analysis, HEAT transfer coefficient

Abstract

The measurement of local temperature distributions within a membrane distillation (MD) channel is a crucial step for the optimization of the channel and spacer geometry. This information allows the estimation of temperature polarization phenomena, which can dramatically influence the thermal efficiency of the process and the optimal choice of the geometric configuration (net spacer features, channel size, etc.). In the present work, a recently presented experimental technique, based on the use of thermochromic liquid crystals and digital image analysis, has been employed in order to assess the temperature polarization phenomena. The local heat transfer coefficient distribution on the membrane surface in a MD spacer-filled channel was thus assessed. The membrane has been modelled by a heat transfer polycarbonate layer. Different diamond spacer geometries were investigated, in order to highlight how the geometrical features affect both pressure drop and heat transfer in spacer-filled channels. [ABSTRACT FROM PUBLISHER]

Published

2015

8. Dynamic behavior of micrometric single water droplets impacting onto heated surfaces with TiO2 hydrophilic coating.

Author

Negeed, El-Sayed R., Albeirutty, M., and Takata, Y.

Subjects

*TITANIUM dioxide, *SURFACE coatings, *ULTRAVIOLET radiation, *WETTING, *HEAT transfer, *HYDRODYNAMICS

Abstract

Abstract: Dynamic behavior of micrometric single water droplets impacting onto heated surfaces with and without superhydrophilic coating is investigated using a high-speed video camera in this research study. Superhydrophilic surface coating, SHS, is achieved by coating the surface with Titanium dioxide, TiO2, and by exposing the surface to ultraviolet, UV. Mirror heat transfer surfaces of different metals have been considered. The experimental runs are carried out by spraying single water droplets onto heated surfaces where, the droplet diameter and velocity were independently controlled. The droplet behavior during the collision with the hot surface has been observed with the high-speed video camera. By analyzing the experimental results and comparison between the present results and the results due to other investigators, the effects of surface wettability, thermal properties of the heat transfer surface, droplet velocity, droplet size and surface superheat on the dynamic behavior of micrometric single water droplets impacting onto the heated surfaces were investigated. Empirical correlations are presented describing the hydrodynamic characteristics of an individual droplet impinging onto the heated surfaces, and concealing the affecting parameters in such process. [Copyright &y& Elsevier]

Published

2014

9. An experimental study for the characterization of fluid dynamics and heat transport within the spacer-filled channels of membrane distillation modules

Author

Michele Ciofalo, Mohammed Albeirutty, Nedim Turkmen, Giorgio Micale, Andrea Cipollina, A. Malik, O. Faruki, Sharaf F. Al-Sharif, S. Bouguecha, Albeirutty M., Turkmen N., Al-Sharif S., Bouguecha S., Malik A., Faruki O., Cipollina A., Ciofalo M., and Micale G.

Subjects

Spacer-filled channel, Materials science, General Chemical Engineering, Membrane distillation, 02 engineering and technology, Heat transfer coefficient, Protein filament, symbols.namesake, 020401 chemical engineering, Fluid dynamics, General Materials Science, 0204 chemical engineering, Composite material, Darcy friction coefficient, Experimental measurement, Water Science and Technology, Pressure drop, Thermochromic Liquid Crystal, Mechanical Engineering, Reynolds number, General Chemistry, 021001 nanoscience & nanotechnology, Volumetric flow rate, Heat transfer, symbols, 0210 nano-technology

Abstract

The thermo-fluid dynamic behavior of spacer-filled channels for membrane distillation was investigated experimentally. Several different geometry were investigated thanks to customized reference spacers manufactured using a 3D printer. In particular, two sets of experiments were conducted: in the first set, cylindrical filaments were orthogonally arranged and the flow attack angle was made to vary from 0o to 90o; in the second set, the flow attack angle was kept symmetrical and the filament angle was made to vary from 30° to 150°. Each spacer was tested for Reynolds numbers between 200 and 900 in the hot channel, while maintaining a constant temperature difference of 13 °C between the hot and the cold channels. Thermochromic Liquid Crystal (TLC) sheets were used for surface temperature measurements. Results showed that, for all spacers, the heat transfer coefficient increases with hot feed flow rate and that the combination of attack angle 45° and filament angle 90° gave the highest heat transfer. Pressure drop measurements showed that spacers could be categorized into two groups relevant to the values of the Darcy friction coefficients (f). One group, associated with spacer designs with filament angles greater than 90°, led to high f values, while the other, associated with filament angles less than 90°, led to moderate f values.

Published

2018

10. Modelling flow and heat transfer in spacer-filled membrane distillation channels using open source CFD code

Author

Giorgio Micale, Andrea Cipollina, Mohammed Albeirutty, Sharaf F. Al-Sharif, Al Sharif, S, Albeirutty, M, Cipollina, A, and Micale, G

Subjects

spacer-filled channel, Pressure drop, Settore ING-IND/26 - Teoria Dello Sviluppo Dei Processi Chimici, Engineering, Work (thermodynamics), business.industry, Mechanical Engineering, General Chemical Engineering, Flow (psychology), temperature polarisation, Mechanical engineering, Membrane distillation, General Chemistry, Computational fluid dynamics, Heat transfer, Fluid dynamics, spacer, General Materials Science, Boundary value problem, CFD, business, Water Science and Technology

Abstract

A good understanding of the details of hydrodynamic and heat transport conditions and their impact on temperature polarisation and pressure drops is essential for optimum design of membrane distillation (MD) modules. To this end, the present work reports on initial progress in the development of a tool for 3D simulation of spacer-filled MD channels based on the open source CFD code library OpenFOAM. The paper discusses a number of modelling and implementation aspects including model geometry and computational domain, choice of boundary conditions, and discretisation schemes. The results pertaining to the effect of three different spacer types on the fluid dynamics and heat transfer inside the channel are presented and discussed in order to highlight the impact of spacer geometrical features on temperature polarisation and pressure drop. Of the three spacer types considered, the 3-layer spacer with the wall-adjacent filament layers aligned with the flow direction was found to cause the lowest pressure drop while producing a robust symmetrical temperature profile. The 2-layer flow aligned square spacer was found to be the least desirable design, producing asymmetric temperature and velocity profiles and high pressure drops.

Published

2013

11. ASSESMENT OF TEMPERATURE POLARIZATION IN MEMBRANE DISTILLATION CHANNELS BY LIQUID CRYSTAL THERMOGRAPHY

Author

Andrea Cipollina, Luigi Gurreri, Sharaf F. Al-Sharif, Mohammed Albeirutty, Giorgio Micale, Alessandro Tamburini, Michele Ciofalo, Tamburini, A., Cipollina, A., Al Sharif, S., Albeirutty, M., Gurreri, L., Micale, G., and Ciofalo, M.

Subjects

Digital Image Analysis, Thermal efficiency, Settore ING-IND/26 - Teoria Dello Sviluppo Dei Processi Chimici, Materials science, Settore ING-IND/25 - Impianti Chimici, Analytical chemistry, Ocean Engineering, Heat transfer coefficient, engineering.material, Membrane distillation, Liquid crystal, Membrane Distillation, Settore ING-IND/19 - Impianti Nucleari, Water Science and Technology, Pressure drop, Thermochromic Liquid Crystal, Diamond, Mechanics, Heat Transfer, Polarization (waves), Pollution, Thermochromic Liquid Crystals, Temperature Polarization, Heat transfer, engineering

Abstract

The measurement of local temperature distributions within a membrane distillation (MD) channel is a crucial step for the optimization of the channel and spacer geometry. This information allows the estimation of temperature polarization phenomena, which can dramatically influence the thermal efficiency of the process and the optimal choice of the geometric configuration (net spacer features, channel size, etc.). In the present work, a recently presented experimental technique, based on the use of thermochromic liquid crystals and digital image analysis, has been employed in order to assess the temperature polarization phenomena. The local heat transfer coefficient distribution on the membrane surface in a MD spacer-filled channel was thus assessed. The membrane has been modelled by a heat transfer polycarbonate layer. Different diamond spacer geometries were investigated, in order to highlight how the geometrical features affect both pressure drop and heat transfer in spacer-filled channels.

Published

2015

12. CFD Investigation of Spacer-Filled Channels for Membrane Distillation

Author

Mariagiorgia La Cerva, Andrea Cipollina, Salah Al-Tahar Bouguecha, Giorgio Micale, Nedim Turkmen, Mohammed Albeirutty, Michele Ciofalo, La Cerva M., Cipollina A., Ciofalo M., Albeirutty M., Turkmen N., Bouguecha S., and Micale G.

Subjects

Settore ING-IND/26 - Teoria Dello Sviluppo Dei Processi Chimici, Materials science, Process modeling, Spacer-filled channel, Filtration and Separation, Membrane distillation, 02 engineering and technology, Heat transfer coefficient, computational fluid dynamics, Computational fluid dynamics, lcsh:Chemical technology, Article, symbols.namesake, Temperature polarization, 020401 chemical engineering, Computational fluid dynamic, Liquid crystal, Chemical Engineering (miscellaneous), lcsh:TP1-1185, 0204 chemical engineering, lcsh:Chemical engineering, Settore ING-IND/19 - Impianti Nucleari, Thermochromic liquid crystals, business.industry, Desalination, Process Chemistry and Technology, Reynolds number, lcsh:TP155-156, Mechanics, 021001 nanoscience & nanotechnology, Polarization (waves), 6. Clean water, Heat transfer, symbols, 0210 nano-technology, business

Abstract

The membrane distillation (MD) process for water desalination is affected by temperature polarization, which reduces the driving force and the efficiency of the process. To counteract this phenomenon, spacer-filled channels are used, which enhance mixing and heat transfer but also cause higher pressure drops. Therefore, in the design of MD modules, the choice of the spacer is crucial for process efficiency. In the present work, different overlapped spacers are investigated by computational fluid dynamics (CFD) and results are compared with experiments carried out with thermochromic liquid crystals (TLC). Results are reported for different flow attack angles and for Reynolds numbers (Re) ranging from ~200 to ~800. A good qualitative agreement between simulations and experiments can be observed for the areal distribution of the normalized heat transfer coefficient. Trends of the average heat transfer coefficient are reported as functions of Re for the geometries investigated, thus providing the basis for CFD-based correlations to be used in higher-scale process models.

13. Enhancement in Heat Transfer Performance of Water Vapor Condensation on Graphene-Coated Copper Surfaces: A Molecular Dynamics Study.

Author

Nurrohman N, Almisbahi H, Tocci E, Abulkhair H, Albeirutty M, Othman R, and Bamaga O

Abstract

The condensation of water vapor plays a crucial role in various applications, including combating water scarcity. In this study, by employing molecular dynamics simulations, we delved into the impact of graphene coatings on water vapor condensation on copper surfaces. Unique to this work was the exploration of various levels of graphene coverage and distribution, a facet largely unexplored in prior investigations. The findings demonstrated a notable increase in the rate of water vapor condensation and heat transfer performance as the graphene coverage was reduced. Using graphene coverages of 84%, 68%, and 52%, the numbers of condensed water molecules were 664, 735, and 880 molecules/ns, respectively. One of the most important findings was that when using the same graphene coverage of 68%, the rate of water vapor condensation and heat transfer performance increased as the graphene coating became more distributed. The overall performance of the water condensation correlated well with the energy and vibrational interaction between the graphene and the copper. This phenomenon suggests how a hybrid surface can enhance the nucleation and growth of a droplet, which might be beneficial for tailoring graphene-coated copper surfaces for applications demanding efficient water vapor condensation.

Published

2024

14. Influence of Inner Gas Curing Technique on the Development of Thermoplastic Nanocomposite Reinforcement.

Author

Totah HS, Moujdin IA, Abulkhair HA, and Albeirutty M

Abstract

In this work, a comprehensive shrinkage and tensile strength characterization of unsaturated polyester (UPE-8340) and vinyl ester (VE-922) epoxy matrices and composites reinforced with multiwall carbon nanotubes (MWCNTs) was conducted. The aspect ratio of UPE and VE with methyl ethyl ketone peroxide (MEKP) was kept at 1:16.6; however, the weight of the MWCNTs was varied from 0.03 to 0.3 gm for the doping of the reinforced nanocomposites. Using a dumbbell-shaped mold, samples of the epoxy matrix without MWCNTs and with reinforced UPE/MWCNT and VE/MWCNT nanocomposites were made. The samples were then cured in a typical ambient chamber with air and an inner gas (carbon dioxide). The effect of the MWCNTs on UPE- and VE-reinforced composites was studied by observing the curing kinetics, shrinkage, and tensile properties, as well as the surface free energy of each reinforced sample in confined saline water. The CO 2 curing results reveal that the absence of O 2 shows a significantly lower shrinkage rate and higher tensile strength and flexural modulus of UPE- and VE-reinforced nanocomposite samples compared with air-cured reinforced nanocomposites. The construction that was air- and CO 2 -cured produced results in the shape of a dumbbell, and a flawless surface was seen. The results also show that smaller quantities of MWCNTs made the UPET- and VE-reinforced nanocomposites more stable when they were absorbed and adsorbed in concentrated salt water. Perhaps, compared to air-cured nanocomposites, CO 2 -cured UPE and VE nanocomposites were better at reducing shrinkage, having important mechanical properties, absorbing water, and being resistant to seawater.

Published

2023

15. Exergetic analysis of direct contact membrane distillation (DCMD) using PVDF hollow fiber membranes for the desalination brine treatment.

Author

Zaheer AHM, Gzara L, Iqbal A, Macedonio F, Albeirutty M, and Drioli E

Abstract

The brines from desalination plants need to be disposed of due to their strong impact on the environment. Membrane operations, like direct contact membrane distillation (DCMD), provide a possible solution to reduce the amount of brine while producing further desalinated water. In this study, an exergy analysis of a laboratory membrane distillation unit working with brines from reverse osmosis (RO) is analyzed. Exergy analysis enables us to assess the energy lost in entropy generation; therefore, it commits us to identify the less efficient configuration of the DCMD module. Unlike other exergy analyses for distillation, in this study, only module inputs and outputs were incorporated. The exergy is calculated at different infeed temperatures, for both in-out and out-in feed configurations of hollow fiber membrane modules. Also, exergy difference, flux, and exergetic efficiency for both configurations are calculated. At high feed temperatures, there is an increase in both flux and exergy change, which increases water recovery and feed side exergetic efficiency. The highest flux that is obtained in the out-in configuration is 13.3 kg/h.m 2 while it is only 6.23 kg/h.m 2 for the in-out system of the module. Also, these exergy changes and feed efficiencies are higher in the out-in module configuration than in the in-out module configuration. Conversely, the exergetic efficiency of the permeate is higher at lower feed temperatures, due to the lower accumulation of concentration polarization along the membrane wall., Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2023 The Authors. Published by Elsevier Ltd.)

Published

2023

16. Evaluation of a Hybrid Moving Bed Biofilm Membrane Bioreactor and a Direct Contact Membrane Distillation System for Purification of Industrial Wastewater.

Author

Alharthi MS, Bamaga O, Abulkhair H, Organji H, Shaiban A, Macedonio F, Criscuoli A, Drioli E, Wang Z, Cui Z, Jin W, and Albeirutty M

Abstract

Integrated wastewater treatment processes are accepted as the best option for sustainable and unrestricted onsite water reuse. In this study, moving bed biofilm reactor (MBBR), membrane bioreactor (MBR), and direct contact membrane distillation (DCMD) treatment steps were integrated successively to obtain the combined advantages of these processes for industrial wastewater treatment. The MBBR step acts as the first step in the biological treatment and also mitigates foulant load on the MBR. Similarly, MBR acts as the second step in the biological treatment and serves as a pretreatment prior to the DCMD step. The latter acts as a final treatment to produce high-quality water. A laboratory scale integrated MBBR/MBR/DCMD experimental system was used for assessing the treatment efficiency of primary treated (PTIWW) and secondary treated (STIWW) industrial wastewater in terms of permeate water flux, effluent quality, and membrane fouling. The removal efficiency of total dissolved solids (TDS) and effluent permeate flux of the three-step process (MBBR/MBR/DCMD) were better than the two-step (MBR/DCMD) process. In the three-step process, the average removal efficiency of TDS was 99.85% and 98.16% when treating STIWW and PTIWW, respectively. While in the case of the two-step process, the average removal efficiency of TDS was 93.83% when treating STIWW. Similar trends were observed for effluent permeate flux values which were found, in the case of the three-step process, 62.6% higher than the two-step process, when treating STIWW in both cases. Moreover, the comparison of the quality of the effluents obtained with the analysed configurations with that obtained by Jeddah Industrial Wastewater Treatment Plant proved the higher performance of the proposed membrane processes.

Published

2022

17. Preparation of ECTFE Porous Membrane for Dehumidification of Gaseous Streams through Membrane Condenser.

Author

Pan J, Chen K, Cui Z, Bamaga O, Albeirutty M, Alsaiari AO, Macedonio F, and Drioli E

Abstract

Due to the good hydrophobicity and chemical resistance of poly(ethylene trifluoroethylene) (ECTFE), it has been an attractive potential material for microfiltration, membrane distillation and more. However, few porous hydrophobic ECTFE membranes were prepared by thermally induced phase separation (TIPS) for membrane condenser applications. In this work, the diluent, di-n-octyl phthalate (DnOP), was selected to prepare the dope solutions. The calculated Hassen solubility parameter indicated that ECTFE has good compatibility with DnOP. The corresponding thermodynamic phase diagram was established, and it has been mutually verified with the bi-continuous structure observed in the SEM images. At 30 wt% ECTFE, the surface contact angle and liquid entry pressure reach their maximum values of 139.5° and 0.71 MPa, respectively. In addition, some other basic membrane properties, such as pore size, porosity, and mechanical properties, were determined. Finally, the prepared ECTFE membranes were tested using a homemade membrane condenser setup. When the polymer content is 30 wt%, the corresponding results are better; the water recovery and condensed water yield is 17.6% and 1.86 kg m -2 h -1 , respectively.

Published

2022

18. CFD Investigation of Spacer-Filled Channels for Membrane Distillation.

Author

La Cerva M, Cipollina A, Ciofalo M, Albeirutty M, Turkmen N, Bouguecha S, and Micale G

Abstract

The membrane distillation (MD) process for water desalination is affected by temperature polarization, which reduces the driving force and the efficiency of the process. To counteract this phenomenon, spacer-filled channels are used, which enhance mixing and heat transfer but also cause higher pressure drops. Therefore, in the design of MD modules, the choice of the spacer is crucial for process efficiency. In the present work, different overlapped spacers are investigated by computational fluid dynamics (CFD) and results are compared with experiments carried out with thermochromic liquid crystals (TLC). Results are reported for different flow attack angles and for Reynolds numbers (Re) ranging from ~200 to ~800. A good qualitative agreement between simulations and experiments can be observed for the areal distribution of the normalized heat transfer coefficient. Trends of the average heat transfer coefficient are reported as functions of Re for the geometries investigated, thus providing the basis for CFD-based correlations to be used in higher-scale process models.

Published

2019

19. Assessment of Blend PVDF Membranes, and the Effect of Polymer Concentration and Blend Composition.

Author

Ali I, Bamaga OA, Gzara L, Bassyouni M, Abdel-Aziz MH, Soliman MF, Drioli E, and Albeirutty M

Abstract

In this work, PVDF homopolymer was blended with PVDF-co-HFP copolymer and studied in terms of morphology, porosity, pore size, hydrophobicity, permeability, and mechanical properties. Different solvents, namely N-Methyl-2 pyrrolidone (NMP), Tetrahydrofuran (THF), and Dimethylformamide (DMF) solvents, were used to fabricate blended PVDF flat sheet membranes without the introduction of any pore forming agent, through a non-solvent induced phase separation (NIPS) technique. Furthermore, the performance of the fabricated membranes was investigated for pressure and thermal driven applications. The porosity of the membranes was slightly increased with the increase in the overall content of PVDF and by the inclusion of PVDF copolymer. Total PVDF content, copolymer content, and mixed-solvent have a positive effect on mechanical properties. The addition of copolymer increased the hydrophobicity when the total PVDF content was 20%. At 25% and with the inclusion of mixed-solvent, the hydrophobicity was adversely affected. The permeability of the membranes increased with the increase in the overall content of PVDF. Mixed-solvents significantly improved permeability., Competing Interests: The authors declare no conflict of interest.

Published

2018