Lijo Francis scite author profile

Given increasing regional water scarcity and that almost half of the world's population lives within 100 km of an ocean, seawater represents a virtually infinite water resource. However, its exploitation is presently limited by the significant specific energy consumption (kWh/m 3) required by conventional desalination technologies, further exasperated by high unit costs ($/m 3) and environmental impacts including GHG emissions (g CO2-eq/m 3), organism impingement/entrainment through intakes, and brine disposal through outfalls. This paper explores the state-of-the-art in present seawater desalination practice, emphasizing membrane-based technologies, while identifying future opportunities in step improvements to conventional technologies and development of emerging, potentially disruptive, technologies through advances in material science, process engineering, and system integration. In this paper, seawater reverse osmosis (RO) serves as the baseline conventional technology. The discussion extends beyond desalting processes into membrane-based salinity gradient energy production processes, which can provide an energy offset to desalination process energy requirements. The future membrane landscape in membrane-based desalination and salinity gradient energy is projected to include ultrahigh permeability RO membranes, renewable-energy driven desalination, and emerging processes including closed-circuit RO, membrane distillation, forward osmosis, pressure retarded osmosis, and reverse electrodialysis according various niche applications and/or hybrids, operating separately or in conjunction with RO.

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Performance modeling of direct contact membrane distillation (DCMD) seawater desalination process using a commercial composite membrane

Lee

Kim

et al. 2015

Journal of Membrane Science

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This paper presents the development of a rigorous theoretical model to predict the transmembrane flux of a flat sheet hydrophobic composite membrane, comprising both an active layer of polytetrafluoroethylene and a scrim-backing support layer of polypropylene, in the direct contact membrane distillation (DCMD) process. An integrated model includes the mass, momentum, species and energy balances for both retentate and permeate flows, coupled with the mass transfer of water vapor through the composite membrane and the heat transfer across the membrane and through the boundary layers adjacent to the membrane surfaces. Experimental results and model predictions for permeate flux and performance ratio are compared and shown to be in good agreement. The permeate flux through the composite layer can be ignored in the consideration of mass transfer pathways at the composite membrane. The effect of the surface porosity and the thickness of active and support layers on the process performance of composite membrane has also been studied. Among these parameters, surface porosity is identified to be the main factor significantly influencing the permeate flux and performance ratio, while the relative influence of the surface porosity on the performance ratio is less than that on flux.

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Modeling of air-gap membrane distillation process: A theoretical and experimental study

Alsaadi

Ghaffour

et al. 2013

Journal of Membrane Science

167

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Synthesis and fabrication of nanostructured hydrophobic polyazole membranes for low-energy water recovery

Maab

Francis

Alsaadi

et al. 2012

Journal of Membrane Science

110

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Material gap membrane distillation: A new design for water vapor flux enhancement

Francis

Ghaffour

Alsaadi

et al. 2013

Journal of Membrane Science

175

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A new module design for membrane distillation, namely material gap membrane distillation (MGMD), for seawater desalination has been proposed and successfully tested. It has been observed that employing appropriate materials between the membrane and the condensation plate in an air gap membrane distillation (AGMD) module enhanced the water vapor fluxsignificantly. An increase in the water vapor flux of about 200% to 800 % was observed by filling the gap with sand and DI water at various feed water temperatures. However, insulating materials such as polypropylene and polyurethane have no effect on the water vapor flux. The influence of material thickness and characteristics has also been investigated in this study. An increase in the water gap width from 9 mm to 13 mm increases the water vapor flux. An investigation on an AGMD and MGMD performance comparison, carried out using two different commercial membranes provided by different manufacturers, is also reported in this paper.

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Performance evaluation of the DCMD desalination process under bench scale and large scale module operating conditions

Francis

Ghaffour

Alsaadi

et al. 2014

Journal of Membrane Science

119

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The flux performance of different hydrophobic microporous flat sheet commercial membranes made of poly tetrafluoroethylene (PTFE) and poly propylene (PP) was tested for Red Sea water desalination using the direct contact membrane distillation (DCMD) process, under bench scale (high ΔT) and large scale module (low ΔT) operating conditions. Membranes were characterized for their surface morphology, water contact angle, thickness, porosity, pore size and pore size distribution. The DCMD process performance was optimized using a locally designed and fabricated module aiming to maximize the flux at different levels of operating parameters, mainly feed water and coolant inlet temperatures at different temperature difference across the membrane (ΔT). Water vapor flux of 88.8 kg/m 2 h was obtained using a PTFE membrane at high ΔT (60 °C). In addition, the flux performance was compared to the first generation of a new locally synthesized and fabricated membrane made of a different class of polymer under the same conditions. A total salt rejection of 99.99% and boron rejection of 99.41% were achieved under the extreme operating conditions. On the other hand, a detailed water characterization revealed that low molecular weight non-ionic molecules (ppb level) were transported with the water vapor molecules through the membrane structure. The membrane which provided the highest flux was then tested under large scale module operating conditions. The average flux of the latter study (low ΔT) was found to be eight times lower than that of the bench scale (high ΔT) operating conditions.

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Experimental and theoretical analyses of temperature polarization effect in vacuum membrane distillation

Alsaadi

Francis

Amy

et al. 2014

Journal of Membrane Science

119

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Effect of feed flow pattern on the distribution of permeate fluxes in desalination by direct contact membrane distillation

et al. 2017

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The current study aims to highlight the effect of flow pattern on the variations of permeate fluxes over the membrane surface during desalination in a direct contact membrane distillation (DCMD) flat module. To do so, a three dimensional (3D) Computational Fluid Dynamics (CFD) model with embedded pore scale calculations is implemented to predict flow, heat and mass transfer in the DCMD module. Model validation is carried out in terms of average permeate fluxes with experimental data of seawater desalination using two commercially available PTFE membranes. Average permeate fluxes agree within 6% and less with experimental values without fitting parameters. Simulation results show that the distribution of permeate fluxes and seawater salinity over the membrane surface are strongly dependent on momentum and heat transport and that temperature and concentration polarization follow closely the flow distribution. The analysis reveals a drastic effect of recirculation loops and dead zones on module performance and recommendations to improve MD flat module design are drawn consequently.

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Lijo Francis

Membrane-based seawater desalination: Present and future prospects

Performance modeling of direct contact membrane distillation (DCMD) seawater desalination process using a commercial composite membrane

Modeling of air-gap membrane distillation process: A theoretical and experimental study

Synthesis and fabrication of nanostructured hydrophobic polyazole membranes for low-energy water recovery

Material gap membrane distillation: A new design for water vapor flux enhancement

Performance evaluation of the DCMD desalination process under bench scale and large scale module operating conditions

Experimental and theoretical analyses of temperature polarization effect in vacuum membrane distillation

Effect of feed flow pattern on the distribution of permeate fluxes in desalination by direct contact membrane distillation

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