Renewable energy-driven desalination technologies: A comprehensive review on challenges and potential applications of integrated systems

Ghaffour, Noreddine; Bundschuh, Jochen; Mahmoudi, Hacène; Goosen, Mattheus F. A.

doi:10.1016/j.desal.2014.10.024

Cited by 436 publications

(194 citation statements)

References 136 publications

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“…For example, a distinct advantage of MD is the ability to harness low-grade thermal energy such as waste heat, geothermal energy, and solar thermal energy for desalination [4][5][6]. Such an advantage, together with the small system footprint and low capital cost, renders MD an appealing process for sustainable and off-grid desalination [7][8][9][10][11]. On the other hand, MD has also been identified as one of the only few promising technological candidates for desalinating shale gas produced water which, in certain cases, is too saline for reverse osmosis to treat [12][13][14].…”

Section: Introductionmentioning

confidence: 99%

Tailoring surface charge and wetting property for robust oil-fouling mitigation in membrane distillation

Wang

Jin

Hou

et al. 2016

Journal of Membrane Science

123

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a b s t r a c tThe efforts of developing anti-oil-fouling membranes have so far been focusing on tailoring membrane surface wetting properties, whereas the impacts of surface charge are often eclipsed. In this study, we investigated the impacts of surface charge and wetting property on oil fouling kinetics in membrane distillation (MD). Two composite membranes with in-air hydrophilic and underwater oleophobic surfaces, one of positive charge and the other of negative charge, were fabricated by modifying a hydrophobic polyvinylidene fluoride (PVDF) membrane with hydrophilic polyelectrolytes with different charges. The modified composite membranes were compared with the reference PVDF membrane for their contact angles, adhesion force curves, and fouling kinetics in MD processes. It was found that the negatively charged composite membrane performed the best in mitigating fouling by the negatively charged oil emulsion, followed by the positively charged composite membrane, with the pristine PVDF membrane being the most susceptible to oil fouling in MD experiments. The results from underwater oil CA measurements and oil probe force spectroscopy corroborated the results in the fouling experiments. The impact of surface charges on oil-membrane interaction and associated mechanism were also discussed.

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Section: Introductionmentioning

confidence: 99%

Tailoring surface charge and wetting property for robust oil-fouling mitigation in membrane distillation

Wang

Jin

Hou

et al. 2016

Journal of Membrane Science

123

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“…As a result, RO may not be suitable for small-scale seawater desalination applications, particularly in areas with unreliable or limited power supply. In this context, membrane distillation (MD), given its ability to use solar thermal and low-grade heat directly as the primary source of energy, has been identified as a potential candidate for small-scale and off-grid seawater desalination applications [2][3][4][5].…”

Section: Introductionmentioning

confidence: 99%

Evaluating energy consumption of air gap membrane distillation for seawater desalination at pilot scale level

Duong

Cooper

Nelemans³

et al. 2016

Separation and Purification Technology

152

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This study aimed to optimise an air gap membrane distillation (AGMD) system for seawater desalination with respect to distillate production as well as thermal and electrical energy consumption. Pilot evaluation data shows a notable influence of evaporator inlet temperature and water circulation rate on process performance. An increase in both distillate production rate and energy efficiency could be obtained by increasing the evaporator inlet temperature. On the other hand, there was a trade-off between the distillate production rate and energy efficiency when the water circulation rate varied. Increasing the water circulation rate resulted in an improvement in the distillate production rate, but also an increase in both specific thermal and electrical energy consumption. Given the small driving force used in the pilot AGMD, discernible impact of feed salinity on process performance could be observed, while the effects of temperature and concentration polarisation were small. At the optimum operating conditions identified in this study, a stable AGMD operation for seawater desalination could be achieved with specific thermal and electrical energy consumption of 90 and 0.13 kW h/m3, respectively. These values demonstrate the commercial viability of AGMD for smallscale and off-grid seawater desalination where solar thermal or low-grade heat sources are readily available. Abstract: This study aimed to optimise an air gap membrane distillation (AGMD) process for seawater desalination with respect to distillate production as well as thermal and electrical energy consumption. Pilot evaluation data shows a notable influence of evaporator inlet temperature and water circulation rate on process performance. An increase in both distillate production rate and energy efficiency could be obtained by increasing the evaporator inlet temperature. On the other hand, there was a trade-off between the distillate production rate and energy efficiency when the water circulation rate varied. Increasing the water circulation rate resulted in an improvement in the distillate production rate, but also an increase in both specific thermal and electrical energy consumption. Given the small driving force used in the pilot AGMD, discernible impact of feed salinity on process performance could be observed, while the effects of temperature and concentration polarisation were small. At the optimum operating conditions identified in this study, a stable AGMD operation for seawater desalination could be achieved with specific thermal and electrical energy consumption of 90 and 0.13 kWh/m 3 , respectively. These values demonstrate the commercial viability of AGMD for small-scale and off-grid seawater desalination where solar thermal or low-grade heat sources are readily available.

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“…This plant is also able to prevent the emission of 8,558.46 tons of greenhouse gases to the atmosphere every year [23]. Also, the desalination of 20 m 3 /d of seawater has been achieved using geothermal heat source at 80°C in Mexico [28]. These examples, among others, have been able to prove that wind and geothermal energy can be used practically in desalination plants.…”

Section: Discussionmentioning

confidence: 83%

“…For example, geothermal energy can reduce the specific cost of desalination by 30%. Surely, this is a significant reduction in cost and a considerable enhancement of the economic sustainability of potable water production [28]. However, it is worth noting that the use of wind and geothermal resources is limited by geographical factors, as these resources can only be used effectively in locations where they are surplus and can be practically exploited for energy generation.…”

Section: Discussionmentioning

confidence: 99%

Wind and Geothermal Energy in Desalination: A Short Review on Progress and Sustainable Commercial Processes

A¹

2015

Ind Eng Manage

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Fossil fuels have been used as the main energy source for the desalination technologies. The continued increase in the demand for desalinated water has resulted in rising greenhouse gas emissions and threat to available fuel reserves. Consequently, most commercial desalination processes powered by fossil fuels have significantly contributed to environmental pollution. Renewable energy comes into the picture as an environmental friendly option as well as a means of fossil energy minimization. In this paper, a review on the use of renewable energy in recent desalination processes has been carried, with a focus on wind and geothermal energy.

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Renewable energy-driven desalination technologies: A comprehensive review on challenges and potential applications of integrated systems

Cited by 436 publications

References 136 publications

Tailoring surface charge and wetting property for robust oil-fouling mitigation in membrane distillation

Tailoring surface charge and wetting property for robust oil-fouling mitigation in membrane distillation

Evaluating energy consumption of air gap membrane distillation for seawater desalination at pilot scale level

Wind and Geothermal Energy in Desalination: A Short Review on Progress and Sustainable Commercial Processes

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