Numerical simulation of combined adsorption desalination and cooling cycles with integrated evaporator/condenser

Youssef, Peter G.; Mahmoud, Saad; Al-Dadah, Raya

doi:10.1016/j.desal.2016.04.011

Cited by 53 publications

(10 citation statements)

References 22 publications

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“…In their work, a comparison between the AQSOA-ZO2 and silica-gel has been performed when operating in a two bed adsorption cycle for the production of desalinated water and cooling. Youssef et al [16], have investigated the use of AQSOA-Z02 in a novel adsorption system consisting of evaporator, condenser, integrated evaporator-condenser device and 4 adsorber beds. Results showed that by utilizing heat recovery between system components, water production can reach 12.4 m 3 /tonne adsorbent/day and cooling of 32.4 Rton/tonne adsorbent at evaporator inlet water temperature of 10 o C.…”

Section: Nomenclature C Pmentioning

confidence: 99%

Experimental investigation of adsorption water desalination/cooling system using CPO-27Ni MOF

et al. 2017

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Section: Nomenclature C Pmentioning

confidence: 99%

Experimental investigation of adsorption water desalination/cooling system using CPO-27Ni MOF

et al. 2017

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“…Recent papers illustrate adsorption materials and adsorption cooling system configurations and their combination with other cooling and desalination systems 19‐21 . The researchers continued to find new sorbent materials with high adsorption capacities like a new MOF, clays, aluminum fumarate, and copper sulfate 22‐30 or improve the existing materials.…”

Section: Introductionmentioning

confidence: 99%

“…Recent papers illustrate adsorption materials F I G U R E 1 Adsorption systems: (A) adsorption desalinationcooling, (B) adsorption desalination with heat recovery (condenser/ evaporator), (C) adsorption cooling system and adsorption cooling system configurations and their combination with other cooling and desalination systems. [19][20][21] The researchers continued to find new sorbent materials with high adsorption capacities like a new MOF, clays, aluminum fumarate, and copper sulfate [22][23][24][25][26][27][28][29][30] or improve the existing materials.…”

Section: Introductionmentioning

confidence: 99%

“…Utilizing bentonite and montmorillonite clays as adsorbent materials, the performance of the adsorption systems detected 4.17 m 3 /ton SDWP, 110.4 to 150 W/kg SCP, and 0.46 to 0.55 COP. 23, 24 Youssef et al 25,26 studied theoretically the advanced adsorption system performance employing AQSOA-Z02. The SDWP and SCP were 6.2-15.4 m 3 /ton and 46.6 W/kg, respectively.…”

Section: Introductionmentioning

confidence: 99%

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Composite adsorbent materials for desalination and cooling applications: A state of the art

Alsaman

Ibrahim

Ahmed

et al. 2022

Intl J of Energy Research

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Summary Adsorption technology is very attractive for producing desalinated water and cooling with no harmful impact on the environment. The performance of adsorption water applications (desalination and cooling) depends on the adsorption characteristics. Many adsorption systems designs were investigated worldwide, employing different adsorbent materials to develop a cost‐effective and high‐performance system. This review presents and summarizes the studies in adsorption and the corresponding applications in desalination and cooling and compares the adsorption properties of composite adsorbents. The review focuses on the composite materials and how they were synthesized while comparing them in terms of the amount of adsorption. The reviewed materials have been classified according to the basic host, such as silica gel, zeolite, carbon, metal‐organic frameworks (MOF), and vermiculite. The review contains more than 70 composites. The maximum reached water vapor uptake is 1.92 kg/kg of PHTS/CaCl2‐20 wt% composite at 0.9 P/Ps. The highest available desorption amount is 1.48 kg/kg of MOF composite for desalination applications and 0.87 kg/kg of vermiculite composite for cooling applications.

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“…A considerable number of studies have been conducted on adsorbents such as silica gel and zeolite [16,17,[27][28][29]. Unfortunately, the regenerating temperatures are usually >60 C [30,31] which are not always available. Therefore, it is desirable to find alternative adsorbents which can efficiently process large amounts of water with low regenerating temperatures [32].…”

Section: Introductionmentioning

confidence: 99%

Hydrothermal stability of water sorption ionogels

Dong

Askalany

Olkis

et al. 2019

Energy

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Adsorption desalination and membrane distillation are the only thermally driven desalination technologies that can be undertaken at temperatures below 70 C. Adsorption desalination is based on an adsorber whose performance primarily depends on the properties of the water sorbent. Water sorption ionogel represents a novel class of materials offering a large working capacity for desalination. In this study, water-sorptive ionogels were prepared and their hydrothermal stability was assessed. The results show that Syloid 72FP silica-based ionogels are hydrothermally stable. The ionic liquid EMIM Ac can be tightly confined in silica at amounts of up to 50 wt% and still withstand high relative humidity and temperature swings. Water uptake of the synthesized ionogel can be up to 1.64 g water g ionogel-1 at 90% RH, which is ~3 times of that of Syloid 72FP silica and ~4 times of that of activated carbon. The EMIM Ac/Syloid 72FP ionogel thus exhibits features appropriate for adsorption desalination systems.

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Numerical simulation of combined adsorption desalination and cooling cycles with integrated evaporator/condenser

Cited by 53 publications

References 22 publications

Experimental investigation of adsorption water desalination/cooling system using CPO-27Ni MOF

Experimental investigation of adsorption water desalination/cooling system using CPO-27Ni MOF

Composite adsorbent materials for desalination and cooling applications: A state of the art

Hydrothermal stability of water sorption ionogels

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