Numerical Analysis of Thermal Performances for a Novel Cascade Solar Desalination Still Design

Numerical analysis of two passive solar desalination designs, the traditional pool evaporation design and the proposed tray design are performed. The significance of common assumption for the pool evaporation design that neglect the mass balance and psychrometric relationships for the air-water vapor volume were investigated and found that neglecting this component results in over predicting the freshwater production by 32.6% and 19.5% for the summer and winter design day, respectively. It was also found that the tray design produced 31.3 % and 7% more freshwater per summer and winter design day, respectively. These results support the need to include all physical components in the numerical simulation. The results also support the tray design as producing significantly more freshwater for the same input.

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Hybrid Solar Desalination to Produce Fresh Water, Electrical Power With Energy Storage

Volume 6A: Energy ◽

10.1115/imece2015-53219 ◽

2015 ◽

Author(s):

Gregory J. Kowalski ◽

Mansour Zenouzi ◽

Masoud Modaresifar

Keyword(s):

Numerical Analysis ◽

Exergy Analysis ◽

Concentration Level ◽

Energy Content ◽

Previous Analysis ◽

Electrical Power ◽

Electrical Energy ◽

Second Law ◽

Salt Mixture ◽

Solar Desalination

The numerical analysis of solar desalination processes in a unique tray was extended to include an RED device to produce electricity either during operation or using the stored concentrated salt mixture. The motivation for this using device was based on an exergy analysis and the second law efficiency. Previous analysis illustrated how the exergy analysis could be used to identify the irreversibilities in the system and indicated modifications to increase the performance of the tray design desalinator for the sensible energy content of the discharge. The exergy related to the higher concentration level of the discharge is now investigated for a RED device. These analyses are extended to investigate the potential of using the higher salinity of the out flowing brine to produce electrical energy by using the reversed electrodialysis (RED) process. The RED process which converts 70–80% of the change in Gibbs energy to electricity uses the concentrated brine to produce electrical power while the freshwater is being produced. The analysis demonstrates it is possible to produce a maximum electrical output of 0.32 kJ/kg for the expected concentration differences. Using the predicted mass flow over the day of 6 kg/(day m2) it is expected that one could produce approximately 1.9 kJ/(day m2) of electricity in addition to the freshwater production.

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