Theoretical Investigation into the Dynamic Performance of a Solar-Powered Multistage Water Gap Membrane Distillation System

Theoretical Investigation into the Dynamic Performance of a Solar-Powered Multistage Water Gap Membrane Distillation System

This article introduces a dynamic theoretical analysis, which is not available in the literature, for the average hourly and monthly performances of a solar-driven multistage water gap membrane distillation system. Based on simultaneous solutions of the combined heat and mass transfer equations usin...

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Bibliographic Details
Published in:Arabian journal for science and engineering (2011) Vol. 48; no. 9; pp. 12499 - 12511
Main Authors: Alawad, Suhaib M., Khalifa, Atia E., Al Hariri, Abdul Hafiz
Format: Journal Article
Language:English
Published: Berlin/Heidelberg Springer Berlin Heidelberg 01-09-2023
Springer Nature B.V
Subjects:
Design parameters
Distillation
Distilled water
Dynamic models
Energy efficiency
Engineering
Humanities and Social Sciences
Mass transfer
Membranes
Meteorological data
multidisciplinary
Research Article-Mechanical Engineering
Science
Solar collectors
Solar energy
Solar radiation
Water heating
Performance evaluation
Integrated system
Multistage water gap
Water desalination
Solar energy utilization
Membrane distillation
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Summary:This article introduces a dynamic theoretical analysis, which is not available in the literature, for the average hourly and monthly performances of a solar-driven multistage water gap membrane distillation system. Based on simultaneous solutions of the combined heat and mass transfer equations using EES software, the dynamic model successfully predicted the average hourly and monthly output from the system. The mid-latitude meteorological data from Dhahran city, Saudi Arabia, are employed in this analysis. This analysis is carried out to examine the variations of the system productivity and energy efficiency with the operating and design parameters of the integrated system, which include the average monthly and hourly solar radiation, the number of the MD units and the number of solar collectors that are used for water heating. Results reveal that an eight-stage MD system with three solar collectors can produce up to 70 L/day of freshwater. The integrated solar MD system is able to effectively improve energy efficiency, with a maximum GOR of 0.95.
ISSN:2193-567X
1319-8025
2191-4281
DOI:10.1007/s13369-023-07898-3