Energy-exergy analysis of seawater reverse osmosis plants

In this paper, a seawater reverse osmosis desalination plant with various energy recovery systems is studied using exergy analysis. These energy recovery devices include turbines and pressure exchangers as well as infinite area based single and two-stage pressure retarded osmosis units. The appropri...

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Bibliographic Details
Published in:Desalination 2016-05, Vol.385, p.138-147
Main Authors: Qureshi, Bilal Ahmed, Zubair, Syed M.
Format: Article
Language:English
Subjects:
Desalination
Devices
Energy recovery
Exergy
Exergy analysis
Osmosis
Pressure retarded osmosis
Reverse osmosis
Sea water
Seawater
Turbines
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Summary:In this paper, a seawater reverse osmosis desalination plant with various energy recovery systems is studied using exergy analysis. These energy recovery devices include turbines and pressure exchangers as well as infinite area based single and two-stage pressure retarded osmosis units. The appropriate exergetic efficiency definition for such systems is mentioned. The effect of pump and turbine efficiency, salinity, temperature and mass ratio is studied using a validated program. In this regard, modified Van't Hoff constants for a large range of seawater surface temperatures are also determined. The best efficiency was obtained using the pressure exchanger for all systems investigated. Use of pressure retarded osmosis units as energy recovery devices provided efficiencies nearly equal to or less than the hydro-turbine. Thus, for the range investigated, it does not seem to be a viable energy recovery method for reverse osmosis units with seawater feed since constraints such as concentration polarization and finite area would further decrease performance. •Energy-exergy analysis of reverse osmosis units is done for seawater applications.•Various energy recovery devices including pressure retarded osmosis are evaluated.•Effect of salinity, pump and turbine efficiencies as well as mass ratio are studied.•Van’t Hoff constants for a range of seawater temperatures are also determined.•It is demonstrated that the pressure exchanger is the best energy recovery device.
ISSN:0011-9164
1873-4464
DOI:10.1016/j.desal.2016.02.009