Saving energy consumption and CO2 emission from sustainable efficient operating zones in inland electrodialysis reversal desalination

Saving energy consumption and CO2 emission from sustainable efficient operating zones in inland electrodialysis reversal desalination

A pre-design parameter, system efficiency (SE) was modeled for operations with water recovery rate through cell pairs (WRRTC)>0.5. The variables for equation were validated with data from a pilot scale study of electrodialysis reversal (EDR). The correlation between experimental and predicted SE...

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Bibliographic Details
Main Author: Maung Thein Myint
Format: Article
Language:English
Published: Elsevier 2014-03-01
Series:Water Resources and Industry
Subjects:
Concentration polarization
Demineralization
Polarization degree
Specific dilute flow rate
System efficiency
Water recover rate through cell pair
Online Access:http://www.sciencedirect.com/science/article/pii/S2212371714000043
Description
Summary:A pre-design parameter, system efficiency (SE) was modeled for operations with water recovery rate through cell pairs (WRRTC)>0.5. The variables for equation were validated with data from a pilot scale study of electrodialysis reversal (EDR). The correlation between experimental and predicted SE are good at overall R2 0.924 with significant p 0.000. System efficiency-to-polarization degree ratio is inversely linear with demineralization, WRRTC, and polarization degree (PD). The most sensitive operational parameter was found to be PD. The sustainable efficient zones for PD, WRRTC, and demineralization were found to be 1040–1315 (A/m2) (L/eq), 0.57–0.67, and 62–90%. By operating EDR in this zone, 8–15% of energy consumption and CO2 emission were saved.
ISSN:2212-3717

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