Integrated approach in eco-design strategy for small RO desalination plants powered by photovoltaic energy

Reverse osmosis (RO) plants powered by photovoltaic (PV) panels at community scale for remote places are increasing in importance. However, RO recovery rates in these seawater desalination plants are usually below 40% because of non-optimized plant configurations. Low recovery rates increase both th...

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Bibliographic Details
Published in:Desalination 2018-06, Vol.435, p.246-258
Main Authors: Monnot, Mathias, Carvajal, Germán Darío Martínez, Laborie, Stéphanie, Cabassud, Corinne, Lebrun, Rémi
Format: Article
Language:English
Subjects:
Concentrate disposal
Energy storage
Environmental Engineering
Environmental Sciences
Optimum configuration
Productivity maximization
Reverse osmosis
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Summary:Reverse osmosis (RO) plants powered by photovoltaic (PV) panels at community scale for remote places are increasing in importance. However, RO recovery rates in these seawater desalination plants are usually below 40% because of non-optimized plant configurations. Low recovery rates increase both the global costs of the plant and the volume of concentrate discharge, which is an ecological issue. This study aims to determine the RO plant configuration that enables the highest recovery rate and leads to the lowest global costs for small PV RO plants. The choice of the plant configuration includes the type, number and arrangement of the RO modules, single or double stage configuration, the area of the PV panels, the possibility of using batteries, and of using evaporation ponds for concentrate disposal. Based on an “optimization procedure” and cost estimation, the best PV RO plant configurations were found according to the production needed. A 65% recovery rate could be possible in double stage plants producing more than 5m3·d−1 and would reduce costs. The use of a battery could reduce the costs in plants producing 5m3·d−1 because the extra cost of the battery would be compensated by the possibility of using fewer RO modules. [Display omitted] •New insights into the design of small-scale PV RO plants are opened.•Low recovery rates increase costs and concentrates' volume which is ecological issue.•The optimal PVRO plant configuration is dependent on the water production need.•A 65% recovery rate was reached in double stage with optimized arrangement of modules.•Increasing recovery rate is justified with evaporation pond as concentrate disposal.
ISSN:0011-9164
1873-4464
DOI:10.1016/j.desal.2017.05.015