We presented economic, energy, exergo-economic, and environmental analyses and multiobjective optimization (MOO) of seawater reverse osmosis (RO) desalination systems with boron restrictions. Exergo-economic unit cost for flows and exergy destruction… Click to show full abstract
We presented economic, energy, exergo-economic, and environmental analyses and multiobjective optimization (MOO) of seawater reverse osmosis (RO) desalination systems with boron restrictions. Exergo-economic unit cost for flows and exergy destruction for components were included. Life cycle assessment (LCA) principles with the contributions of construction and operating were introduced. An improved augmented e-constraint method was adopted for solving the MOO problems. Unnecessary iterations were avoided by bypass parameter. Results showed that the Pareto-solution with a weighting of 0.4 could provide good performances for all objective functions. The CO2 emissions reduction of 9.0% could be achieved, while the water cost is increased by 3.3%. Fixed cost dominates EUC. The environmental impact of construction is neglectable, while electricity consumption accounts for the largest share of CO2 emissions from 93.4% to 97.8%. The details of energy utilization for components, the irreversibility, and equipment...
               
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