Abstract
Desalination of brackish groundwater (BW) is an effective approach to augment water supply, especially for inland regions that are far from seawater resources. Brackish water reverse osmosis (BWRO) desalination is still subject to intensive energy consumption compared to the theoretical minimum energy demand. Here, we review some of the BWRO plants with various system arrangements. We look at how to minimize energy demands, as these contribute considerably to the cost of desalinated water. Different configurations of BWRO system have been compared from the view point of normalized specific energy consumption (SEC). Analysis is made at theoretical limits. The SEC reduction of BWRO can be achieved by (i) increasing number of stages, (ii) using an energy recovery device (ERD), or (iii) operating the BWRO in batch mode or closed circuit mode. Application of more stages not only reduces SEC but also improves water recovery. However, this improvement is less pronounced when the number of stages exceeds four. Alternatively and more favourably, the BWRO system can be operated in Closed Circuit Desalination (CCD) mode and gives a comparative SEC to that of the 3-stage system with a recovery ratio of 80%. A further reduction of about 30% in SEC can be achieved through batch-RO operation. Moreover, the costly ERDs and booster pumps are avoided with both CCD and batch-RO, thus furthering the effectiveness of lowering the costs of these innovative approaches.
Highlights
Water is vital for all living creatures on Earth
Taking the brackish water reverse osmosis (BWRO) plant in Saja’a UAE as an example, the feed water of the plant is from a well water field with average total dissolved solids (TDS) being 3261 mg/L, and the reverse osmosis (RO) feed pressure is maintained in the range of 18–20 bar
We have showed that brackish water composition varies widely among different locations; proper analysis of water composition should be conducted prior to the BWRO plant design
Summary
Water is vital for all living creatures on Earth. About 97% of the water is seawater in oceans, leaving only 2.5% of the water on the Earth as fresh water, and about 99% of that water is in ice and underground. For the large amount of brine from desalination facilities in Texas, a proper treatment that can overcome the environmental problems associated with the direct discharge of RO brine increases costs considerable [5]. Besides brine management, another major challenge is the energy demand of inland BWRO systems, which is again linked to the cost of desalinated water. Improving the energy efficiency of BW desalination, increasing water output per land area, minimizing the discharged brine, and eventually reducing cost are some of the desirable properties when designing the BWRO system. We further elucidate the advantages of these innovative systems in real-world applications
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