Iliev, I.K.; Chichirov, A.A.; Filimonova, A.A.; Chichirova, N.D.; Pechenkin, A.V.; Beloev, I.H. Development of Hybrid Membrane Systems for Highly Mineralized Waste Utilization in the Power Industry. Energies2023, 16, 6166.
Iliev, I.K.; Chichirov, A.A.; Filimonova, A.A.; Chichirova, N.D.; Pechenkin, A.V.; Beloev, I.H. Development of Hybrid Membrane Systems for Highly Mineralized Waste Utilization in the Power Industry. Energies 2023, 16, 6166.
Iliev, I.K.; Chichirov, A.A.; Filimonova, A.A.; Chichirova, N.D.; Pechenkin, A.V.; Beloev, I.H. Development of Hybrid Membrane Systems for Highly Mineralized Waste Utilization in the Power Industry. Energies2023, 16, 6166.
Iliev, I.K.; Chichirov, A.A.; Filimonova, A.A.; Chichirova, N.D.; Pechenkin, A.V.; Beloev, I.H. Development of Hybrid Membrane Systems for Highly Mineralized Waste Utilization in the Power Industry. Energies 2023, 16, 6166.
Abstract
Hybrid reverse osmosis electrodialysis systems make it possible to obtain solutions with a higher concentration of components compared to single electrodialysis treatment, i.e. more efficient separation of brine and pure water. The article proposes experimental and pilot-industrial studies of a hybrid membrane system operation using industrial wastewater for the disposal of liquid waste from an ion-exchange chemical-desalting water treatment plant of a thermal power plant, followed by a calculation of economic efficiency and an analysis of the environmental feasibility of their use. The developed technological scheme offers separate processing of acidic and alkaline waste regeneration solutions using calcium carbonate reagent and desalination on baromembrane and electromembrane units to obtain clean water and dry residue. The hybrid system includes a booster filter press and an evaporator. The hybrid system makes it possible to provide a thermal power plant with a "zero discharge" with a minimum consumption of reagents and electricity, as well as return all water from wastewater to the power plant cycle.
Keywords
reverse osmosis; electrodialysis; hybrid process; energy consumption; brine management; zero liquid discharge; reverse osmosis; electrodialysis; hybrid process; energy consumption; brine management; zero liquid discharge
Subject
Engineering, Chemical Engineering
Copyright:
This is an open access article distributed under the Creative Commons Attribution License which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.