Water purification in innovative ecosystems.
Authors
Liubov Skokova
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The article examines the development and implementation of integrative technological solutions for the treatment, purification, and regeneration of contaminated process water with the aim of its recirculation. It describes a scalable, modular, and adaptive system based on synchronized electrochemical and hydrodynamic processes that enable effective removal of organic and inorganic impurities, including metals, sulfates, phosphates, oils, and other contaminants. Particular attention is given to the design of an electrochemical reactor with parallel electrode cells and a synchronized power supply system, ensuring stable operation under fluctuating conditions.
The study highlights the role of coagulation, sedimentation, and redox reactions in forming removable impurity complexes, as well as the importance of automated control systems with feedback for process stabilization. The proposed solution is characterized by low energy consumption, high efficiency, and adaptability to varying conditions, including low-conductivity water. Its modular design enables integration into larger systems and supports autonomous operation.
The article also outlines structural and technological features that enhance performance, such as synchronized current supply and optimized flow conditions, demonstrating improved treatment efficiency and environmentally sustainable water treatment for industrial and wastewater applications.
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Authors
Liubov Skokova
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