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The results of electrochemical processing of spent acidic, neutral, and alkaline sulfate-chloride-containing regenerative solutions in two- and three-chamber electrolyzers are presented. It has been determined that the highest current efficiency for the products of electrodialysis can be achieved in the presence of hardness ions when processing acidic sulfate-containing solutions using three-chamber electrolyzers. It has been established that during electrodialysis of alkaline solutions after regeneration of anionites containing chloride ions, accumulation of alkali occurs in the cathodic region, and in the anodic region, chloride ions accumulate due to diffusion through the anion exchange membrane during the first stage, followed by preferential oxidation of chloride ions with liberation of free chlorine during the second stage. It has been shown that electrodialysis can effectively solve the problem of comprehensive processing of neutral, alkaline, and acidic regenerative sulfate-chloride-containing solutions, with the production of alkali and acid at concentrations suitable for reuse in regeneration processes.
Słowa kluczowe
Czasopismo
Rocznik
Tom
Strony
171--180
Opis fizyczny
Bibliogr. 16 poz.
Twórcy
autor
- Dr. Hab Eng.; Department of Ecology and Technology of Plant Polymers National Technical University of Ukraine“Igor Sikorsky Kyiv Polytechnic Institute”, 37 Prospect Beresteiskyi (former Peremohy), Kiev, 03056, Ukraine
autor
- Dr. Hab Eng.; Department of Ecology and Technology of Plant Polymers National Technical University of Ukraine“Igor Sikorsky Kyiv Polytechnic Institute”, 37 Prospect Beresteiskyi (former Peremohy), Kiev, 03056, Ukraine
autor
- Dr. Eng.; Automation Hardware and Software Department National Technical University of Ukraine “Igor SikorskyKyiv Polytechnic Institute”, 37 Prospect Beresteiskyi (former Peremohy), Kiev, 03056, Ukraine
- Departmentof Heat-Physical Problems of Heat Supply Systems, Institute of Engineering Thermophysics of National Academyof Sciences, 2a, Marii Kapnist (Zhelyabova) Str., Kyiv, 03057, Ukraine
autor
- Dr. Eng.; Department of Heat-Physical Problems of Heat Supply Systems Institute of Engineering Thermophysicsof National Academy of Sciences, 2a, Marii Kapnist (Zhelyabova) Str., Kyiv, 03057, Ukraine
autor
- Dr. Eng.; Department of Heat-Physical Problems of Heat Supply Systems Institute of Engineering Thermophysicsof National Academy of Sciences, 2a, Marii Kapnist (Zhelyabova) Str., Kyiv, 03057, Ukraine
autor
- Dr. Eng..; Department of Chemical, Polymer and Silicate Engineering National TechnicalUniversity of Ukraine “Igor Sikorsky Kyiv Polytechnic Institute”, 37 Prospect Beresteiskyi (former Peremohy),Kiev, 03056, Ukraine
Bibliografia
- [1] Liu D., Edraki M., Malekizadeh A., Schenk P. M., Berry L. (2019). Introducing the hydrate gel membrane technology for filtration of mine tailings. Minerals Engineering, 135, 1–8.
- [2] Haan T. Y., Shah M., Chun H. K., Mohammad A. W. (2018). A study on membrane technology for surface water treatment: Synthesis, characterization and performance test. Membrane Water Treatment, 9(2), 69–77.
- [3] Trus, I., Radovenchyk, I., Halysh, V., Skiba, M., Vasylenko, I., Vorobyova, V., Hlushko, O., and Sirenko, L. (2019). Innovative Approach in Creation of Integrated Technology of Desalination of Mineralized Water. Journal of Ecological Engineering, 20(8), 107–113.
- [4] Trus I., Gomelya M., Tverdokhlib M., Halysh V., Radovenchyk I., Benatov D. (2022). Purification of Mine Waters Using Lime and Aluminum Hydroxochloride. Ecological Engineering & Environmental Technology, 3(5), 169–176.
- [5] Trus I., Gomelya M. (2021). Desalination of mineralized waters using reagent methods. Journal of Chemistry and Technologies, 29(3), 417–424.
- [6] Kim J. E., Phuntsho S., Chekli L., Choi J. Y., Shon H. K. (2018). Environmental and economic assessment of hybrid FO-RO/NF system with selected inorganic draw solutes for the treatment of mine impaired water. Desalination, 429, 96–104.
- [7] Gomelya M., Hrabitchenko V., Trokhymenko A., Shabliy T. (2016). Research into ion exchange softening of highly mineralized waters. Easten-Europen Journal of Enterprise Technologies, 4/10(82), 4–9.
- [8] Kinnunen P., Kyllönen H., Kaartinen T., Mäkinen J., Heikkinen J., Miettinen V. (2018). Sulphate removal from mine water with chemical, biological and membrane technologies. Water Science and Technology, 1, 194–205.
- [9] Akhter M., Habib G., and Qamar S. (2018). Application of Electrodialysis in Waste Water Treatment and Impact of Fouling on Process Performance. Journal of Membrane of Science&Technology, 8(2), 1–8.
- [10] Trus, I. M., Hrabitchenko, V. M., Homela, M. D. (2013). Otymannia sirkhanoi kysloty pry elektrokhimichnii pererobtsi eluiativ, shcho mistiat sylfaty [Obtaining sulfuric acid during the electrochemical processing of eluates containing sulfates]. Vostochno-Evropeiskii zhurnal peredovykh tekhnologii, 4/6(64), 10–13.
- [11] Trus, I. M., Homela, M. D., Radovenchyk, Ya. V. (2013). Sposib kontsentruvannia rozchyniv luhu pry elektrokhimichnii pererobtsi eluiativ, scho mistiat soli natriiu [Method of concentration of alkaline solutions during the electrochemical processing of eluates containing sodium salts]. Vostochno-Evropeiskii zhurnal peredovykh tekhnologii, 5/6(65), 20–23. (In Ukraine).
- [12] Pylypenko, A. T., Goronovsky, I. T., & Grebenyuk, V. D. (1985). Kompleksnaya pererabotka shakhtnikh vod [Integrated processing of mine waters]. Kyiv: Tekhnika, 183. (In Russian).
- [13] Melnik, L. O. (2016). Naukovi zasady vydalennia toksychnykh mikrokomponentiv manganu, boru, arsenu v protsesakh membranoho oprisnennia [Scientific principles of removing toxic microcomponents of manganese, boron, and arsenic in membrane desalination processes]. Doctoral dissertation, 21.06.01, Kyiv, National Academy of Sciences of Ukraine, A. V. Dumansky Institute of Colloid Chemistry and Water Chemistry, 320. (In Ukraine).
- [14] Nabyvanets, B. Y., Osadchiy, V. I., Osadcha, N. M., & Nabyvanets, Y. B. (2007). Analytychna khimiya poverkhnevykh vod: monohrafiya [Analytical chemistry of surface waters: monograph]. Kyiv: Naukova dumka, 455. (In Ukraine).
- [15] Lurie, Y. Y. (1989). Spravochnik po analiticheskoy khimii [Handbook of analytical chemistry]. Moscow: Khimiya, 448. (In Russian).
- [16] Pisarska, B., & Dylevski, R. (2005). Analiz usloviy polucheniya H2SO4 i NaOH iz rastvorov sulfata natriya metodom elektrodializa [Analysis of conditions for obtaining H2SO4 and NaOH from sodium sulfate solutions by electrodialysis method]. Zhurnal prikladnoy khimii, 78(8), 1311–1316. (In Russian).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-86a4dc50-94a9-4180-85e8-3be19203c8b4