Email this article Concentration distribution of molecules and particles in a chromium-containing model system: Fe-K2Cr2O7-NaCl-H2SO4-H2O at different temperatures of electrocoagulation process
- Authors: Maimekov Z.K.1, Sambaeva D.A.2, Izakov Z.B.1, Shaikieva N.T.1, Dolaz M.1, Kob’ya M.1
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Affiliations:
- Manas Kyrgyz-Turkish University
- Razzakov Kyrgyz State Technical University
- Issue: Vol 59, No 2 (2025)
- Pages: 90-99
- Section: Articles
- Published: 15.04.2025
- URL: https://journals.rcsi.science/0040-3571/article/view/308934
- DOI: https://doi.org/10.31857/S0040357125020082
- EDN: https://elibrary.ru/ndohry
- ID: 308934
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Abstract
Thermodynamic modeling of the electrocoagulation process in the systemFe-K2Cr2O7-NaCl-H2SO4-H2Oat wide limits of temperature change (278-300 K) has been carried out for the purpose of water purification from chromium (Cr6+). Physicochemical (pH, I, Eh, Cp) and thermodynamic (H, S, U, G) parameters of the system at the established optimal ratios of the initial components have been calculated. Taking into account the calculated data the experimental research was carried out and the influence on the electrocoagulation processes was revealed: pH, current, type and concentration of electrolytes. The concentration distribution of individual molecules and particles (cations, anions) was established, including: Cr2+, Cr3+, CrO+, CrOH2+, Fe+, FeOH+, FeOH2+in solution and thereby eliminating the use of ion chromatography for analytical purposes. AnEh-pHdiagram showing the fields of presence of various forms of chromium has been drawn up, and a formula for calculating the value of the redox potential as a function of solution pH has been obtained. It is shown that Eh> 0, i.e., the medium is oxidizing, and the formation ofCr3+in concentrated solution (I > 0.8) was observed. The electrocoagulation process achieved the binding of sulfur and iron in the form of FeS2and followed by the production ofFe(ОН)3and co-precipitation ofCr(OH)3.The degree of water purification from chromium was more than 97% (reduction ofCr6+in water from 100 mg/L to 2.29-2.30 mg/L).
About the authors
Z. K. Maimekov
Manas Kyrgyz-Turkish University
Email: zarlyk.maymekov@manas.edu.kg
Bishkek, Kyrgyz Republic
D. A. Sambaeva
Razzakov Kyrgyz State Technical University
Email: zarlyk.maymekov@manas.edu.kg
Bishkek, Kyrgyz Republic
Z. B. Izakov
Manas Kyrgyz-Turkish University
Email: zarlyk.maymekov@manas.edu.kg
Bishkek, Kyrgyz Republic
N. T. Shaikieva
Manas Kyrgyz-Turkish University
Email: zarlyk.maymekov@manas.edu.kg
Bishkek, Kyrgyz Republic
M. Dolaz
Manas Kyrgyz-Turkish University
Email: zarlyk.maymekov@manas.edu.kg
Bishkek, Kyrgyz Republic
M. Kob’ya
Manas Kyrgyz-Turkish University
Author for correspondence.
Email: zarlyk.maymekov@manas.edu.kg
Bishkek, Kyrgyz Republic
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