Журналы →  CIS Iron and Steel Review →  2021 →  №1 →  Назад

Chemical Technologies
Название The pH and medium composition impact on the efficiency of electroflotation-based extraction of slightly soluble iron, chromium and manganese compounds from water solutions and physical-chemical properties of these compounds
DOI 10.17580/cisisr.2021.01.13
Автор V. A. Brodskiy, D. Yu. Zhukov, Yu. O. Malkova, V. A. Kolesnikov
Информация об авторе

Mendeleev University of Chemical Technology of Russia (Moscow, Russia):

V. A. Brodskiy, Cand. Chem., Associate Prof., Dept. “Technologies of inorganic substances and electrochemical processes”, e-mail: vladimir_brodsky@mail.ru
D. Yu. Zhukov, Cand. Eng., Associate Prof., Advisor to the Rector, e-mail: dzhukov35@yandex.ru
Yu. O. Malkova, Leading Eng.
V. A. Kolesnikov, Dr. Eng., Prof., Head of Dept. “Technologies of inorganic substances and electrochemical processes”

Реферат

The study demonstrates the pH and solution ion composition impact on the average hydrodynamic diameter dm and electrokinetic potential (ζ-potential) of the dispersed phase of slightly soluble ferrous metals compounds. We examined formation dispersed phases of slightly soluble Fe (III), Cr (III), and Mn (II) compounds in the presence of OН, CO32–, PO43– ions as precipitating agents and anionic, cationic, and non-ionic flocculating agents. The electroflotation-based extraction of slightly soluble ferrous metals compounds was found to be directly linked to dispersity and electrokinetic potential of particles, that depend on acidity and ionic medium composition. The maximal hydrodynamic diameter of dispersed phases of the slightly soluble Fe (III), Cr (III), and Mn (II) compounds were observed at isoelectric point and corresponded with pH value of the minimal dispersed phase solubility. In this case, electroflotation-based extraction was more efficient, the iron (III), manganese (II), and chromium (III) removal α reached 98, 96, and 83 %, respectively. Cationic flocculating agent additives increased the iron, manganese, and chromium extraction up to 99, 98, and 94 %, respectively. If carbonate and phosphate ions were added, the electrokinetic potential of compounds of all examined slightly soluble metals changed to negative values: –(12–19) mV in the presence of CO32– ions and –(35–43) mV in the presence of PO43– ions. This shift hindered coagulation and decreased electroflotation-based extraction of the dispersed phases, especially in case of manganese compounds (α ≤ 10%). Cationic and non-ionic flocculating agents additives balanced the high negative charge of the dispersed phases of slightly soluble ferrous metals compounds, enlarged the removal up to 98 % depending on the dispersed phase and flocculating agent.

The research was conducted under financial support of the Mendeleev University of Chemical Technology of Russia within the frame of investigations on strategic development directions, project No. 3-2020-033.

Ключевые слова Iron (III), chromium (III), manganese (II), dispersed phase, electrokinetic potential, particles size, electroflotation, phosphates, carbonates, and hydroxides
Библиографический список

1. Ershova E. V., Zublyuk E. V., Krishtopa O. A., Lapteva A. M., Renizova L. I., Rudnev A. V. Mineral and raw material base of ferrous and alloying metals in Russia. Razvedka i okhrana nedr. 2016. No. 9., pp. 88–95.
2. Sanitary Rules and Regulations 2.1.4.1074-01. Drinking water. Hygienic requirements to water quality from centralized systems of drinking water supply. Quality control. 90 p.
3. Water Framework Directive (WFD) 2000/60/EC: Directive 2000/60/EC of the European Parliament and of the Council of 23 October 2000 establishing a framework for Community action in the field of water policy. 73 p.
4. Vdovin K. N., Feoktistov N. A., Sinitskiy E. V., Gorlenko D. A., Durov N. A. Melting of high-manganese steel in the electric arc furnace. Technology. Message 1. Izvestiya vesshikh uchebnykh zavedeniy. Chernaya metallurgiya. 2015. Vol. 58. No. 10. pp. 735–739.
5. Soifer V. M. Deoxidation of acidic carbon electric steel by ferromanganese in a ladle. Metallurgiya mashinostroeniya. 2020. No. 5. pp. 2–5.
6. Kolpishon E. Yu., Ivanova M. V., Shitov E. V. Nitrogen-containing steels with equivalent composition. Chernye metally. 2007. No. 2. pp. 10–12.
7. Gorynin I. V., Malyshevskiy V. A., Kalinin G. Yu., Mushnikova S. Yu., Bannykh O. A., Blinov V. M., Kostina M. V. Corrosionresistant high-strength nitrogen steels. Voprosy materialovedeniya. 2009. No. 3 (59). pp. 7–16.
8. Aleksandrov V. I., Koshel A. A., Yudin V. S. Manganese-zinc elements. Innovatsii v nauke. 2017. No. 4 (65). pp. 62–65.
9. Beloglazov I. N., Zyryanova O. V., Saltykova S. N. Processing of manganese-bearing raw materials with manufacture of high-quality product. Zapiski gornogo instituta. 2013. Vol. 12. pp. 273–277.
10. Mohtashami R., Shang J. Q. Electroflotation for Treatment of Industrial Wastewaters: A Focused Review Environmental Process. 2019. pp. 1–29.
11. Kuokkanen V., Toivo K., Rämö J., Lassi U. Recent Applications of Electrocoagulation in Treatment of Water and Wastewater – A Review. Green and Sustainable Chemistry. 2013. No. 3. pp. 89–121.
12. Kolesnikov V. A., Ilyin V. I., Kapustin Yu. I. et al. Electroflotation technology for cleaning of waste waters at industrial works. Moscow, Khimiya. 2007. 304 p.
13. Romanov A. M. Electroflotation in Waste Water Treatment: Results and Perspectives. In: Gallios G. P., Matis K. A. (eds) Mineral Processing and the Environment. NATO ASI Series (Series 2: Environment). Springer, Dordrecht. 1998. Vol. 43. pp. 335–360.
14. Brodskiy V. A., Gaidukova A. M., Kolesnikov V. A., Ilyin V. I. Impact of medium pH on physical-chemical parameters and efficiency of electroflotation extraction of slightly soluble compounds of ferrous metals from water solutions. Khimicheskaya fizika. 2017. Vol. 36. No. 8. pp. 56–63.
15. Kokarev G. A., Kolesnikov V. A., Kapustin Yu. I. Intra-phase appearances on separation boundary oxide/solution in electrolyte. Moscow, Izd. Tsentr RKhTU. 2004. 72 p.

16. Poling L. General chemistry. Moscow, Mir. 1964. 583 p.
17. Atlas of Eh-pH diagrams. Intercomparison of thermodynamic databases. National Institute of Advanced Industrial Science and Technology Research Center for Deep Geological Environments. Naoto TAKENO. May 2005. 285 p.
18. Amanbaev T. R. Simulation of flotation process in dispersed systems. Teoreticheskie osnovy khimicheskoy tekhnologii (TOKhT). 2014. Vol. 48. No. 2. p. 203.
19. Belkacem M., Khodir M., Abdelkrim S. B. Treatment characteristics of textile wastewater and removal of heavy metals using the electroflotation technique. Desalination. 2008. Vol. 228, Nos. 1–3. p. 245.
20. Brodskiy V. A., Kolesnikov V. A., Gibin A. F., Ilyin V. I. Mechanism of charge forming in disperded particles of hardly soluble metal compounds in water solutions. Khimicheskaya fizika. 2012. Vol. 31. No. 10. p. 46.
21. Tzoupanos N. D., Zouboulis A. I. Coagulation–flocculation processes in water/wastewater treatment: the application of new generation of chemical reagents. 6th IASME/WSEAS international conference on heat transfer, thermal engineering and environment (HTE’08). pp. 309–317.
22. Bratby J. Coagulation and Flocculation in Water and wastewater Treatment. IWA Publishing, London, Seattle, 2006. 583 p.
23. Zaletova N. A. General phosphorus and phosphates in waste waters. Collection of scientific works based on the materials of International scientific and practical conference in 16 parts: Modern society, education and science. 2015. pp. 48–50.
24. Rubanov Yu. K., Tokach Yu. E., Nechaev A. F., Ognev M. N. The galvanic productions waste waters and sludges processing with the heavy metals ions extraction. European Journal of Natural History. 2009. No. 6. pp. 79–80.
25. Ripan R., Chetanu I. Inorganic chemistry. Vol. 2. Moscow, Mir. 1972. 871 p.
26. Kumok V. N., Kuleshova O. M., Karabin L. A. Solubility productions. Novosibirsk. Nauka. 1983. 267 p.
27. Brodskiy V. A. Role of surface parameters of dispersed phase and medium composition in intensification and rise of efficiency of electroflotation process in cleaning of waste waters. Dissertation … of a Candidate of Chemical Sciences. Mendeleev University of Chemical Technology of Russia. Moscow. 2012. 195 p.
28. Alam R., Shang J. Q., Khan A. H. Bubble size distribution in a laboratory-scale electroflotation study. Environ. Monit. Assess. 2017. Vol. 189. p. 193.

Полный текст статьи The pH and medium composition impact on the efficiency of electroflotation-based extraction of slightly soluble iron, chromium and manganese compounds from water solutions and physical-chemical properties of these compounds
Назад