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Wastewaters from dairy processing factories contaminated with α-oxypropionic acid were monitored. Theoretical analysis of industrial wastewater treatment methods on zeolites of Sokyrnytsia deposit was carried out. The process of sorption of α-oxypropionic (α-oxypropionic) acid by natural zeolite of Sokyrnytsia deposit was considered. It was established that the most economically advantageous and safe is the method of adsorption using a natural sorbent - zeolite, which provides the lowest concentration of contaminants in treated wastewaters from dairies. An assessment of their number, localization features and measures of toxicological impact on the environment was done. The existing theoretical apparatus of description of adsorption processes was analyzed. The sorption properties of natural zeolite (clinoptilolite of Sokyrnytsia deposit) and activated carbon to α-oxypropionic acid were tested. Equilibrium values of adsorption capacity were calculated and corresponding isotherms at a temperature of 20° С were constructed. The porosity of the sorbent and its influence on the sorption properties were studied by the methods of physicochemical analysis. Infrared spectroscopic and electron microscopic studies confirmed the presence of the process of sorption by the surface of the internal pores of the zeolite of α-oxypropionic acid molecules. Experimental studies have confirmed the possibility of using natural zeolite for wastewater treatment of dairy factories. It was experimentally confirmed by physicochemical methods of analysis (electron microscopy, IR spectroscopy, microprobe analysis, mercury porometry) and was established that the process takes place both by the mechanism of ion exchange and physical adsorption. The content of carbon radicals in the zeolite matrix after the sorption process was confirmed by X-ray spectral microanalysis. The ability of zeolite to adsorb organic carboxylic acid radicals was confirmed by the results of IR spectroscopic studies. On the IR spectra there are strips of deformation and valence oscillations of the groups of the crystal lattice of the zeolite Si-O, Si-O-SiOH: 452, 990–1210, 1638, 3368 cm-1. The oscillation spectra of free OH groups in the region of 2600 cm-1 were revealed.
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Czasopismo
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Strony
43--56
Opis fizyczny
Bibliogr. 27 poz., rys., tab.
Twórcy
autor
- Lviv National Polytechnic University, Viacheslav Chornovil Institute of Sustainable Development, Department of Ecology and Sustainable Environmental Management, 79013, Lviv, Ukraine
autor
- Lviv National Polytechnic University, Viacheslav Chornovil Institute of Sustainable Development, Department of Ecology and Sustainable Environmental Management, 79013, Lviv, Ukraine
autor
- Lviv National Polytechnic University, Viacheslav Chornovil Institute of Sustainable Development, Department of Ecology and Sustainable Environmental Management, 79013, Lviv, Ukraine
autor
- Lviv National Polytechnic University, Viacheslav Chornovil Institute of Sustainable Development, Department of Ecology and Sustainable Environmental Management, 79013, Lviv, Ukraine
Bibliografia
- 1. Karadag D., Köroğlu O. E., Ozkaya B., Cakmakci M.: A review on anaerobic biofilm reactors for the treatment of dairy industry wastewater. Process Biochemistry. 50.2 (2015) 262-271.
- 2. Iervolino G., Zammit I., Vaiano V., Rizzo L.: Limitations and prospects for wastewater treatment by UV and visible-light-active heterogeneous photocatalysis: a critical review. Topics in Current Chemistry. 378(1) (2020). 7.
- 3. Chezeau B., Boudriche L., Vial C., Boudjemaa A.: Treatment of dairy wastewater by electrocoagulation process: Advantages of combined iron/aluminum electrodes. Separation Science and Technology. 55(14) (2020) 2510-2527.
- 4. Trujillo-Rodríguez M. J., Pacheco-Fernández I., Taima-Mancera I., Díaz J. H. A., Pino V.: Evolution and current advances in sorbent-based microextraction configurations. Journal of Chromatography A. (2020). 461670.
- 5. Garcia-Rodríguez A., Matamoros V., Fontàs C., Salvad, V.: The ability of biologically based wastewater treatment systems to remove emerging organic contaminants—a review. Environmental Science and Pollution Research. 21(20) (2014) 11708-11728.
- 6. Kolev Slavov A.: General characteristics and treatment possibilities of dairy wastewater–a review. Food Technology and Biotechnology. 55(1) (2017) 14-28.
- 7. Farizoglu B., Uzuner S.: The investigation of dairy industry wastewater treatment in a biological high performance membrane system. Biochemical Engineering Journal. 57 (2011) 46-54.
- 8. Ahmad T., Aadil R. M., Ahmed, H. i in.: Treatment and utilization of dairy industrial waste: A review. Trends in Food Science & Technology. 88 (2019) 361-372.
- 9. Lohse M. S., Stassin T., Naudin G., Wuttke S., Ameloot R., De Vos D., Bein T.: Sequential pore wall modification in a covalent organic framework for application in α-oxypropionic acid adsorption. Chemistry of Materials. 28 (2016) 626-631.
- 10. Ogunleye O. O., Adeniyi A. G., Durowoju M. O.: Factorial design based optimisation of crevice corrosion for type 304 stainless steel in chloride solutions. Advances in Materials Science. 16(2) (2016) 5-20.
- 11. Sabadash V., Gumnitsky J., Lyuta O. Combined Adsorption of the Copper and Chromium Cations by Clinoptilolite of the Sokyrnytsya Deposit. Journal of Ecological Engineering. 21 (2020) 42-46.
- 12. Polupan Y., Bashcheko M., Rieznykova N., Priyma S.: Genetic resources of dairy and beef cattle breeding in Ukraine. Zhivotnov'dni Nauki/Bulgarian Journal of Animal Husbandry. 57 (2020) 3-12.
- 13. Kausar A., Ullah W., Muhammad B., Siddiq M.: Novel mechanically stable, heat resistant and nonflammable functionalized polystyrene/expanded graphite nanocomposites. Advances in Materials Science. 14 (2014) 61-74.
- 14. Ates A., Akgül G.: Modification of natural zeolite with NaOH for removal of manganese in drinking water. Powder Technology. 287 (2016) 285-291.
- 15. Li Y., Li L., Yu J.: Applications of zeolites in sustainable chemistry. Chem. 3 (2017) 928-949.
- 16. Sakalova H., Malovanyy M., Vasylinycz T., Palamarchuk O., Semchuk J.: Treatment of effluents from ions of heavy metals as display of environmentally responsible activity of modern businessman. Journal of Ecological Engineering, 20 (2019) 167-176.
- 17. Sabadash V.V., Givlyud A.M., Gumnitsky Y.M.: Investigation of α-oxypropionic acid adsorption under dynamic conditions. Scientific Bulletin of NLTU of Ukraine. 26 (3) (2016) 333-338.
- 18. Sabadash V.V., Givlyud A.N., Gumnitsky Y.M.: Investigation of intradiffusion kinetics of α-oxypropionic acid sorption by natural zeolite. Bulletin of Vinnytsia Polytechnic Institute. (2) (2016) 9-14.
- 19. Hyvlud A., Sabadash V., Gumnitsky, J., Ripak, N.: Statics and kinetics of albumin adsorption by natural zeolite. Chemistry & Chemical Technology. 1 (13) (2019) 95-100.
- 20. Sabadash V. V., Givlyud A. M., Gumnitsky Y. M.: Investigation of α-oxypropionic acid adsorption under dynamic conditions. Scientific Bulletin of NLTU of Ukraine. 26 (3) (2016) 333-338.
- 21. Shi G., Guan Y., Liu G., Müller A.J., Wang D.: Segmental Dynamics Govern the Cold Crystallization of Poly (α-oxypropionic acid) in Nanoporous Alumina. Macromolecules 52 (2019) 6904-6912.
- 22. Zhang L., Theng D.S., Du Y., Xi S., Huang L., Gao F., Borgna A.: Selective conversion of α-oxypropionic acid to acrylic acid over alkali and alkaline-earth metal co-modified NaY zeolites. Catalysis Science & Technology. 7 (2017) 6101-6111.
- 23. Czekaj I., Sobuś N.: Cluster model DFT study of α-oxypropionic acid dehydration over Fe and Sn-BEA zeolite. Current Chemistry Letters. 8 (2019) 187-198.
- 24. Sobieszczyk S., Melaniuk M., Zieliński A.: Bioactive core material for porous load-bearing implants. Advances in Materials Science. 12(3) (2012) 25-36.
- 25. Gashchin O.R., Viten’ko T.N.: The combined effect of hydrodynamic cavitation, hydrogen peroxide, and silver ions on the Escherichia coli microorganisms. Journal of Water Chemistry and Technology. 33(4) (2011)266.
- 26. Dusselier M., Van Wouwe P., Dewaele A., Jacobs P.A., Sels B.F. Shape-selective zeolite catalysis for bioplastics production. Science. 349(6243) (2015) 78-80.
- 27. Gyvljud A., Sabadash V., Gumnitskij J. The kinetics of oxypropionic acid on natural zeolite. Litteris et Artibus. Lviv Polytechnic Publishing House. (2015) 450-451.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).
Typ dokumentu
Bibliografia
Identyfikator YADDA
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