Tytuł artykułu
Treść / Zawartość
Pełne teksty:
Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
As a result of the anthropogenic activity and the continuous increase in the scale of water consumption, surface and groundwater, which are sources of freshwater, have been degraded. Today, most water sources have high iron content. Contamination of groundwater with iron and other metals can occur due to the development of ore deposits and the operation of quarries. The existing technologies solve this problem only partially. Ions of heavy metals are toxic and dangerous for living organisms, including human beings. In this regard, it is important to develop effective methods of water treatment of various pollutants. Today, pollution of water bodies with iron ions has reached a critical level. This creates a problem for many regions not only in Ukraine, but also far beyond its borders. The problem is urgent and needs to be solved. When the pH value in water is less than 6.8–7.0 and the concentration of iron is high, it is advisable to use a combination of a number of methods with the introduction of reagents in order to perform deep purification. The reagent method of deironing is implemented by treating the source water with a suspension of lime water Ca(OH)2. This approach allows deironing water effectively, but its implementation is accompanied by the formation of a large amount of sludge, which must be disposed of. An effective way to dispose of such precipitates is their use as a chemical additive in the production of cement, which was confirmed by the conducted research.
Wydawca
Rocznik
Tom
Strony
116--123
Opis fizyczny
Bibliogr. 43 poz., rys.
Twórcy
autor
- Department of Ecology and Technology of Plant Polymers, Faculty of Chemical Engineering, National Technical University of Ukraine "Igor Sikorsky Kyiv Polytechnic Institute", Peremogy Av. 37/4, 03056 Kyiv, Ukraine
autor
- Department of Ecology and Technology of Plant Polymers, Faculty of Chemical Engineering, National Technical University of Ukraine "Igor Sikorsky Kyiv Polytechnic Institute", Peremogy Av. 37/4, 03056 Kyiv, Ukraine
autor
- Department of Ecology and Technology of Plant Polymers, Faculty of Chemical Engineering, National Technical University of Ukraine "Igor Sikorsky Kyiv Polytechnic Institute", Peremogy Av. 37/4, 03056 Kyiv, Ukraine
autor
- Department of Ecology and Technology of Plant Polymers, Faculty of Chemical Engineering, National Technical University of Ukraine "Igor Sikorsky Kyiv Polytechnic Institute", Peremogy Av. 37/4, 03056 Kyiv, Ukraine
Bibliografia
- 1. Aziz H.A., Tajarudin H.A., Wei T.H.L. et al. 2020. Iron and manganese removal from groundwater using limestone filter with iron-oxidized bacteria. Int. J. Environ. Sci. Technol. 17, 2667–2680.
- 2. Biela R., Kucera T. 2016. Efficacy of sorption materials for nickel, iron and manganese removal from water. Procedia Eng. 162, 56–63.
- 3. Chaurasia M. and Srivastava S.K. 2020. Evaluation of Iron and Manganese Levels from Ramgarh Lake, Gorakhpur, U.P., India. Nature Environment and Pollution Technology. 19, 1, 373-377.
- 4. Choo K., Lee H., Choi S. 2005. Iron and manganese removal and membrane fouling during UF in conjunction with prechlorination for drinking water treatment. J. Membr. Sci. 267, 18–26.
- 5. Dabrowski A., Hubicki Z., Podkoscielny P., Robens E. 2004. Selective removal of heavy metal ions from waters and industrial wastewaters by ion-exchange method. Chemosphere. 56, 2, 91.
- 6. Ellis D., Bouchard C., Lantagne G. 2000. Removal of iron and manganese from groundwater by oxidation and microfiltration. Desalination. 130, 3, 255-264.
- 7. Fazzo L., Minichilli F., Santoro M., Ceccarini A., Seta M.D., Bianchi F., Comba P., Martuzzi M. 2017. Hazardous waste and health impact: a systematic review of the scientific literature. Environ Health. 16, 107.
- 8. Flannigan K.L., Wallace J.L. 2015. Hydrogen sulfi de-based anti-infl ammatory and chemopreventive therapies: an experimental approach. Current Pharmaceutical Design. 21, 21, 3012-3022.
- 9. Gomelya N.D., Trus I.N., Nosacheva Y.V. 2014. Water purification of sulfates by liming when adding reagents containing aluminum. Journal of Water Chemistry and Technology. 36. 2, 70-74.
- 10. Gubari M.Q., Zwain H.M., Al-Zahiwat M.M., Alekseeva N.V. 2021. Characteristics of the MK- 40 and MA-40 Membranes for Industrial Wastewater Treatment – A Review. Ecol. Eng. Environ. Technol. 1, 39–50.
- 11. Halysh V., Trus I., Gomelya M., Trembus I., Pasalskiy B., Chykun N., Trokhymenko G., Remeshevska I. 2020a. Utilization of Modified Biosorbents Based on Walnut Shells in the Processes of Wastewater Treatment from Heavy Metal Ion. J. Ecol. Eng. 21(4), 128–133.
- 12. Halysh V., Trus I., Nikolaichuk A., Skiba M., Radovenchyk I., Deykun I., Vorobyova V., Vasylenko I., Sirenko L. 2020b. Spent Biosorbents as Additives in Cement Production. Journal of Ecological Engineering. 21, 2, 131–138.
- 13. Hashim K.S., Shaw A., Al Khaddar R., Pedrola M.O., Phipps D. 2017. Iron removal, energy consumption and operating cost of electrocoagulation of drinking water using a new flow column reactor. J. Environ. Manage. 189, 98–108.
- 14. Hryhorenko L.V. 2019. Water Quality Assessment in the Mining and Industrial Region on the Example of Karachunovskyi Reservoir in Ukraine. Advanced Engineering Forum. 33, 19–31.
- 15. Hu F.P., He W., Tang C.C. 2012. Purification efficiency study of biological treatment of iron and manganese for groundwater. Adv. Mater. Res. 599, 383–386.
- 16. Hu H., Zhang Q., Li X., Wu L., Liu Y. 2020. Efficient heterogeneous precipitation and separation of iron in copper-containing solution using dolomite. Separation and Purification Technology, 248.
- 17. Jaishankar M., Tseten T., Anbalagan N., Mathew B.B., Beeregowda K.N. 2014. Toxicity, mechanism and health effects of some heavy metals. Interdisciplinary Toxicology. 7(2), 60–72.
- 18. Kasim N., Mohammad A.W., Sheikh Abdullah S.R. 2017. Iron and manganese removal by nanofiltration and ultrafiltration membranes: Influence of pH adjustment. Malaysian Journal of Analytical Science. 21, 149–158.
- 19. Khadse G.K., Patni P.M., Labhasetwar P.K. 2015. Removal of iron and manganese from drinking water supply. Sustain. Water Resour. Manag. 1, 157–165
- 20. Khatri N., Tyagi S. 2015. Influences of natural and anthropogenic factors on surface and groundwater quality in rural and urban areas. Front. Life Sci. 8, 23–39.
- 21. Khatria N., Tyagia S., Rawtani D. 2017. Recent strategies for the removal of iron from water: A review. Journal of Water Process Engineering. 19, 291–304.
- 22. Khilchevskyi V.К., Kurylo S.М., Sherstyuk N.P 2018. Chemical composition of different types of natural waters in Ukraine. Journ.Geol.Geograph. Geoecology. 27, 1, 68-80.
- 23. Korchef A., Kerkeni I., Amor M.B., Galland S., Persin F. 2009. Iron removal from aqueous solution by oxidation, precipitation and ultrafiltration. Desalination and Water Treatment. 9, 1-3, 1–8.
- 24. Li N., Hefferren J.J., Li K. 2013. Quantitative Chemical Analysis, World Scientific Pub Co Inc.
- 25. Linnik P.N., Zhezherya V.A., Linnik R., Ivanechko Ya. S. 2012. Concentrations of aluminium, iron, and copper in water of some Shatskiye Lakes and specificity of their distribution among different forms of occurrence. Russian Journal of General Chemistry. 82, 13, 2226-2238.
- 26. Linnik P.N., Zhezherya V.A., Linnik R.P. 2018. Iron in Natural Surface Waters of Ukraine: Content, Peculiarities of Migration and Biological Role. Hydrobiological Journal. 54, 5, 63-80.
- 27. Martínez-Cruz A., Fernandes A., Ramos F., Soares S., Correia P., Baía A., Lopes A., Carvalho F. 2021. An Eco-Innovative Solution for Reuse of Leachate Chemical Precipitation Sludge: Application to Sanitary Landfill Coverage. Ecol. Eng. Environ. Technol. 2, 52–58.
- 28. Pleasant S., O’Donnell A., Powell J., Jain P., Townsend Timothy. 2014. Evaluation of air sparging and vadose zone aeration for remediation of iron and manganese-impacted groundwater at a closed municipal landfill. Sci. Total Environ. 485-486, 31–40.
- 29. Radovenchyk I., Trus I., Halysh V., Krysenko T.,Chuprinov E., Ivanchenko A. 2021. Evaluation of Optimal Conditions for the Application of Capillary Materials for the Purpose of Water Deironing. Ecol. Eng. Environ. Technol. 2, 1–7.
- 30. Shevchenko O., Kornienko S., Dihtyaruk O. 2013. Analysis of the reasons for the increase in the concentration of iron in the groundwater of the water intakes of Shepetivka. Visnyk, Kyiv, Kyiv National University named after Taras Shevchenko. (In Ukrainian)
- 31. Shkolnikov V., Bahga S.S., Santiago J.G. 2012. Desalination and hydrogen, chlorine, and sodium hydroxide production via electrophoretic ion exchange and precipitation. Phys. Chem. Chem Phys. 14, 32, 11534–11545.
- 32. Trus I., Gomelya M.D., Makarenko I.M., Khomenlo A.S., Trokhymenko G.G. 2020b. The Study of the particular aspects of water purification from heavy metal ions using the method of nanofiltration. Naukovyi Visnyk Natsionalnogo Hirnychogo Universytety. 4, 117–123.
- 33. Trus I., Halysh V., Gomelya M., Benatov D., Ivanchenko A. 2021. Techno-economic feasibility for water purification from copper ions, Ecol. Eng. Environ. Technol. 3.
- 34. Trus I., Halysh V., Radovenchyk Y., Fleisher H. 2020a. Conditioning of iron-containing solutions. Journal of Chemical Technology and Metallurgy. 55, 2, 486-491.
- 35. Trus I., Radovenchyk I., Halysh V., Skiba M., Vasylenko I., Vorobyova V., Hlushko O., Sirenko L. 2019a. Innovative Approach in Creation of Integrated Technology of Desalination of Mineralized Water. Journal of Ecological Engineering, 20, 8, 107–113.
- 36. Trus І., Gomelya N., Trokhymenko G., Magas N., Hlushko O. 2019b. Determining the influence of the medium reaction and the technique of magnetite modification on the effectiveness of heavy metals sorption. Eastern-European Journal of Enterprise Technologies. 6/10, 102, 49-54.
- 37. Van Genuchten C.M., Ahmad A. 2020. Groundwater As Removal by As(III), Fe(II), and Mn(II) Co- Oxidation: Contrasting As Removal Pathways with O2, NaOCl, and KMnO4. Environ. Sci. Technol. 54, 23, 15454–15464.
- 38. Vardhan K.H., Kumar P.S., Panda R.C. 2019. A review on heavy metal pollution, toxicity and remedial measures: Current trends and future perspectives. Journal of Molecular Liquids. 290, 111197. doi: 10.1016/j.molliq.2019.111197
- 39. Vasudevan S., Lakshmi J., Sozhan G. 2009. Studies on the removal of iron from drinking water by electrocoagulation—a clean process. Clean. 7, 1, 45–51.
- 40. Vorobyova V.I., Skiba M.I., Trus I. 2019. Apricot pomaces extract (prunus armeniaca l.) as a highly efficient sustainable corrosion inhibitor for mild steel in sodium chloride solution. International Journal of Corrosion and Scale Inhibition. 8 (4), 1060-1083.
- 41. Vries D., Bertelkamp C., Kegel F. Schoonenberg, Hofs B., Dusseldorp J., Bruins J.H., de Vet W., van den Akker B. 2017. Iron and manganese removal: Recent advances in modelling treatment efficiency by rapid sand filtration. Water Research. 109, 35 – 45.
- 42. Wang K., Zhang Q., Hu H., Liu Y. 2019. Efficient removal of Iron (II) from manganese sulfate solution by using mechanically activated CaCO3. Hydrometallurgy. 188, 169-173.
- 43. Wang Y., Sikora S., Kim H., Boyer T.H., Bonzongo J.C., Townsend T.G. 2013. Effects of solution chemistry on the removal reaction between calcium carbonate-based materials and Fe(II). Sci. Total Environ. 443, 717–724.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-7dd8f93c-54b5-487e-9a0a-065929bab95a