Electric spark method of purification of galvanic waste waters

• Autorzy: Przystupa Krzysztof

Identyfikatory

DOI

10.15199/48.2020.12.50

Warianty tytułu

PL

Metoda elektroiskrowa oczyszczania wód odpadowych galwanicznych

• Języki publikacji: EN

Abstrakty

EN

The purification of multicomponent galvanic waste water by the electric-spark method using metal loading (Fe, Al) and low-voltage (up to 1000 V) equipment have been carried out.

PL

Przeprowadzono oczyszczanie wieloskładnikowych ścieków galwanicznych metodą iskry elektrycznej za pomocą urządzeń do ładowania metali (Fe, Al) i niskonapięciowych (do 1000 V).

Słowa kluczowe

EN

electro spark method; water treatment; galvanic processes; water quality

PL

metoda elektroiskrowa; uzdatnianie wody; procesy galwaniczne; jakość wody

• Wydawca: Wydawnictwo SIGMA-NOT
• Czasopismo: Przegląd Elektrotechniczny
• Rocznik: 2020
• Tom: R. 96, nr 12
• Strony: 230--233
• Opis fizyczny: Bibliogr. 23 poz., rys., tab.

Twórcy

autor

Przystupa Krzysztof

• Dept. of Automation Faculty of Mechanical Engineering Lublin University of Technology, 36,Nadbystrzycka Str., 20-618, Lublin, Poland

Bibliografia

• [1] Phadatare S.S., Gawande S., Review Paper on Development of Water Quality Index, International Journal of Engineering Research & Technology, (2016), 5(05), 765-767.
• [2] Mitryasova O., Pohrebennyk V., Cygnar M., Sopilnyak I., Environmental Natural Water Quality Assessment by Method of Correlation Analysis. International Multidisciplinary Scientific Geoconference SGEM, (2016), 2, 317-324.
• [3] Wang J., Kochan O., Przystupa K., & Su J., Informationmeasuring System to Study the Thermocouple with Controlled Temperature Field, Measurement Science Review, (2019), 19(4), 161-169.
• [4] Guidance document N7. Monitoring under the Water Framework Directive, Common Implementation Strategy for the Water Framework Directive (2000/60/EC), Luxembourg, Office for Official Publication of the European Communities, (2003). 159 p.
• [5] Kvaterniuk S., Petruk V., Kochan O., & Frolov, V., Multispectral ecological control of parameters of water environments using a quadrocopter, In Sustainable Production: Novel Trends in Energy, Environment and Material Systems, (2020), 75-89, Springer.
• [6] Pohrebennyk, V., Dzhumelia, E., Korostynska, O., Mason, A., Cygnar, M., X-Ray Fluorescent Method of Heavy Metals Detection in Soils of Mining and Chemical Enterprises, 9th International Conference on Developments in eSystems Engineering, DeSE 2016, (2017), 7930667, 323–328.
• [7] Mitryasova О., Pohrebennyk V., Kardasz P., Hydrochemical Aspects of Surface Water Quality Assessment. International Multidisciplinary Scientific Geoconference SGEM, (2018),18(5.2), 513-520.
• [8] Filatova E., Soboleva A.: Intensification of the electrocoagulation method of wastewater treatment of galvanic production, International Research Journ. 5(5), (2012) 127– 128, 2012 (in Russian). – URL: http://dx.doi.org/10.18454/IRJ.2227-6017.
• [9] Dudarev V., Pomazkina O., Electrocoagulation wastewater treatment of galvanic production from nickel ions, Modern problems of science and education, 2, (2012) – URL: http://www.science-education.ru/ru/article/view?id=5860 (in Russian).
• [10] Kobya M., Demirbas E., Parlak N.U., Yigit, S., Treatment of cadmium and nickel electroplating rinse water by electrocoagulation, Environmental Technology & Innovation, (2010), 31, 1471-1481.
• [11] Kobya M., Soltani R.D.C., Omwene P.I., Khataee A.: A review on decontamination of arsenic-contained water by electrocoagulation: Reactor configurations and operating cost along with removal mechanisms, Environmental Technology & Innovation, (2020), 17, 100519.
• [12] Crittenden JC., Trussell RR., Hand DW., Howe KJ., Tchobanoglous G.: MWH’s water treatment: principles and design, 2nd edn. Wiley, New York, (2012).
• [13] Pohrebennyk V., Petryk A., The degree of pollution with heavy metals of fallow soils in rural administrative units of Psary and Płoki in Poland. 17th International Multidisciplinary Scientific GeoConference, SGEM, (2017), 17 (52), 967-974.
• [14] Nester A.A., Drapak G.M., Microstructure research and recovery copper technology, released from restored water solutions, Polish Journal of Environmental Studies, (2008), Vol.17, No. 3A, Olsztyn, 423-426.
• [15] Hargreaves AJ., Vale P., Whelan J., Alibardi L., Constantino C, Dotro G., Cartmell E., Campo P.: Impacts of coagulation– flocculation treatment on the size distribution and bioavailability of trace metals (Cu, Pb, Ni, Zn) in municipal wastewater, Water Res., (2018), 128, 120-128.
• [16] Solozhenkin P., Nebera M., Zubulis A., Theoretical aspects and practical use of the galvanochemical process in the treatment of industrial waters, Mountain News and Analysis Bulletin, (2003), 6, 201-205, (in Russian).
• [17] КND 211.1.4.035-95, Method of extraction-photometric determination of copper with lead diethyldithiocarbamate in surface and waste water, (1995). (in Ukrainian).
• [18] Mitryasova O., Pohrebennyk V., Kochanek A., Stepanova A., Environmental Footprint Enterprise as Indicator of Balance it’s Activity. International Multidisciplinary Scientific Geoconference SGEM, (2017), 17, 371–378.
• [19] Khajnaczkij S., Zubenko A., Smalko A., Kreshhenko V., Kovalenko V., Studies of complex water purification from heavy metal ions during high-voltage electric discharges in reactors with granular metal loading, Electronic material processing, (2005), 6, 53–58. (in Russian).
• [20] Petrichenko S., Listovskij D., Kuskova N., Stabilization of discharge pulses and peculiarities of matching spark load during electroerosive dispersion of metal and graphite granules in a liquid, Electronic material processing, (2016), 2(52), 8–13. (in Russian).
• [21] MVV № 081/12 0178 05, Surface, groundwater and return water. Method of performing measurements of mass concentration of nickel by photocolorimetric method, (2005) (in Ukrainian).
• [22] MVV № 081/12 0173 05, Surface, groundwater and return water. Method of performing measurements of mass concentration of zinc by photocolorimetric method (0,005– 1,0 мг/дм3, (2005) (in Ukrainian).
• [23] MVV № 081/12-0114-03, Surface, groundwater and return water. Methods of measurement of mass concentration of chromium total, chromium(VI) and chromium(III) by extractionphotocolorimetric method with diphenylcarbazide), (2003) (in Ukrainian).

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).