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Four-parameter electromagnetic method for determining the parameters of brewery effluents

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Purpose: of the article is to study a four-parameter electromagnetic method for joint measurements of electrical resistivity k, relative permittivity εr, temperature t and density ρ of samples of acidic, alkaline and average effluents from a microbrewery based on a magnetic flux probe (MFP), which considers the influence of informative parameters of beer effluents on the components of the amplitude and phase signals of a multiparameter device. Design/methodology/approach: The implementation of the four-parameter method is carried out on the basis of the dependences G1 = f (A1) and G2 = f (A2) at two frequencies of the electromagnetic field f0 and f1 for acid, alkaline and average effluent and allows you to jointly determine the four parameters of effluent samples with the same converter in the same control area. The proposed method makes it possible to improve the accuracy of identifying effluent samples since the obtained multiparameter information makes it possible to determine the nature and properties of effluent samples using only one transducer with certain physical characteristics. The research results lead to the expansion of the technical capabilities of electromagnetic measurement methods, as well as to an increase in the metrological characteristics of electromagnetic transducers and an increase in the accuracy of measuring the parameters of effluent samples compared to reference methods and measuring instruments. Thus, the implementation of this approach contributes to the prediction and prevention of the reasons for the deviation of beer effluent samples from the specified indicators of environmental safety. Findings: The universal conversion functions MFP have been established, connecting the amplitude and phase components of the converter signals with the parameters k, εr, t and ρ of acidic, alkaline and average effluents. Based on the universal transformation functions G1 = f (A1) and G2 = f (A2), a four-parameter electromagnetic method for joint measurements of electrical resistivity k, relative permittivity εr, temperature t and density ρ of acidic, alkaline, and average effluents from breweries has been developed. When conducting research at two close frequencies of the electromagnetic field f0 = 20.3 MHz and f1 = 22 MHz, algorithms were obtained for measuring and calculating procedures for determining k, εr, t and ρ for samples of acidic, alkaline and average effluents from the brewing industry. Research limitations/implications: Research perspectives consist in the creation of automated systems for multiparameter measuring control of the physicochemical characteristics of acidic and alkaline effluent from food and processing industries based on the immersed electromagnetic transducer. Based on the data obtained using informative methods to measure the parameters of effluent samples, an integrated method for treating beer effluents of various compositions will be proposed. At the same time, the scheme of the integrated treatment method should include a filter that provides the introduction of a magnetic fluid and a separation device that allows us to remove a fraction, including pollution in itself. Practical implications: Is that the proposed four-parameter electromagnetic method makes it possible to determine to what composition the controlled samples of wastewater should be attributed (acidic or alkaline). It, in turn, makes it possible to choose a rational method for treating beer effluents and to prevent the reasons for the deviation of effluent samples from the environmental safety indicators set by the standards. Originality/value: of the article is the research related to the expansion of the functional and technical capabilities of the electromagnetic two-frequency transducer MFP through the implementation of a four-parameter electromagnetic method of joint measurements of electrical resistivity k, relative permittivity εr, temperature t and density ρ of acidic, alkaline and average effluents from breweries. The universal transformation functions G1 = f (A1) and G2 = f (A2) found in the work at two close magnetic field frequencies, f0 = 20.3 MHz and f1 = 22 MHz, make it possible to control four physicochemical parameters of acidic, alkaline and average wastewater at the same time by the same MFP. An algorithm has been developed for determining the signal components of a two-frequency thermal MFP, the ranges of which correspond to the ranges of changes in electrical resistivity k, relative permittivity εr, temperature t and density ρ of acidic, alkaline, and average brewery effluents. The basic relations that describe the two-frequency four-parameter electromagnetic method of joint measurements of the physicochemical parameters of acidic, alkaline and averaged beer effluents have been obtained.
Rocznik
Strony
49--64
Opis fizyczny
Bibliogr. 27 poz., rys., tab., wykr.
Twórcy
autor
  • Department of Chemical Engineering and Industrial Ecology, National Technical University «Kharkiv Polytechnic Institute», Kirpicheva Str. 2, Kharkiv, 61000, Ukraine
  • Department of Chemical Engineering and Industrial Ecology, National Technical University «Kharkiv Polytechnic Institute», Kirpicheva Str. 2, Kharkiv, 61000, Ukraine
  • Department of Information and Measurement Technologies, National Technical University of Ukraine «Igor Sikorsky Kyiv Polytechnic Institute», Peremohy Ave., 37, Kyiv, 03056, Ukraine
  • Department of Information and Measurement Technologies, National Technical University of Ukraine «Igor Sikorsky Kyiv Polytechnic Institute», Peremohy Ave., 37, Kyiv, 03056, Ukraine
  • Department of Information and Measurement Technologies, National Technical University of Ukraine «Igor Sikorsky Kyiv Polytechnic Institute», Peremohy Ave., 37, Kyiv, 03056, Ukraine
Bibliografia
  • [1] S. Wunderlich, W. Back, Overview of Manufacturing Beer: Ingredients, Processes, and Quality Criteria, in: V.R. Preedy (ed.), Beer in Health and Disease Prevention, Academic Press, Cambridge, MA, 2009, 3-16. DOI: https://doi.org/10.1016/B978-0-12-373891-2.00001-8
  • [2] J. Thanikachalam, M. Ramkumar, P. Nagaraj, Electromagnetic analysis of magnetorheological brakes, Journal of Achievements in Materials and Manufacturing Engineering 76/2 (2016) 61-66. DOI: https://doi.org/10.5604/17348412.1229481
  • [3] O. Hrevtsev, N. Selivanova, P. Popovych, L. Poberezhny, O. Shevchuk, G. Hrytsuliak, L. Poberezhna, The movement investigation of an axisymmetric rotation body under the action of electromagnetic fields, Journal of Achievements in Materials and Manufacturing Engineering 103/2 (2020) 67-77. DOI: https://doi.org/10.5604/01.3001.0014.7196
  • [4] ISO 22000:2005. Food Safety Management Systems - Requirements for any organization in the food chain, ISO, Geneva, 2005.
  • [5] European Commission, European Integrated Pollution Prevention and Control Bureau (EIPPCB). Reference Document on Best Available Techniques (BAT) in the Food, Drink and Milk Industries, EIPPCB, Seville, 2006.
  • [6] Directive 2008/98/EC of the European Parliament and of the Council of 19 November 2008 on waste and repealing certain Directives (Text with EEA relevance), Official Journal of the European Union L 312 (2008) 3-30.
  • [7] S.Ya. Alibekov, N.N. Zhurkin, Improvements in the method of mechanical wastewater treatment, Bulletin of the Volga State Technical University (PSTU). Series: Forest. Ecology. Nature Management 1 (2013) 92-96 (in Russian).
  • [8] N.I. Posvyatenko, Yu.E. Demidova, T.V. Melnik, Physico-chemical methods of wastewater treatment from oil products, Bulletin of the National Transport University 29/1 (2014) 250-258 (in Ukrainian).
  • [9] V.A. Kovalchuk, O.V. Kovalchuk, V.I. Samelyuk, Biotechnology of wastewater treatment of food industry enterprises, Communal Economy of Cities: Scientific-Technical 93 (2010) 182-187 (in Ukrainian).
  • [10] L. Mekuto, A.V.A. Olowolafe, S. Pandit, N. Dyantyi, P. Nomngongo, R. Huberts, Microalgae as a biocathode and feedstock in anode chamber for a self-sustainable microbial fuel cell technology: a review, South African Journal of Chemical Engineering 31 (2020) 7-16. DOI: https://doi.org/10.1016/j.sajce.2019.10.002
  • [11] A. Ghorai, S. Roy, S. Das, H. Komber, M.M. Ghangrekar, B. Voit, S. Banerjee, Chemically Stable Sulfonated Polytriazoles Containing Trifluoro-methyland Phosphine Oxide Moieties for Proton Exchange Membranes, ACS Applied Polymer Materials 2/7 (2020) 2967-2979. DOI: https://doi.org/10.1021/acsapm.0c00443
  • [12] I. Das, S. Das, M.M. Ghangrekar, Application of bimetallic low-cost CuZn as oxygen reduction cathode catalyst in lab-scale and field-scale microbial fuel cell, Chemical Physics Letters 751 (2020) 137536. DOI: https://doi.org/10.1016/j.cplett.2020.137536
  • [13] V.F. Ochkov, Water and magnet. Water-cleaning, water-treatment, water supply, National Research University "Moscow Power Engineering Institute" 10 (2011) 36-48.
  • [14] S.M. Maevskiy, V.P. Babak, L.M. Shcherbak, The basics of stimulating systems for signal analysis in non-linear control, Libid, 1993.
  • [15] X. Fan, G.L. Brown, Probe for measurements of density/conductivity in flows of conducting fluids, Review of Scientific Instruments 77/4 (2006) 045104. DOI: https://doi.org/10.1063/1.2189949
  • [16] H.A. Shilajyan, Electrical conductivity of potassium salt dimethylsulfoxide-water systems at different temperatures, Proceedings of the YSU B: Chemical and Biological Sciences 47/1(230) (2013) 3-6. DOI: https://doi.org/10.46991/PYSU:B/2013.47.1.003
  • [17] M.I. Chaudhari, A. Muralidharan, L.R. Pratt, S.B. Rempe, Assessment of Simple Models for Molecular Simulation of Ethylene Carbonate and Propylene Carbonate as Solvents for Electrolyte Solutions, in: M. Korth (eds), Modeling Electrochemical Energy Storage at the Atomic Scale, Topics in Current Chemistry Collections, Springer, Cham, 2018, 53-77. DOI: https://doi.org/10.1007/978-3-030-00593-1_3
  • [18] С. Odinaev, R. Mahmadbegov, Research of dielectric properties and frequency spectrum of dielectric losses of an water solution of NaCl, depending on the state parameters, Ukrainian Physical Journal 60/9 (2015) 862-868 (in Ukrainian).
  • [19] A.A. Fenin, S.A. Fenin, V.I. Ermakov, Electrical conductivity, characteristics of current carriers, dielectric constant and structure of electrolyte solutions. I. Measurement of electrical conductivity and dielectric constant by separating impedance components, Electronic Journal Researched in Russia. Moscow Institute of Physics and Technology (2005) 1-7 (in Russian).
  • [20] W. Zhang, X. Chen, Y. Wang, L. Wu, Y. Hu, Experimental and Modeling of Conductivity for Electrolyte Solution Systems, ACS Omega 5/35 (2020) 22465-22474. DOI: https://doi.org/10.1021/acsomega.0c03013
  • [21] S.M. Maevsky, Separate eddy current control of defects and thickness of a paint covering, Technical Diagnostics and Non-Destructive Testing 3 27-30 (in Ukrainian).
  • [22] Y. Li, B. Yan, W. Li, H. Jing, Z. Chen, D. Li, Pulsemodulation eddy current probes for imaging of external corrosion in nonmagnetic pipes, NDT&E International 88 (2017) 51-58. DOI: https://doi.org/10.1016/j.ndteint.2017.02.009
  • [23] D. Zhou, J. Wang, Y. He, D. Chen, K. Li, Influence of metallic shields on pulsed eddy current sensor for ferromagnetic materials defect detection, Sens Actuators A: Physical 248 (2016) 162-172. DOI: https://doi.org/10.1016/j.sna.2016.07.029
  • [24] V.V. Sebko, Small-sized electromagnetic temperature transducer, Proceedings of the II International Scientific and Technical Conference Metrological support in the field of electrical, magnetic and radio measurements “Metrology in Electronics – 97”, vol. 2., Kharkov, 1997, 187-189 (in Ukrainian).
  • [25] Ye.V. Pyrozhenko, V.V. Sebko, V.G. Zdorenko, N.M. Zashchepkina, O.M. Markina, Informative testing method of beer sewage samples for mini-breweries, Journal of Materials Science and Engineering 106/1 (2020) 28-41. DOI: https://doi.org/10.5604/01.3001.0014.5930
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Uwagi
PL
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-f85194a8-9ad9-48fe-9ba0-86c1d1c62e01
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