PURIFICATION OF LIQUID BY ELECTROMAGNETIC FOCUSING OF IMPURITIES
DOI:
https://doi.org/10.20535/1813-5420.4.2021.257275Keywords:
purification, filtrate, physical purification, ion focusing, Larmor precession, experiment planning.Abstract
The article discusses topical issues of increasing the efficiency of the filtrate purification system by physical methods developed at the Institute of Energy Saving and Energy Management «Igor Sikorsky Kyiv Polytechnic Institute». The work is devoted to the urgent problem of introducing the latest resource-saving, energy-saving integrated technologies for the purification of contaminated liquid media. To date, not a single theoretical base has been developed, there are only hypotheses, and there are no practical methods for calculating the magnetic treatment of water. The article is devoted to the purification by physical methods of the filtrate of domestic and industrial wastewater of industrial and domestic waste. An electromagnetic control unit was used to clean the fluid flow. Reducing the aggressiveness of the filtrate involves multi-stage control of the trajectory of impurities when they are removed from the main stream. Taking into account the properties of the experiment planning matrix, the coefficients of the regression equation were calculated, which adequately reflect the processes of liquid purification during its magnetization. Pollutant ions are charged particles. To remove them from the general flow, it is necessary to place generators on the pipeline to create developed cavitation in the fluid flow and inductance. Cavitation bubbles are internal oscillators and, releasing energy upon impact, crush and purify impurities.
In practical water purification, insufficient attention is paid to the control of the dynamics of charged impurities by the action of external and internal forces. Magnetic treatment of an aqueous medium has a number of advantages over other physical methods: it acts on all groups of impurities; influence on both chemical and physical processes in the aquatic environment; leads to the vivacity of the environment within the enterprise due to the destruction of electromagnetic bonds between the molecules of the indium and impurities, activates the aquatic environment. The main advantage in the purification of an aqueous medium from ions of impurities is the ability to control mobile ions in a magnetic field, and therefore direct vidions of impurities per stream. Magnetic treatment of aqueous media has found its application in many industries, which, in turn, confirms the effectiveness of such devices.
References
Abdulhussain A. Abbas, Guo Jingsong, Liu Z. Ping, Pan Y. Ya, Wisaam S. Al-Rekabi. Reviev on Landfi || Leachate Treatments [Text]/ Abdulhussain A. Abbas, Guo Jingsong, Liu Z. Ping, Pan Y. Ya, Wisaam S. Al-Rekabi. //American Journal of Applied Sciences. 2009; 6(4): page 672-684].
Sathish, Selvaganesa Pandian, Arul Amuthan. Effect of soaking of Phyllanthus emblica wood in drinking-water for purification [Text]/ Sathish, Selvaganesa Pandian, Arul Amuthan//International Journal of Pharmacology and Clinical Sciences. 2012; 1(1): page 19-27.
Ambashta Ritu D Water purification using magnetic assistance[Text]/ Ritu D. Ambashta, Mika Sillanpää//Journal of Hazardous Materials, Volume 180, Issues 1–3, 15 August 2010, Pages 38-49.
Piyadasa, C. et al. The application of electromagnetic fields to the control of the scaling and biofouling of reverse osmosis membranes—a review. Desalination 418, 19–34 (2017).
Salman, M. & Al-Nuwaibit, G. Anti-scale magnetic method as a prevention method for calcium carbonate scaling. TOJSAT 7, (2017)
Sun, J. et al. Performance and mechanisms of ultrafiltration membrane fouling mitigation by coupling coagulation and applied electric field in a novel electrocoagulation membrane reactor. Environ. Sci. Technol. 51, 8544–8551 (2017).
Piyadasa, C. et al. The influence of electromagnetic fields from two commercially available water-treatment devices on calcium carbonate precipitation. Environ. Sci. 3, 566–572 (2017).
Al Helal, A., Soames, A., Gubner, R., Iglauer, S. & Barifcani, A. Influence of magnetic fields on calcium carbonate scaling in aqueous solutions at 150 °C and 1bar. J. Colloid Interf. Sci. 509, 472–484 (2018).
Han, Y. et al. Effect of alternating electromagnetic field and ultrasonic on CaCO3 scale inhibitive performance of EDTMPS. J. Taiwan Inst. Chem. Eng. 99, 104–112 (2019)
Yezhov, S.M. Classical mechanics./ S.M. Yezhov, M.V. Makarets, O.V. Romanenko //.– K .: VPTs "Kyiv University", 2008. - 480 p.
Gaidadin A.N. Application of a complete factorial experiment in research: a method. instructions./ A.N. Gaidadin, S.A. Efremova.–VolgSTU. - Volgograd, 2008. - 16 p.
Downloads
Published
Issue
Section
License
Автори, які публікуються у цьому журналі, погоджуються з наступними умовами:
- Автори залишають за собою право на авторство своєї роботи та передають журналу право першої публікації цієї роботи на умовах ліцензії Creative Commons Attribution License, котра дозволяє іншим особам вільно розповсюджувати опубліковану роботу з обов'язковим посиланням на авторів оригінальної роботи та першу публікацію роботи у цьому журналі.
- Автори мають право укладати самостійні додаткові угоди щодо неексклюзивного розповсюдження роботи у тому вигляді, в якому вона була опублікована цим журналом (наприклад, розміщувати роботу в електронному сховищі установи або публікувати у складі монографії), за умови збереження посилання на першу публікацію роботи у цьому журналі.
- Політика журналу дозволяє і заохочує розміщення авторами в мережі Інтернет (наприклад, у сховищах установ або на особистих веб-сайтах) рукопису роботи, як до подання цього рукопису до редакції, так і під час його редакційного опрацювання, оскільки це сприяє виникненню продуктивної наукової дискусії та позитивно позначається на оперативності та динаміці цитування опублікованої роботи (див. The Effect of Open Access).