Thermodynamic Concept of Nanotechnological Processes Reagent-Free Water Treatment in Heat and Power Systems of Construction

  • Authors

    • Nataliia Zhuravska
    • Petro Kulikov
    2018-10-13
    https://doi.org/10.14419/ijet.v7i4.8.27284
  • nanotechnology, efficiency of functional processes, electromagnetic fields, technogenic-resource processes
  • In the article the thermodynamic concept of nanotechnological processes of non-reagent preparation of technical water of thermal power engineering enterprises is considered. The thermodynamic functional characteristic is presented in heat energy systems of construction with non-reagent water treatment in electromagnetic fields. It is noted, with regard to biological impurities in water, that this method eliminates the accumulation of salts in the pipeline, biological damage, as the emergence of potentially possible critical technogenic situations.

     

     

     
  • References

    1. [1] Figovski O. (2005), The Purposes of Mankind in the Millennium to come. Ecology and human health. Protection of air and water basins. Waste utilization: 2 tons. T.1: Collection of scientific articles for the XIII International Scientific and Practical Conference. Kharkov: Ryder UkrGSTEC "Energostal". 360 pp.

      [2] Klassen V.I. (1973), Water and Magnet. Moscow: Publishing House "Nauka". 112 pp.

      [3] Malkin E.S., Zhuravska N.E. (2017), Ecologo end energy-saving technologies with the use of water in the magnetic fields. Ecological safety and natural resources: Zb. sciences works. KNUBA. V. 24. 106 - 111.

      [4] Kulikov P., Bondar О. & Zhuravska N. (2018), Environmental management of production processes in heating systems when receiving magnetic water in a reagent-free method with the aim of environmentalization International Journal of Engineering and Technology (UAE). Vol. 7, no 3.2. 621-625.

      [5] Zhuravska N.E. (2018), Non-reagent water treatment in electromagnetic fields. Urban Planning and Territorial Planning: Scientific-Technical. collection. From. Ed. MM Osetrin. KNUBA. V. 66. - P. 193-198.

      [6] Malkin E.S., Furatat I.E. & Zhuravska N.E., Usachev V.P (2014), Perspectives of creating energy-saving technologies by processing water and water solutions. Ventilation, lighting and heat and gas supply. B. 17. KNUBA. P. 121-127.

      [7] Mantashov A.T. (2015), Workshop on heat engineering: a manual. Perm: IPC "Procrost". 90 p.

      [8] Kozlobrodov A.N., Nemov T.N. & Flowers N.A. (2015), Workshop on heat engineering: in 3 hours. Part 1. Technical thermodynamics. TGASU. - 200 p.

      [9] Erofeev V.L. (2018), Heat engineering. Workshop: a manual for SPO. Publishing House Yurayt. - 395 p.

      [10] Malkin E.S., Furatat I.E. & Zhuravsk N.E. (2017), Special issues of heat and mass transfer. Scientific textbook. KNUBA. 288 pp.

      [11] Malkin E.S., Furtat I.E. & Zhuravska N.E. (2015), The system of preparation of magnetized water in the electromagnetic fields of water and solutions and compounds based on it. The patent for useful mode 102494.

      [12] Bondarenko V.I. (2012-2013), From Fire and Water to Electricity [Electronic resource] Energy: History, Present and Future. Access mode: http: energetika.in.ua/ru/books/book-1/zaklyuchenie. (Revocation Date: 1.10.2018).

      [13] Gotovsky M.A. & Suslov V.A. (2013), Heat exchange in technological installations of the CBP: study. Ðllowance. SPb GTU RP. St. Petersburg. Part 4. 85 p.

      [14] Prigogine I. & Stengers І. (1986), The Order of Chaos: The New Dialogue of Man with Nature. Progress. 432 pp.

      [15] Zhuravska N.E. (2016), Energy saving technology of the influence of biocorrosion on materials Urban Planning and Territorial Planning: Scientific-Technical. collection. From. Ed. M.M. Osetrin. KNUBA. Vip. 60. p.155-162.

  • Downloads

  • How to Cite

    Zhuravska, N., & Kulikov, P. (2018). Thermodynamic Concept of Nanotechnological Processes Reagent-Free Water Treatment in Heat and Power Systems of Construction. International Journal of Engineering & Technology, 7(4.8), 428-431. https://doi.org/10.14419/ijet.v7i4.8.27284