ASSESSMENT OF THE DEGREE OF AUTOMATION AND IMPLEMENTATION OF DIGITAL PLATFORMS FOR MANAGING WASTEWATER TRANSPORTATION SYSTEMS

UDC 628.3:621.3

 

Voitau Igar Vital’yevich – DSc (Engineering), Professor, Rector. Belarusian State Technological University (13a, Sverdlova str., 220006, Minsk, Republic of Belarus). E-mail: rector@belstu.by

Shtepa Vladimir Nikolaevich – DSc (Engineering), Associate Professor, Head of the Department of Life Safety. Belarusian State Technological University (13a, Sverdlova str., 220006, Minsk, Republic of Belarus). E-mail: tppoless@gmail.com

Smelov Vladimir Vladislavovich – PhD (Engineering), Associate Professor, Head of the Department of Software Engineering. Belarusian State Technological University (13a, Sverdlova str., 220006, Minsk, Republic of Belarus). E-mail: smw@belstu.by

Karpovich Dzmitry Semenovich – PhD (Engineering), Associate Professor, Head of the Department of Automation of Production Processes and Electrical Engineering. Belarusian State Technological University (13a, Sverdlova str., 220006, Minsk, Republic of Belarus). E-mail: d.karpovich@belstu.by

 

DOI: https://doi.org/ 10.52065/2520-6141-2024-284-7.

Key words: water supply and sewerage, water disposal, automation, digital modeling.

For citation: Voitau I. V., Shtepa V. N., Smelov V. V., Karpovich D. S. Аssessment of the degree of automation and implementation of digital platforms for managing wastewater transportation systems. Proceedings of BSTU, issue 3, Physics and Mathematic. Informatics, 2024, no. 2 (284), pp. 43–52 (In Russian). DOI: 10.52065/2520-6141-2024-284-7.

Abstract

The article substantiates the relevance using digital solutions in the construction (modernization, reconstruction) water supply and sewerage facilities of the Republic of Belarus based on Internet of Things technologies, including virtual representations real objects, hardware and software modeling solutions using artificial intelligence, distributed and remote information transmission systems. Functional modeling taking into account the multifactorial and nonlinear nature parameter fluctuations demonstrated the need to increase the level of automation technological processes in order to coordinate the actions various installations and increase their efficiency, especially in case of risks man-made emergency situations. Calculation and analysis of the degree automation wastewater disposal, existing and necessary, substantiated the relevance creating methodological and information and communication support for a digital platform for managing wastewater disposal. The planned results of the functioning such platform are formulated, among which the main ones are: compliance with state social standards for serving the population in the field of water and wastewater services while ensuring the environmental safety of the functioning water disposal systems and wastewater treatment systems, increasing the efficiency their functioning at various stages life cycles and compliance with environmental safety requirements.

Download

References

  1. Stankevich A. P. Water Strategy of the Republic of Belarus for the period up to 2030. Vodnyye resursy i klimat: materialy V Mezhdunarodnogo vodnogo foruma [Water resources and climate: materials at the International Water Forum]. Minsk, 2017, pp. 26–27 (In Russian).
  2. Voitau I. V. Nauchnyye osnovy ratsional’nogo upravleniya i okhrany vodnykh resursov [Scientific foundations of rational management and protection of water resources]. Minsk, BSU Publ., 2000. 386 p. (In Russian).
  3. Semyachkov K. A. Transformation of the public sector in the digital economy. Zhurnal ekonomicheskoy teorii [Journal of Economic Theory], 2018, vol. 15, no. 3, pp. 545–548 (In Russian).
  4. Gartner Identifies the Top 10 Strategic Technology Trends for 2019. Available at: URL: https: //www.gartner.com/en/newsroom/press-releases/2018-10-15-gartner-identifies-the-top-10-strategic-technology-trends-for-2019 (accessed 17.01.2024).
  5. Grieves M., Vickers J. Digital Twin: Mitigating Unpredictable, Undesirable Emergent Behavior in Complex System. Transdisciplinary Perspectives on Complex Systems. Springer, 2017, pp. 85–113.
  6. Information Integration for Concurrent Engineering (IICE) Compendium of Methods Report. Available at: https://www.cs.tcd.ie/Andrew.Butterfield/Teaching/CS4098/IDEF/IDEFcompendium.pdf (accessed 17.01.2024).
  7. R 50.1.031–2001. Continouos acquisition and life-cycle support. Glossary. Part 1. Product life-cycle stages. Moscow, Izdatel’stwo Standardov Publ., 2001. 28 p. (In Russian).
  8. Sharshunov V. A. Ochistka stochnykh vod i utilizatsiya ikh otkhodov [Digitization of stock felts and the utility of their waste]. Minsk, Misanta Publ., 2020. 642 p. (In Russian).
  9. Gruzdeva E. K., Dushin S. E., Kuzmin N. N. Dynamic models of controlled biochemical processes of wastewater treatment. Izvestiya vyzov. Priborostroyeniye [News of higher educational institutions. Instrumentation], 2015, vol. 58, no. 9, pp. 732–737 (In Russian).
  10. Alekseev E. V., Vikulina V. B., Vikulin P. D. Osnovy modelirovaniya system vodosnabzheniya i vodootvedeniya [Fundamentals of modeling water supply and sanitation systems]. Moscow, Izdatel’stvo MISI – MGSU Publ., 2017. 126 p. (In Russian).
  11. Ladanjuk A. P., Pluzhnikov L. N., Tregub V. G. Proyektirovaniye, montazh i ekspluatatsiya system avtomatizatsii v pishchevoy promyshlennosti [Design, installation and operation of automation systems in the food industry]. Moscow, Agropromizdat Publ., 1991. 352 p. (In Russian).
  12. Shtepa V. N., Shikunec A. B. Innovative technologies for purification of multicomponent aqueous solutions with counteraction to emergency situations of man-made origin. Pryrodnaye asyaroddze Palessya і perspektyvy razvіtstsya: zbornіk navukovych prats [Natural environment of Polesie and development prospects: collection of scientific papers]. Brest, 2022, vol. 14, pp. 184–187 (In Russian).
  13. Shtepa V. N., Shikunec A. B., Zolotyh N. Ju. Management of ecological and energy efficiency of water supply and sewerage facilities. Nauchno-technicheskiy progress v zhilishchno-kommunal’nom khozyaystve: sbornik trudov [Scientific and technical progress in housing and communal services: proceedings]. Minsk, 2022, pp. 209–215 (In Russian).
  14. Weijers S. R. Modelling, Identification and Control of Activated Sludge Plants for Nitrogen Removal. Eindhoven, Techn. Univ., 2000. 235 p.
  15. Shtepa V. N. Conceptual foundations of an energy-efficient control system for combined water treatment systems. Energetika. Izvestiya vysshikh uchebnykh zavedeniy i energeticheskikh ob’’yedineniy SNG [Energetics. News higher educational institutions and energy associations of the CIS], 2016, no. 5, pp. 479–487 (In Russian).

15.05.2024