The impact of the technical decisions made in the operation of energy systems in Tashkent city

PURPOSE. Development and testing at a real facility of an integrated approach to the modernization of heat supply systems, taking into account the introduction of modern energy-saving technologies to reduce costs and optimize the processes of generation and consumption of thermal energy.

METHODS. During the study, a comprehensive analysis of the performance of all parts of the system was carried out: instrumental measurements were made, information was collected on the parameters of the system for the last two heating-winter periods.

RESULTS. Modernization of an outdated heat supply system to increase the efficiency of its operation in all elements of the system (source - heating network - consumer). The achieved practical significance today lies in the development of several measures to regulate the operating mode aimed at switching from an open heat supply system to a more efficient, closed one by equipping consumers with individual heating points, as well as optimizing the processes of generation and consumption of thermal energy.

CONCLUSION. Modernization of the existing heat supply system from the boiler house under study will optimize the processes of generation and consumption of thermal energy, reduce the cost of energy resources used. The developed concept of the development of the object under study can be applied to similar facilities not only in the Republic of Uzbekistan, but also throughout the Russian Federation, as part of programs to improve the efficiency of morally and physically obsolete energy systems.

1. Scheme of heat supply for the municipality of Naberezhnye Chelny for 2021 for the period until 2035. Naberezhnye Chelny: LLC «EC Energoaudit» 2020:4:82.

2. Zhukov V, Kamaletdinov I, Minakov A. 2014 Economic efficiency of mass introduction of individual thermal points in the city of Elabuga. Energosovet. 36:36-37.

3. ITP versus TTC. 2017 Why does Kazan change the hot water supply scheme: weekly «Arguments and Facts» 13 URL: https://kazan.aif.ru/society/details/itp_protiv_ctp_

4. Stennikov V. Provision of parametric reliability of heat supply systems. Izvestiya of higher educational institutions. Energy problems. 2017; 19 (3-4):20-30.

5. Gabrielaitiaene I. Evaluation of approaches for modeling temperature wave propagation in district heating pipelines. Heat transfer engineering. 2008; 1:45–46.

6. Wernstedt F. An agent-based approach to monitoring and control of district heating systems. Lecture notes in computer science. 2017; 2358:801.

7. Zvonareva U, Vankov Y, Vera Y. The work of heat supply system in a phased implementation of automated individual heating stations. News of higher educational institutions. Energy problem. Publisher: Kazan state power engineering University (Kazan) 2017;19 (1-2):3140.

8. Filimonov A. Features of the transition of Kazan to AITP in the implementation of a comprehensive program to improve the efficiency of the heat supply system. Bulletin KSPEU. 2019; 2 (42):127-137.

9. Morvaj B. Optimising urban energy systems: Simultaneous system sizing, operation, and district heating network layout. Energy. 2016 ;116 (1):619–636.

10. Abdulaev D. Hydraulic stability of the heating network. Construction of unique buildings and structures. 2017; 1 (52):67–85.

11. Zvonareva Y, Vankov Y, Shlychkov V. Commercial effectiveness assessment of implementation the energy efficiency raising of the building project due to introduction of automatic heat consumption control. SHS Web of Conferences 35, 01124 (2017). doi: 10.1051/shsconf/20173501124.

12. Zvonareva Y. Assessment of the economic effect for consumers during the installation of automated metering and control units for heat energy. Engineering Bulletin of the Don. 2015; 4:156-161.

13. Kuzborskaya K , Zvonareva Y. Comparison of consumer connection schemes in an automated individual heating station. Instrument-making and automated electric drive in fuel and energy and housing and communal services: materials of the 6 National scientific-practical. conf. Kazan. 2020; 2:324–327.

14. Zapolskaya I, Vankov Y. Improving the efficiency of hot water supply systems by installing automated ITP. Bulletin KSPEU. 2017; 4 (36):23–34.

15. Drigo M.F. Methodology of an assessment of economic efficiency investment decisions Management in Russia and abroad. 2008;1:18-24.

16. Rafalskaya T.A. Investigation of failures in operation of heat networks of large heat supply systems Thermal Engineering. 2017; 64 (4)313-7.

17. Sikerin I. 2010 The influence of the hydraulic mode of the heat supply network on the thermal stability of subscribers. Actual problems of modern science, technology and education. 2010; 2:20-22.

18. Livchak V. 2004 Improvement of district heating systems in large cities of Russia. AVOK 5 p. 42-49.

19. Zvonareva Y. 2017 The work of the heat supply system with the phased introduction of automated individual heating points. Izvestia of higher educational institutions. Energy problems 2017;1-2 : 31-40.

20. Orekhov V. 2012 Indicators of heat supply quality. Heat supply news. 2012;5 (141):2225.

21. Nevsky V. 2015 Standard automated block heating points Danfoss: manual. M.: LLC "Danfoss" 50 p.

22. The composition and principle of operation of ITP: [website]. [M., 2021]. URL: http://www.itp.plus/

23. Volkov D. 2017 About the heat supply system of the city of Naberezhnye Chelny. Heat supply news. 2013;(199):25-32.

24. Shilkin N. 2007 Economic aspects of the introduction of individual heating points // Energy saving 3 p. 34-38.

25. Kanina L, Chapkina G. 2008 Experience in solving issues of complex protection of equipment of heat supply systems under transient hydraulic conditions // Thermal power engineering 4 p. 10-14.

26. Sharapov V, Rotov P. 2003 Technologies for regulating the load of heat supply systems. Ulyanovsk: UlSTU 160 p.

27. Pyrkov V. 2008 Modern thermal points. Automation and regulation. K.: "Takispravi" 252 p.

28. Glukhov S. 2010 Investigation of the degree of efficiency of automatic regulation in heating systems // Izvestiya Transsib 2 p. 64-70.

29. Zvonareva Y. 2019 The impact of the phased introduction of AITP on the hydraulic stability and efficiency of heat supply systems: dis. Candidate of Technical Sciences. Kazan 172 p.

30. Bashmakov I. 2008 Analysis of the main trends in the development of heat supply systems in Russia // Heat supply News 2 p. 67-74.

31. On the provision of public services to owners and users of premises in apartment buildings and residential buildings [Electronic resource]: decree of the Government of the Russian Federation. Federation dated May 06, 2011 No. 354. Access from the help. - the legal system "Garant"

32. Kolesnikov A. 2016 On the transition from open heat supply and hot water supply systems to closed ones (in the interpretation of 190-FZ) // Heat supply News 11 (171) p. 21-27.

33. Balberov A. 2011 Justification of the economic efficiency of energy-saving thermal points in the construction of buildings // Economics and management 5 (78) p. 191-195.

34. The scheme of heat supply to the city of Yelabuga until 2028. SPb.: OOO "Nextenergo" 2014 1 42 p.