Reliable and safe heat supply of residential buildings in transitional conditions with independent connection of the heating system

The arrangement for heat supply of residential buildings with indirect connection to external heating systems is considered, providing reliability of heat input and required comfort in case of cold snaps after the official end of the heating season or before its beginning by supplying water from the return main of the heating system downstream the hot water supply heat exchangers. The calculations have been made to determine the amount of the main components of heat balance of a residential building on an example of one of standard projects being currently used in the climatic conditions of Moscow, subject to the structural characteristics of the building and its occupancy level. It is established that the actual heat output of the heating system when using the system of chilled water downstream the hot water supply heat exchangers as a heat source enables to main-tain an indoor temperature required for safe living conditions with the average daily outdoor air temperature above +2°C, the heat gain from solar radiation being moderate. It is proven that, tak-ing into account the thermal stability of the enclosing structures, the daily flow rate fluctuations do not significantly affect the stability of the temperature conditions of residential buildings or the comfort of their indoor microclimate at high outdoor air temperatures. It is noted that, in terms of reliability of heat supply of the main group of residential buildings and ensuring the life safety, the proposed arrangement is not inferior to the standard two-stage arrangement of connection of DHW heat exchangers with restriction of the total consumption of delivery water and with the associated regulation of heat supply for DHW, heating and ventilation. It is shown that the use of this arrangement involves virtually no extra costs, provides hydraulic resistance of the heating system and ensures a system-wide effect in the form of higher electricity generation at thermal consumption when using cogeneration.

1. Tretyakova P. A., Menshikova A. A., Tretyakova T. V. Performance indicators for the use of heat pumps in a district heating system. Energy saving and water treatment 2020; 2(124); 17–21. (In Russ.)

2. Amerkhanov R. A., Daybova L. A., Arakelyan N. S., Armaganyan E. G., Dvornyi V. V. Energy saving technologies for office buildings. Energy saving and water treatment 2019; 1(117): 3–5. (In Russ.)

3. Goloborod’ko I. E., Kozlov S. A., Gudko A. N. Discussion: sweating boilers and low-temperature schedule in heating systems. Sanitary engineering. Heating. Air conditioning 2016; 1: 26–30. (In Russ.)

4. Safiullin R. G., Akhmerova G. M. Experimental study of the thermal characteristics of a plate heat exchanger on the example of the installation "block heat point" of the center "Systems" in the KSASU. Proceedings of the VIII International Science and Technical Conference «Theoretical foundations of heat and gas supply and ventilation». – Moscow: NR MSUCE 2020; 127–132. (In Russ.)

5. Rafalskaya T. A. Reliability and controllability of systems of centralized heat supply. Eastern European Scientific Journal 2016; (2): 228–235.

6. De Rosa M., Bianco V., Scarpa F., Tagliafico L. A. Modelling of energy consumption in buildings: an assessment of static and dynamic models. Russian Journal of Construction Science and Technology 2016; 1(2): 12–24.

7. Serale G., Capozzoli A., Fiorentini M., Bernardini D., Bemporad A. Model predictive control (MPC) for enhancing building and HVAC system energy efficiency: problem formulation, applications and opportunities. Energies 2018; 3(11); 631.

8. Samarin O. D. On substantiated definition of heating season boundaries. Residential construction 2017; 1–2: 33–35. (In Russ.)

9. Samarin O. D. The secure and safe heat supply of residential buildings during the transitive climatic conditions. Safety and Reliability of Power Industry 2018; 2(11): 149–153. (In Russ.)

10. SP (Set of Rules) 60.13330.2016 «SNiP (Building Code) 41-01-2003 "Heating, ventilation and air conditioning"». – Moscow: Minrstroy RF 2016; 95. (In Russ.)

11. Samarin O. D. The analysis of the secure and safe heat supply of residential buildings using the waste water after the heat exchangers for DHW 2020; 1(13): 41 – 47. (In Russ.)

12. SP (Set of Rules) 50.13330.2018 «SNiP (Building Code) 23-02-2003 "Thermal performance of the buildings"». – Moscow: Minrstroy RF 2018; 96. (in Russ.)

13. SP (Set of Rules) 131.13330.2018 «SNiP (Building Code) 23-01-99* "Building climatology"». – Moscow: Minstroy RF 2018; 107. (in Russ.)

14. SP (Set of Rules) 30.13330.2016 «SNiP (Building Code) 2.04.01-85 "Domestic water supply and drainage systems in buildings"». – Moscow: Minrstroy RF 2016; 92.

15. Makhov L. M. Heating. 2nd ed., corr. and upd. Moscow: ASV Publishers 2015; 400. (in Russ.)

16. Malyavina E. G, Samarin O. D. Building thermal physics and room microclimate. Moscow: MISI-MGSU Publishers 2018; 288. (in Russ.)