Modeling of physical characteristics of heat-accumulating building materials

The article discusses the results of studies of the physical characteristics of heataccumulating building materials. Modern trends in the production and use of materials determine the need to develop new scientific and methodological devices for assessing the physical characteristics of energy-saving building materials, which will significantly improve the properties of materials, reduce their cost and improve the quality and reliability of structures and products. As such a device, the authors propose the use of a mathematical model, the statistical description of experimental data of which is linear regression. The initial substances for the formation of a microcapsulated heat-accumulating material are selected as input parameters of the system, and the output characteristics are dependent variables (specific heat of the phase transition, compressive strength). Based on the results of experimental studies and using the DataFit program.

1. Bodrov V. I., Shevchenko A. A., Ionychev E. G. Model′ energosberegayushchego proizvodstvennogo sel′skokhozyaystvennogo zdaniya [Model of an energy-efficient production agricultural building] // Izvestiya Vuzov. Stroitel′stvo. Izvestia of Higher Education Institutions. Construction. 2005. No. 9. P. 114–116. (In Russ.).

2. Matrosov Yu. A. Energosberezheniye v zdaniyakh. Problema i puti ee resheniya [Energy saving in buildings. The problem and how to solve it]. Moscow, 2008. 496 p. (In Russ.).

3. Mal′tsev A. V. Energosberegayushchiye ograzhdayushchiye konstruktsii s ispol′zovaniyem mestnykh materialov pri var′iruyemykh parametrakh teplomassoperenosa [Energy-saving building envelopes using local materials with varying heat and mass transfer parameters]. Penza, 2014. 169 p. (In Russ.).

4. Ob utverzhdenii Energeticheskoy strategii Rossii na period do 2030 goda: rasporyazheniye Pravitel′stva RF ot 13 noyabrya 2009 g. № 1715-r. [On Approval of Russia's Energy Strategy to 2030: Russian Government Order No. 1715-r of 13 November 2009]. URL: https://legalacts.ru/doc/rasporjazhenie-pravitelstvarf-ot-13112009-n-1715-r/ (accessed: 12.02.2023). (In Russ.).

5. SP 50.13330.2012. Svod pravil. Teplovaya zashchita zdaniy [SP 50.13330.2012. The course of rules. Thermal performance of the buildings]. Moscow, 2012. 96 p. (In Russ.).

6. SNiP 23-02-2003. Teplovaya zashchita zdaniy [SNiP 23- 02-2003. Thermal performance of the buildings]. Moscow, 2004. 25 p. (In Russ.).

7. Matrosov Yu. A. Sravnitel′nyy analiz territorial′nykh norm Rossii po energoeffektivnosti zhilykh zdaniy i novogo postanovleniya Germanii [Comparative analysis of Russian territorial standards for energy efficiency in residential buildings and the new German regulation] // Energosberezheniye. Energy Efficiency. 2002. No. 4. P. 60–63. (In Russ.).

8. SP 23–101-2000. Proyektirovaniye teplovoy zashchity zdaniy [SP 50.13330.2012. Thermal performance design of buildings]. Moscow, 2001. 95 p. (In Russ.).

9. Energosberezheniye v zdaniyakh. Normativy po teplozashchite i teplovodoelektrosnabzheniyu. MGSN 2.01.-99 [Energy-efficient in buildings. Standards for thermal protection and thermo-electricity. MGSN 2.01.-99.]. Moscow, 1999. 78 p. URL: https://ohranatruda.ru/upload/iblock/5fd/4294850043.pdf (accessed: 10.02.2023). (In Russ.).

10. Al′tshuller E. N. O pokazatele udel′noy energoyemkosti v industrial′nom domostroyenii [On the indicator of specific energy intensity in industrial house building] // Beton i zhelezobeton. Concrete and Reinforced Concrete. 1982. No. 8. P. 27–28. (In Russ.).

11. Al′tshuller E. N. Effektivnost′ primeneniya sloistykh sten v monolitnom domostroyenii Effectiveness of the use of laminated walls in monolithic construction // Beton i zhelezobeton. Concrete and Reinforced Concrete. 1993. No. 2. P. 27–28. (In Russ.).

12. Ushkov F. V., Tsaplev N. N. Energoyemkost′ i teplovaya effektivnost′ naruzhnykh sten [Energy intensity and thermal efficiency of exterior walls] // Zhilishchnoye stroitel′stvo. Housing Construction. 1981. No. 4. P. 11–12. (In Russ.).

13. Shkarin A. V. Sukhiye teploizolyatsionnyye smesi na kompozitsionnykh vyazhushchikh [Dry heat insulating mixtures based on composite binders]. Belgorod, 2013. 26 p. (In Russ.).

14. Buslenko N. P. Modelirovaniye slozhnykh sistem [Modelling of complex systems]. Moscow, 1988. 400 p. (In Russ.).

15. Haken H. Sinergetika. Ierarkhiya neustoychivostey v samoorganizuyushchikhsya sistemakh i ustroystvakh [Advanced Synergetics] / trans. from Engl. Yu. A. Danilova; ed. by Yu. L. Klimontovicha. Moscow, 1985. 419 p. (In Russ.).

16. Sovetov B. Ya., Yakovlev S. A. Modelirovaniye system [Systems Modeling]. 3nd ed. Moscow, 2001. 343 p. (In Russ.).

17. Shestak Ya. Teoriya termicheskogo analiza [Theory of thermal analysis]. Moscow, 1978. 528 p. (In Russ.).

18. Mayorova A. F. Termoanaliticheskiye metody issledovaniya [Thermoanalytical research methods] // Sorosovskiy obrazovatel′nyy zhurnal. Soros Education Journal. 1998. No. 10. P. 50–54. (In Russ.).

19. Hemminger W., Hohne G. Kalorimetriya. Teoriya i praktika [Calorimetry: Fundamentals and practice] / ed. by O. B. Salamatinoy. Moscow, 1989. 90 p. (In Russ.).

20. Yakovleva Yu. S. Rezul′taty eksperimental′nykh issledovaniy energoeffektivnogo stroitel′nogo materiala dlya ob′′yektov voyennoy infrastruktury [Experimental results on an energy-efficient building material for military infrastructure] // Aktual′nyye problemy yestestvennykh i tekhnicheskikh nauk. Current Issues in Natural and Technical Sciences. St. Petersburg, 2021. P. 295–302. (In Russ.).

21. Yakovleva Yu. S. Sovremennaya tekhnologiya polucheniya stroitel′nogo teploakkumuliruyushchego materiala [State-of-theart technology for building heat storage material] // Tendentsii razvitiya stroitel′stva ob′′yektov grazhdanskogo i spetsial′nogo naznacheniya. Trends in Civil and Special Construction Projects. Tyumen, 2022. P. 215–218. (In Russ.).

22. GOST P 58279-2018. Smesi sukhiye stroitel′nyye shtukaturnyye na gipsovom vyazhushchem. Tekhnicheskiye usloviya [Dry building levelling plaster mixes based on gypsum binder. Specifications]. Moscow, 2019. 16 p. (In Russ.).