Introduction to the "Theory of Compensation"

Fesenko, Andrii; Tsyhanenko, Liudmyla; Sribniak, Nataliia; Ujma, Adam

doi:10.17512/bozpe.2024.13.03

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Tytuł artykułu

Introduction to the "Theory of Compensation"

Autorzy

Fesenko Andrii , Tsyhanenko Liudmyla , Sribniak Nataliia , Ujma Adam

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DOI

10.17512/bozpe.2024.13.03

Warianty tytułu

Języki publikacji

Abstrakty

In this article, we systematize and emphasize the information elements that are the starting point for step-by-step actions related to the improvement of technological maps in accordance with the “energy model” to ensure sustainable sanitary and hygienic standards throughout the life cycle of buildings. In particular, we draw attention to the lack of analytical methodologies to visually or technically incorporate optimization measures to achieve the final building outcome in accordance with energy models A, B and C throughout the life cycle of buildings. These findings serve as a basis for research aimed at improving the analytical methods and ensuring their compliance with the established legal standards.

Słowa kluczowe

energy efficiency life cycle optimization compensation theory

efektywność energetyczna koło życia optymalizacja teoria kompensacji

Wydawca

Wydawnictwo Politechniki Częstochowskiej

Czasopismo

Budownictwo o Zoptymalizowanym Potencjale Energetycznym

Rocznik

2024

Tom

Vol. 13

Strony

23--34

Opis fizyczny

Bibliogr. 31 poz., rys.

Twórcy

autor

Fesenko Andrii

FALVI Limited Liability Company, Ukraine

https://orcid.org/0009-0003-4133-4947

autor

Tsyhanenko Liudmyla

Sumy National Agrarian University, Ukraine

https://orcid.org/0000-0002-6628-3635

autor

Sribniak Nataliia

Sumy National Agrarian University, Ukraine

https://orcid.org/0000-0003-3205-433X

autor

Ujma Adam

Czestochowa University of Technology, University of Applied Sciences in Nysa, Poland

https://orcid.org/0000-0001-5331-6808

Bibliografia

1. About Energy Efficiency of Buildings: Law of Ukraine of 22.06.2017 No. 2118-VIII: as of 3 August. 2023.
2. About Energy Efficiency. Bulletin of the Verkhovna Rada of Ukraine (VRU), 2022, No. 2, Art. 8. (As amended by Laws No. 2392-IX of 09.07.2022 No. 2710-IX of 03.11.2022 No. 3220-IX of 30.06.2023).
3. Bilous, I. Yu., Deshko, V.I. et al. (2015) Management of energy use efficiency of higher educational institutions. NTUU “KPI”, 157p. [in Ukrainian].
4. DSTU 9190:2022 Energy efficiency of buildings. Method for calculating energy consumption during heating, cooling, ventilation, lighting and hot water supply – SE “UkrNDNC”.
5. EN 15603:2008. Оverall energy use and definition of energy ratings. CEN. European Committee for Standardization. 2008.
6. EN 13790:2008. Calculation of energy use for space heating and cooling. CEN. European Committee for Standardization. 2008.
7. EN 12831:2003. Heating system in buildings – Method for calculation of the design heat load.CEN. European Committee for Standardization. 2003.
8. EN 13829:2000. Thermal performance of buildings- Determination of air permeability of buildings -Fan pressurization method. CEN. European Committee for Standardization. 2000.
9. EN 14501:2005. Blinds and shutters. Thermal and visual comfort. Performance characteristics and classification. CEN. European Committee for Standardization. 2005.
10. EN 13779:2007. Ventilation for non-residential buildings. Performance requirements for ventilation and room-conditioning systems. CEN. European Committee for Standardization. 2008.
11. EN 15217:2007. Energy performance of buildings – Methods for expressing energy performance and for energy certification of buildings. CEN. European Committee for Standardization. 2007.
12. EN 15232:2007. Energy performance of buildings – Impact of building automation, controls and building management. CEN. European Committee for Standardization. 2007.
13. EN 15316-2-1:2007. Heating system in buildings – Method for calculation of system energy requirements and system efficiencies. Part 1. CEN. European Committee for Standardization. 2007.
14. EN 7730:2005. Ergonomics of the thermal environment. Analytical determination and interpretation of thermal comfort using calculation of the PMV and PPD indices and local thermal comfort criteria. CEN. European Committee for Standardization. 2005.
15. Franco, A., Miserocchi, L. & Testi, D. (2023) Energy efficiency in shared buildings: Quantification of the potential at multiple scales. Energy Reports, 9, 84-95.
16. Fesenko, A. & Tsyhanenko, L. (2023) On the issue of energy efficiency of residential buildings. Proceedings of the International Scientific and Technical Online Conference. Problems of Building and Transportation, Problems of the Construction and Transport Complexes. Central National Technical University, p. 161-162 [in Ukrainian].
17. Geikins, A. (2022) Methodology for Evaluation of Energy Efficiency of Unclassified Buildings. RTU Press.
18. Hromadka, V. (2023) Optimizing energy-saving measures in new residential buildings regarding life-cycle costs. Buildings, 13(8), 1907.
19. Huang, C. (2023) Discussion on optimization measures of building construction management technology. Journal of Architectural Research and Development, 7(1), 17-24.
20. Hummel, M., Muller, A., Forthuber, S., Krenzl, L., Mayr, B. & Haas, R. (2023) How cost-efficient is energy efficiency in buildings? A comparison of building shell efficiency and heating system change in the European building stock. Energy Efficiency, 16(5), 32.
21. Juszczyk, S. (2021) Theory and its characteristics: discourse in the field of social sciences. Athenaeum. Polskie Studia Politologiczne, 69(1), 134-144.
22. Karimi, H., Adibhesami, M.A., Bazazzadek, H. & Morafagh, S. (2023) Green buildings: Human-centered and energy efficiency optimization strategies. Energies, 16(9), 3681.
23. Kuzionko-Ochrymiuk, E. (2020) Scientific canons in the process of knowledge creation. In: Grząba, M., III Ogolnopolska Konferencja Naukowa Wspołczesne problemy ekonomiczne w badaniach młodych naukowcow (online). Białystok, Wydawnictwo Uniwersytetu w Białymstoku.
24. Lapa, M., Dvoieglazova, M., Pechonkin, I. & Lapa, Y. (2017) Providing of buildings energoefficiency. Technical Sciences and Technologies (online), 1(7), 225-233 [in Ukrainian].
25. On the National Energy Efficiency Action Plan for the period up to 2030: Decree of the Cabinet of Ministers of Ukraine dated 29.12.2021.
26. Papadakis, N. & Katsaprakakis, D.A. (2023) A review of energy efficiency interventions in public buildings. Energies, 16(17), 6329.
27. Popper, K. (1935) Logik der Forschung. Verlag Vox Julius Springer.
28. Rodriguez, J.S.T. et al. (2023) The interconnection between energy efficiency and CO2 mitigation in the development of multifamily buildings. International Journal of Membrane Science and Technology, 10(3), 1333-1339.
29. Vilinska, L.M., Burlak, H.M. & Gurska, A.V. (2023) Energy efficiency of an apartment building. Ukrainian Journal of Civil Engineering and Architecture, 3(015), ISSN 2710-0367 (Print), ISSN 2710-0375 (online) [in Ukrainian].
30. Walter, I., Tanasković, M. & Stanković, M. (2023) Energy efficiency assessment for buildings based on the generative adversarial network structure. Eng-Advances in Engineering, 4(3), 2178-2190.
31. What Is a Theory? A Scientific Definition – AMNH (online), (no date). American Museum of Natural History.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024).

Typ dokumentu

Bibliografia

Identyfikator YADDA

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