AbstractAbout AuthorsReferences
At present, residential and public buildings with a large area of faсade glazing are widely spread. Increasing the area of translucent structures leads to increasing the heat losses and reducing the specific heat protection characteristic of the building. When designing the heat protection of the buildings, it is necessary to strive for creating the harmonically insulated shell meeting the normative requirements. The problem of determining the maximal coefficient of facade glazing meeting the complex requirement of heat protection is considered. The influence of the change in the reduced resistance to heat transfer of some fragments of the heat protection shell on the maximum value of the glazing coefficient has been analyzed. It is shown by example that the redistribution of costs for the construction of various fragments of the heat protecting shell makes it possible o achieve the necessary coefficient of facade glazing meeting the normative requirements
D.V. KRAYNOV, Candidate of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.)
Kazan State University of Architecture and Engineering (1, Zelenaya Street, 420043, Kazan, Russian Federation)
1. Gagarin V. G., Zemcov V.A., Igumnov N.M. Equal efficiency of window blocks by thermal protection and light transmission parameters. Vestnik otdelenija stroitel’nyh nauk RAASN. Belgorod. 2008. No. 12, pp. 342–349. (In Russian).
2. Korkina E.V. Comprehensive comparison of window blocks for lighting and thermotechnical parameters. Zhilishhnoe Stroitel’stvo [Housing Construction]. 2015. No. 6, pp. 60–62. (In Russian).
3. Halikova F.R., Kuprijanov V.N. Experimental studies of the penetration of UV radiation through window glass. Vestnik MGSU. 2011. No. 3. P. 2, pp. 30–35. (In Russian).
4. Maljavina E.G., Frolova A.A. Analysis of annual energy consumption for heating and cooling office building. AVOK: Ventiljacija, otoplenie, kondicionirovanie vozduha, teplosnabzhenie i stroitel’naja teplofizika. 2017. P. 1. No. 1, pp. 68–75. (In Russian).
5. Kozlov V.V. Basics of optimization of thermal protection of enclosing structures by energy-saving activities recoupment. Stroitel’nye Materialy [Construction Materials]. 2013. No. 6, pp. 10–13. (In Russian).
6. SP 50.13330.2012. Teplovaya zashchita zdanii. Aktualizirovannaya redaktsiya SNiP 23-02–2003 [Thermal performance of the buildings. Actualized edition of SNiP 23-02–2003]. Moscow: Minregion Rossii. 2012. 95 p.
7. SNiP 23-02–2003. Teplovaya zashchita zdanii [Thermal performance of the buildings]. Moscow: TsITP Gosstroya Rossii. 2003. 70 p.
2. Korkina E.V. Comprehensive comparison of window blocks for lighting and thermotechnical parameters. Zhilishhnoe Stroitel’stvo [Housing Construction]. 2015. No. 6, pp. 60–62. (In Russian).
3. Halikova F.R., Kuprijanov V.N. Experimental studies of the penetration of UV radiation through window glass. Vestnik MGSU. 2011. No. 3. P. 2, pp. 30–35. (In Russian).
4. Maljavina E.G., Frolova A.A. Analysis of annual energy consumption for heating and cooling office building. AVOK: Ventiljacija, otoplenie, kondicionirovanie vozduha, teplosnabzhenie i stroitel’naja teplofizika. 2017. P. 1. No. 1, pp. 68–75. (In Russian).
5. Kozlov V.V. Basics of optimization of thermal protection of enclosing structures by energy-saving activities recoupment. Stroitel’nye Materialy [Construction Materials]. 2013. No. 6, pp. 10–13. (In Russian).
6. SP 50.13330.2012. Teplovaya zashchita zdanii. Aktualizirovannaya redaktsiya SNiP 23-02–2003 [Thermal performance of the buildings. Actualized edition of SNiP 23-02–2003]. Moscow: Minregion Rossii. 2012. 95 p.
7. SNiP 23-02–2003. Teplovaya zashchita zdanii [Thermal performance of the buildings]. Moscow: TsITP Gosstroya Rossii. 2003. 70 p.
For citation: Kraynov D.V. Accounting of glazing of the faсade when designing the heat protection of a building. Stroitel’nye Materialy [Construction Materials]. 2017. No. 6, pp. 32–34. DOI: https://doi.org/10.31659/0585-430X-2017-749-6-32-34. (In Russian).