English
Русский 50-55 p.
The article raises issues related to the use of profile glass (glass profilite) in the device of external vertical enclosing structures of modern building systems. There is a need for a combination of composite materials, especially foam composite, in the manufacture of translucent enclosing structures, which greatly reduces the weight of the outer panels and increases their heat and sound insulation characteristics. It is emphasized the need to consider the issues of energy efficiency not only at the stage of operation of the building, but also at the stage of its construction, as energy efficiency is not only the ability to save heat at the stage of operation of buildings, but also high technological performance of works at the stage of their construction.
The novelty of this study is just the design of the wall panel with a possible combination of two materials – profiled glass and foam. The article describes in detail not only the design of the panel itself, but the technology of its manufacture, as well as the technological processes associated with the device of enclosing structures. Two variants of connection of wall panels with floor slabs are considered and connection nodes are given. Based on the analysis of a number of scientific publications, the variants of the mechanisms used for the installation of panels taking into account the nodes of the connection of structural elements – the panel itself and the floor slabs are considered. Due to the fact that the article discusses the use of boxed glass, emphasizes the need to continue the study in order to identify the possibility of using other types of glass (channel, ribbed, edged) for the manufacture of multi-component wall panels, taking into account the climatic conditions of the regions.
The novelty of this study is just the design of the wall panel with a possible combination of two materials – profiled glass and foam. The article describes in detail not only the design of the panel itself, but the technology of its manufacture, as well as the technological processes associated with the device of enclosing structures. Two variants of connection of wall panels with floor slabs are considered and connection nodes are given. Based on the analysis of a number of scientific publications, the variants of the mechanisms used for the installation of panels taking into account the nodes of the connection of structural elements – the panel itself and the floor slabs are considered. Due to the fact that the article discusses the use of boxed glass, emphasizes the need to continue the study in order to identify the possibility of using other types of glass (channel, ribbed, edged) for the manufacture of multi-component wall panels, taking into account the climatic conditions of the regions.
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16. Ortiz J.A., A. de la Fuente, Sebastia F.M., Segura I. at al. Steelfibre-reinforced self-compacting concrete with 100% recycled mixed aggregates suitable for structural applications. Construction and Building Materials. 2017. 156. P. 230 – 241.
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2. Bedon C., Zhang XH., Santos F., Honfi D. at al. Lange, Performance of structural glass facades under extreme loads – Design methods, existing research, current issues and trends. Construction and Building Materials. 2018. 163. P. 921 – 937.
3. Sun Y.Y., Liang R.Q., Wu Y.P., Wilson R. Glazing systems with Parallel Slats Transparent Insulation Material (PS-TIM): Evaluation of building energy and daylight performance. Energy and Buildings. 2018. 159. P. 213 – 227.
4. Attoye D.E., Aoul K.A.T., Hassan A. Review on Building Integrated Photovoltaic Facade Customization Potentials. Sustainability. 2017. 9 (12). Article number: 2287.
5. Vigna I., Bianco L., Goia F., Serra V. Phase Change Materials in Transparent Building Envelopes: A Strengths, Weakness, Opportunities and Threats (SWOT) Analysis. Energies. 2018. 11 (1). Article number: 111.
6. Ilter S., Vural S.M. Cross method and design process for DSF elements. Open house international. 2017. 42 (2). P. 36 – 43.
7. Giovannini L., Goia F., Lo Verso V.R.M., Serra V. Phase Change Materials in glazing: implications on light distribution and visual comfort. Preliminary results. Energy Procedia. 2017. 11. P. 367 – 376.
8. Nikitin Yu., Murgul V., Vatin N., Pukhkal V.Uses of Glass in Architecture: Heat Losses of Buildings Based on Translucent Structures. Applied Mechanics and Materials. 2014. 680. P. 481 – 485.
9. Ihara T., Gao T., Grynning S., Jelle B.P. at al.Aerogel granulate glazing facades and their application potential from an energy saving perspective. Applied Energy. 2015. 142. P. 179 – 191.
10. Cuerda E., Perez M., Neila J. Facade typologies as a tool for selecting refurbishment measures for the Spanish residential building stock. Energy and Buildings. 2014. 76. P. 119 – 129.
11. Guerlich D., Reber A., Biesinger A., Eicker U. Daylight Performance of a Translucent Textile Membrane Roof with Thermal Insulation. Buildings. 2018. 8 (9). (Article number: 118.
12. Souayfane F., Biwole P.H., Fardoun F. Thermal behavior of a translucent superinsulated latent heat energy storage wall in summertime. Applied Energy. 2018. 217. P. 390 – 408.
13. Sun Y.Y., Wu Y.P., Wilson R. Analysis of the daylight performance of a glazing system with Parallel Slat Transparent Insulation Material (PS-TIM). Energy And Buildings. 2017. 139. P. 616 – 653.
14. Akhmyarov T.A., Spiridonov A.V., Shubin I.L. New Solutions for Translucent Structures. Light & Engineering. 2016. 24 (1). P. 66 – 72.
15. Mohajerani A., Vajna J., Cheung T.H.H., Kurmus H. at al. Practical recycling applications of crushed waste glass in construction materials: A review. Construction and Building Materials. 2017. 156. P. 443 – 467.
16. Ortiz J.A., A. de la Fuente, Sebastia F.M., Segura I. at al. Steelfibre-reinforced self-compacting concrete with 100% recycled mixed aggregates suitable for structural applications. Construction and Building Materials. 2017. 156. P. 230 – 241.
17. Leone M., Centonze G., Colonna D., Micelli F. at al. Fiberreinforced concrete with low content of recycled steel fiber: Shear behavior. Construction and Building Materials. 2018. 161. P. 141 – 155.
Abramyan S.G., Polyakov V.G., Oganesyan O.V. External translucent coatings device with the use of glassprofite and composite materials. Construction Materials and Products. 2019. 2 (4). P. 50 – 55. https://doi.org/10.34031/2618-7183-2019-2-4-50-55