Paper Titles

Calculation Method of Justification of Technical Actions for Prevention of Ice Dams Formation on Buildings with a Pitched Roof
p.9

Fire Resistance of Non-Crack Resistant Flexural Reinforced Concrete Elements
p.15

Heat and Mass Transfer in Low-Temperature Insulation in Moisture Conditions
p.21

Comparison of Different Types of Transparent Structures for High-Rise Buildings with a Fully Glazed Facade
p.26

Prodrome in Experimental Investigation the Thermal Shielding Systems in Enclosure Structures
p.34

Improvement of the Double Skin Facades
p.41

Reduced Thermal Resistance of a Two-Layer Wall Construction
p.49

Unsteady Temperature Condition of the Enclosure Structure
p.57

Unsteady Airway as an Effective Method of the Ice Melting Prevention on the Building’s Roof
p.63

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 725-726Prodrome in Experimental Investigation the Thermal...

Prodrome in Experimental Investigation the Thermal Shielding Systems in Enclosure Structures

Article Preview

Abstract:

This work is devoted to description the outset of research the modern thermal shielding systems on the model of house, and desired outcome. Results can be basement for modernisation of building regulation, in prospect. Experiment consists in tests conducting and drafting of troubleshooting guideline.

You might also be interested in these eBooks

Innovative Technologies in Development of Construction Industry

Info:

Periodical:

Applied Mechanics and Materials (Volumes 725-726)

Pages:

34-40

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.725-726.34

Citation:

Cite this paper

Online since:

January 2015

Authors:

Nikolay Vatin, Issa Togo, Vladimir Bespalov*, Dmitriy Kuzmenkov, German Panteleev, Dmitriy Smirnitskiy

Keywords:

Building Materials, Construction, Enclosure Structure, Energy Efficiency, Energy-Savings, Engineering, Experimentation, Heat Loss, Heat Transfer Resistance

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2015 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

* - Corresponding Author

[1] Gorshkov, A.S., Nemova, D.V., Vatin, N.I. The energy saving formula [Formula energoeffektivnosti] (2013) Construction of Unique Buildings and Structures, 7, pp.49-63.

[2] Semenov, V.N., Korolev, D.U., Lukinov, V.A. Issledovaniye vliyaniya energoeffektivnykh pokrytiy na teplovuyu zashchitu zdaniy [Study of impact energy-efficiency covering on building heat insulation] (2011) Nauchnyi vestnik, 4, pp.36-44.

[3] Federal statute of 23. 11. 2009 N 261-FZ Ob energoeffektivnosti i o povyshenii energeticheskoy effectivnosti i o vnesenii izmeneniy v otdelnye zakonodatelnye akty Rossiyskoy Federatsii.

DOI: 10.31085/9785392337583-2020-184

[4] Fidrikova, A. S., Grishina, O. S., Marichev, A. P., Rakova, X. M. Energy-efficient technologies in the construction of school in hot climates (2014) Applied Mechanics and Materials, 587-589, pp.287-293.

DOI: 10.4028/www.scientific.net/amm.587-589.287

[5] Platonova, M.A., Vatin, N.I., Nemova, D.V., Matoshkina, S.A., Iotti, D., Togo, I. The influence of the airproof composition on the thermo technical characteristics of the enclosing structures [Vliyanie vozdukhoizolyatsionnogo sostava na termo tekhnicheskie kharakteristiki ograjdayushchikh konstruktsiy] (2014).

[6] Gonçalvesa M.R.F., Bergmann C.P. Thermal insulators made with rice husk ashes: Production and correlation between properties and microstructure (2007) Construction and Building Materials, p.2059–(2065).

DOI: 10.1016/j.conbuildmat.2006.05.057

[7] Harren-Lewisa, T., Rangavajhalab, S., Messacc, A., Zhangd, J. Optimization-based feasibility study of an active thermal insulator (2012) Building and Environment. 53. p.7–15.

DOI: 10.1016/j.buildenv.2012.01.002

[8] Vatin, N., Gorshkov, A., Kazimirova, A., Gureev, K., Nemova, D. Calculation of payback period mineral wool with longitudinal fibers of ITE PARISO (PAREXLANKO) (2014) Journal of Applied Engineering Science, 294, pp.207-216.

DOI: 10.5937/jaes12-6552

[9] Gorelik, P.I., Zolotova, U.S. Modern thermal insulation materials and some features of their application [Sovremennye teploizolyatsionnye materialy i osobennosti ikh primeneniya] (2014).

[10] Gorshkov, A.S. Puti povysheniya energoeffektivnosti ograjdayuschikh konstruktsiy zdaniy [The ways of increase energy-efficiency enclosure structures of buildings] (2009).

[11] Vatin, N.I., Nemova, D.V. Increase of power efficiency of buildings of kindergartens [Povyshenie energoeffektivnosti zdaniy detskikh sadov] (2012) Construction of Unique Buildings and Structures, 3, pp.52-76.

[12] Teplova, Z.S., Solovyeva, K.I., Nemova, D. V, Trubina, D.A., Petrosova, D.V. Thermo technical calculation of enclosure structure of comprehensive school [Termo tekhnicheskiy raschet ograjdayuschey konstruktsii obshcheobrazovatelnoy shkoly] (2014).

[13] Karin, B., Geir, A., Sverre, T. Ambitious Renovation of a Historical School Building in Cold Climate (2014) Energy Procedia, 46, pp.1442-1448.

DOI: 10.1016/j.egypro.2014.02.163

[14] Kang, D. -H., Lorente, S., Bejan, A. Constructal distribution of multi-layer insulation (2013) International Journal of Energy Research, 37, pp.153-160.

DOI: 10.1002/er.1895

[15] Nizovtsev, M.I., Belyi, V.T. Sterlygov, A.N. The facade system with ventilated channels for thermal insulation of newly constructed and renovated buildings (2014) Energy and Buildings, 75, pp.60-69.

DOI: 10.1016/j.enbuild.2014.02.003

[16] Rahmi, A. The Role of Building Thermal Simulation for Energy Efficient Building Design (2014) Energy Procedia, 47, pp.217-226.

DOI: 10.1016/j.egypro.2014.01.217

[17] Tech album. Façade insulation system ITE PARISO МВ and PPS.

[18] SNiP II-3-79* Stroitelnaya teplotekhnika [Construction Norms and Regulations; construction heat engineering].

[19] Vatin, N.I., Nemova, D.V., Kazimirova, A.S., Gureev, K.N. Increase of energy efficiency of the building of kindergarten (2014) Advanced Materials Research, 953-954, pp.1537-1544.

DOI: 10.4028/www.scientific.net/amr.953-954.1537

[20] Penic, M., Vatin, N., Murgul, V. Double skin facades in energy efficient design (2014) Applied Mechanics and Materials, 680, pp.534-538.

DOI: 10.4028/www.scientific.net/amm.680.534