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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 633-634Hydraulic Methods for Calculation of System of...

Hydraulic Methods for Calculation of System of Rear Ventilated Facades

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Abstract:

In this article the capacity of systems of rear ventilated facades is defined. In work theoretical dependences of the main characteristics of the flow, helping to pick up an optimum design in thermogravitational convection conditions are offered.

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Advanced Materials and Processes IV

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Periodical:

Applied Mechanics and Materials (Volumes 633-634)

Pages:

1007-1012

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.633-634.1007

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Online since:

September 2014

Authors:

Nikolay Vatin, Mikhail Petrichenko, Darya Nemova*

Keywords:

Efficiency, Energy Building, Energy Saving, External Envelops, Renovation of Facades, System of Rear Ventilated Facades, Thermogravitational Convection

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© 2014 Trans Tech Publications Ltd. All Rights Reserved

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[1] V.G. Gagarin: Teplofizicheskie problemyi sovremennyih stenovyih ograzhdayuschih konstruktsiy mnogoetazhnyih zdaniy, Akademiya. Arhitektura i stroitelstvo, 5 (2009) pp.297-305.

[2] V.G. Gagarin, V.V. Kozlov: O normirovanii teplopoter cherez obolochku zdaniya, Akademiya. Arhitektura i stroitelstvo, 3 (2010) pp.279-286.

[3] A.S. Gorshkov: The energy efficiency in the field of construction: questions of norms and standarts and solutions for the reduction of energy consumption at buildings, Magazine of Civil Engineering, 1 (2010) рр. 9-13.

[4] N.I. Vatin, A.S. Gorshkov, D.V. Nemova, A.A. Staritcyna, D.S. Tarasova: Increase of energy efficiency for educational institution building, Advanced Materials Research, Vols. 941-944 (2014) pp.905-920.

DOI: 10.4028/www.scientific.net/amr.941-944.905

[5] N.I. Vatin, D.V. Nemova: Increase of power efficiency of buildings of kindergartens, Construction of Unique Buildings and Structures, 3 (2012) pp.52-76.

[6] D.N. Tseytin, D.V. Nemova, E.V. Kurasova: Autonomous power installation with complex power effective electroproviding, Construction of Unique Buildings and Structures, 5 (2013) pp.1-11.

[7] M.R. Petrichenko: Nonsteady filtration in a uniform soil mass, Power Technology and Engineering, (2012) pp.1-3.

[8] M.R. Petrichenko, V.N. Bukhartsev: Problem of filtration in a uniform rectangular soil mass is solved by variational principles, Power Technology and Engineering, 46 (3) (2012) pp.185-189.

DOI: 10.1007/s10749-012-0329-6

[9] V.N. Bukhartsev, M.R. Petrichenko: Approximation of the depression curve of the inflow to an ideal trench, Power Technology and Engineering, 44 (5) (2011) pp.374-377.

DOI: 10.1007/s10749-011-0193-9

[10] M.R. Petrichenko, N.S. Khar'kov: Experimental study of the pumping action of helical flow, Technical Physics, 54 (7) (2009) pp.1063-1065.

DOI: 10.1134/s1063784209070238

[11] M.R. Petrichenko: Convective heat and mass transfer in combustion chambers of piston engines. Basic results, Heat transfer. Soviet research, United States 23 (5) (1991) pp.703-715.

[12] R.M. Petrichenko, A.B. Kanishchev, L.A. Zakharov, B. Kandakzhi: Some principles of combustion of homogeneous fuel-air mixtures in the cylinder of an internal combustion engine Journal of Engineering Physics, 59 (6) (1990) pp.1539-1544.

DOI: 10.1007/bf00870411

[13] R.M. Petrichenko, A. Yu. Shabanov: Hydrodynamics of oil film under internal combustion engine piston rings, Trudy LPI, 411 (1985) pp.38-42.

[14] N.I. Vatin: Weight vector of a conduction transducer of a correlation flowmeter, Magnetohydrodynamics New York, N.Y., 21 (3) (1985) pp.316-320.

[15] N.I. Vatin, T.N. Mikhailova: Computation of cross correlation function of induced potential for developed turbulent flow with axisymmetric mean velocity profile, Magnetohydrodynamics New York, N.Y., 22 (4) (1986) pp.385-390.

[16] A. Borodinecs, B. Gaujena: The implementation of building envelopes with controlled thermal resistance. 10th International Conference on Healthy Buildings (2012) pp.1715-1722.

[17] A. Kaklauskas, J. Rute. E. Zavadskas, A. Daniunas. V. Pruskus, J. Bivainis, R. Gudauskas, V. Plakys: Passive House model for quantitative and qualitative analyses and its intelligent system Energy and Buildings, 50 (2012) pp.7-18.

DOI: 10.1016/j.enbuild.2012.03.008

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

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

[19] N.I. Vatin, A.S. Gorshkov, D.V. Nemova, A.A. Staritcyna, D.S. Tarasova: The energy-efficient heat insulation thickness for systems of hinged ventilated facades (Advanced Materials Research, Switzerland 2014).

DOI: 10.4028/www.scientific.net/amr.941-944.905

[20] N. Vatin, V. Murgul, G. Radovic: Fast urban development of Cetinje – old royal capital of Montenegro (Applied Mechanics and Materials, Switzerland 2014).

DOI: 10.4028/www.scientific.net/amm.584-586.564