Paper Titles

An Investigation of Photocatalytic Activity of Coatings Based on Strontium Bismuthate Deposited on a Ceramic Carrier
p.987

Features of Femtosecond Micromachining of Solid Transparent Materials
p.993

Influence of Three-Component Barrier Layers on Optical Properties of Photodetectors with Quantum Dots
p.999

Numerical Modeling of the Anomalous Low-Temperature Dependence of the Tunneling Conductance of a "Dirty" N-I-N Junction
p.1004

The Possibility of Using the Ultra-Thin Liquid Thermal Insulation to Insulate the Ceiling above the Basement in Residential Buildings
p.1013

Influence of High-Calcium Ash Composition on the Composite Binders’ Properties
p.1019

Geo-Composite Drainage Material for Hydro-Technical and Civil Engineering
p.1025

New Types of Geo-Composite Materials for Anti-Filtration Systems
p.1031

Technology of 3D Printing of Light Ceramics for Construction Products
p.1038

HomeSolid State PhenomenaSolid State Phenomena Vol. 316The Possibility of Using the Ultra-Thin Liquid...

The Possibility of Using the Ultra-Thin Liquid Thermal Insulation to Insulate the Ceiling above the Basement in Residential Buildings

Article Preview

Abstract:

The issues of energy saving, as well as comfortable operation of buildings in modern construction practice are relevant. The experience of operation of the premises, located above the basement, shows that the most common problem is the cooling of the floor slab and, as a consequence, the presence of a cold floor. The article presents the results of calculations on the change of thermal properties of the ceiling above the basement in residential buildings. A variant of insulation of the ceiling with ultra-thin liquid insulation is proposed. The graphical analysis of the problem is carried. As a result of graphical analysis, it was revealed that the proposed method of insulation makes it possible to increase the floor temperature in the rooms of the ground floor in the residential buildings.

You might also be interested in these eBooks

Materials Engineering and Technologies for Production and Processing VI

Info:

Periodical:

Solid State Phenomena (Volume 316)

Pages:

1013-1018

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.316.1013

Citation:

Cite this paper

Online since:

April 2021

Authors:

Oleg V. Burlachenko, Oksana G. Chesnokova, Tatiana F. Cherednichenko*

Keywords:

Calculation of Temperature Fields, Energy Saving, Thermal Properties of Materials, Thermal Protection of Buildings

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2021 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

* - Corresponding Author

[1] A. Trabelsi, R. Belarbi, K. Abahri, M. Qin, Assessment of temperature gradient effects on moisture transfer through thermogradient coefficient, Building Simulation, 3 (2012) 107–115.

DOI: 10.1007/s12273-012-0063-x

[2] C. Siligardi, P. Miselli, E. Francia, et al., Temperature-induced microstructural changes of fiber-reinforced silica aerogel (FRAB) and rock wool thermal insulation materials: A comparative study, Energy and Buildings, 138 (2017) 80-87.

DOI: 10.1016/j.enbuild.2016.12.022

[3] O.G. Chesnokova, V.D. Chesnokova, T.F. Cherednichenko, Use of ultrathin insulation to protect monolithic concrete slab, Bullet. of Volgograd state university of architecture and construction. Series: Construction and architecture, 50 (69) (2017) 16-23/.

[4] O.V. Burlachenko, O.G. Chesnokova, T.F. Cherednichenko, Research of thermophysical properties of the ultrathin liquid heat-insulation, J. of Solid State Phenomena 284 (2018) 1080-1085.

DOI: 10.4028/www.scientific.net/ssp.284.1080

[5] O.G. Chesnokova. The use of the superfine insulation to prevent freezing of the steel window lintels, ,Bullet. of Volgograd state university of architecture and construction. Series: Construction and architecture, 45 (64) (2016) 94-101.

[6] O.G. Chesnokova, А.G. Grigorov, The analysis of the distribution of temperature fields of the upper slope of the window depending on the construction of steel lintels, International center for innovative research Omega Science,, Ufa, KON 96 (2) (2016) 208-211.

[7] O.V. Burlachenko, O.G. Chesnokova, T.F. Cherednichenko, Effective way to improve thermophysical properties of exterior walls of brick buildings during reconstruction, IOP Conference Series: Materials Science and Engineering,451 (2018) 012050.

DOI: 10.1088/1757-899x/451/1/012050

[8] O.G. Chesnokova, V.D. Tukharely, A.V. Tukharely, The possibility of using the ultrafine liquid thermal insulation to protect the load-bearing reinforced concrete elements in multi-layered outer wall [Electronic resource], Engineering journal of Don, 2 (2017) 9.

[9] O.G. Chesnokova, The use of ultra-thin insulation to avoid freezing of the steel window lintels [Electronic resource], Modern scientific research: current theories and concepts, Scientific centre Olympus,, Moscow, (2016) 302-307.

[10] O.G. Chesnokova, А.G. Grigorov, The analysis of the distribution of temperature fields of boundary areas of the frame with the external insulation, Science in the modern world: theory and practice, Research Center of legal information technologies, Ufa, 1(4), (2016) 14-18.

[11] A.G. Perekhojentsev, O.G. Chesnokova, The possibility of using hyperfine thermal insulation to improve the thermal properties of enclosing structures, Internet-Vestnik VolgGASU. Ser. Polythematic, 2 (38) (2015).

[12] N. Williams Portal, A. Sasic Kalagasidis, A.W.M. van Schijndel, Evaluation of heat and moisture induced stress and strain of historic building materials and artefacts, Building Simulation, 7 (3) (2014) 217–227.

DOI: 10.1007/s12273-013-0153-4

[13] Menyhart K., Krarti M. Potential energy savings from deployment of dynamic insulation materials for US residential buildings, Building and Environment, 114 (2017) 203-218.

DOI: 10.1016/j.buildenv.2016.12.009

[14] A. Lakatos Comprehensive thermal transmittance investigations carried out on opaque aerogel insulationblanket, Materials and Structures, 50 (1) (2017), article number: UNSP 2.

DOI: 10.1617/s11527-016-0876-7

[15] V. Koshí, J. Madera, R. Cherny, Exterior thermal insulation systems for AAC building envelopes: Computational analysis aimed at increasing service life, Energy and Buildings, 47 (2012) 84–90.

DOI: 10.1016/j.enbuild.2011.11.030

[16] O.G. Chesnokova The possibility of using ultra-thin liquid insulation to protect the steel embedded elements in a multi-layer exterior wall, New science: experience, tradition, innovation, Sterlitamak: International research agency, 2 (2) (2017) 130-135.

[17] F. Roberz, R. C. G. M. Loonen, P. Hoes, et al. Ultra-lightweight concrete: Energy and comfort performance evaluation in relation to buildings with low and high thermal mass, Energy and Buildings, 138 (2017) 432-442.

DOI: 10.1016/j.enbuild.2016.12.049

[18] A.G. Perekhojentsev, I.Y. Grundo, Climate effects on the surface layers of cladding of buildings, Quality оf indoor and environment air, Volgograd: VolgGASU, (2016) 80-89.

[19] M. Alam, H. Singh, S. Suresh, et al., Energy and economic analysis of Vacuum Insulation Panels used in non-domestic buildings, Applied Energy, 188 (2017) 1-8.

DOI: 10.1016/j.apenergy.2016.11.115

[20] O.G. Chesnokova, Analysis of moisture accumulation in foam concrete block, Bullet. of Volgograd state university of architecture and construction. Series: Construction and architecture, 47 (66) (2017) 70-81.

[21] O.G. Chesnokova, Comparative analysis of moisture accumulation in the enclosing structure depending on the location of the insulation layer, Bullet. of Volgograd state university of architecture and construction. Series: Construction and architecture, 47 (66) (2017) 51-60.

[22] H. Janssen, A comment to «Assessment of temperature gradient effects on moisture transfer through thermogradient coefficient», Building Simulation, 6 (2013) 103–108.

DOI: 10.1007/s12273-012-0099-y

[23] A.G. Perekhojentsev, I.Y. Grundo, Temperature and humidity state of the surface layers of the outer walling of buildings, Bullet. of construction equipment, 6 (982) (2016) 70-71.