Paper Titles

The Brickwork Joints Effect on the Thermotechnical Uniformity of the Exterior Walls from Gas-Concrete Blocks
p.3

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

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 725-726Comparison of Different Types of Transparent...

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

Article Preview

Abstract:

Transparent structures are widely used in the construction of modern high-rise buildings. It is necessary to consider a number of important features in selecting of suitable design of the construction. These are energy efficiency, durability, simplicity of installation, exterior of the building, cost of the construction and payback period. The aim of this work is to determine the most appropriate transparent structure for high-rise buildings with a fully glazed facade according to these requirements. Accomplish this aim such challenges as comparison of characteristics of different methods of glazing, energy efficiency and cost-effectiveness problems were figured out. Basing on this comparison, most suitable transparent structures for the various priority factors have been identified.

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:

26-33

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.725-726.26

Citation:

Cite this paper

Online since:

January 2015

Authors:

Darya Nemova, Elisaveta Reich*, Svetlana Subbotina, Faina Khayrutdinova

Keywords:

Enclosing Structures, Energy Efficiency, Energy Savings, Heat Loss, Post-Bar Glazing, Spider Glazing System, Structural Glazing, Transparent Structures, Ventilated Double-Skin Faсade

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] Begoulev S.A. Experience reduce thermal requirements for the building envelope in the North-West region (2007) Building materials, 2, pp.18-19.

[2] Vatin N.I., Nemova D.V., Rymkevich P.P., Gorshkov A.S. Vliyaniye urovnya teplovoy zashchity ograzhdayushchikh konstruktsiy na velichinu poter teplovoy energii v zdanii [Influence of level of enclosing structures heat protection on the value of heat loss in a building] (2012).

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

[4] Darkwa J., Li Y. Chow, D.H.C. Heat transfer and air movement behaviour in a double-skin façade (2014) Sustainable Cities and Society, 10, pp.130-139.

DOI: 10.1016/j.scs.2013.07.002

[5] Vyzantiadou M.A., Avdelas A.V. Point fixed glazing systems: technological and morphological aspects (2004) Journal of Constructional Steel Research, 60 (8), pp.1227-1240.

DOI: 10.1016/j.jcsr.2003.11.005

[6] Freire R.Z., Mazuroski W., Abadie M.O., Mendes N. Capacitive effect on the heat transfer through building glazing systems (2011) Applied Energy, 88 (12), pp.4310-4319.

DOI: 10.1016/j.apenergy.2011.04.006

[7] Gorshkov A.S., Zadvinskaya T.O. Comprehensive method of energy efficiency of residential house (2014) Advanced Materials Research, pp.1570-1577.

DOI: 10.4028/www.scientific.net/amr.953-954.1570

[8] Kanga N.N., Choa S.H., Kimb J.T. The energy-saving effects of apartment residents awareness and behavior (2012) Energy and Buildings, 46, p.112–122.

DOI: 10.1016/j.enbuild.2011.10.039

[9] Spiridonov A. V. Razvitiye svetoprozrachnykh konstruktsiy v kontekste sovremennoy istorii energosberezheniya [Development of transparent structures within the context of contemporary history of energy savings] (2011) Energosberezheniye, 5.

[10] Murgul V. Solar energy systems in the reconstruction of heritage historical buildings of the northern towns (for example Sankt-Petersburg) (2014) Journal of Applied Engineering Science, 12 (2), pp.121-128.

DOI: 10.5937/jaes12-6136

[11] Murgul V. Features of energy efficient upgrade of historic buildings (illustrated with the example of Saint-Petersburg) (2014) Journal of Applied Engineering Science, 12 (1), pp.1-10.

DOI: 10.5937/jaes12-5609

[12] Alihodzic R., Murgul V., Vatin V.N., Aronova E., Nikolić V., Tanić M., Stanković D. Renewable Energy Sources used to Supply Pre-school Facilities with Energy in Different Weather Conditions (2014) Applied Mechanics and Materials, 624, pp.604-612.

DOI: 10.4028/www.scientific.net/amm.624.604

[13] Borodinecs A., Gaujena B. The implementation of building envelopes with controlled thermal resistance (2012), pp.1715-1722.

[14] Kurenkova A.Y., Kononova A.N. Puti energoeffektivnogo ostekleniya [Ways of energy-efficient glazing] (2012) Energosberejeniye, 2.

[15] Paulauskayte S., Sasnauskayte V., Valanchyus K. Vliyaniye kharakteristik ostekleniya zdaniya na raskhod energii v sistemakh otopleniya i okhlazhdeniya [Influence of characteristics of buildings glazing on energy consumption in heating and cooling] (2010).

[16] Borodinecs A., Zemitis J., Prozuments A. Passive use of solar energy in double skin facades for reduction of cooling loads (2012).

[17] Kaklauskas A.A., Rute J.A., Zavadskas E.K.A., Daniunas A.A., Pruskus V.A., Bivainis J.A., Gudauskas R.B., Plakys V.A. Passive House model for quantitative and qualitative analyses and its intelligent system (2012).

DOI: 10.1016/j.enbuild.2012.03.008

[18] Uygunoğlua T., Keçebaşb A. LCC analysis for energy-saving in residential buildings with different types of construction masonry blocks (2011) Energy and Buildings, 43 (9), p.2077–(2085).

DOI: 10.1016/j.enbuild.2011.04.011

[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] Petronijevic P., Ivanisevic N., Rakocevic M., Arizanovic D. Methods of calculating depreciation expenses of construction machinery (2012) Journal of Applied Engineering Science, 1 (10), pp.43-48.

[21] Vatin N.I., Nemova D.V., Tarasova D.S., Staritcyna A.A. Increase of energy efficiency for educational institution building (2014) Advanced Materials Research, 953-954, pp.854-870.

DOI: 10.4028/www.scientific.net/amr.953-954.854

[22] Pukhkal V., Murgul V., Vatin N. Central ventilation system with heat recovery as one of the measures to upgrade energy efficiency of historic buildings (2014) Applied Mechanics and Materials, 633-634, pp.1077-1081.

DOI: 10.4028/www.scientific.net/amm.633-634.1077

[23] Petrov K.V., Sled I.A., Eagles O.A., Lynx I.V., Urustimov A.I. Competition Architectural concept of building with zero energy consumption, (2012) Construction of unique buildings and structures, 1, pp.53-60.

[24] Knatko M.V., Efimenko M.N. Ampere-second pots to a question of durability and energy efficiency of modern protecting wall designs of residential, office and production buildings (2008) Magazine of Civil Engineering, 2, pp.50-53.

[25] Nemova D.V., Gorshkov A.S., Kazimirova A.S., Gureev K.N. Calculation of payback period mineral wool with longitudinal fibers of ITE PARISO (PAREXLANKO) (2014) 5TH International conference civil engineering-science and practice, pp.1609-1615.

DOI: 10.5937/jaes12-6552

[26] Grinfeld G., Gorshkov A., Vatin N. Tests results strength and thermophysical properties of aerated concrete block wall samples with the use of polyurethane adhesive (2014) Advanced Materials Research, pp.786-799.

DOI: 10.4028/www.scientific.net/amr.941-944.786

[27] SNiP 23-01-99* Stroitelnaya klimatologiya [Construction climatology. ].

[28] SNiP 23-02-2003 Teplovaya zashchita zdaniy [Thermal protection of buildings. ].

[29] http: /www. sakti. com. ua/upload/i/00000316_b. jpg.

[30] http: /www. build-online. ru/images/stories/walls/doublefas1. jpg.

[31] http: /gbd. su/news/spaydernoe_osteklenie.