Energy-Plus House for the Climatic Conditions of Macedonia

Meri Cvetkovska; Vera Murgul; Ekaterina Aronova; Nikolay Vatin; Maxim Shvarts

doi:10.4028/www.scientific.net/AMM.725-726.1512

Paper Titles

Energy Efficiency of Single-Family Houses in Serbia and Montenegro: Strategy for Upgrading the Performance of Existing Stock
p.1486

The Role of the State and Citizens to Improve Energy Efficiency
p.1493

Estimation of Industrial Wastewaters Treatment Efficiency by Biotesting
p.1499

Energy-Efficient Modernization of the Nobel’s Mansion in Saint Petersburg: Solar Energy Supply Potential
p.1505

Energy-Plus House for the Climatic Conditions of Macedonia
p.1512

Impact of Thermal Insulation and Type of Windows on Energy Demand of Buildings with Passive House Standard
p.1519

Climate Changes in the Light of Relation between Highly Developed Countries and the Rest of the World
p.1530

Definition of Climatic Parameters for Calculation of Energy Performance of Buildings
p.1537

Structural Design of Energy Efficient Buildings Using Multi-Objective BB-BC Algorithm
p.1544

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 725-726Energy-Plus House for the Climatic Conditions of...

Energy-Plus House for the Climatic Conditions of Macedonia

Abstract:

In this paper the Energy-plus house project, functioning under the climate conditions of Macedonia, was presented. On the basis of previous studies carried out for a single-family house, the concept of a fully non-volatile home using solar photovoltaic modules for the operation of the electrical equipment was designed according to "Passive house". The estimates of solar resources of the territory, defined energy input of solar radiation on differently oriented surfaces and selected the optimum tilt angle of PV modules to the horizon were presented for this article. It is shown that the solar modules generated enough electricity to meet the needs of the considered house. At the same time in the summer there is surplus electricity. The calculations presented in this paper were based on the methods of thermodynamics, using MKS EN and DIN standards, the program packages PHPP 2007, as well as the algorithm developed for calculating the amount of solar radiation on differently oriented surfaces.

You might also be interested in these eBooks

Innovative Technologies in Development of Construction Industry

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volumes 725-726)

Pages:

1512-1518

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.725-726.1512

Citation:

Cite this paper

Online since:

January 2015

Authors:

Meri Cvetkovska, Vera Murgul*, Ekaterina Aronova, Nikolay Vatin, Maxim Shvarts

Keywords:

Energy Efficiency, Energy-Plus House, Macedonia, Passive House, Photovoltaic Systems, Solar Power

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] Cvetkovska, M., Trpevski, S., Andreev, A., Knezevic, M. Parametric analysis of the energy demand in buildings with Passive House standard (2013) Portugal SB13 - Contribution of Sustainable Building to Meet EU 20-20-20 Targets, pp.303-310.

Google Scholar

[2] Feist, W., Schnieders, J., Dorer, V., Haas, A. Re-inventing air heating: Convenient and comfortable within the frame of the Passive House concept (2005) Energy and Buildings, Vol. 37(11), p.1186–1203.

DOI: 10.1016/j.enbuild.2005.06.020

Google Scholar

[3] Gabriyel, I., Ladener, Kh. Rekonstruktsiya zdaniy po standartam energoeffektivnogo doma (2011) SPb.: BKhV-Peterburg, 470 p.

Google Scholar

[4] Ostrowska, A., Sobczyk, W. Małgorzata Pawul Ocena efektów ekonomicznych i ekologicznych wykorzystania energii słonecznej na przykładzie domu jednorodzinnego (2013).

Google Scholar

[5] Žegarac Leskovar, V., Premrov, M. Design approach for the optimal model of an energy-efficient timber building with enlarged glazing surface on the south façade (2012).

DOI: 10.3130/jaabe.11.71

Google Scholar

[6] Žegarac Leskovar, V., Premrov, M., Vidovič, K. Architectural geometry of timber-glass buildings and its impact on energy flows through building skin (2013).

DOI: 10.1201/b14563-20

Google Scholar

[7] Leskovar, V.Ž., Premrov, M. An approach in architectural design of energy-efficient timber buildings with a focus on the optimal glazing size in the south-oriented façade (2011) Energy and Buildings, 43 (12), pp.3410-3418.

DOI: 10.1016/j.enbuild.2011.09.003

Google Scholar

[8] Žegarac Leskovar, V., Premrov, M. Design approach for the optimal model of an energy-efficient timber building with various glazing types and surfaces on the south façade (2011) WIT Transactions on the Built Environment, 118, pp.541-552.

DOI: 10.2495/str110451

Google Scholar

[9] Žegarac Leskovar, V., Premrov, M. Influence of glazing size on energy efficiency of timber-frame buildings (2012) Construction & building materials, vol. 30, pp.92-99.

DOI: 10.1016/j.conbuildmat.2011.11.020

Google Scholar

[10] Murgul, V., Vuksanovic, D., Vatin, N., Pukhkal V. The use of decentralized ventilation systems with heat recovery in the historical buildings of St. Petersburg (2014) Applied Mechanics and Materials, Vols. 635-637, pp.370-376.

DOI: 10.4028/www.scientific.net/amm.635-637.370

Google Scholar

[11] Andreev A., Parametric analysis of the energy demand in buildings with Passive House standard (2013) Master thesis, University Ss. Cyril and Methodius, Skopje, 182 p.

Google Scholar

[12] Standards: MKC EN 410: 200; MKC EN 673/A1/A2: 2006; MKC ISO 6946: 2009; MKC EN ISO 9288: 2008; MKC EN ISO 13788: 2006; MKC EN ISO 13947: 2009; DIN 277; DIN V 4108-4; DIN EN 1283; DIN EN 13363 ; DIN EN 13829; DIN EN ISO 13790: 2004; DIN ISO 13370 ; DIN V 18599-2; DIN V 4180-6; DIN EN ISO 10211-1: 1995; DIN V 4701-10; DIN EN ISO 6946: (1996).

DOI: 10.3139/9783446452749.fm

Google Scholar

[13] Information on: http: /solargis. info.

Google Scholar