10.1007/s40095-014-0140-2

Numerical and experimental thermal analysis for the improvement of various types of windows frames and rolling-shutter boxes

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  • Nicola Cardinale1,
  • Gianluca Rospi*1,
  • Tiziana Cardinale1,
  1. Department of European and Mediterranean Cultures: Architecture, Environment, Cultural Heritages (DICEM), University of Basilicata, Matera, 75100, IT
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Published in Issue 2015-03-24

How to Cite

Cardinale, N., Rospi, G., & Cardinale, T. (2015). Numerical and experimental thermal analysis for the improvement of various types of windows frames and rolling-shutter boxes. International Journal of Energy and Environmental Engineering, 6(2 (June 2015). https://doi.org/10.1007/s40095-014-0140-2
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Abstract

Abstract Data provided by Italian Ministry of Environment say that in 5 years you consume, just for heating of an apartment, an amount of energy equal to that required for the all construction of the same apartment. The years come down to three if one includes other energy consumption. In terms of primary energy, the building-plant system is responsible for about 45 % of the national energy demand. The rolling-shutter box system, in most cases, is the first responsible for thermal dispersions and input of free heat coming from outside. In addition, the window frames have the obligation of the CE marking to be sold on the free European market. Among the basic requirements, the thermal transmittance is the parameter responsible for the energy performance. The research concerned the energy study of different window frames and rolling-shutter boxes through the use of finite element methodology and experiments in situ. This study was carried out on six different types of windows frames (PVC, wood, and wood-aluminium) and four different models of rolling shutters-boxes (all with structure made by expanded polystyrene). The experimental analysis allowed the comparison between the thermal transmittance values calculated according to the UNI EN ISO 10077-1/2 and measured in accordance with ISO 9869.

Keywords

  • Experimental and thermal analysis,
  • Thermal transmittance,
  • Energy efficiency of windows frames and rolling-shutter boxes,
  • Finite element analysis
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