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Thermal Modeling and Investigation of the Most Energy-Efficient Window Position

Abstract

The energy consumption in buildings contributes substantially to the worldwide energy use and greenhouse gas emissions. One of the crucial elements defining energy consumption is the building envelope, which in modern designs includes growing share of fenestration. Due to recent improvements of windows and walls, the thermal bridging effects occurring on their connections, become more significant. Window-to-wall connections appear to be especially important and can contribute up to 40% of the total heat loss caused by thermal bridges in building envelope. Thus, this study is investigating thermal properties of window-to-wall connections. The main scope of the work is to determine the most efficient window position in the window opening regarding minimizing thermal bridging effects. Five different wall constructions are investigated along with two windows with different U-values. The thermal simulation results show that the window position has a crucial impact on the amount of energy loss through the thermal bridges. For each wall type, the most energy-efficient position is found, resulting from detailed analysis of sill, head, and jambs construction details. For some cases placing the window in the most energy-efficient position reduces linear thermal transmittance (LTT) over 50%. Among considered positions, the temperatures on the internal surface of the assemblies are weakly influenced by the window position. Example calculations show that significant share of energy losses from the fenestration presence is caused by thermal bridge occurring on window-to-wall.
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Category

Academic article

Language

English

Author(s)

  • Cezary Misiopecki
  • Marine Bouquin
  • Arild Gustavsen
  • Bjørn Petter Jelle

Affiliation

  • SINTEF Community / Architecture, Materials and Structures
  • University of Pau and Pays de l'Adour
  • Norwegian University of Science and Technology

Year

2018

Published in

Energy and Buildings

ISSN

0378-7788

Volume

158

Page(s)

1079 - 1086

View this publication at Norwegian Research Information Repository