2 Citationer (Scopus)
121 Downloads (Pure)

Resumé

The use of solar shading in future low energy office buildings is essential for minimizing energy consumption for building services, while maintaining thermal conditions. Implementing solar shading technologies in energy calculations and thermal building simulation programs is essential in order to demonstrate the effect of adaptive solar shading. In order to document the benefits of the shading technology, the description of the shading device in the thermal building simulation software must be described at a reasonably accurate level, related to the specific solar shading device.

This research presents different approaches for modeling solar shading devices, demonstrating the level of accuracy in relation to measurement conducted in a full-scale façade test facility at Aalborg University. The research bridges the gap between increased complexity of solar shading technologies and the use of these technologies in thermal building simulation software.
OriginalsprogEngelsk
TidsskriftEnergy Procedia
Vol/bind132
Udgave nummerOctober 2017
Sider (fra-til)472-477
ISSN1876-6102
DOI
StatusUdgivet - 2017
Begivenhed11th Nordic Symposium on Building Physics - The Electro Building at Gløshaugen campus, NTNU, Trondheim, Norge
Varighed: 11 jun. 201714 jun. 2017
Konferencens nummer: 11
http://www.ntnu.edu/web/nsb2017/home
http://www.ntnu.edu/nsb2017

Konference

Konference11th Nordic Symposium on Building Physics
Nummer11
LokationThe Electro Building at Gløshaugen campus, NTNU
LandNorge
ByTrondheim
Periode11/06/201714/06/2017
Internetadresse

Fingerprint

Numerical analysis
Office buildings
Test facilities
Energy utilization
Hot Temperature

Emneord

  • Glazed façade
  • Solar shading
  • Venetian blinds
  • Dynamic modeling

Citer dette

@inproceedings{5918660756c64f1493bdbb7831ed775e,
title = "Experimental and Numerical Analysis of Modelling of Solar Shading",
abstract = "The use of solar shading in future low energy office buildings is essential for minimizing energy consumption for building services, while maintaining thermal conditions. Implementing solar shading technologies in energy calculations and thermal building simulation programs is essential in order to demonstrate the effect of adaptive solar shading. In order to document the benefits of the shading technology, the description of the shading device in the thermal building simulation software must be described at a reasonably accurate level, related to the specific solar shading device.This research presents different approaches for modeling solar shading devices, demonstrating the level of accuracy in relation to measurement conducted in a full-scale fa{\cc}ade test facility at Aalborg University. The research bridges the gap between increased complexity of solar shading technologies and the use of these technologies in thermal building simulation software.",
keywords = "Glazed fa{\cc}ade, Solar shading, Venetian blinds, Dynamic modeling, Glazed fa{\cc}ade, Solar shading, Venetian blinds, Dynamic modeling",
author = "Winther, {Frederik Vildbrad} and Mingzhe Liu and Heiselberg, {Per Kvols} and Jensen, {Rasmus Lund}",
year = "2017",
doi = "10.1016/j.egypro.2017.10.001",
language = "English",
volume = "132",
pages = "472--477",
journal = "Energy Procedia",
issn = "1876-6102",
publisher = "Elsevier",
number = "October 2017",

}

Experimental and Numerical Analysis of Modelling of Solar Shading. / Winther, Frederik Vildbrad; Liu, Mingzhe; Heiselberg, Per Kvols; Jensen, Rasmus Lund.

I: Energy Procedia, Bind 132, Nr. October 2017, 2017, s. 472-477.

Publikation: Bidrag til tidsskriftKonferenceartikel i tidsskriftForskningpeer review

TY - GEN

T1 - Experimental and Numerical Analysis of Modelling of Solar Shading

AU - Winther, Frederik Vildbrad

AU - Liu, Mingzhe

AU - Heiselberg, Per Kvols

AU - Jensen, Rasmus Lund

PY - 2017

Y1 - 2017

N2 - The use of solar shading in future low energy office buildings is essential for minimizing energy consumption for building services, while maintaining thermal conditions. Implementing solar shading technologies in energy calculations and thermal building simulation programs is essential in order to demonstrate the effect of adaptive solar shading. In order to document the benefits of the shading technology, the description of the shading device in the thermal building simulation software must be described at a reasonably accurate level, related to the specific solar shading device.This research presents different approaches for modeling solar shading devices, demonstrating the level of accuracy in relation to measurement conducted in a full-scale façade test facility at Aalborg University. The research bridges the gap between increased complexity of solar shading technologies and the use of these technologies in thermal building simulation software.

AB - The use of solar shading in future low energy office buildings is essential for minimizing energy consumption for building services, while maintaining thermal conditions. Implementing solar shading technologies in energy calculations and thermal building simulation programs is essential in order to demonstrate the effect of adaptive solar shading. In order to document the benefits of the shading technology, the description of the shading device in the thermal building simulation software must be described at a reasonably accurate level, related to the specific solar shading device.This research presents different approaches for modeling solar shading devices, demonstrating the level of accuracy in relation to measurement conducted in a full-scale façade test facility at Aalborg University. The research bridges the gap between increased complexity of solar shading technologies and the use of these technologies in thermal building simulation software.

KW - Glazed façade

KW - Solar shading

KW - Venetian blinds

KW - Dynamic modeling

KW - Glazed façade

KW - Solar shading

KW - Venetian blinds

KW - Dynamic modeling

U2 - 10.1016/j.egypro.2017.10.001

DO - 10.1016/j.egypro.2017.10.001

M3 - Conference article in Journal

VL - 132

SP - 472

EP - 477

JO - Energy Procedia

JF - Energy Procedia

SN - 1876-6102

IS - October 2017

ER -