Influence of thermal zoning and electric radiator control on the energy flexibility potential of Norwegian detached houses

Energy flexibility of buildings can be used to reduce energy use and costs, peak power, CO2eq- emissions or to increase self-consumption of on-site electricity generation. Thermal mass activation proved to have a large potential for energy flexible operation. The indoor temperature is then allowed t...

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Bibliographic Details
Published in:E3S web of conferences 2019-01, Vol.111, p.6030
Main Authors: Johnsen, Thea, Taksdal, Katrine, Clauß, John, Yu, Xingji, Georges, Laurent
Format: Article
Language:English
Subjects:
Activation analysis
Bedrooms
Buildings
Construction
Electricity consumption
Electricity pricing
Energy
Energy consumption
Energy costs
Flexibility
Houses
Housing
Insulation
Power consumption
Radiators
Residential areas
Residential buildings
Residential energy
Temperature effects
Windows (intervals)
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Summary:Energy flexibility of buildings can be used to reduce energy use and costs, peak power, CO2eq- emissions or to increase self-consumption of on-site electricity generation. Thermal mass activation proved to have a large potential for energy flexible operation. The indoor temperature is then allowed to fluctuate between a minimum and maximum value. Many studies investigating thermal mass activation consider electric radiators. Nevertheless, these studies most often assume that radiators modulate their emitted power, while, in reality, they are typically operated using thermostat (on-off) control. Firstly, this article aims at comparing the energy flexibility potential of thermostat and P-controls for Norwegian detached houses using detailed dynamic simulations (here IDA ICE). It is evaluated whether the thermostat converges to a P-control for a large number of identical buildings. As the buildings are getting better insulated, the impact of internal heat gains (IHG) becomes increasingly important. Therefore, the influence of different IHG profiles has been evaluated in the context of energy flexibility. Secondly, most studies about energy flexibility consider a single indoor temperature. This is questionable in residential buildings where people may want different temperature zones. This is critical in Norway where many occupants want cold bedrooms (~16°C) during winter time and open bedroom windows for this purpose. This article answers to these questions for two different building insulation levels and two construction modes (heavy and lightweight).
ISSN:2267-1242
2555-0403
2267-1242
DOI:10.1051/e3sconf/201911106030