Modeling, numerical simulation and validation of the hygrothermal transfer through a wooden building wall in Nancy, France

•The study focused on heat and mass transfer through building walls in Nancy, France.•Sorption isotherms in adsorption/desorption phases are experimentally determined and modelled using Nelson sorption model.•Temperature and humidity evolutions through the wooden wall during the year are modelled.•T...

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Bibliographic Details
Published in:Thermal science and engineering progress 2021-05, Vol.22, p.100808, Article 100808
Main Authors: Simo-Tagne, Merlin, Remond, Romain, Kharchi, Razika, Bennamoun, Lyes, Ndukwu, Macmanus Chinenye, Rogaume, Yann
Format: Article
Language:English
Subjects:
Distemonanthus benthamianus
Engineering Sciences
Heat and mass transfer
Lovoa trichilioides
Modeling and simulation
Nancy
Picea abies
Sacoglottis gabonensis
Sorption isotherms
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Summary:•The study focused on heat and mass transfer through building walls in Nancy, France.•Sorption isotherms in adsorption/desorption phases are experimentally determined and modelled using Nelson sorption model.•Temperature and humidity evolutions through the wooden wall during the year are modelled.•The liquid water coming from the rain has been neglected.•The model can be used to predict heat and mass transfer through building walls in Nancy. The present work aims to model heat and mass transfer through wooden building walls in Nancy. Adsorption and desorption isotherms of three exotic wood and one temperate wood using a dynamic vapor sorption apparatus at 35 °C were experimentally determined then modelled using Nelson sorption isotherm model. Sorption hysteresis of these woods was deduced. Heat and mass transfer model validation shows that the thickness of wooden wall higher than 0.15 m permits to cancel the influences of ambient air temperature on the temperature of the air in the building. Also, the results show that influence of the four wood species is not observed and can be neglected. To reduce the quantity of water absorbed by the wooden wall, it is important to dry the plank to a moisture content of 0.14 kg/kg dry basis. It is observed that heat and mass transfer gradients are highly influenced by the seasonal variations and characteristics of indoor air. During the day, the wooden wall gives a low variation of climatic conditions of air inside the house.
ISSN:2451-9049
2451-9049
DOI:10.1016/j.tsep.2020.100808