Heat losses caused by the temporary influence of wind in timber frame walls insulated with fibrous materials
Artykuł w czasopiśmie
MNiSW
140
Lista 2021
Status: | |
Autorzy: | Kosiński Piotr, Brzyski Przemysław, Suchorab Zbigniew, Łagód Grzegorz |
Dyscypliny: | |
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Rok wydania: | 2020 |
Wersja dokumentu: | Drukowana | Elektroniczna |
Język: | angielski |
Numer czasopisma: | 23 |
Wolumen/Tom: | 13 |
Numer artykułu: | 5514 |
Strony: | 1 - 14 |
Impact Factor: | 3,623 |
Web of Science® Times Cited: | 6 |
Scopus® Cytowania: | 10 |
Bazy: | Web of Science | Scopus |
Efekt badań statutowych | NIE |
Finansowanie: | This research was financially supported by the Ministry of Science and Higher Education in Poland within the statutory research of scientific units under subvention for the science program. This paper was prepared within the timeframe of project Mobility FCE, Mobility CTU and with project No. SGS19/143/OHK1/3T/11. |
Materiał konferencyjny: | NIE |
Publikacja OA: | TAK |
Licencja: | |
Sposób udostępnienia: | Witryna wydawcy |
Wersja tekstu: | Ostateczna wersja opublikowana |
Czas opublikowania: | W momencie opublikowania |
Data opublikowania w OA: | 3 grudnia 2020 |
Abstrakty: | angielski |
The paper presents the results of research concerning three fiber materials—mineral wool, hemp fiber and wood wool—as loose-fill thermal insulation materials. The analysis used the material parameters determined in previous works conducted by the authors, such as thermal conductivity and air permeability in relation to bulk density. These materials exhibit open porosity; thus, convection is an essential phenomenon in the heat transfer process. The paper aimed at conducting thermal simulations of various frame wall variants which were filled with the above-mentioned insulation materials. The simulations were performed with the Control Volume Method using the Delphin 5.8 software. The studies accounted for the effect of wind pressure and the time of its influence on a wall insulated by means of fiber material with a thickness of 150 as well as 250 mm. The simulation enabled us to obtain such data as maximal R-value reduction and time to return to equilibrium after filtration for the analyzed materials. The study proved that heat transfer in these insulations strongly depends on the bulk density, thickness of the insulation and wind pressure. The decrease in R is reduced as the density increases. This results from the decreased air permeability characterizing the material. Wind washing causes lower R reduction than air filtration in all models. The greater the thickness, the longer it takes for the models to return to the equilibrium state following air filtration (and wind washing). This period is comparable for air filtration and wind washing. Hemp fibers were characterized with the strongest susceptibility to air filtration; in the case of wood wool, it was also high, but lower than for hemp fibers, while mineral wool was characterized with the lowest. |