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T. Lewis, A. Sarkany, E. Heiduk, M. Grüner, T. Bednar, H. Hofbauer:
"Influences on the drying behavior of a concrete ceiling below a cold attic";
Vortrag: 8th International Buildings Physics Conference 2021 (IBPC 2021), Kopenhagen, Dänemark; 25.08.2021 - 27.08.2021; in: "Journal of Physics: Conference Series", IOP Publishing, 2069 (2021), S. 1 - 9.

The article describes the current state of a project examining the influences on the moisture distribution in cold attics above concrete ceilings of residential buildings. Considerable research has been done on moisture damages in cold attics, especially in Scandinavia and North America, focussing on spaces above wooden ceilings. The project (ongoing until Sept 2021) underlying the article deals with cold attics above concrete ceilings resting on masonry walls, a frequent variant in Austria. Research was triggered by a regional Austrian building industry association to shed light onto recent detrimental moisture accumulation in the wooden wall plate (= bearing for the rafters along the eaves) and in the two EPS insulation layers on top of the ceiling. Suspected reasons for the moisture problems and for the local moisture distribution are 1) a too small diffusion resistance of the vapour retarder covering the ceiling, 2) insufficient (natural) attic ventilation and 3) convection, e. g. in the gap between the polystyrene blocks. In order to rank these potential causes by influence and also to find a practical solution a two stage experimental approach was chosen: 1) A handy small scale replica (order of dimension: 1m) of the situation was exposed to the according indoor and outdoor climate in a climate chamber. Different vapour retarders on top of the ceiling were chosen. 2) A larger 1:1 replica has been erected as well but not yet delivered monitoring data. In parallel, a hygrothermic model taking convection into account was established and simulations carried out. The project will deliver a contribution to the Austrian standard on moisture safety 8110-2 on how to judge the moisture safety of joints via simulation.

http://dx.doi.org/10.1088/1742-6596/2069/1/012034

https://publik.tuwien.ac.at/files/publik_302639.pdf