Moisture performance of building materials: From material characterization to building simulation using the Moisture Buffer Value
Abadie, M.O. and Mendon?a, K.C.
2009 Building and Environment, 44(2): 388-401
Moisture; Buffering; MBV; Penetration depth; Lumped model; Building simulation,
Moisture; Buffering; MBV; Penetration depth; Lumped model; Building simulation
Abadie, M.O. and Mendon?a, K.C., (2009), "Moisture performance of building materials: From material characterization to building simulation using the Moisture Buffer Value", Building and Environment, 44(2): 388-401.
Abstract:
Predicting the indoor air relative humidity evolution is of great importance to evaluate people thermal comfort, perceived air quality and energy consumption. In building environments, porous materials of the envelope and furniture act on the indoor air humidity by reducing its variations. Solving the physical processes involved inside the porous materials requires the knowledge of the material hygrothermal properties that needs multiple and, for some of them, time-consuming experimental procedures. Recently, both the NORDTEST Project and Japanese Industrial Standard described a new Moisture Buffer Capacity index that accounts for surrounding air vapor concentration variation. The Moisture Buffer Value (MBV) indicates the amount of water vapor that is transported in or out of a material, during a certain period of time, when the vapor concentration of the surrounding air varies. The MBV evaluation requires only one experimental procedure and its value permits a direct comparison of the building materials moisture performance. However, two limitations can be distinguished: first, no relation between the MBV and the usual material hygrothermal properties has been clearly identified and second, no model has been proposed to actually use the MBV in building simulation. The present study aims to solve these two problems. First, the MBV fundamentals are introduced and discussed; followed by its relation with the usual material properties. Then, a lumped model for building simulation, whose parameters can be determined from the MBV experimental procedure, is described. To finish, examples of the use of this MBV-based lumped model for moisture prediction in buildings are presented.
Keywords: Moisture; Buffering; MBV; Penetration depth; Lumped model; Building simulation
