Vorträge und Posterpräsentationen (mit Tagungsband-Eintrag):
P. Wegerer, T. Bednar:
"Improving Durability of Wooden Beam Bearings in Inside Insulated Walls by Tempering the Beamīs Heads";
Vortrag: 7th International Building Physics Conference, IBPC2018,
Syracuse, NY, USA;
23.09.2018
- 26.09.2018; in: "IBPC2018 - Healthy, Intelligent and Resilient Buildings and Urban Environments",
(2018),
S. 329
- 334.
Kurzfassung englisch:
Improving durability of wooden beam bearings after a thermal renovation via interior insulation is highly demanding for planners. Because of an isolated thermal bridge in the area of the wooden beam head the risk of condensation water forming in this area increases after installing interior insulation. The problem with wooden beam ends has been analysed increasingly in the last few years by many research institutions as wooden ceiling constructions are common in existing buildings. Furthermore, thermal renovation makes a vital contribution regarding improving the energy-efficiency of existing buildings.
In this paper a method to temper wooden beam ends is introduced. It is a patent pending which is currently developed further using laboratory-prototypes in a double climate chamber. This technology is based on thermo conductive types of sheet metal, which are driven into the construction at the joint between the wooden beam and the surrounding masonry. The thermal energy is provided by a heating pipe and fed into the metal. Because of the metalīs high thermal conductivity, heat can be fed specifically into the beamīs end in order to avoid wood rotting at this crucial point.
Calculating the beamīs end temperature control was done using three-dimensional HAM simulations with air flows in the ceiling cavity being taken into account. The results of different measurements in the double climate chamber as well as the HAM simulations clearly show that the durability of an interior insulation can be increased via a temporary and local tempering of wooden beam bearings. At the same time the risk of wood rotting at the ceilingīs bearing structure is minimised.
Comparative analyses show that this method of tempering the beam ends is especially energy-saving as the energy input is low due to the special feeding of heat via thermo conductive types of sheet metal.
Schlagworte:
Wooden beam ceiling, interior insulation, 3D HAM model, local temperature control, double climate chamber
Erstellt aus der Publikationsdatenbank der Technischen Universität Wien.