论文和技术资料

As a part of the Pan-Canadian framework for clean growth, Canada is intent on meeting its 2030 emission targets for which 17% of Canada’s total Green House Gas emissions come from buildings. Given this challenge, emphasis is being placed on developing building designs having greatly reduced energy use to the extent these can be regarded as net-zero ready. It is recognized that thermal bridges are areas of a wall assembly that have higher thermal transmittance than the surrounding wall components and hence create paths of greatly diminished thermal resistance. As a consequence, the effects arising from thermal bridging can significantly reduce the thermal performance of wall assemblies and thus can affect the overall thermal performance and total energy use in buildings. Such effects, as well, produce other undesirable risks such as the thermal discomfort of occupants and condensation in walls.

In this project the COMSOL Multiphysics Heat Transfer Module was used to model the steady state and transient thermal performance of three steel stud wall assemblies from which the thermal bridging effects were calculated. The modeling sequence for consisted of: (i) selecting and creating the geometry to be modelled; (ii) selecting the material properties; (iii) determining and applying the boundary conditions; (iv) performing mesh verification; (v) conducting the numerical simulations, and; (vi) comparing the results to those obtained from laboratory tests (Vii) using the steady state results as the initial condition for the transient simulations.

Laboratory thermal tests were conducted on these wall assemblies in NRC’s Guarded Hot Box (GHB) following the test procedures given in ASTM C1363. The results from thermal tests were used to benchmark the steady state results derived from simulation. The benchmarking procedure demonstrated that the techniques and procedures used to produce R and RSI values can accurately reproduce test measurements using measured (or typical) material properties and consistent boundary conditions. For the transient study, the exterior temperature was ramped up and down linearly in 48 hours. The amount of energy to keep the interior warm was measured and compared with the steady state condition.

The 3-D geometries were imported in COMSOL Multiphysics and material properties were assigned to the corresponding domains. Temperature dependent thermal conductivities for the insulation materials were measured using a Guarded Hot Plate (GHP) in accordance with ASTM C519; these results were used in the simulations. Parametric sweeps of the thermal conductivities were conducted to capture the different boundary conditions to which the wall assemblies were exposed when subjected to different climate zones. The interior side of the wall assemblies was always exposed to 21 °C, whereas exterior wall temperatures of -5, -20 and -35 °C were used for the parametric sweep in the steady state condition. The temperate was also varied from -5 °C to -29 °C for the transient condition. Contact thermal resistances were in compliance with information provided in the 2009 ASHRAE Handbook-Fundamentals. Mesh verification was conducted on one of the wall assemblies to determine the effect of changes in mesh sizing.