77 research outputs found
BES with FEM: Building Energy Simulation using Finite Element Methods
An overall objective of energy efficiency in the built environment is to
improve building and systems performances in terms of durability, comfort and
economics. In order to predict, improve and meet a certain set of performance
requirements related to the indoor climate of buildings and the associated
energy demand, building energy simulation (BES) tools are indispensable. Due to
the rapid development of FEM software and the Multiphysics approaches, it
should possible to build and simulate full 3D models of buildings regarding the
energy demand. The paper presents a methodology for performing building energy
simulation with Comsol. The method was applied to an international test box
experiment. The results showed an almost perfect agreement between the used BES
model and Comsol. These preliminary results confirm the great opportunities to
use FEM related software for building energy performance simulation.Comment: 5 pages, 6 figures, Proceedings of the 2012 COMSOL Conference in
Mila
The development of a mapping tool for the evaluation of building systems for future climate scenarios on European scale
The paper presents a tool for the mapping of the performance of building
systems on European scale for different (future) time periods. The tool is to
use for users and be applicable for different building systems. Users should
also be able to use a broad range of climate parameters to assess the influence
of climate change on these climatic parameters. Also should the calculation
time be reasonable short. The mapping tool is developed in MATLAB, which can be
used by other users for their own studies.Comment: 21 pages, 24 figures, pre-conferenc
Comsol Simulations of Cracking in Point Loaded Masonry with Randomly Distributed Material Properties
This paper describes COMSOL simulations of the stress and crack development
in the area where a masonry wall supports a floor. In these simulations one of
the main material properties of calcium silicate, its E-value, was assigned
randomly to the finite elements of the modeled specimen. Calcium silicate is a
frequently used building material with a relatively brittle fracture
characteristic. Its initial E-value varies, as well as tensile strength and
post peak behavior. Therefore, in the simulation, initial E-values were
randomly assigned to the elements of the model and a step function used for
describing the descending branch. The method also allows for variation in
strength to be taken into account in future research. The performed non-linear
simulation results are compared with experimental findings. They show the
stress distribution and cracking behavior in point loaded masonry when varying
material properties are used.Comment: Conference pape
The multiphysics modeling of heat and moisture induced stress and strain of historic building materials and artefacts
The basic structure of historic sites and their associated interior artefacts can be damaged or even destroyed by climate change. The evaluation of combined heat and moisture induced stress and strain (HMSS) can predict possible damage-related processes. In this paper, the development of one- and two-dimensional HMSS models of building materials and artefacts in COMSOL Multiphysics Version 4, a commercial finite element software, is presented. The validation of the numerical models is revealed using analytical, numerical and experimental solutions. As a result, the HMSS model was shown to be an adequate predictive tool to determine possible damage-related processes in building assemblies and artefacts
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