Software / WUFI / Introduction
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Software / WUFI / Introduction
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WUFI®PC-Program for calculating the coupled heat and moisture transfer in building componentsRealistic calculation of the transient hygrothermal behaviour of multi-layer building components exposed to natural climate conditions. |
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Besides the thermal properties of a building component and their impact on heating losses, its hygric behaviour has to
be considered, too. Permanently increased moisture content in the component may result in moisture damages. Elevated
surface moisture levels in living rooms can lead to hygienic problems and health risks due to mould growth.
In addition, thermal and hygric behaviour of a building component are closely interrelated: an increased moisture content
favours heat losses; the thermal situation affects moisture transport. Therefore, both have to be investigated together
in their mutual interdependence; the research field of hygrothermics is dealing with these problems.
The Glaser method as detailed in German standard DIN 4108 has been a common method to assess the moisture balance of a
building component by considering vapour diffusion transport in its interior. However, this method does not allow for the
capillary moisture transport in the component, nor for its sorption capacity, both of which reduce the risk of damage in
case of condensation. Furthermore, since the method only considers steady-state transport under heavily simplified boundary
conditions, it cannot reproduce individual short-term events or allow for rain and solar radiation. It is meant to provide
a general assessment of the hygrothermal suitability of a component, not to produce a simulation of realistic heat and
moisture conditions in a component exposed to the weather prevailing at its individual location.
The menu-driven PC program WUFI (Wärme und Feuchte instationär - Transient Heat and
Moisture), developed by IBP and validated using data derived from outdoor and laboratory tests, allows realistic
calculation of the transient hygrothermal behaviour of multi-layer building components exposed to natural climate conditions.
WUFI is based on the newest findings regarding vapour diffusion and liquid transport in building materials.
WUFI only requires standard material properties and easy-to-determine moisture storage and liquid transport functions.
WUFI can use measured weather data - including driving rain and solar radiation - as boundary conditions, thus allowing realistic investigations on the behaviour of the component under exposure to natural weather.
WUFI can be used for assessing
WUFI is a tool for developing and optimising building materials and components. For example, it was used as a development tool for the smart vapour retarder.
WUFI is directed at manufacturers of building products, consultants, designers, engineering offices and experts in the field of hygrothermics.
WUFI may be used as a teaching aid or advertising tool because of the instructive visualisation of its calculation results.
WUFI can be switched between 11 languages (English, German, Finnish, Polish, French, Norwegian, Swedish, Spanish,
Italian, Portugese and Czech.).
A free Research and Education version is available for download.
Proper application of WUFI requires experience in the field of hygrothermics and some basic knowledge in the use of
numerical calculation methods.
| Minimum System Requirements: | |
| Operating System: | Windows 2000, Windows XP, Windows Vista, Windows 7 |
| CPU: | 1 GHz or higher |
| RAM: | 512 MB XP, 1.5 GB Vista, Windows 7 (32 bit), 2.5 GB Vista, Windows 7 (64 bit) |
| Video Adapter: | 32 MB |
| Hard Disk: | 300 MB free space |
| Recommended: | |
| Operating System: | Windows XP SP3, Windows Vista SP1, Windows 7 |
| CPU: | 2 GHz or higher |
| RAM: | 1 GB XP, 3 GB Vista, Windows 7 |
| Video Adapter: | 128 MB and better, OpenGL 2.0 capable |
| Hard Disk: | 300 MB free space |
| Minimum Requirements for WUFIGraph / WUFI Bio: | |
| Java 1.6 or higher | |
| Additional hard disk space needed for project files: | |
| 1D: | average project: 100-200 MB |
| 2D: | average project: 2-4 GB/year |
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WUFI - What's that?
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Become familiar with WUFI by participating in a tour through an example. These pages show you which material parameters
and climate data WUFI needs, how the calculation is performed and which types of results WUFI delivers to you.
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These pages give a short overview of the theory of coupled heat and moisture transport on which WUFI is based. WUFI's
fields of application and its limitations are also discussed.
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The ongoing work on the IBP outdoor testing field results in numerous well-documented investigations on the hygrothermal
behaviour of building components exposed to natural weather. The comparison between experiment and calculation shows
convicingly that WUFI is able to reproduce the complex effects which natural weather induces in a building component.
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A small gallery of applications demonstrates WUFI's versatility. The list of possible uses includes parametric studies,
interpretation assistance for measured data, long-term extrapolations and many others.
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Investigations using WUFI as a simulation tool and the basics of the practical application of heat and moisture transport
calculations are the subject of numerous publications of IBP and other institutes.
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Download a demo version of WUFI, a demo film with visualisations of WUFI calculation results or material parameters.
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These pages offer information to assist you in the practical application of WUFI: bug report, update history, Questions & Answers.
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IBP offers introductory and advanced seminars for WUFI users.
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News about WUFI.
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Commercial WUFI licences are available from IBP as well as free non-commercial licences.
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