1D:Wufi 1D: Unterschied zwischen den Versionen

Aus Wufiwiki
Zur Navigation springenZur Suche springen
Keine Bearbeitungszusammenfassung
Keine Bearbeitungszusammenfassung
Zeile 1: Zeile 1:
= What is WUFI? =
= Welcome to WUFI =
 
<P>
<P>
WUFI is the acronym for &quot;<B>W</B>&auml;rme- <B>u</B>nd <B>F</B>euchtetransport
WUFI is a Windows-based program for the hygrothermal (i.e., heat and moisture) analysis
<B>i</B>nstation&auml;r&quot; (&quot;Transient Heat and Moisture Transport&quot;).
of building envelope constructions. WUFI is an easy-to-use, menu-driven program for use
on a personal computer which can provide customized solutions to moisture engineering
and damage assessment problems for various building envelope systems.
</P>
</P>
<P>
<P>
WUFI is designed to calculate the simultaneous heat and moisture transport in
The <B>WUFI</B> simulation model is a transient heat and mass transfer model which can
one-dimensional multi-layered building components.
be used to assess the heat and moisture distributions for a wide range of building
material classes and climatic conditions.
</P>
</P>
<P>
<P>
A comfortable Windows<SUP>&reg;</SUP> user interface allows quick set-up of a
With <B>WUFI</B> you can estimate the drying times of masonry and lightweight structures
calculation project, easy change of parameters for numerical experiments and
with trapped or concealed construction moisture, investigate the danger of interstitial
comfortable viewing of the results as graphics or a 'film'.
condensation or study the influence of driving rain on exterior building components.
The program can also help to select repair and retrofit strategies with respect to the
hygrothermal response of particular roof or wall assemblies subjected to various climates.
This allows the comparison and ranking of different designs with respect to total
hygrothermal performance.
</P>
</P>
<P>
<P>
The physical and numerical ideas underlying WUFI are developed and discussed in the
In addition, <B>WUFI</B> provides an instructive overview of the complex moisture
doctoral thesis:
transport phenomena occurring in construction assemblies, making the basic principles
and interactions present during moisture transport more accessible and allowing both
designers and architects insight into design decisions.
</P>
</P>
<TABLE>
<TR><TD WIDTH="10">&nbsp;</TD>
    <TD>K&uuml;nzel, H.M.:<BR> Verfahren zur ein- und zweidimensionalen Berechnung des gekoppelten W&auml;rme- und Feuchtetransports in Bauteilen mit einfachen Kennwerten.<BR> Dissertation Universit&auml;t Stuttgart 1994<BR>
&nbsp;<BR> (may be ordered from IBP: [http://www.hoki.ibp.fhg.de/index.html])<BR>
&nbsp;<BR>
</TD>
</TR>
<TR><TD>&nbsp;</TD>
    <TD>or<BR>
&nbsp;<BR>
    </TD>
</TR>
<TR><TD>&nbsp;</TD>
    <TD>K&uuml;nzel, H.M.:<BR> Simultaneous Heat and Moisture Transport in Building Components.<BR>
One- and two-dimensional calculation using simple parameters.<BR> IRB Verlag 1995<BR>
&nbsp;<BR>
(may be ordered from IRB Verlag, Stuttgart: [http://www.irb.fhg.de]).<BR>
&nbsp;<BR>
</TD>
</TR>
</TABLE>
<P>
<P>
In the calculation of heat transport, WUFI takes into account:
This design tool can also aid the development and optimization of innovative building
</P>
materials and components. One example is that <B>WUFI</B> simulations led to the
* thermal conduction
development of the smart vapor retarder; a successful application of a software tool
* enthalpy flows through moisture movement with phase change
to a practical moisture control problem.
* short-wave solar radiation
* nighttime long-wave radiation cooling (with [[Details:TRY-File | TRY]],[[Details:DAT-File | DAT]], [[Details:WAC-File | WAC]] and [[Details:WBC-File | WBC]] weather data only).
 
<P>
Convective heat transport by air flows has been disregarded, since it is usually
difficult to quantify and rarely one-dimensional.<BR>
&nbsp;<BR>
</P>
 
<P>
The vapor transport mechanisms included in WUFI are:
</P>
* vapor diffusion
* solution diffusion.
<P>
Again, convective vapor transport by air flows has been ignored.<BR>
&nbsp;<BR>
</P>
 
<P>
The liquid transport mechanisms taken into account are:
</P>
* capillary conduction
* surface diffusion.
 
<P>
Seepage flow through gravitation, hydraulic flow through pressure differentials,
as well as electrokinetic and osmotic effects have not been included.<BR>
&nbsp;<BR>
</P>
 
<P>
The choice of temperature and relative humidity as driving potentials allows the use
of simple, easily comprehensible storage and transport coefficients. These can also
readily be derived from standard material data if no measured data are available and
utmost precision of the results is not required.<BR>
&nbsp;<BR>
</P>
 
<P>
The boundary conditions for each time step are expressed in terms of meteorological
data (temperature, relative humidity, driving rain, radiation), since in building
physics these are the relevant parameters specifying the conditions at surfaces
exposed to natural weather.<BR>
However, conditions for laboratory experiments (e.g. imbibition measurements) can
also be expressed as 'meteorological' data.<BR>
Heat, moisture and air change sources may be specified within the component.
</P>
</P>

Version vom 30. September 2008, 08:57 Uhr

Welcome to WUFI

WUFI is a Windows-based program for the hygrothermal (i.e., heat and moisture) analysis of building envelope constructions. WUFI is an easy-to-use, menu-driven program for use on a personal computer which can provide customized solutions to moisture engineering and damage assessment problems for various building envelope systems.

The WUFI simulation model is a transient heat and mass transfer model which can be used to assess the heat and moisture distributions for a wide range of building material classes and climatic conditions.

With WUFI you can estimate the drying times of masonry and lightweight structures with trapped or concealed construction moisture, investigate the danger of interstitial condensation or study the influence of driving rain on exterior building components. The program can also help to select repair and retrofit strategies with respect to the hygrothermal response of particular roof or wall assemblies subjected to various climates. This allows the comparison and ranking of different designs with respect to total hygrothermal performance.

In addition, WUFI provides an instructive overview of the complex moisture transport phenomena occurring in construction assemblies, making the basic principles and interactions present during moisture transport more accessible and allowing both designers and architects insight into design decisions.

This design tool can also aid the development and optimization of innovative building materials and components. One example is that WUFI simulations led to the development of the smart vapor retarder; a successful application of a software tool to a practical moisture control problem.