A NEW MODEL FOR PREDICTION AND ITS APPLICATION IN PRACTICE

Similar documents
Comparative evaluation of the predictions of two established mould growth models

Proceedings Cold Climate HVAC Sisimiut, Greenland, March 2009

Hygrothermal Evaluation of Icynene Spray Foam Insulation Installed Between Roof Rafters on Pitched Roofs

Design of Mineral Fibre Durability Test Based on Hygrothermal Loads in Flat Roofs.

Development of an improved model for mould growth: Modelling

Hygrothermal Calculations applied to water-repellent surfaces - Validation and Application -

Flexible Vapor Control Solves Moisture Problems of Building Assemblies - Smart Retarder to Replace the Conventional PE-Film

INVESTIGATIONS OF GYPSUM BOARDS WITH REGARD TO THE MOISTURE-BUFFERING-EFFECTS

PH-CALCULATION Dynamic simulation with WUFI

The Rijksmuseum Amsterdam - Hygrothermal analysis and dimensioning of thermal insulation

SUPPLY AND EXHAUST VENTILATION SYSTEM WITH HEAT RECOVERY IN COMPARISON TO A DEMAND-BASED (MOISTURE-CONTROLLED) EXHAUST VENTILATION SYSTEM

Thermal Performance Degradation of Foam Insulation in Inverted Roofs Due to Moisture Accumulation

Adapted vapour control for durable building enclosures

On the hygrothermal performance of straw bale wall elements in Belgium

HOUSING CHARACTERISTICS PREDICTING MOULD GROWTH IN BATHROOMS

Hygrothermal simulation of green roofs new models and practical application

Buildings XI Conference Workshop 2: Thermal Mass IV Assessing Thermal and Moisture Control Benefits of PCM Components by Hygrothermal Simulation

Hygrothermal Simulation of ventilated pitched roofs with effective transfer parameters

RESTORATION MEASURES THAT SAVE ENERGY. Insulating Without Losing Face

Breathability of building elements

Moisture supply Set Point for avoidance of moisture damage in Swedish multifamily houses

1. Introduction. Carl-Magnus Capener, Ph.D. 1 Stephen Burke, Ph.D. 2 Simon Le Roux, Architect 3 Stephan Ott, Architect 4

Hygrothermal performance of sarking roof structure

DETERMINATION OF THERMAL TECHNICAL PROPERTIES OF ORGANIC THERMAL INSULATING MATERIALS BUILT-IN TO HISTORICAL BUILDINGS

Smart Vapor Retarders

Hygrothermal properties applied in numerical simulation: Interstitial condensation analysis Received (in revised form): 24th July 2009

Accuracy of simplified indoor humidity simulation

Building envelope and sealing systems interior and exterior

MOISTURE CONDITIONS IN WALLS AND CEILINGS OF A SIMULATED OLDER HOME DURING WINTER

Energy Efficient Buildings in Germany An Introduction

Evaluation of the long term durability of adhesive tapes and its substrates: Requirements and testing

Conditions for mould growth on typical interior surfaces

See how to use WUFI in conjunction with ASHRAE s New Standard 160, Design Criteria for Moisture Control in Buildings.

Improving the hygrothermal properties of clay plasters

See how to use WUFI in conjunction with ASHRAE s New Standard 160, Design Criteria for Moisture Control in Buildings.

RESIDENTIAL MOLD ASSESSMENT. Final Report. Your Address Here

Experimental Assessment of Hygrothermal Performance of Wood Frame Wall System in Suzhou's Lake Tai Climate Zone

Concept of a New Airing Strategy and Simulation of the Expected Indoor Climate in Linderhof Palace

Faculty of Heat and Material Transfer Rheinisch-Westfälische Technische Hochschule, Aachen Professor R. Kneer (Dr. Ing)

Thermablok Aerogel Insulation Blanket Thermablok Aerogel Blanket

Thermal Rehabilitation of Existing Building Enclosures by Using VIP (Vacuum Insulation Panel) Sandwich and Timber Based Panels

Moisture and temperature conditions in cold lofts and risk of mould growth

Peter Häupl ON USE OF CAPILLARY ACTIVE MATERIALS FOR REHABILITATION OF HISTORIC BUILDINGS. Extract from lectures at SU presented by Mark Bomberg

Coupled windows in the current guise

Xtratherm Thin-R Thermal Liner (XT/TL Grade)

Renovation of a Detached Single-Family House into an Energy Efficient Low Energy House Larsen, Tine Steen; Maagaard, Steffen; Jensen, Rasmus Lund

Hygrothermal modelling of a sustainable retrofit taking into account the urban microclimate. Case study of the medieval city center of Cahors (France)

Technical Data Sheet Sto-RFP

Thermablok Aerogel Isolation Strips Thermablok Aerogel Isolation Strips

ENERGY PERFORMANCE R-VALUE: PART 2, EXAMPLES OF INTEGRATED METHODOLOGY FOR EVALUATION OF ENERGY EQUIVALENT R-VALUE FOR BUILDING ENCLOSURES;

The effect of additional thermal lining on the acoustic performance of a wall

Durability of Biocidal Agents in Facade Coatings and their Release Under Real Climatic Conditions

Contents: 3. Benefits of CLT with regard to airtightness. 4. Technical aspects of airtightness. 5. Configurations and specific connections. 6.

Indoor climate design for a monumental building with periodic high indoor moisture loads.

A MATHEMATICAL MODELING OF MOISTURE BEHAVIOUR AND MOULD GROWTH IN BUILDING ENVELOPES

Building America Special Research Project: High-R Walls Case Study Analysis

Cellulose. The Convenience of Insulation

Roof Adhered bituminous roofing, sanded, nailed down 1" OSB sheathing 2.5 degree pitch (0.3:12) Vented cavity (ave. 3") Roof boards (1x4) 3x9 roof joi

Thermal insulation of buildings and cooling demand

DECLARATION OF PERFORMANCE

Incorporating Insulating Sheathing into the Design of the Thermal and Moisture Management System of the Building Enclosure

Reduce Wall Condensation Potential with Insulated Sheathing TECH SOLUTIONS 214.0

Insulating Basements: Part 1 Fundamentals

Condensation Risk of Mechanically Attached Roof Systems in Cold Climate Zones

SUSREF. Sustainable Refurbishment of Building Facades and External Walls 1 (57) Deliverable: D2.2

Advanced Storage Concepts for Solar Combisystems

Hygroscopic Materials versus Mechanical Ventilation

DESIGNING FOR RESILIENCE: ideal HOUSE AUCKLAND. PAULA HUGENS BE, MIPENZ, CPEng, CEPH 1 DENISE HENKENHAF, CEPH 1


EcoHome-Insulation.com. Aluminium Foil Bubble Insulation. General Purpose Insulation. Dry Lining. Cavity Wall. Insulation System.

Massive timber elements in roofs moisture performance

Energy equivalent R-value

MOISTURE ACCUMULATION IN WALLS: COMPARISON OF FIELD AND COMPUTER-PREDICTED DATA

Using Thermal Modeling to Evaluate Cladding Support Systems

STAYFLEX CORROSION CONTROL AND THERMAL INSULATION SYSTEM

ATRIA IN SHOPPING CENTRES, OFFICE BUILDINGS AND HOSPITALS. E.Ph.J. de Ruiter. Adviesbureau Peutz & Associés BV., The Hague, Holland

ADJUSTABLE SOLAR SHADING AND HEAT CONSERVATION LOUVRES FOR TRANSPARENT, MULTI-LAYERED GLASS FACADES


MOLD FAQs. Frequently Asked Questions About Mold By Dr. Nathan Yost, MD. Building Sciences Corporation

IBP FRAUNHOFER INSTITUTE FOR BUILDING PHYSICS IBP ENERGY SYSTEMS

Developing Durable CLT Building Enclosure Assemblies

Study. Calculating Potential Freedom from Structural Damage of Thermal Insulation structure in Timber-Built Systems. - Roof, Wall, Ceiling -

Spray Polyurethane Foam: The Need for Vapor Retarders in Above-Grade Residential Walls

STEADY STATE AND DYNAMIC THERMOPHYSICAL PARAMETERS OF TRANSPARENT BUILDING COMPONENTS

building science.com Building Science Digest 106 Understanding Vapor Barriers (rev. April 2011) by Joseph Lstiburek Abstract:

RETROFIT INSULATION in WOOD ROOFS

Keep your home. FREE from DAMP, CONDENSATION and MOULD

PREFABRICATED STRUCTURAL SYSTEM FOR PASSIVE HOUSES

Is Your Envelope Effective? BCBEC Luncheon January 29, 2009

WUFI Pro 5 Manual. D. Zirkelbach Th. Schmidt M. Kehrer H.M.Künzel

Royal Institute for Cultural Heritage (KIK-IRPA), Laboratories Department, Brussels, Belgium; 2 Daidalos-Peutz Engineers, Leuven, Belgium

OVERALL PERFORMANCE OF VENTILATED DOUBLE FAÇADES COMPARED TO A STATE OF THE ART SINGLE SKIN FAÇADE

Is the moisture buffer value a reliable material property to characterise the hygric buffering capacities of building materials?

Technical Data Sheet StoLevell Duo plus

FAST DRYING CONCRETE

Catalogue of Learning Targets

Insight. Stress Relief. By Joseph W. Lstiburek, Ph.D., P.Eng., Fellow ASHRAE

COMP ONENT CATA LO GUE FOR B UILDING YO UR OWN HOME

Transcription:

A NEW MODEL FOR PREDICTION AND ITS APPLICATION IN PRACTICE M. Krus, and K. Sedlbauer Fraunhofer Institute for Building Physics, Holzkirchen, Germany ABSTRACT In buildings growing conditions for mould fungi can occur and cause fungus infestation. Therefore, consequent measures have to be taken to avoid health dangers that come from mould fungi in buildings. In order to avoid the mould fungus formation, a strategy has to be set up that focuses on the growth conditions for mould fungi. While in Germany only relative humidity is used as an assessment criterion for mould growth risk, more and more measured isopleths are used abroad. But all these growth curves have been determined for steady state conditions, in spite of the non-steady state conditions in reality. The most important boundary conditions for the growth of fungi are temperature, humidity and substrate conditions which have to be simultaneously available. A new biohygrothermal procedure is developed, which allows the prediction of mould growth under transient boundary conditions. The assessment results from a comparison of the water content in a modeled mould spore determined by transient calculations, with the critical water content, above which the spore germinates and grows. This new model is described and its application is demonstrated on different practical examples. KEYWORDS Mould growth, modeling, biohygrothermal model, health effects. INTRODUCTION The application of biocides is always accompanied by additional health risks, especially when used indoors, and moreover can prevent the formation of mould fungus only over a limited period of time. A prerequisite for preventing mould fungus without the use of biocides is the knowledge of the boundary conditions under which fungus growth takes place. In reference to the boundary conditions for the growth of fungus it turns out that the decisive parameters of influence like humidity (Grant, 1989) and temperature (Smith1982) as well as the substrate (Ritschkoff 2000) have to be available over a certain period of time simultaneously in order to enable the formation of mould fungi. Therefore, the main focus of this scientific paper on hand is to develop a planning instrument from the point of view of an engineer that aims at predicting the formation of mould fungus. This procedure consists of two consecutive predictive models, i.e. the Isopleth model and the transient Biohygrothermal model. HEALTH ASPECTS OF MOULD People are exposed to mould spores in the air they breathe daily; however, sometimes moulds grow excessively in certain areas and can cause different types of illnesses (Pasanen 2001). The most prevalent affect of mould on human health is caused by the allergenic impact of its spores (Horner 1995). Some moulds are more hazardous than others. Different people have different responses to mould exposure. In particular, those with allergies, existing respiratory conditions or suppressed immune systems are especially susceptible to health problems. In addition, some moulds produce chemicals called mycotoxins, which can cause flu-like symptoms. It should be noted that the causes Corresponding Author: Tel: + 49 8024 643258, Fax: + 49 8024 643366 E-mail address: krus@hoki.ibp.fhg.de

and effects of mould exposure on people are not very well understood. For this reason mould growth should be restricted as far as possible. GROWTH CONDITIONS FOR MOULD German literature often states a relative humidity of 80% at wall surfaces as decisive criterion for mould growth, independent of temperature. Sometimes it is mentioned that many types of mould can also thrive at lower humidities (see for example the new draft of DIN 4108-X, Mould (Deutsches Institut für Normung 1999)). Other growth conditions, namely a suitable nutrient substrate and a temperature within the growth range are taken for granted on all types of building elements usually. The growth conditions for mould may be described in so-called isopleth diagrams (Ayerst 1969). These diagrams describe the germination times or growth rates. Beyond the lowest line every mould activity ceases, under these unfavourable temperature and humidity conditions spore germination or growth can be ruled out. The isopleths are determined under steady state conditions, i.e. constant temperature and relative humidity. The three factors required for growth nutrients, temperature and humidity must exist simultaneously for a certain period of time; this is the reason why time is one of the most important influence factors. It is assumed that germinable spores are present in most cases. This means that mould growth will occur when hygrothermal growth conditions are fulfilled. ISOPLETH SYSTEMS Significant differences exist among the various fungus species. Therefore, when developing common Isopleth systems all fungi were regarded that can be detected in buildings. Quantitative statements on the growth prerequisites temperature and humidity will be set up for these more than 150 species that fulfil both features, as far as they are given in literature. Within the Isopleth model the prerequisites for the growth of mould fungi in dependence of temperature and relative humidity are stated for the above mentioned hazardous classes at first for the optimal culture medium. The Isopleth systems are based on measured biological data and also consider the growth prerequisites of all fungi of one hazardous class. The resulting lowest boundary lines of possible fungus activity are called LIM (Lowest Isopleth for Mould). In order to regard the influence of the substrate, that is the building materials or possible soiling, on the formation of mould fungus, Isopleth systems for 4 categories of substrates were suggested that could be derived from experimental examinations: Substrate category 0: Optimal culture medium; Substrate category I: Biologically recyclable building materials like wall paper, plaster cardboard, building materials made of biologically degradable raw materials, material for permanent elastic joints; Substrate category II: Biologically adverse recyclable building materials such as renderings, mineral building material, certain wood as well as insulation material not covered by Ι; Substrate category III: Building materials that are neither degradable nor contain nutrients. For the substrate category III no Isopleth system is given since it can be assumed that formation of mould fungi is not possible without soiling. In case of considerable soiling, substrate category I always has to be assumed (Fig. 1 left). Persistent building materials with high open porosity mostly belong to substrate category II. The basic principle of the new method and of defining the building material categories is to assume a worst case scenario, therefore always being on the safe side in respect of preventing the formation of mould fungi. To what extent correcting the Isopleth systems for individual building material categories towards increased relative humidity can still be done with a clear conscience, has to be proved by further measurements.

Figure 1 Isopleth systems for 3 categories of substrates (left), in order to regard the influence of the substrate on the formation of mould fungus (Sedlbauer, 2001) and Isopleth systems for the so called critical fungus species (right). In order to differentiate the mould fungi according to the health dangers they may cause, a so called hazardous class K will be defined as follows (Krus and Sedlbauer 2002): The isopleth system K applies to mould fungi, which are discussed in the literature because of their possible health effect (Fig. 1 right). For these species (Aspergillus fumigatus, Apergillus flavus and Stachybotrys chartarum) growth data from (Sedlbauer 2001) are available. The isopleth system for the fungi estimated as critical is based on the available data on optimum culture medium. To make a adequate substrate specific isopleth precise measurements are missing. To move the isopleth to a higher humidity analogically to the development of the imagined building material isopleth, is too risky especially for these fungi according to today s knowledge. APPLICATION OF THE ISOPLETH SYSTEM Mould growth damage is not rare in non-insulated houses (Künzel 1999). But mould growth can also occur in insulated houses, insulated according to today s standards, when too high humidity (for example due to built-in moisture) are combined with insufficient ventilation. Calculations with a new hygrothermal building simulation tool, which has been developed at the IBP and which is being validated, show in which way increasing air humidity appears because of built-in moisture in the first years after construction (Sedlbauer 2001). With it a wall construction (made of aerated concrete) with an U-value in its standard cross-section of 0.25 W/m 2 K has been investigated. As built-in moisture an initial water content of 20 Vol.-% is taken in account. The change of air rate has been decreased to an extremely low value of 0.1 h -1 starting with the DIN-Standard required 0.5 h -1, which should be realistic based on closed windows in some cases. The results of these calculations hour values of temperature and relative humidity have served as boundary conditions for the following determinations of the boundary conditions on the surface of the wall. This way the hygrothermal situation has been examined on the external wall in the corner, behind a closet as well as in the extreme case in the corner behind a closet. The internal heat-transfer coefficient is assumed for the unobstructed wall corner with 5 W/m 2 K, behind the closet on the external wall a value of 4 W/m 2 K and in the corner a value of 2 W/m 2 K is assumed. With the calculations it is assumed that the house will be lived-in after one month after building finish. The calculations take place for the first heating period.

The calculated transient courses of temperature and relative humidity on the component surface as growth conditions are compared with the data in the corresponding isopleth systems of the spores. These data can for example be plotted as hourly values in the isopleth systems. With help of the individual isolines (for example four days) it is fixed, which contribution an hourly value, which lies for example on this isoline, leads to spore germination (in this case it is one hour / 4 (days) x 24 hours) = 0.01). These values are added and shown as a germination course dependent on time. When the total value reaches 1, it is assumed, that the spore germination is finalised and that the fungus is starting to grow. This results in an easy way of assessment; it can be shown, whether it comes to spore germination in a specific time. Analogue to this with help of the substrate specific isopleth system for mould growth the celerity of mycelium grows can be determined. Figure 2 (left) shows the results of substrate group I determined by the described way. Despite of built-in moisture mould growth is not prognosed by an air change of 0.5 h -1 or by a decreased air change of 0.3 h -1 (both cases not shown). But when the air change rate is decreased to 0.2 h -1, it rapidly comes to complete germination in the corner. In the free wall corner only a small mould growth appears, it is to be expected that in the corner behind the closet a clear growth appears. Because the isopleth system for fungi estimated as critical (although determined for ideal medium) other results are obtained (see Fig. 2 right). They show, that critical fungi do not grow in contrast with the other ones under these conditions. Figure 2 Course of the calculated degree of germination (below) and mycelial growth (above) for a decreased air change of 0.2 h -1 with concomitance of built-in moisture underlying the isopleths of substrate group I (left) and hazardous class K (right). BIOHYGROTHERMAL MODEL For transient boundary conditions of temperature and relative humidity, either spore germination time or the mycel growth can be determined with the help of these Isopleth systems. The assessment of spore germination on the basis of the Isopleth model has the disadvantage that an interim drying out of the fungi spores cannot be taken into account in case of occurring transient micro-climatic boundary conditions. Therefore in these cases, this process will more often predict the germination of spores than the following Biohygrothermal model. In order to describe the mode of action for the fundamental means of influence on the germination of spores, i.e. the humidity available at certain temperatures, this new model was developed.

The decisive condition for the germination of the spores is the ambient humidity which determines the moisture content within a spore. The objective of the so called Biohygrothermal Model (Sedlbauer, 2001) is to predict this moisture balance as affected by realistic unsteady boundary conditions as found in buildings, in order to permit predictions of growth probabilities. Of course, the moisture content of a spore is also determined by biological processes, but the current knowledge is far from sufficient to allow modelling of these. It is safe to assume that only above a certain minimum moisture content the spore begins to germinate and no biological metabolic processes occur before that. Until then, the spore may be considered as an abiotic material whose properties are subject to purely physical principles (see Fig. 3). The Biohygrothermal Model only describes the development of the spore up to this point. Due to the small size of the spore an isothermal model is sufficient, so that liquid transport processes (such as capillary suction) can be lumped together with diffusion transport. Under these assumptions only the moisture storage function of the spore and the moisture-dependent vapour diffusion resistance of the spore wall are needed as material parameters (Krus 1996). According to the assumptions noted earlier the germination is principally affected by thermal and hygric conditions only. Therefore it should be independent of the substrate. But normally the starting point of germination is defined by the first visible growth and not by the start of metabolism. The apparent start of germination depends on the quality of the substrate according to these considerations. This influence of the substrate is taken into account by using the LIMs (Fig. 1) in order to calculate the so called critical water content. Figure 3 Schematic diagram of the Biohygrothermal Model (Sedlbauer 2001). EXAMPLE ROOF COVERED WITH METAL SHEETS Roofs covered with metal sheets have a very high vapour diffusion resistance, so that virtually no moisture can escape through the covering. Therefore, a sufficiently permeable inside vapour retarder must allow the moisture to dry out towards the room side, especially during the warm summer months. In order to compare different vapour retarders, extensive investigations were carried out in the test site of the IBP. Because of the high insolation on the southern plane of the roof and the resulting high temperatures of the metal covering, so-called summer condensation occurs. This means that moisture diffuses from the hot outer parts of the roof assembly to the cooler room side and temporarily increases the humidity at the vapour retarder. The above mentioned outdoor tests show that a polyamide sheet results in the lowest wood moisture levels so that the proper function of this kind of vapour retarder could be confirmed. In the variant conducted with kraft paper, mouldy odour and patches of mould were found at the end of the investigations which showed that extensive mould growth had taken place in the roof assembly. This gable roof has a pitch of 50 and the ridge is oriented in an east-west direction, so that one of the roof planes is facing north and the other is facing south. Figure 4 (left) displays the basic design of the test sections. The interior view of the insulated roof in Figure 4 (right) shows three different variants. The space between the rafters (rafter height 18 cm) had been completely filled with mineral wool (thermal conductivity ca. 0.04 W/mK), so that no air gap was left between the insulation and the rough boarding (30 mm thick). For rafters and boarding moist wood with a moisture content of at least 30

mass-% had been used. The investigated vapour retarders were Kraft paper with a permeability of approx. 3 m, a polyethylene sheet with 50 m and a smart vapour retarder (Künzel 1999) with a permeability between 0.4 and 4 m, depending on the ambient humidity. Figure 4 The tested roof covered with metal sheets. Left: Basic design of the test sections. Right: Photographical view of the interior. Figure 5 Calculated results for the vapor retarders inside the roof (Sedlbauer 2001). Left: Courses of the relative humidities. This courses serves as boundary conditions for the calculation of the moisture balance of the spore. Middle: Courses of the water content inside the spores. The courses of the starting point for germination are implied for both materials (horizontal lines). Right: Courses of the water content inside the spores. The courses of the starting point for germination of mould concerning to the hazardous class K is implied. The variation of RH on the interior surfaces of the Kraft paper and the smart vapour retarder in this roof, calculated with the aid of the WUFI model for an observed period of 180 days, are shown in Figure 5 (left). The surface temperatures (not shown in Fig. 5) were nearly constant with time at about 21 C. These records have served as boundary conditions for the calculation of the courses of the water content inside the spore in step 2 of the analysis. Due to the high vapour diffusion resistance of the spore wall the courses of the calculated moisture content in the spores are smoothened (compare Fig. 5 middle) compared to the RH on the interior surface of the roof. On Kraft paper the spore shows a distinctive higher water content in comparison with the smart vapour retarder and reaches more than 60 % per Volume. Additionally the variation of the starting point of germination are implied for both materials. Since the surface temperature was nearly constant these records show almost no change with time. It is evident, that the water content of the spore calculated for the Kraft paper lies for a long period at a much higher level than necessary for germination. After about 30 days the growth of mould starts, a result which is quite consistent with the observations on this roof. With the polyamide foil the moisture content exceeds this limit only for a very short period and therefore no risk of mould growth should be expected. The right side of Figure 5 shows the results for the hazardous class K. For the smart vapour retarder the occurrence of these hazardous mould fungi can be excluded. For Kraft paper instead the risk to get them is obvious.

EXAMPLE RUIKSMUSEUM AMSTERDAM The change of use of rooms, storeys or whole buildings mostly leads to a change of internal climatic conditions. During the phase of planning of substantial refurbishment measures in the Ruiksmuseum amsterdam it could be foreseen that decisive changes of the interior climate have to be expected. Already the existing building shows moisture problems (surface condensation). After the realisation of all measures planned even more adverse relative humidities had to be expected in the room and at the inner surfaces of the exterior walls. For this reasons an internal heat insulation made of diffusion open calcium silicate was projected and for critical building details the risk of condensate and mould growth is calculated by one- and two-dimensional simulations (Häupl et al 2003). As an example, results for the reveal of a window and for an outside wall will be shown. The reveal of the windows is made of sandstone from inside to outside. The simulation results show that because of its high thermal conductivity, especially during winter time, low surface temperatures occur as well as a high relative humidity (10.8 C and 97% RH, Fig. 6). An interior insulation of calcium silicate with a thickness of 40 mm will improve the conditions: the temperature reaches 13.1 C at 87% RH. Figure 6 Course of temperature (left side) and relative humidity (right side) during the winter time at the reveal of a window and behind a canvas painting on the wall. It was also planned to fix canvas paintings at the thinner sections of the exterior wall of rooms which had been unused until then. If the wooden frame of a picture is fixed holohedral to the wall, it can be assumed that because of the missing air exchange the air layer behind the picture has a function of an additional insulating layer resulting in lowered surface temperatures. The courses of temperature and relative humidity (fig. 6, red and green colour) correspond to the inside surface of the exterior wall behind a picture. The positive influence of the interior insulating layer is obvious. During winter time the surface temperature is increased about 2 C and the RH is lowered about 10 to 15 %. Figure 7 shows the result of the mould growth prediction. Whereas with the interior insulation no mould growth is predicted, without additional insulation increasing problems have to be expected after the planned change of use. Figure 7 Predicted Mould growth behind a picture fixed on the outside wall and at the reveal of a window without insulation.

CONCLUSIONS The only chance for the long term prevention of mould growth is to ensure that the hygrothermal situation on the surface is not convenient for mould growth. Up to now the common methods to assess the risk of mould growth are based on steady boundary conditions. The biohygrothermal model allows a fast, easy and reliable judge of an existing or planned construction or of a refurbishment measure concerning mould growth. This newly developed model, describing the hygrothermal behaviour of the spore, allows for the first time to employ the changing surface temperatures and RH s for the prediction of mould growth. The calculational assessment of mould growth allows the handling of problems which until now couldn t be solved with simple estimations or with reasonable metrological expense. Therewith the effectivity of refurbishment measures on behalf of the elimination of the risk of mould growth can be determined. The optimization of building constructions may now be performed in an easy way. The capability of the Biohygrothermal Model to assess the risk of mould growth has been demonstrated impressively be the shown results for a roof covered with metal sheets and for the Ruiksmuseum. REFERENCES 1. Ayerst, G. 1969. The Effect of Moisture and Temperature on Growth and Spore Germination in some Fungi. J. stored Prod. Res., 5, S. 127-141. 2. Deutsches Institut für Normung 1999. Wärmeschutz und Energie Einsparung in Gebäuden, Teil x: Vermeidung von Schimmelpilzen (heat protection and energy saving in buildings, part x: prevention of mould growth), Beuth Verlag, draft 10.05.99. 3. Grant, C.; Hunter, C. A.; Flannigan, B.; Bravery, A. F.: The moisture requirements of moulds isolated from domestic dwellings. International Biodeterioration 25, (1989), S. 259-284. 4. Horner, W. E.; Helbling, A.; Salvaggio, J. E.; Lehrer, S. B.: Fungal allergens. Clinical Microbiology Reviews Vol. 8 (1995), H. 2, S. 161-179. 5. Krus, M. 1996. Moisture Transport and Storage Coefficients of Porous Mineral Building Materials. Theoretical Principles and New Test Methods. IRB-Verlag Stuttgart, S. 1-172, ISBN 3-8167-4535-0. 6. Krus, M. & Sedlbauer, K. 2002. Brauchen wir Gefährdungsklassen für Schimmelpilze zur Beurteilung von Baukonstruktionen? (Do we need hazardous classes of mould fungi for the assessment of building parts?), Tagungsbeitrag für das 11. Bauklimatische Symposium der TU Dresden. 26. 30. Sep. 2002, Dresden, S. 790 802. 7. Künzel, H. M. 1999. Flexible vapour control solves moisture problems of building assemblies Smart Retarder to replace the conventional PE-film. Journal of Thermal Envelope & Building Science, Vol. 23, pp. 95-102. 8. Pasanen, A. L.: A review: Fungal exposure assessment in indoor environments. Indoor Air 11 (2001), H. 2, S. 87-98. 9. Ritschkoff, A.-C.; Viitanen, H.; Koskela, K.: The response of building materials to the mould exposure at different humidity and temperature conditions. Proceedings of Healthy Buildings (2000), Vol. 3, S. 317-322. 10. Sedlbauer, K. 2001. Vorhersage von Schimmelpilzbildung auf und in Bauteilen (Prediction of mould manifestation on and in building parts). Thesis, University of Stuttgart. 11. Smith, S. L.; Hill, S. T. 1982. Influence of temperature and water activity on germination and growth of aspergillus restrictus and aspergillus versicolor. Trans. Br. Mycol. Soc., 79(3), S. 558-560. 12. Häupl, P.; Petzold, H.; Finkenstein, C.: Feuchteschutztechnische und energetische Bewertung der Gebäudesanierung mit raumseitiger Wärmedämmung aus Calciumsilikat (Energetic and hygric assessment of an interior insulation with calcium silicate boards), Forschungsbericht, TU Dresden, Februar 2003.