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3. Hygrothermal assessment of three bio-based insulation systems for internal retrofitting solid masonry walls.

Author

Jensen, Nickolaj Feldt, Møller, Eva B., Hansen, Kurt Kielsgaard, and Rode, Carsten

Subjects
*VAPOR barriers, *INSULATING materials, *MINERAL wool, *RAINFALL, *MASONRY, *HYGROTHERMOELASTICITY
Abstract

The present project investigated the hygrothermal performance and risk of mould growth in solid masonry walls retrofitted internally with three diffusion-open bio-based insulation materials (two loose-fill cellulose and one hemp fibre), installed in test containers with controlled indoor climate. Focus was on bio-based insulation materials, as these are upcoming due to necessary CO2 reductions and because the hygroscopic properties of bio-based materials are different from traditional insulation materials like mineral wool therefore, some manufacturers claim a vapour barrier is unnecessary, even in relatively cold climates. The project was a large experimental study in two reefer containers with reconfigured facades, in which solid masonry walls with embedded wooden elements were constructed. The study focused on the conditions in the masonry/insulation interface and in the embedded wooden elements. The effect of hydrophobization and different indoor moisture loads were also investigated. Moreover, the bio-based insulation systems were compared with a wall insulated with the traditional mineral wool and vapour barrier system. Relative humidity and temperature were measured at several locations in the test walls for 1 year and 9 months. Measurements show that exposed masonry walls retrofitted internally with diffusion-open bio-based insulation materials resulted in unacceptably high moisture levels (>80% RH over longer periods). Lower moisture levels were observed when the internal insulation was combined with hydrophobization against wind-driven rain, but unacceptably high moisture levels still occurred (60%–70% in summer and 95%–100% in winter in the interface). Hydrophobization reduced the moisture levels in the interface and embedded wooden elements only in walls facing southwest, which is the direction with the most wind-driven rain. Mould growth tests showed no growth in the interface in walls insulated with cellulose insulation (mycometer surface value <25). Meanwhile growth was found in all four walls insulated with hemp fibre matts (mycometer surface value >400). [ABSTRACT FROM AUTHOR]

Published
2024
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4. Damp Buildings: Associated Fungi and How to Find Them.

Author

Loukou, Evangelia, Jensen, Nickolaj Feldt, Rohde, Lasse, and Andersen, Birgitte

Subjects
*PENICILLIUM chrysogenum, *BUILDING inspection, *FUNGAL growth, *FUNGI, *ASPERGILLUS niger, *ASPERGILLUS, *PENICILLIUM
Abstract

The number of buildings experiencing humidity problems and fungal growth appears to be increasing as energy-saving measures and changes in construction practices and climate become more common. Determining the cause of the problem and documenting the type and extent of fungal growth are complex processes involving both building physics and indoor mycology. New detection and identification methods have been introduced, and new fungal species have been added to the list of building-related fungi. However, the lack of standardised procedures and general knowledge hampers the effort to resolve the problems and advocate for an effective renovation plan. This review provides a framework for building inspections on current sampling methods and detection techniques for building-related fungi. The review also contains tables with fungal species that have been identified on commonly used building materials in Europe and North America (e.g., gypsum wallboard, oriented strand board (OSB), concrete and mineral wool). The most reported building-associated fungi across all materials are Penicillium chrysogenum and Aspergillus versicolor. Chaetomium globosum is common on all organic materials, whereas Aspergillus niger is common on all inorganic materials. [ABSTRACT FROM AUTHOR]

Published
2024
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5. Risk of mould growth in future climate in different European locations for two bio-based insulation systems for interior retrofitting.

Author

Jensen, Nickolaj Feldt, Møller, Eva B., Hansen, Kurt Kielsgaard, and Rode, Carsten

Subjects
*MARINE west coast climate, *RETROFITTING, *EXTERIOR walls, *FIELD research, *HUMIDITY
Abstract

This research project investigated the hygrothermal performance of two bio-based insulation systems for interior retrofitting solid masonry walls; loose-fill cellulose insulation and hemp fibre insulation mats. The study was carried out through HAM simulations calibrated with 1 year and 2 months of measurements and material data from a field experiment in Denmark's Nordic, maritime climate. The experimental setup comprised a 40-foot (12.2 m) insulated reefer container with controlled indoor climate, reconfigured with several holes (1 m×2 m each) accommodating the solid masonry walls. Some of the masonry walls had exterior hydrophobisation. The calibrated simulation models were used to investigate the long-term robustness of the bio-based insulation systems to the future climate conditions caused by different emission scenarios between year 2020 and 2050, for several locations around Europe. The focus of the study was on the conditions in the interface between the masonry and the internal insulation, and the mould risk was evaluated using the VTT mould growth model. The findings showed high relative humidity levels in the masonry/insulation interface with a high risk of mould growth, already exposed to the current climate data. The results indicate that the future climate conditions would exacerbate the hygrothermal conditions in the insulated masonry walls. Exterior hydrophobisation positively affected the hygrothermal balance in the insulated masonry walls, lowering the risk of mould growth under future climate conditions. However, the results indicate that in some cases, the insulation systems would still experience critical relative humidity levels despite the combination with hydrophobisation. [ABSTRACT FROM AUTHOR]

Published
2023
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6. Hygrothermal assessment of solid masonry walls internally insulated with bio-based insulation materials.

Author

Jensen, Nickolaj Feldt, Møller, Eva B., Hansen, Kurt Kielsgaard, and Rode, Carsten

Subjects
*THERMAL insulation, *INSULATING materials, *EXTERIOR walls, *MASONRY, *WALLS, *HUMIDITY, *RISK assessment
Abstract

This study investigated the hygrothermal performance and risk of mould growth in two bio-based thermal insulation systems for internal retrofitting purposes; loose-fill cellulose insulation and hemp fibre insulation. The experimental set-up comprised a 40-feet (12.2 m) insulated reefer container with controlled indoor climate, reconfigured with several holes (1x2 m each) containing solid masonry walls with embedded wooden elements on the interior side and different internal insulation systems, with and without exterior hydrophobisation. The container was placed in Denmark. Throughout 1 year and 2 months, temperature and relative humidity were measured in the interface between the masonry and the internal insulation and in the embedded wooden elements. The effect of exterior hydrophobisation was also investigated. The VTT mould growth model was used to evaluate the mould risk. Lastly, the hygrothermal performance of the bio-based systems was compared with that of previously examined inorganic internal insulation systems. Findings for the two bio-based thermal insulation systems showed that exposed walls experienced high relative humidity. The combination with exterior hydrophobisation to lower intrusion of driving rain had a positive effect on the moisture balance for the masonry walls. However, the insulated walls with hydrophobisation still showed high relative humidity levels during specific periods of the year in some of the examined masonry walls. The mould risk evaluation showed a high risk of mould growth in masonry/insulation interface, as well as in the wooden wall plates in some test walls. [ABSTRACT FROM AUTHOR]

Published
2023
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7. Fungal growth on concrete surfaces of floors and walls.

Author

Jensen, Nickolaj Feldt, Andersen, Birgitte, and Morelli, Martin

Subjects
*FUNGAL growth, *MORTAR, *CONCRETE floors, *ADHESIVE cements, *BUILDING envelopes, *SURFACE cleaning
Abstract

Generally, a high pH-value (above 12) in building structures is considered to be an inhibitory factor against fungal growth. However, fungal growth can in some cases be detected on concrete surfaces in new buildings shortly after commissioning and in existing walls retrofitted with internal insulation installed using cement based adhesive mortars. This paper deals with two building envelope structures: newly casted concrete floors fitted with vapor membranes and existing walls fitted with internal insulation. In both fungal growth has been detected and linked to the decreasing pH-value and lingering moisture. For floors, several new buildings were investigated and the cleaning method, moisture content, concrete age after casting and fungal species were registered. Furthermore, the development in pH-value was measured on newly casted concrete to determine the decrease in pH-value. For walls, laboratory and field experiments were conducted both under realistic and worst-case condition. After 1-4½ years, samples of the internal insulation were taken to investigate fungal growth, fungal species, moisture content and pH-value behind the insulation. Moreover, the development in pH-value of fresh cement-based adhesive mortars was investigated. The results showed that the fungal species, Aspergillus versicolor, was common in both floors and walls and indicate that the A. versicolor spores can survive the high pH-value (above 12), and then later germinate and grow when pH-value decreases and moisture content increases. Furthermore, the results showed that the pH-value decreased faster, when the surface/interface has access to air and that only a totally clean surface would prevent later fungal growth in the interface, if the pH and moisture conditions change in favour of fungal growth. [ABSTRACT FROM AUTHOR]

Published
2023
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10. Internal insulation of solid masonry walls – field experiment with Phenolic foam and lime-cork based insulating plaster

Author

Jensen Nickolaj Feldt, Rode Carsten, Andersen Birgitte, Bjarløv Søren Peter, and Møller Eva B.

Subjects
Environmental sciences, GE1-350
Abstract

The study investigated the hygrothermal performance and risk of mould growth in two thermal insulation systems for internal retrofitting purposes; a phenolic foam system with a closed cell structure, and a capillary active diffusion-open lime-cork based insulating plaster. The setup consisted of a 40-feet (12.2 m) insulated reefer container with controlled indoor climate, reconfigured with several holes (1x2 m each) containing solid masonry walls with embedded wooden elements on the interior side and different interior insulation systems, with and without exterior hydrophobisation. Focus was on the conditions in the interface between wall and insulation system, and in the embedded wooden elements. Relative humidity and temperature were measured in several locations in the test walls over two years, and the mould risk was evaluated by measurements and the VTT mould growth model. Findings for the interior phenolic foam system indicated that exposed walls experienced high relative humidity and high risk of moisture-induced problems. Exterior hydrophobisation had a positive effect on the moisture balance for the southwest oriented wall with phenolic foam. The lime-cork based insulating plaster showed high relative humidity and risk of moisture-induced problems, with and without hydrophobisation.

Published
2020
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11. Robust solutions for internal retrofitting solid masonry walls in historic buildings with regards to hygrothermal performance

Author

Jensen, Nickolaj Feldt

Subjects
SDG 13 - Climate Action
Abstract

The built environment is estimated to be responsible for nearly 40% of the world’s total energy usage, and 30-40% of the emissions. Approximately 40% of the European building stock was constructed before 1960, and these buildings often have large heat losses through the building envelope and perhaps also thermal comfort issues. A large share of the aforementioned buildings have an exterior appearance worthy of preservation due to their historic or aesthetic values which prevents the use of renovation measures that could compromise these values. In terms of retrofitting the façade walls, external insulation is often prohibited leaving internal insulation as the only remaining option. However, internal thermal retrofitting solid masonry walls is generally regarded as risky since the added insulation causes the existing wall structure to become colder and wetter, which increases the risk of interstitial condensation. In addition, the added insulation reduces vapour diffusion drying to the room side. These factors contribute to elevated moisture levels in the wall structure and an increased risk of moisture induced damage. Consequently, there exists a need for defining robust methodologies for the installation of internal insulation of historic solid masonry walls, which do not cause hazardous fungal growth or other undesirable issues e.g. decay of embedded wooden elements.The purpose of this study was, in a large field experiment, to investigate several either diffusion-open or diffusion-tight insulation systems to determine if it is possible to internally retrofit solid masonry walls without causing hazardous fungal growth. The investigated diffusion-open insulation systems were: polyurethane with calcium silicate channels, monolithic calcium silicate, lightweight autoclaved aerated concrete, and lime-cork based insulating plaster. The diffusion-tight systems were: phenolic resin foam, and traditional mineral wool with a vapour barrier. These systems were examined in combination with exterior hydrophobisation. The field study findings were complemented by calibrated numeric simulations performed to investigate additional parameters and the robustness against changing climate conditions in the future. The field experiment and the laboratory tests also investigated if controlling the immediate surroundings would prevent the occurrence of fungal growth and the risk of fungal growth affecting the indoor climate. Lastly, several mathematical models for prediction of mould growth and wood decay were assessed and compared to on-site microbiological tests.The field study showed high relative humidity levels in the internally insulated solid masonry walls without exterior hydrophobisation in the case of high indoor moisture load during winter. In addition, the diffusion tightness of the insulation was found to be of considerable importance in terms of the hygrothermal performance. Without exterior hydrophobisation the diffusion-open insulation systems were found to perform slightly better than the diffusion-tight systems. However, in the case of test walls with exterior hydrophobisation the diffusion-tight systems performed considerably better. The material and microbiological tests in the field experiment and the laboratory study showed no fungal growth in the interface between the masonry wall and insulation in the case of high alkalinity (pH>12) in the surrounding materials i.e. the internal render and adhesive glue mortar. This suggests that if high alkalinity could be maintained then fungal growth could probably be prevented despite the presence of unacceptably high moisture levels. In systems where the alkalinity declined rapidly it was found to be of considerable importance to ensure that no organic additives or elements were present in the critical locations. Furthermore, diffusion tests with VOCs mimicking Microbial Volatile Organic Compounds produced by fungal growth showed that in the case of growth behind the insulation the VOCs were able to penetrate most of the examined systems and potentially affecting the indoor air quality negatively. The rate of diffusion through the systems was found to be relatively large for the highly water vapour diffusion-open insulation systems, especially in the case of highly volatile VOCs such as acetone or ethanol. The mould growth and wood decay prediction models were found to overestimate the risk, and for the mould growth predictions this was probably due to the high alkalinity and insufficient access to nutrition in the critical locations.

Published
2021

13. Monitored conditions in wooden wall plates in relation to mold and wood decaying fungi

Author

Hansen, Tessa Kvist, Jensen, Nickolaj Feldt, Møller, Eva, Hansen, Ernst Jan De Place, and Peuhkuri, Ruut Hannele

Abstract

In historic masonry buildings, wood can be embedded in the walls as storey partition beams, or as supportive wall plates. Half-timbered masonry constructions, or wooden frames, e.g. combined with internal insulation, are other examples of wooden elements. Wood decaying fungi can cause serious damage to wood, which may lose mass and strength, ultimately yielding the risk of collapse. In addition, some fungal species may even be hazardous for occupants. All wood decaying fungi depend on favorable moisture and temperature conditions, although the threshold conditions may vary with various fungal species and types, and state of the wood. To predict the risk of occurrence of wood rot, several models have been developed, however most of these are based on a limited number of experiments, or very specific cases. For these reasons, the applicability of the models to other scenarios (fungal species, wood species) may not be appropriate. Furthermore, another failure mode for wood and moisture, is mold growth, which is initiated at lower moisture levels. An indication of risk of mold growth would indicate problems or risks before the initiation of wood rot. Mold growth does not deteriorate the wood, but is usually equally undesired due to health concerns of occupants. For this reason, there might be places where some mold growth would be acceptable, e.g. embedded beam ends if there is no transfer of air from the moldy area to the indoor air. Therefore, risk of rot could be important. The paper investigates models for mass loss due to wood decay and mold growth based on exposure time to favorable hygrothermal conditions. The investigation is based on inspection of wood samples (wall plates) from a full-scale experimental setup of masonry with embedded wood and monitored conditions, to which the prediction models will be applied. Monitored hygrothermal conditions were implemented in mold and wood decay models, and samples were removed from the test setup. The implemented models yielded high mold index and mass loss, whereas neither mold nor decay was observed in the physical samples. Results indicate that the implemented models, in these cases appear to overestimate the risks of mold and rot in the supportive lath behind the insulation.

Published
2020
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14. RIBuild Deliverable no. D2.2 – Threshold values for failure, linked to types of building structures and failure modes

Author

Johansson, Pernilla, Lång, Lukas, Capener, Carl-Magnus, Møller, Eva B., Quagliarini, Enrico, D’Orazio, Marco, Gianangeli, Andrea, Janssen, Hans, Feng, Chi, Langmans, Jelle, Jensen, Nickolaj Feldt, de Place Hansen, Ernst Jan, Peuhkuri, Ruut Hannele, and Hansen, Tessa Kvist

Subjects
algae, laboratory testing, mold, threshold values, frost, fungi, rot, predictive models, cyanobacteria, failure modes
Abstract

This report comprises a study of material threshold values, failure modes and related failureprediction models to enable an evaluation of adding internal insulation in historic brick buildings.Threshold values and prediction models have been investigated both within literature and throughlaboratory study, by for instance comparing prediction models to real field results and by testingthreshold values in laboratory. The aim of this report is to find threshold values and suitable andreliable prediction models to be included in the decision guidelines and the web tool, which are thefinal outcomes of the RIBuild project. Failure modes included in the report are mould growth onbuilding materials, rot and wood decay, frost damage and discoloration of facades.

Published
2019

16. Laboratory‐based investigation of the materials' water activity and pH relative to fungal growth in internally insulated solid masonry walls.

Author

Jensen, Nickolaj Feldt, Bjarløv, Søren Peter, Rode, Carsten, Andersen, Birgitte, and Møller, Eva B.

Subjects
*FUNGAL growth, *WALLS, *MASONRY, *INDOOR air quality, *VOLATILE organic compounds, *MORTAR
Abstract

This project investigated fungal growth conditions in artificially contaminated interfaces between solid masonry and adhesive mortar for internal insulation. The project comprised several laboratory experiments: test of three fungal decontamination methods; investigation of development of fungal growth in solid masonry walls fitted with five internal insulation systems; and investigation of volatile organic compounds (VOC) diffusion through materials and whole insulation systems. One aim was to examine whether the alkaline environment (pH > 9) in the adhesive mortars could prevent fungal growth despite the water activity (aw) in the interface exceeds the level (aw > 0.75) commonly considered critical for fungal growth. The findings indicate that do‐it‐yourself decontamination solutions were inadequate for removal of fungal growth, while professional solutions were successful. However, the choice of decontamination method was of minor importance in the case of application of internal insulation with high pH adhesive mortar, as the high pH adhesive mortars were found to inactivate existing growth and prevented spore germination during the experimental period. The three tested VOCs were capable of diffusing through most of the examined products and could potentially affect the indoor air quality. [ABSTRACT FROM AUTHOR]

Published
2021
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17. Hygrothermal performance of six insulation systems for internal retrofitting solid masonry walls.

Author

Jensen, Nickolaj Feldt, Bjarløv, Søren Peter, Rode, Carsten, Andersen, Birgitte, and Møller, Eva B

Subjects
*HYGROTHERMOELASTICITY, *FUNGAL growth, *FIELD research, *HUMIDITY, *TEMPERATURE
Abstract

The study investigated the hygrothermal performance and risk of fungal growth in a phenolic foam system with a closed cell structure and a diffusion-open and capillary active lime-cork based insulating plaster, for internal retrofitting purposes. The setup comprised two 40-feet (12.2 m) insulated reefer container with controlled indoor climate, reconfigured with 24 holes (1 × 2 m each) containing solid masonry walls with embedded wooden elements on the interior side. Focus was on the conditions in the masonry/insulation interface and embedded wooden elements, and the performance of the two systems were compared to three diffusion-open insulation systems and one diffusion-tight. The effect of exterior hydrophobisation was also investigated. Relative humidity and temperature were measured in several locations in the test walls over 2½ years, and the risk of fungal growth was evaluated by on-site measurements and the VTT mould-growth model. The findings indicate that internally insulated walls with bare brick exterior surfaces performed poorly with high risk of fungal growth. The effect of exterior hydrophobisation was found to vary with the orientation and the installed insulation system, with a generally positive effect on walls facing south-west but limited effect for north-east. Furthermore, the more diffusion-tight insulation systems were found to perform better in combination with exterior hydrophobisation than the highly diffusion-open systems. The lime-cork insulating plaster showed high relative humidity and risk of moisture-induced problems. The on-site fungal tests showed no growth in the masonry/insulation interface inside the two insulation systems, probably due to high initial pH-value. [ABSTRACT FROM AUTHOR]

Published
2021
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19. Hygrothermal assessment of internally insulated solid masonry walls fitted with exterior hydrophobization and deliberate thermal bridge

Author

Jensen, Nickolaj Feldt, Bjarløv, Søren Peter, Rode, Carsten, and Odgaard, Tommy Riviere

Subjects
Damage models, Hydrophobization, Internal insulation, Mineral insulation board, Field study
Abstract

Relative humidity (RH) and temperature were measured in several solid masonry walls with embedded wooden beams, fitted with autoclaved aerated concrete (AAC) thermal insulation on the interior surface and exposed to a cool, temperate climate. The field study was based on the use of a 40‐feet insulated reefer container reconfigured with eight 1 × 2 m holes containing the solid masonry walls. The study investigated the influence of AAC thermal insulation on the interior side with a combination of exterior hydrophobization and a deliberate thermal bridge in front of the embedded wooden wall plate using a material with higher thermal conductivity. Validated HAM simulations were used to investigate the effect of controlling the indoor humidity, and how this would affect the theoretical risk predictions from the damage models. Experimental findings indicate that hydrophobization of solid masonry walls with internal insulation have both positive and negative effects on the moisture balance of the wall, in relation to moisture‐induced damage, and that a deliberate thermal bridge installed in front of the embedded wooden wall plate can reduce the moisture content in the wooden elements. Simulation findings indicate that a combination of exterior hydrophobization and decreased indoor moisture load can reduce the RH to acceptable levels in relation to moisture induced damage at the interface between existing wall and new insulation. No major changes were observed in relation to the risk of frost damage at the exterior surface.

Published
2018
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20. Hygrothermal assessment of north-facing, cold attic spaces under the eaves with varying structural roof scenarios.

Author

Jensen, Nickolaj Feldt, Bjarløv, Søren Peter, Johnston, Christopher Just, Pold, Casper Fabian Hillestrøm, Hansen, Morten Hjorslev, and Peuhkuri, Ruut Hannele

Subjects
*ATTICS, *VENTILATION, *ATMOSPHERIC temperature, *HUMIDITY, *ROOF insulation
Abstract

The objective of this study was to test whether compliance with the current Danish best practice recommendations concerning design of the cold attic space will prevent damaging moisture levels. The project was performed as a full-scale experimental setup in the cool temperate climate of Denmark. The setup comprised 18 north-facing attic spaces with varying ventilation principles and varying infiltration scenarios. The relative humidity and temperature were measured in attic spaces, indoor and outdoor, for almost 3 years. The hygrothermal performance of the attics was evaluated by post-processing and comparing the data with predicted mould growth risk and with visual observations of mould growth. The results showed that following the recommended passive ventilation strategies made the hygrothermal performance in attics with diffusion-open roofing underlay worse. In addition, increasing vapour diffusion tightness of the roofing underlay made the hygrothermal performance of the cold attic spaces under the eaves worse, except for attics with passive ventilation but without infiltration. The hygrothermal performance of the attics with diffusion-tight roofing underlay was poor when combining infiltration and the assessed ventilation strategy. The performance of the same attic without infiltration showed that some degree of ventilation was needed. External roof insulation did not significantly improve the hygrothermal performance of the attic. [ABSTRACT FROM AUTHOR]

Published
2020
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21. Hygrothermal assessment of four insulation systems for interior retrofitting of solid masonry walls through calibrated numerical simulations.

Author

Jensen, Nickolaj Feldt, Bjarløv, Søren Peter, Rode, Carsten, and Møller, Eva B.

Subjects
MASONRY, WOODEN beams, WALLS, COMPUTER simulation, RETROFITTING, TEMPERATE climate, HUMIDITY, MOISTURE content of food
Abstract

The present research project investigates the hygrothermal performance of four insulation systems for internal retrofitting solid masonry walls with embedded wooden wall plate and beam end. The study was carried out through numerical simulations calibrated with 2–4 years of measurements and material data from a large field experimental in the cool, temperate climate of Lyngby, Denmark. The experiment comprised two 40-foot insulated reefer containers reconfigured with 24 1 × 2 m holes, accommodating the solid masonry walls. The calibrated simulation models were used to investigate several untested design variations which included alternative brick and mortar types, masonry and insulation thickness, indoor moisture load and future climate conditions. The findings indicate that a reduction of the indoor moisture load would improve the hygrothermal performance in the interface between wall and insulation, and in the embedded wooden elements. Increased masonry thickness was seen to make the hygrothermal conditions worse due to increased drying time for the built-in moisture, while in the case of low initial moisture content, increased masonry thisckness improved the hygrothermal performance in the interface and embedded wooden elements. Increased insulation thickness also made the hygrothermal conditions worse. Regarding the brick and mortar types, the results showsed increased relative humidity in the critical locations in the case of high cement mortar compared to low cement mortar. The brick type was however found not to impact the relative humidity levels considerably. Robustness against future climate conditions was seen only for two of the four insulation systems, when combined with exterior hydrophobisation. • Hygrothermal assessment of four insulation systems for interior retrofitting of solid masonry based on numerical simulations calibrated with four years of measurements. • Investigation of the effect of varying brick and mortar types. • Investigation of the effect of increased masonry- and insulation thickness. • A reduction of the indoor moisture load improved the hygrothermal conditions. • Two systems were found robust against future climate conditions. [ABSTRACT FROM AUTHOR]

Published
2020
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