Impact of Envelope Structure on the Solutions of Thermal Insulation from the Inside

[1] Rozporządzenie Ministra Infrastruktury z dn. dnia 12 kwietnia 2002 r. w sprawie warunków technicznych jakim powinny odpowiadać budynki i ich usytuowanie (Dz. U. nr 75. poz. 690). z późniejszymi zmianami (Regulation of the Minister of Infrastructure dated on April 12, 2002, on technical conditions which should be met by buildings and their location (Journal of Laws No. 75, item 690). with later changes). Rozporządzenie Ministra Infrastruktury z dn. dnia 12 kwietnia 2002 r. w sprawie warunków technicznych jakim powinny odpowiadać budynki i ich usytuowanie (Dz. U. nr 75. poz. 690). z późniejszymi zmianami (Regulation of the Minister of Infrastructure dated on April 12, 2002, on technical conditions which should be met by buildings and their location Journal of Laws No. 75 item 690). with later changes) Search in Google Scholar

[2] Hens H. (1998). Performance prediction for masonry walls with inside insulation using calculation procedures and laboratory testing. Journal of Thermal Envelope and Building Science 22, 32–48. Hens H. 1998 Performance prediction for masonry walls with inside insulation using calculation procedures and laboratory testing Journal of Thermal Envelope and Building Science 22 32 48 10.1177/109719639802200104 Search in Google Scholar

[3] Nowoświat A., Pokorska-Silva I. (2018). The influence of thermal mass on the cooling off process of buildings. Perioica Polytechnica Civil Engineering, 62, 173–179. Nowoświat A. Pokorska-Silva I. 2018 The influence of thermal mass on the cooling off process of buildings Perioica Polytechnica Civil Engineering, 62 173 179 10.3311/PPci.10132 Search in Google Scholar

[4] Stopp H., Strangeld P., Fechner H., Häupl P. (2016). The Hygrothermal Performance of External Walls with Inside Insulation. Buildings VIII/Wall Performance—Practices, 1–13. Stopp H. Strangeld P. Fechner H. Häupl P. 2016 The Hygrothermal Performance of External Walls with Inside Insulation Buildings VIII/Wall Performance—Practices 1 13 Search in Google Scholar

[5] Straube J.F., Schumacher C.J. (2007). Interior insulation retrofits of load-bearing masonry walls in cold climates. Journal of Green Buildings 2, 42–50. Straube J.F. Schumacher C.J. 2007 Interior insulation retrofits of load-bearing masonry walls in cold climates Journal of Green Buildings 2 42 50 10.3992/jgb.2.2.42 Search in Google Scholar

[6] Straube J.F., Ueno K., Schumacher C.J. (2012). Building Science Corporation; Measure Guideline: Internal Insulation of Masonry Walls. U.S. Department of Energy. Straube J.F. Ueno K. Schumacher C.J. 2012 Building Science Corporation; Measure Guideline: Internal Insulation of Masonry Walls U.S. Department of Energy Search in Google Scholar

[7] Fechner H., Häupl P., Stopp H., Strangfeld P. (1999). Measurements and numerical simulation of the heat and moisture transfer in envelope parts of buildings. Proceedings of the International Conference on Thermophysical Properties of Materials. Singapore. Fechner H. Häupl P. Stopp H. Strangfeld P. 1999 Measurements and numerical simulation of the heat and moisture transfer in envelope parts of buildings Proceedings of the International Conference on Thermophysical Properties of Materials Singapore Search in Google Scholar

[8] Akram A. H., Wallentén P. (2017). Hygrothermal assessment of internally added thermal insulation on external brick walls in Swedish multifamily buildings. Building and Environment., 123, 351–362. Akram A. H. Wallentén P. 2017 Hygrothermal assessment of internally added thermal insulation on external brick walls in Swedish multifamily buildings Building and Environment. 123 351 362 10.1016/j.buildenv.2017.05.019 Search in Google Scholar

[9] Walker R., Pavía S. (2015). Thermal performance of a selection of insulation materials suitable for historic buildings. Journal of Building and Environment, 94, 155–165. Walker R. Pavía S. 2015 Thermal performance of a selection of insulation materials suitable for historic buildings Journal of Building and Environment 94 155 165 10.1016/j.buildenv.2015.07.033 Search in Google Scholar

[10] Orlik-Kożdoń B., Steidl T. (2017). Impact of internal insulation on the hygrothermal performance of brick wall. Journal of Building Physics, 41, 120–134. Orlik-Kożdoń B. Steidl T. 2017 Impact of internal insulation on the hygrothermal performance of brick wall Journal of Building Physics, 41 120 134 10.1177/1744259116671322 Search in Google Scholar

[11] Szymanowska-Gwiżdż A., Steidl T. (2016). Impact of building walls of historic objects from half-timbered wall in their state of thermal protection. Civil and Environmental Engineering Reports, 20(1), 171–178. Szymanowska-Gwiżdż A. Steidl T. 2016 Impact of building walls of historic objects from half-timbered wall in their state of thermal protection Civil and Environmental Engineering Reports 20 1 171 178 10.1515/ceer-2016-0014 Search in Google Scholar

[12] Szymanowska-Gwiżdż A., Orlik-Kożdoń B., Krause P., Steidl T. (2016). Zmiany zawilgocenia przegród budynków historycznych przy zadanych warunkach klimatu zewnętrznego (Changes of the moisture in the partitions of historical buildings under given external climate conditions). Journal of Civil Engineering Environmental and Architecture, 63, 589–596. Szymanowska-Gwiżdż A. Orlik-Kożdoń B. Krause P. Steidl T. 2016 Zmiany zawilgocenia przegród budynków historycznych przy zadanych warunkach klimatu zewnętrznego (Changes of the moisture in the partitions of historical buildings under given external climate conditions) Journal of Civil Engineering Environmental and Architecture, 63 589 596 Search in Google Scholar

[13] Radoń J., Künzel H., Olesiak J. (2006). Problemy cieplno-wilgotnościowe przy renowacji ścian budynków z muru pruskiego (Thermal and moisture problems during the renovation of walls of half-timbered buildings). Acta Scientarum Polonorum, Architektura, 5, 45–53. Radoń J. Künzel H. Olesiak J. 2006 Problemy cieplno-wilgotnościowe przy renowacji ścian budynków z muru pruskiego (Thermal and moisture problems during the renovation of walls of half-timbered buildings) Acta Scientarum Polonorum, Architektura, 5 45 53 Search in Google Scholar

[14] Radoń J., Künzel H. (2004). Zalety stosowania paroizolacji wspierających proces wysychania (The advantages of using a vapor barrier to support the drying process). Warstwy dachy ściany, 4, 98–103. Radoń J. Künzel H. 2004 Zalety stosowania paroizolacji wspierających proces wysychania (The advantages of using a vapor barrier to support the drying process) Warstwy dachy ściany, 4 98 103 Search in Google Scholar

[15] DIN 4108-3 Klimabedingter Feuchteschutz; Anforderungen, Berechnungsverfahren und Hinweise für Planung und Ausführung Enthält Randbedingungen und Rechenvorschriften für das Glaser-Verfahren (Climate-related moisture protection; Requirements, calculation methods and notes for planning and execution. Contains boundary conditions and calculation rules for the Glaser method). DIN 4108-3 Klimabedingter Feuchteschutz; Anforderungen, Berechnungsverfahren und Hinweise für Planung und Ausführung Enthält Randbedingungen und Rechenvorschriften für das Glaser-Verfahren (Climate-related moisture protection; Requirements, calculation methods and notes for planning and execution. Contains boundary conditions and calculation rules for the Glaser method) Search in Google Scholar

[16] Wójcik R. (2017). Docieplanie budynków od wewnątrz (Thermal insulation from the inside). Grupa MEDIUM. Wójcik R. 2017 Docieplanie budynków od wewnątrz (Thermal insulation from the inside) Grupa MEDIUM Search in Google Scholar

[17] Künzel H. (2015):. Criteria defining rain protection external rendering systems. Energy Procedia, 78, 2524–2529. Künzel H. 2015 Criteria defining rain protection external rendering systems Energy Procedia, 78 2524 2529 10.1016/j.egypro.2015.11.260 Search in Google Scholar

[18] Kozakiewicz P., Matejak M. (2013). Klimat a drewno zabytkowe. Dawna i współczesna wiedza o drewnie (Climate and antique wood. Old and contemporary knowledge of wood). Warszawa, Wydawnictwo SGGW. Kozakiewicz P. Matejak M. 2013 Klimat a drewno zabytkowe. Dawna i współczesna wiedza o drewnie (Climate and antique wood. Old and contemporary knowledge of wood) Warszawa Wydawnictwo SGGW Search in Google Scholar

[19] Künzel H. (2011). Schäden an Fassadenputzen. Stuttgart, Fraunhofer IRB Verlag. Künzel H. 2011 Schäden an Fassadenputzen Stuttgart Fraunhofer IRB Verlag Search in Google Scholar

[20] Innendämmung nach WTA I Planungsleitfaden, Referat 6 Bauphysik und Bauchemie, Wissenschaftlich-Technische Arbeitsgemeinschaft für Bauwerkserhaltung und Denkmalpflege e.V. (Interior insulation according to WTA I Planning Guidelines, Unit 6 Building Physics and Construction Chemicals, Scientific and Technical Association for Building Conservation and Historic Preservation), Fraunhofer IRB Verlag, Stuttgart, 2009. Innendämmung nach WTA I Planungsleitfaden, Referat 6 Bauphysik und Bauchemie, Wissenschaftlich-Technische Arbeitsgemeinschaft für Bauwerkserhaltung und Denkmalpflege e.V. (Interior insulation according to WTA I Planning Guidelines, Unit 6 Building Physics and Construction Chemicals, Scientific and Technical Association for Building Conservation and Historic Preservation) Fraunhofer IRB Verlag Stuttgart 2009 Search in Google Scholar

[21] Karsten R. (1992). Bauchemie: fur stadium und praxis (Construction chemistry: for stadium and practice). Karsten R. 1992 Bauchemie: fur stadium und praxis (Construction chemistry: for stadium and practice) Search in Google Scholar

[22] Orlik-Kożdon B., Steidl T. (2018). Projektowanie izolacji cieplnej od wewnątrz z uwagi na wodochłonność elewacji (Designing thermal insulation from the inside due to the water absorption of the facade), Materiały budowlane 1, 44–48. Orlik-Kożdon B. Steidl T. 2018 Projektowanie izolacji cieplnej od wewnątrz z uwagi na wodochłonność elewacji (Designing thermal insulation from the inside due to the water absorption of the facade) Materiały budowlane 1 44 48 10.15199/33.2018.01.11 Search in Google Scholar

[23] Künzel, H.M. (1995). Simultaneous Heat and Moisture Transport in Building Components. One-and two-dimensional calculation using simple parameters. IRB Verlag. Künzel H.M. 1995 Simultaneous Heat and Moisture Transport in Building Components One-and two-dimensional calculation using simple parameters IRB Verlag Search in Google Scholar

[24] ISO 10211: 2017. Thermal bridges in building construction — Heat flows and surface temperatures — Detailed calculations. ISO 10211 2017 Thermal bridges in building construction — Heat flows and surface temperatures — Detailed calculations Search in Google Scholar

[25] ISO 13788:2012 Hygrothermal performance of building components and building elements – Internal surface temperature to avoid critical surface humidity and interstitial condensation – Calculation methods. ISO 13788 2012 Hygrothermal performance of building components and building elements – Internal surface temperature to avoid critical surface humidity and interstitial condensation – Calculation methods Search in Google Scholar