Hygrothermal Design of Connections in Wall Systems Insulated from the Inside in Historic Building

[1] Ali K.A., Ahmad M.I., Yusup Y. (2020). Issues, impacts, and mitigations of carbon dioxide emissions in the building sector, Sustainability (Switzerland), 12(18). Ali K. A. Ahmad M.I. Yusup Y. ( 2020 ). Issues, impacts, and mitigations of carbon dioxide emissions in the building sector , Sustainability (Switzerland) , 12 ( 18 ). Search in Google Scholar

[2] Atmaca N., Atmaca A., Ali İhsan Özçetin (2021). The impacts of restoration and reconstruction of a heritage building on life cycle energy consumption and related carbon dioxide emissions, Energy and Buildings, 253. Atmaca N. Atmaca A. Özçetin Ali İhsan ( 2021 ). The impacts of restoration and reconstruction of a heritage building on life cycle energy consumption and related carbon dioxide emissions , Energy and Buildings , 253 . Search in Google Scholar

[3] Sizirici B., Fseha Y., Cho C.S., Yildiz I., Byon Y.J. (2021). A review of carbon footprint reduction in construction industry, from design to operation, Materials, 14(20). Sizirici B. Fseha Y. Cho C.S. Yildiz I. Byon Y.J. ( 2021 ). A review of carbon footprint reduction in construction industry, from design to operation , Materials , 14 ( 20 ). Search in Google Scholar

[4] Global Status Report, Towards a zero emission, efficient and resilient buildings and construction sector https://www.worldgbc.org/sites/default/files/2018%20GlobalABC%20Global%20Status%20Report.pdf Global Status Report, Towards a zero emission, efficient and resilient buildings and construction sector https://www.worldgbc.org/sites/default/files/2018%20GlobalABC%20Global%20Status%20Report.pdf Search in Google Scholar

[5] https://ec.europa.eu/info/news/focus-energy-efficiency-buildings-2020-lut-17_en (access 21.10.21). https://ec.europa.eu/info/news/focus-energy-efficiency-buildings-2020-lut-17_en (access 21.10.21 ). Search in Google Scholar

[6] Directive (EU) 2024/1275 of the European Parliament and of the Council of 24 April 2024 on the energy performance of buildings Directive (EU) 2024/1275 of the European Parliament and of the Council of 24 April 2024 on the energy performance of buildings Search in Google Scholar

[7] COMMISSION RECOMMENDATION (EU) 2021/1749 of 28 September 2021 on the Energy Efficiency First Principle: From Principles to Practice Guidance and Examples on its Implementation in Decision Making in the Energy Sector and in other sectors, https://eur-lex.europa.eu/legal-con-tent/PL/TXT/PDF/?uri=CELEX:32021H1749&from=PL COMMISSION RECOMMENDATION (EU) 2021/1749 of 28 September 2021 on the Energy Efficiency First Principle: From Principles to Practice Guidance and Examples on its Implementation in Decision Making in the Energy Sector and in other sectors , https://eur-lex.europa.eu/legal-con-tent/PL/TXT/PDF/?uri=CELEX:32021H1749&from=PL Search in Google Scholar

[8] ITB instruction 447/2009: Complex thermal insulation systems for external walls of buildings ETICS, Principles of design and construction, Warsaw 2009. ITB instruction 447/2009: Complex thermal insulation systems for external walls of buildings ETICS, Principles of design and construction , Warsaw 2009 . Search in Google Scholar

[9] Arbeiter K. (2014). Innendammung; Auswahl, Konstruktion, Ausfuhhrung. Arbeiter K. ( 2014 ). Innendammung; Auswahl, Konstruktion, Ausfuhhrung . Search in Google Scholar

[10] Johansson P., Geving S., Hagentoft C.E., Jelle B.P., Rognvik E., Kalagasidis A.S., Time B. (2014): Interior insulation retrofit of a historical brick wall using vacuum insulation panels: Hygrothermal numerical simulations and laboratory investigations, Building and Environment, 79, 31–45 Johansson P. Geving S. Hagentoft C.E. Jelle B.P. Rognvik E. Kalagasidis A.S. Time B. ( 2014 ): Interior insulation retrofit of a historical brick wall using vacuum insulation panels: Hygrothermal numerical simulations and laboratory investigations , Building and Environment , 79 , 31 – 45 Search in Google Scholar

[11] Muller R. (2016). Fachverband Innendammung; Praxihandbuch Innendammung: Planung-Konstruktion – Details Beispiele. Muller R. ( 2016 ). Fachverband Innendammung; Praxihandbuch Innendammung: Planung-Konstruktion – Details Beispiele . Search in Google Scholar

[12] Orlik-Kożdoń B., Radziszewska-Zielina E., Fedorczak-Cisak M., Steidl T., Białkiewicz A., Żychowska M., Muzychak A. (2020). Historic building thermal diagnostics algorithm presented for the example of a townhouse in Lviv, Energies, 13(20). Orlik-Kożdoń B. Radziszewska-Zielina E. Fedorczak-Cisak M. Steidl T. Białkiewicz A. Żychowska M. Muzychak A. ( 2020 ). Historic building thermal diagnostics algorithm presented for the example of a townhouse in Lviv , Energies , 13 ( 20 ). Search in Google Scholar

[13] Orlik-Kożdoń B., Szymanowska-Gwiżdż A. (2018). Impact of envelope structure on the solutions of thermal insulation from the inside, Architecture, Civil Engineering, Environment, 11(4), 123–134. Orlik-Kożdoń B. Szymanowska-Gwiżdż A. ( 2018 ). Impact of envelope structure on the solutions of thermal insulation from the inside , Architecture, Civil Engineering, Environment , 11 ( 4 ), 123 – 134 . Search in Google Scholar

[14] Orlik-Kożdoń B., Steidl T. (2017). Impact of internal insulation on the hygrothermal performance of brick wall, Journal of Building Physics, 41(2), 120–134. Orlik-Kożdoń B. Steidl T. ( 2017 ). Impact of internal insulation on the hygrothermal performance of brick wall , Journal of Building Physics , 41 ( 2 ), 120 – 134 . Search in Google Scholar

[15] Zhou X., Derome D., Carmeliet J. (March 2022). Analysis of moisture risk in internally insulated masonry walls, Building and Environment, 15. Zhou X. Derome D. Carmeliet J. ( March 2022 ). Analysis of moisture risk in internally insulated masonry walls , Building and Environment , 15 . Search in Google Scholar

[16] Vereecken E., Roels S. (2014). A comparison of the hygric performance of interior insulation systems: A hot box-cold box experiment, Energy and Buildings, 80, 37–44. Vereecken E. Roels S. ( 2014 ). A comparison of the hygric performance of interior insulation systems: A hot box-cold box experiment , Energy and Buildings , 80 , 37 – 44 . Search in Google Scholar

[17] Walker R., Pavía S. (2018). Thermal and moisture monitoring of an internally insulated historic brick wall, Building and Environment, 133, 178–186. Walker R. Pavía S. ( 2018 ). Thermal and moisture monitoring of an internally insulated historic brick wall , Building and Environment , 133 , 178 – 186 . Search in Google Scholar

[18] Worch A. (2009). Innendammung – Moglichkeiten und Grenzen, WTA-Schriftenreihe, 31. Worch A. ( 2009 ). Innendammung – Moglichkeiten und Grenzen, WTA-Schriftenreihe , 31 . Search in Google Scholar

[19] Worch A. (2012). Innendammung von einschaligem Ziegelmauerwerk, Bausubstanz, 3, 56–61. Worch A. ( 2012 ). Innendammung von einschaligem Ziegelmauerwerk , Bausubstanz , 3 , 56 – 61 . Search in Google Scholar

[20] Zhao J., Grunewald J., Ruisinger U., Feng S. (2017). Evaluation of capillary active mineral insulation systems for interior retrofit solution, Building and Environment, 115, 215–227. Zhao J. Grunewald J. Ruisinger U. Feng S. ( 2017 ). Evaluation of capillary active mineral insulation systems for interior retrofit solution , Building and Environment , 115 , 215 – 227 . Search in Google Scholar

[21] Hansen W., Kung J.H. (1988). Pore structure and frost durability of clay bricks, Materials and Structures/Matdriaux et Constructions, 21, 443–447. Hansen W. Kung J.H. ( 1988 ). Pore structure and frost durability of clay bricks , Materials and Structures/Matdriaux et Constructions , 21 , 443 – 447 . Search in Google Scholar

[22] Künzel H.M. (1998). Effect of interior and exterior insulation on the hygrothermal behaviour of exposed walls, Materials and Structures, 31, 99–103. Künzel H.M. ( 1998 ). Effect of interior and exterior insulation on the hygrothermal behaviour of exposed walls , Materials and Structures , 31 , 99 – 103 . Search in Google Scholar

[23] Straube J., Schumacher C. (2007). Interior insulation retrofits of load-bearing masonry walls in cold climates, In Journal of Green Building, 2(2), 42–50. Straube J. Schumacher C. ( 2007 ). Interior insulation retrofits of load-bearing masonry walls in cold climates , In Journal of Green Building , 2 ( 2 ), 42 – 50 . Search in Google Scholar

[24] Vereecken E., Van Gelder L., Janssen H., Roels S. (2015). Interior insulation for wall retrofitting. A probabilistic analysis of energy savings and hygrother-mal risks, Energy and Buildings, 89, 231 244. Vereecken E. Van Gelder L. Janssen H. Roels S. ( 2015 ). Interior insulation for wall retrofitting. A probabilistic analysis of energy savings and hygrother-mal risks , Energy and Buildings , 89 , 231 – 244 . Search in Google Scholar

[25] Wójcik R., Bomberg M. On interior rehabilitation of buildings with historic facades, Journal of Building Physics, 40(2), 144–161. Wójcik R. Bomberg M. On interior rehabilitation of buildings with historic facades , Journal of Building Physics , 40 ( 2 ), 144 – 161 . Search in Google Scholar

[26] Guizzardi M., Carmeliet J., Derome D. (2015). Risk analysis of biodeterioration of wooden beams embedded in internally insulated masonry walls, Construction and Building Materials, 99, 159–168. Guizzardi M. Carmeliet J. Derome D. ( 2015 ). Risk analysis of biodeterioration of wooden beams embedded in internally insulated masonry walls , Construction and Building Materials , 99 , 159 – 168 . Search in Google Scholar

[27] Morelli M., Svendsen S. (2013). Investigation of interior post-insulated masonry walls with wooden beam ends, Journal of Building Physics, 36(3), 265–273. Morelli M. Svendsen S. ( 2013 ). Investigation of interior post-insulated masonry walls with wooden beam ends , Journal of Building Physics , 36 ( 3 ), 265 – 273 . Search in Google Scholar

[28] Viitanen H., Salonvaara M. (). Moisture conditions and biodeterioration risk of building materials and structure, https://www.researchgate.net/publication/228735301_Moisture_conditions_and_biodeterioration_risk_of_building_materials_and_structure (access 9.02.2020) Viitanen H. Salonvaara M. (). Moisture conditions and biodeterioration risk of building materials and structure , https://www.researchgate.net/publication/228735301_Moisture_conditions_and_biodeterioration_risk_of_building_materials_and_structure (access 9.02.2020 ). Search in Google Scholar

[29] Krause P., Nowoświat A., Pawłowski K. (2020). The impact of internal insulation on heat transport through the wall: case study, Applied Sciences-Basel, MDPI, 10(21). Krause P. Nowoświat A. Pawłowski K. ( 2020 ). The impact of internal insulation on heat transport through the wall: case study , Applied Sciences-Basel, MDPI , 10 ( 21 ).Standards and related documents: Search in Google Scholar

[30] Orlik-Kożdoń B. (2022). Forecasting moisture condition of walls insulated from the inside in historic brick buildings, Gliwice. Orlik-Kożdoń B. ( 2022 ). Forecasting moisture condition of walls insulated from the inside in historic brick buildings, Gliwice . Search in Google Scholar

[31] Scheffler A.G. (2015). Bauphysik der Innendammung, Frauhofer IRB. Scheffler A.G. ( 2015 ). Bauphysik der Innendammung, Frauhofer IRB . Search in Google Scholar

[32] Wyrwał J., Marynowicz A. (2002). Vapour condensation and moisture accumulation in porous building wall, Building and Environment, 37(3), 313–318. Wyrwał J. Marynowicz A. ( 2002 ). Vapour condensation and moisture accumulation in porous building wall , Building and Environment , 37 ( 3 ), 313 – 318 . Search in Google Scholar

[33] Regulation of the Minister of Infrastructure on the technical conditions to be met by buildings and their location. Regulation of April 12, 2002. (Journal of Laws of 2019, item 1065), Unified text – taking into account the introduced amendments (Journal of Laws of September 16, 2020, item 1608). Regulation of the Minister of Infrastructure on the technical conditions to be met by buildings and their location . Regulation of April 12, 2002. (Journal of Laws of 2019, item 1065), Unified text – taking into account the introduced amendments (Journal of Laws of September 16, 2020, item 1608) . Search in Google Scholar

[34] Orlik-Kożdoń B. (2019). Interior insulation of masonry walls-selected problems in the design, Energies, 12(20), 1–22. Orlik-Kożdoń B. ( 2019 ). Interior insulation of masonry walls-selected problems in the design , Energies , 12 ( 20 ), 1 – 22 . Search in Google Scholar

[35] Orlik-Kożdoń B. (2020). Microclimate conditions in rooms: Their impact on mold development in buildings, Energies, 13(17). Orlik-Kożdoń B. ( 2020 ). Microclimate conditions in rooms: Their impact on mold development in buildings , Energies , 13 ( 17 ). Search in Google Scholar

[36] ISO 10211: 2017 9: Thermal bridges in building construction – Heat flows and surface temperatures – Detailed calculations. ISO 10211: 2017 9: Thermal bridges in building construction – Heat flows and surface temperatures – Detailed calculations . Search in Google Scholar

[37] ISO 13788: 2013 Hygrothermal performance of building components and building elements – Internal surface temperature to avoid critical surface humidity and interstitial condensation – Calculation methods. ISO 13788: 2013 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