Assessment of Passive Retrofitting Scenarios in Heritage Residential Buildings in Hot, Dry Climates

Ibrahim, Hanan; Khan, Ahmed; Mahar, Waqas Ahmed; Attia, Shady; Yehya, Serag

doi:10.3390/en14113359

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Assessment of Passive Retrofitting Scenarios in Heritage Residential Buildings in Hot, Dry Climates

Ibrahim, Hanan; Khan, Ahmed; Mahar, Waqas Ahmed et al.

2021 • In Energies, 14 (11), p. 3359

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https://hdl.handle.net/2268/260773

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10.3390/en14113359

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Keywords :

adaptive thermal comfort; reference building; mixed-mode building; building simulation; field measurements; Egypt; downtown Cairo; Khedivial Cairo

Abstract :

[en] Retrofitting heritage buildings for energy efficiency is not always easy where cultural values are highly concerned, which requires an integrated approach. This paper aims to assess the potential of applying passive retrofitting scenarios to enhance indoor thermal comfort of heritage buildings in North Africa, as a hot climate, a little attention has been paid to retrofit built heritage in that climate. A mixed-mode ventilation residential building in Cairo, Egypt, was selected as a case study. The study combines field measurements and observations with energy simulations. A simulation model was created and calibrated on the basis of monitored data in the reference building, and the thermal comfort range was evaluated. Sets of passive retrofitting scenarios were proposed. The results (based on the ASHRAE-55-2020 adaptive comfort model at 90% acceptability limits) showed that the annual thermal comfort in the reference building is very low, i.e., 31.4%. The application of hybrid passive retrofitting scenarios significantly impacts indoor thermal comfort in the reference building, where annual comfort hours of up to 66% can be achieved. The originality of this work lies in identifying the most effective energy measures to improve indoor thermal comfort that are optimal from a conservation point of view. The findings contribute to set a comprehensive retrofitting tool that avoids potential risks for the conservation of residential heritage buildings in hot climates.

Disciplines :

Architecture

Author, co-author :

Ibrahim, Hanan

Khan, Ahmed

Mahar, Waqas Ahmed

Attia, Shady ; Université de Liège - ULiège > Département ArGEnCo > Techniques de construction des bâtiments

Yehya, Serag

Language :

English

Title :

Assessment of Passive Retrofitting Scenarios in Heritage Residential Buildings in Hot, Dry Climates

Publication date :

07 June 2021

Journal title :

Energies

ISSN :

1996-1073

Publisher :

Multidisciplinary Digital Publishing Institute (MDPI), Switzerland

Volume :

Issue :

Pages :

3359

Peer reviewed :

Peer Reviewed verified by ORBi

Additional URL :

https://www.mdpi.com/1996-1073/14/11/3359

Available on ORBi :

since 07 June 2021

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Bibliography

International Energy Agency (IEA). World Energy Balances: Overview. International Energy Agency IEA. 2018. Available online: https://www.iea.org/reports/world‐energy‐balances‐overview#africa (accessed on 30 November 2020).
Lee, J.; Shepley, M.M.; Choi, J. Exploring the effects of a building retrofit to improve energy performance and sustainability: A case study of Korean public buildings. Build. Eng. 2019, 25, 100822.
Ahmed, S.A. Financial aspect and practicability of converting existing buildings to nZEB case study in Cairo, Egypt. In IOP Conference Series: Earth and Environmental Science; IOP Publishing: Bristol, UK, 2019.
Fahmy, M.; Mahmoud, S.; Elwy, I.; Mahmoud, H. A review and insights for eleven years of urban microclimate research towards a new Egyptian era of low carbon, comfortable and energy‐efficient housing typologies. Atmosphere 2020, 11, 236.
Hanna, G.B. Sustainable energy potential in the Egyptian residential sector. J. Environ. Sci. Eng. 2013, 2, 374.
Theodoridou, I.; Papadopoulos, A.M.; Hegger, M. A typological classification of the Greek residential building stock. Energy Build. 2011, 43, 2779–2787.
Lidelöw, S.; Örn, T.; Luciani, A.; Rizzo, A. Energy‐efficiency measures for heritage buildings: A literature review. Sustain. Cities Soc. 2019, 45, 231–242.
Ibrahim, H.S.S.; Khan, A.Z.; Attia, S.; Serag, Y. Classification of heritage residential building stock and defining sustainable retrofitting scenarios in Khedivial Cairo. Sustainability 2021, 13, 880.
Fouseki, K.; Newton, D.; Camacho, K.S.M.; Nandi, S.; Koukou, T. Energy efficiency, thermal comfort, and heritage conservation in residential historic buildings as dynamic and systemic socio‐cultural practices. Atmosphere 2020, 11, 604.
Abuelnuor, A.A.A.; Adil, A.M.O.; Khalid, M.S.; Ibrahim, H.I.E. Improving indoor thermal comfort by using phase change materials: A review. Int. J. Energy Res. 2018, 42, 2084–2103.
Fahmy, M.; Mohamed, M.; Sherif, M.; Marwa, A.; Sherif, E.; Attia, S. Influence of urban canopy green coverage and future climate change scenarios on energy consumption of new sub‐urban residential developmentsusing using coupled simulation techniques: A case study in Alexandria, Egypt. In Proceedings of the 6th International Conference on Energy and Environment Research, ICEER 2019, Aveiro, Portugal, 22–25 July 2020.
Bellia, L.; Alfano, F.R.; Giordano, J.; Ianniello, E.; Riccio, G. Energy requalification of a historical building: A case study. Energy Build. 2015, 95, 184–189.
Hassan, O.A.B. An alternative method for evaluating the air tightness of building components. Build. Environ. 2013, 67, 82–86.
Pereira, P.F.; Almeida, R.; Ramos, N.M.M.; Sousa, R. Testing for building components contribution to airtightness assessment. In Proceedings of the 35th AIVC Conference Ventilation and Airtightness in Transforming the Building Stock to High Performance, Poznan, Poland, 24–25 September 2014.
Bastian, Z.; Alexandra, T. Energy Efficiency Solutions for Historic Buildings; De Gruyter: Berlin, Germany, 2015.
Eriksson, P.; Hermann, C.; Hrabovszky‐Horváth, S.; Rodwell, D. EFFESUS methodology for assessing the impacts of energy-related retrofit measures on heritage significance. Hist. Environ. Policy Pract. 2014, 5, 132–149.
Ganobjak, M.; Samuel, B.; Jannis, W. Aerogel materials for heritage buildings: Materials, properties and case studies. J. Cult. Herit. 2020, 42, 81–98.
Wakili, K.G.; Binder, B.; Zimmermann, M.; Tanner, C. Efficiency verification of a combination of high performance and conventional insulation layers in retrofitting a 130‐year old building. Energy Build. 2014, 82, 237–242.
Lucchi, E.; Becherini, F.; di Tuccio, M.C.; Troi, A.; Frick, J.; Roberti, F.; Hermann, C.; Fairnington, I.; Mezzasalma, G.; Pockelé, L.; et al. Thermal performance evaluation and comfort assessment of advanced aerogel as blown‐in insulation for historic buildings. Build. Environ. 2017, 122, 258–268.
Attia, S.; Carlucci, S. Impact of different thermal comfort models on zero energy residential buildings in hot climate. Energy Build. 2015, 102, 117–128.
Köppen, W.P.; Geiger, R. Handbuch der Klimatologie; Gebrüder Borntraeger: Berlin, Germany, 1930.
Attia, S.; Evrard, A.; Gratia, E. Development of benchmark models for the Egyptian residential buildings sector. Appl. Energy 2012, 94, 270–284.
Weather Data|EnergyPlus. Available online: https://energyplus.net/weather (accessed on 26 April 2021).
BizEE Degree Days, Weather Data for Energy Saving. Available online: https://www.degreedays.net (accessed on 26 April 2021).
Setyantho, G.R.; Park, H.; Chang, S. Multi‐criteria performance assessment for semi‐transparent photovoltaic windows in different climate contexts. Sustainability 2021, 13, 2198.
Central Agency for Public Mobilization and Statistics (CAPMAS). Housing and Establishment Census 2017; Central Agency for Public Mobilization and Statistics (CAPMAS): Cairo, Egypt, 2019.
National Organization for Urban Harmony in Egypt (NOUH). Inventory Lists of Distinguished Buildings. 2008. Available online: http://urbanharmony.org/ar_cities.asp (accessed on 30 November 2020).
Egyptian Electricity Holding Company (EEHC). Annual Report 2018/2019; Ministery of Electricity & Renewable Energy: Cairo, Egypt, 2020.
Albadry, S.; Khaled, T.; Hani, S. Achieving net zero‐energy buildings through retrofitting existing residential buildings using PV. Energy Procedia 2017, 115, 195–204.
Egyptian Law No. 144 of 2006—Regulation of the Demolition of Unthreatened Buildings and Constructions and the Conservation of the Architectural Heritage; Egyptian Law: Cairo, Egypt, 2006. (In Arabic)
Egyptian Law No. 119 of 2008. Building Law; Egyptian Law: Cairo, Egypt, 2008. (In Arabic)
Housing and Building National Research Center (HBRC). The Egyptian Code for Energy Efficiency Improvement in Buildings Part 1(ECP 306–2005); Ministry of Housing, Utilities & Urban Communities: Cairo, Egypt, 2006. (In Arabic)
Kottek, M.; Jürgen, G.; Christoph, B.; Bruno, R.; Franz, R. World map of the Köppen‐Geiger climate classification updated. Meteorol. Z. 2006, 15, 259–263.
Domínguez, A.; Samuel, Á.L.L.; Pedro, B.; Juan, J.S. Energy intervention in the residential sector in the south of Spain: Current challenges. Inf. Constr. 2013, 65, 457–464.
Blázquez, T.; Simone, F.; Rafael, S.; José, S.J. Adaptive approach‐based assessment of a heritage residential complex in southern Spain for improving comfort and energy efficiency through passive strategies: A study based on a monitored flat. Energy 2019, 181, 504–520.
Caro, R.; Juan, J.S. Evaluation of indoor environment and energy performance of dwellings in heritage buildings. The case of hot summers in historic cities in Mediterranean Europe. Sustain. Cities Soc. 2020, 52, 101798.
Suárez, R.; Jessica, F. Passive energy strategies in the retrofitting of the residential sector: A practical case study in dry hot climate. Build. Simul. 2015, 8, 593–602.
Martín‐Garín, A.; Millán‐García, J.A.; Hidalgo‐Betanzos, J.M.; Hernández‐Minguillón, R.J.; Baïri, A. Airtightness analysis of the built heritage—Field measurements of nineteenth century buildings through blower door tests. Energies 2020, 13, 6727.
Evola, G.;Luigi, M.; Vincenzo, C.; Giovanni, C. Different strategies for improving summer thermal comfort in heavyweight traditional buildings. In Proceedings of the 6th International Building Physics Conference, IBPC, Turin, Italy, 14–17 June 2015.
Silvero, F.; Sergio, M.; Fernanda, R.; Enrico, S.; Humberto, V. Energy retrofit solutions for heritage buildings located in hothumid climates. In Proceedings of the XIV International Conference on Building Pathology and Constructions Repair (CINPAR), Florence, Italy, 20–22 January 2018.
Rospi, G.; Cardinale, N.; Negro, E. Energy performance and economic feasibility study of historical building in the city of Matera, Southern Italy. Energies 2017, 10, 2009.
Piselli, C.; Romanelli, J.; di Grazia, M.; Gavagni, A.; Moretti, E.; Nicolini, A.; Cotana, F.; Strangis, F.; Witte, H.J.; Pisello, A.L. An integrated HBIM simulation approach for energy retrofit of historical buildings implemented in a case study of a medieval fortress in Italy. Energies 2020, 13, 2601.
Sfakianaki, A.; Pavlou, K.; Santamouris, M.; Livada, I.; Assimakopoulos, M.N.; Mantas, P.; Christakopoulos, A. Air tightness measurements of residential houses in Athens, Greece. Build. Environ. 2008, 43, 398–405.
Michel, S.; Elsayed, H. Examples of low energy design at urban scale in Egypt. In Proceedings of the 23rd Conference on Passive and Low Energy Architecture (PLEA), Geneva, Switzerland, 6–8 September 2006.
Attia, S.; de Herde, A. Impact and potential of community scale low‐energy retrofit: Case study in Cairo. In Proceedings of the 3rd CIB International Conference on Smart and Sustainable Built Environment, Delft, The Netherlands, 15–19 June 2019.
Sheta, W. Delivering quality indoor environment in houses—The potentials and impact of building materials for facade design in Cairo. In Proceedings of the 27th International Conference on Passive and Low Energy Architecture, Louvain‐la‐Neuve, Belgium, 13–15 July 2011.
Sedki, Y.A. Improving Indoor Thermal Comfort in Residential Buildings in Hot‐Arid Climates Through the Combination of Natural Ventilation and Insulation Retrofitting Techniques‐Case Study: Existing Social Housing Stocks in Greater Cairo; University of Ferrara: Ferrara, Italy, 2014.
El Sorady, D.A.; Rizk, S.M. LEED v4.1 operations & maintenance for existing buildings and compliance assessment: Bayt Al‐ Suhaymi, Historic Cairo. Alex. Eng. J. 2020, 59, 519–531.
Saleh, H.S.; Saied, S.Z. Green architecture as a concept of Historic Cairo. Procedia Environ. Sci. 2017, 37, 342–355.
Ezzeldin, S.; Rees, S.J. The potential for office buildings with mixed‐mode ventilation and low energy cooling systems in arid climates. Energy Build. 2013, 65, 368–381.
Ezzeldin, S.; Simon, R.; Malcolm, C. Performance of mixed‐mode cooling strategies for office buildings in arid climates. In Proceedings of the 11th International IBPSA Conference, Glasgow, Scotland, 27–30 July 2009.
Mahar, W.A.; Verbeeck, M.K.S.G.; Attia, S. An investigation of thermal comfort of houses in dry and semi‐arid climates of quetta, pakistan. Sustainability 2019, 11, 5203.
Semahi, S.; Noureddine, Z.; Manoj, K.S.; Attia, S. Comparative bioclimatic approach for comfort and passive heating and cooling strategies in Algeria. Build. Environ. 2019, 161, 106271.
Rashed, M.; Mostafa, M. Architectural Identity in Contemporary Cairo; Politecnico Di Milano: Milan, Italy, 2015.
National Organization for Urban Harmony in Egypt (NOUH). The Foundations and Guidelines of Urban Harmony for Heritage Buildings and Areas; National Organization for Urban Harmony in Egypt (NOUH): Cairo, Egypt, 2010. (Translated from Arabic)
Abdelmegeed, M.M.M. Documentation of construction systems, type of damages and modification processes in façades of unregistered heritage‐buildings in Khedival Cairo, Egypt. HBRC J. 2020, 16, 77–112.
Statistical Yearbook, Geography & Climate; General Meteorological Authority: Cairo, Egypt, 2016.
Mostafa, A.N.; Wheida, A.; el Nazer, M.; Adel, M.; el Leithy, L.; Siour, G.; Coman, A.; Borbon, A.; Magdy, A.W.; Omar, M.; et al. Past (1950–2017) and future (–2100) temperature and precipitation trends in Egypt. Weather Clim. Extrem. 2019, 26, 100225.
Housing and Building National Research Center (HBRC). Specifications of Thermal Insulation Work Items; Ministry of Housing, Utilities & Urban Communities: Cairo, Egypt, 2007.
Attia, S.; Hamdy, M.; Ezzeldin, S. Twenty‐year tracking of lighting savings and power density in the residential sector. Energy Build. 2017, 154, 113–126.
American Society of Heating, Refrigerating, and Air‐Conditioning Engineers (ASHRAE). In Guideline 14‐2002: Measurement of Energy and Demand Savings; American Society of Heating, Refrigerating, and Air‐Conditioning Engineers (ASHRAE): Atlanta, GA, USA, 2002.
Ruiz, G.R.; Carlos, F.B. Validation of calibrated energy models: Common errors. Energies 2017, 10, 1587.
De Dear, R.J.; Akimoto, T.; Arens, E.A.; Brager, G.; Candido, C.; Cheong, K.W.D.; Li, B.; Nishihara, N.; Sekhar, S.C.; Tanabe, S.; et al. Progress in thermal comfort research over the last twenty years. Indoor Air 2013, 23, 442–461.
Attia, S.; Jan, L.H. Investigating the impact of different thermal comfort models for zero energy buildings in hot climates. In Proceedings of the 1st International Conference on Energy and Indoor Environment for Hot Climates, Doha, Qatar, 24–26 February 2014.
Luo, M.; Bin, C.; Jerome, D.; Borong, L.; Yingxin, Z. Evaluating thermal comfort in mixed‐mode buildings: A field study in a subtropical climate. Build. Environ. 2015, 88, 46–54.
Brager, G. Mixed‐mode cooling. ASHRAE J. 2006, 48, 30–37.
American Society of Heating, Refrigerating and Air conditioning Engineers (ASHRAE). Thermal Environmental Conditions for Human Occupancy (ANSI Approved); Standard 55‐2020; American Society of Heating, Refrigerating and Air conditioning Engineers (ASHRAE): Atlanta, GA, USA, 2020.
Ibrahim, H.S.S.; Khan, A.Z.; Attiya, M.A.M.; Serag, Y. Evaluation of a retrofitted heritage building in downtown Cairo as a best practice example. In Proceedings of the SBE21 Sustainable Built Heritage, Renovating Historic Buildings for a Low‐Carbon Built, Bolzano, Italy, 14–16 April 2021.
Abdin, A.R.; Ashraf, R.E.; Mahmoud, A.M. The role of nanotechnology in improving the efficiency of energy use with a special reference to glass treated with nanotechnology in office buildings. Ain Shams Eng. J. 2018, 9, 2671–2682.
Yew, M.C.; Ming, K.Y. Active and passive systems for cool roofs. In Eco‐Efficient Materials for Reducing Cooling Needs in Buildings and Construction; Elsevier: Berlin, Germany, 2021; pp. 275–288.
De Masi, R.F.; Ruggiero, S.; Vanoli, G.P. Acrylic white paint of industrial sector for cool roofing application: Experimental investigation of summer behavior and aging problem under Mediterranean climate. Solar Energy 2018, 169, 468–487.
Dornelles, K.; Roriz, M.; Roriz, V.; Caram, R. Thermal performance of white solar‐reflective paints for cool roofs and the influence on the thermal comfort and building energy use in hot climates. In Solar World Congress, ISES; International Solar Energy Society: Freiburg im Breisgau, Germany, 2011.
Berdahl, P.; Sarah, E.B. Preliminary survey of the solar reflectance of cool roofing materials. Energy Build. 1997, 25, 149–158.
FIXIT GRUPPE. Aerogel Insulating Plaster System Application Guidelines. The FIXIT GROUP, Building Materials with Systems, Freising, Germany, May 2019. Available online: https://mamview.fixit‐holding.com (accessed on 25 April 2021).
Alaidroos, A.; Almaimani, A.; Baik, A.; Al‐Amodi, M.; Rahaman, K.R. Are historical buildings more adaptive to minimize the risks of airborne transmission of viruses and public health? A study of the Hazzazi House in Jeddah (Saudi Arabia). Int. J. Environ. Res. Public Health 2021, 18, 3601.