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The influence of microclimate on architectural projects: a bioclimatic analysis of the single-family detached house in Spain’s Mediterranean climate

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Abstract

As a departure from the standard bioclimatic models for architectural design which are based on regional climatic conditions, this study argues for the need to adapt architecture to the local microclimate in order to achieve maximum energy efficiency with regard to indoor thermal conditioning for the benefit of the occupants. Taking a commonly accepted, conventional bioclimatic housing model as a starting point, this study analyses the effect of passive systems of energy usage (based on orientation, shape and materials) in the transfer of heat across all facades between the microclimatic conditions outside the house and the interior of the house, thereby affecting internal comfort conditions. An optimised bioclimatic model which achieves a greater reduction in energy consumption has been established through the manipulation of these elements. The study, which uses the typology of the single-family house, was carried out in the municipality of Estepona, taken as a model city with respect to the process of urban consolidation within the Mediterranean enclave in the south of Spain. The analysis demonstrates that the optimised housing model significantly improves the daily thermal performance of the house as well as heating and cooling loads. Therefore, the adaptation of architecture to microclimatic conditions may be used as a basic strategy in the design and construction of more efficient housing.

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References

  • Albatici, R., & Passerini, F. (2011). Bioclimatic design of buildings considering heating requirements in Italian climatic conditions. A simplified approach. Building and Environment, 46, 1624–1631.

    Article  Google Scholar 

  • Brown, R. D., & Gillespe, R. J. (1995). Microclimatic landscape design. Creating thermal comfort and energy efficiency. New York: John Wiley & Sons.

    Google Scholar 

  • Cardinale, N., Francese, D., & Ruggiero, F. (2001). Bio-climatic technologies in Mediterranean countries. Towards Sustainable Building, 61, 59–76.

    Article  Google Scholar 

  • Council of Estepona (delegation of urbanism). (2010). General urban planning plan for Estepona. Sevilla: BOJA. http://ayuntamiento.estepona.es/ayuntamiento/documentos/pgou. (in Spanish).

    Google Scholar 

  • CSCAE (2008a). Strategies. In: An ecological vitruvius. Principles and practice of sustainable architectural design (pp. 72–75). Barcelona: GG. (in Spanish).

  • CSCAE (2008b). Themes. In: An ecological vitruvius. Principles and practice of sustainable architectural design (pp. 38–48). Barcelona: GG. (in Spanish).

  • Edwards, B. (2004). Sustainability guide. Barcelona: GG. in Spanish.

    Google Scholar 

  • Fariña, J. (1998). The city and the natural environment. Madrid: Akal (in Spanish).

    Google Scholar 

  • Fernández-Membrive, V., Lastra-Bravo, X., & Tolón-Becerra, A. (2015). Cost-benefit analysis of changes in energy in building technology in Southeast Spain. Building and Environment, 103, 29–37.

    Article  Google Scholar 

  • Gaitani, N., Mihalakakou, G., & Santamouris, M. (2007). On the use of bioclimatic architecture principles in order to improve thermal comfort conditions in outdoor spaces. Building and Environment, 42, 317–324.

    Article  Google Scholar 

  • Granderson, J., Piette, M., & Ghatikar, G. (2010). Building energy information systems: user case studies. Energy Efficiency, 4, 17–30.

    Article  Google Scholar 

  • Haase, M., & Amato, A. (2009). An investigation of the potential for natural ventilation and building orientation to achieve thermal comfort in warm and humid climates. Solar Energy, 83, 389–399.

    Article  Google Scholar 

  • Jorge, G., Puigdomenech, J., & Cusidó, J. A. (1993). A practical tool for sizing optimal shading devices. Building and Environment, 28, 69–72.

    Article  Google Scholar 

  • Kontoleon, K., & Bikas, D. (2007). The effect of south wall’s outdoor absortion coefficient on time lag, decrement factor and temperature variations. Energy and Buildings, 39, 1011–1018.

    Article  Google Scholar 

  • Li, D., & Lam, T. (2007). Determining the optimum tilt angle and orientation for solar energy collection based on measured solar radiance data. International Journal of Photoenergy, 2007, 1–9.

    Google Scholar 

  • Mingfang, T. (2002). Solar control for buildings. Building and Environment, 37, 659–664.

    Article  Google Scholar 

  • Ministry of Agriculture, Fisheries and Environment, Andalusia, Spain. (2004). Spatial plan of the western Costa del Sol of Andalusia. Sevilla: BOJA. http://www.juntadeandalucia.es/medioambiente/site/portalweb/menuitem.7e1cf46ddf59bb227a9ebe205510e1ca/?vgnextoid=ad8c2d926c828310VgnVCM1000001325e50aRCRD&vgnextchannel=91de8a3c73828310VgnVCM2000000624e50aRCRD. (in Spanish).

    Google Scholar 

  • Ministry of Agriculture, Fisheries and Environment, Andalusia, Spain (2002). Historical data. Alert network and phytosanitary information. Resource document. https://ws128.juntadeandalucia.es/agriculturaypesca/fit/clima/info.estacion.do?id=27. (in Spanish).

  • Ministry of Development, Spain. (2011). Estimation of the housing fleet, 2001–2011. Architecture, Housing and Land Department. Madrid: BOE. http://www.fomento.gob.es. (in Spanish).

    Google Scholar 

  • Ministry of Economy, Innovation, Science and Employment, Andalusia, Spain (Institute of Statistics and Cartography, Andalusia, Spain). (2011). Population and housing census. Sevilla: BOJA. http://www.ine.es/jaxi/menu.do?type=pcaxis&path=%2Ft20%2Fe260%2Fa2011%2F&file=pcaxis&N=&L=0. (in Spanish).

    Google Scholar 

  • Ministry of Housing, Spain. (2006). Technical building code. Basic document DB-HE energy saving. Madrid: BOE. http://www.fomento.gob.es/NR/rdonlyres/B83B66E3-0BA0-4270-BEF5-84A07A4C77F8/95714/14.pdf. (in Spanish).

    Google Scholar 

  • Ministry of Housing, Spain. (2006b). Appendix E. Calculation of the characteristic parameters of demand. In: Technical building code. Basic document DB-HE energy saving (pp. 43–46). Madrid: BOE. (in Spanish).

  • Ministry of Housing, Spain. (2006c). Appendix H. Sheets justifying the simplified option. In: Technical building code. Basic document DB-HE energy saving (pp. 59–61). Madrid: BOE. (in Spanish).

  • Ministry of Industry, Tourism and Trade, Spain. (2000). Energy efficient urban planning guide. Madrid: Institute for Diversification and Energy Saving. http://www.idae.es/uploads/documentos/documentos_10528_Guia_Planeamiento_urbanistico_2ed_07_2bb4de9e.pdf. (in Spanish).

    Google Scholar 

  • Muselli, M. (2010). Passive cooling for air-conditioning energy savings with new radiative low-cost coatings. Energy and Buildings, 42, 945–954.

    Article  Google Scholar 

  • Neila, J. (2004a). Climate and the bioclimatics invariants in the popular architecture. In: Architecture and technology (Ed.), Bioclimatic architecture in a sustainable environment (pp. 17–21). Madrid: Munilla-Lería. (in Spanish).

  • Neila, J. (2004b). Walls. In: Architecture and technology (Ed.), Bioclimatic architecture in a sustainable environment (pp. 300–303). Madrid: Munilla-Lería. (in Spanish).

  • Neila, J. (2004c). Glazed openings. In: Architecture and technology (Ed.), Bioclimatic architecture in a sustainable environment (pp. 287–294). Madrid: Munilla-Lería. (in Spanish).

  • Neila, J. (2004d). Calculation of radiation by analytical methods (Ed.), Bioclimatic architecture in a sustainable environment (pp. 138–159). Madrid: Munilla-Lería. (in Spanish).

  • Neila, J., & Bedoya, C. (1994a). Architectural and construction techniques of environmental conditioning. Madrid: Munilla-Lería. in Spanish.

    Google Scholar 

  • Neila, J., & Bedoya, C. (1994b). Thermal bridges in building (Ed.), Architectural and construction techniques of environmental conditioning (pp. 169–184). Madrid: Munilla-Lería, 1994. (in Spanish).

  • Papparelli, A., Kurbán, A., & Cúnsulo, M. (1998). Time savings of energy consumption using bioclimatic architecture. Architectural Science Review, 41, 165–171.

    Article  Google Scholar 

  • Pino, A., Bustamante, W., Escobar, R., & Encinas, F. (2012). Thermal and lighting behaviour of office buildings in Santiago of Chile. Energy and Buildings, 47, 441–449.

    Article  Google Scholar 

  • Ralegaonkar, R. V., & Gupta, R. (2010). Review of intelligent building construction: a passive solar architecture approach. Renewable and Sustainable Energy Reviews, 14, 2238–2242.

    Article  Google Scholar 

  • Santamouris, M., & Allard, F. (1998). Natural ventilation in buildings: a design handbook. London: James & James.

    Google Scholar 

  • Santamouris, M., Synnefa, A., & Karlessi, T. (2011). Using advanced cool materials in the urban built environment to mitigate heat islands and improve thermal comfort conditions. Solar Energy, 85, 3085–3102.

    Article  Google Scholar 

  • Schlueter, A., & Thesseling, F. (2009). Building information model based energy/exergy performance assessment in early design stages. Automation in Construction, 18, 153–163.

    Article  Google Scholar 

  • Schulze, T., & Eicker, U. (2013). Controlled natural ventilation for energy efficient buildings. Energy and Buildings, 56, 221–232.

    Article  Google Scholar 

  • Torres, E., & Navarro, E. (2007). Reducing urban congestion factor as quality tourism and life in mature destinations. Tourism Studies, 172–173, 193–199 (in Spanish).

    Google Scholar 

  • European Conference on Sustainable Cities & Towns (1994). Charter of European Cities & Towns Sustainability; Part I: Consensus Declaration: European Cities & Towns towards Sustainability; Part II: The European Sustainable Cities & Towns Campaign; Part III: Engaging in Local Agenda 21 Processes: Local Action Plans Towards Sustainability. Aalborg (Denmark).

  • Tzikopoulos, A. F., Karatza, M. C., & Paravantis, J. A. (2005). Modeling energy efficiency of bioclimatic buildings. Energy and Buildings, 37, 529–544.

    Article  Google Scholar 

  • Van Moeseke, G., Bruyere, I., & De Herde, A. (2007). Impact of control rules on the efficiency of shading devices and free cooling for office buildings. Building and Environment, 42, 784–793.

    Article  Google Scholar 

  • Wilson, K. (2000). Drought, debate, and uncertainty: measuring reporters’ knowledge and ignorance about climate change. Public Understanding of Science, 9, 1–13.

    Article  Google Scholar 

  • Yáñez, G. (2008a). Calculation of the direct and diffuse irradiation from the horizontal irradiation (Ed.), Solar architecture and natural light (pp. 248–249). Madrid: Munilla-Lería. (in Spanish).

  • Yáñez, G. (2008b). Elementary heat transfer concepts (Ed.), Solar architecture and natural light (pp. 95–117). Madrid: Munilla-Lería. (in Spanish).

  • Yilmaz, Z. (2007). Evaluation of energy efficient design strategies for different climatic zones: comparison of thermal performance of buildings in temperature-humid and hot-dry climate. Energy and Buildings, 39, 306–316.

    Article  MathSciNet  Google Scholar 

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Correspondence to José Luis Pérez Galaso.

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Pérez Galaso, J.L., Ladrón de Guevara López, I. & Boned Purkiss, J. The influence of microclimate on architectural projects: a bioclimatic analysis of the single-family detached house in Spain’s Mediterranean climate. Energy Efficiency 9, 621–645 (2016). https://doi.org/10.1007/s12053-015-9383-x

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  • DOI: https://doi.org/10.1007/s12053-015-9383-x

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