ESTRATEGIAS DE DISEÑO PASIVO PARA EDIFICACIONES EN ALTURA EN LA CIUDAD DE MADRID: ENFOQUE EN EL CONFORT TÉRMICO Y LUMÍNICO

Patricio Simbaña Escobar; Luis Miguel Bermejo Jauregui; Cristian Omar Bravo-Fichamba; Ariel Sebastián Ortega Vasco

doi:10.33324/daya.vi19.1063

Authors

Patricio Simbaña Escobar Universidad UTE https://orcid.org/0000-0002-9172-1457
Luis Miguel Bermejo Jauregui Investigador Independiente, Ecuador https://orcid.org/0009-0008-4262-3560
Cristian Omar Bravo-Fichamba Investigador Independiente, Ecuador https://orcid.org/0009-0003-0423-1033
Ariel Sebastián Ortega Vasco Investigador Independiente, Ecuador https://orcid.org/0009-0009-3902-461X

DOI:

https://doi.org/10.33324/daya.vi19.1063

Keywords:

Diseño bioclimático, confort térmico, eficiencia energética, protección solar, iluminación natural, sostenibilidad

Abstract

In previous decades, the field of museography focused on presenting a chronological narrative of historical events, progressing from the simple to the complex, and emphasizing condensed, factual data. Public engagement was limited to a passive role, with visitors positioned as spectators who remained on the margins of pre-established and pre-interpreted content, thereby discouraging critical and individual thinking. However, this paradigm has shifted in recent decades, as contemporary museography has introduced new strategies in exhibition design. This discussion paper explores storytelling as a museographic tool to foster meaningful connections with audiences, stimulate inquiry and the pursuit of knowledge, and reinforce a sense of identity and community.

Keywords: Museography, interiorism, culture, storytelling.

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Author Biography

Cristian Omar Bravo-Fichamba, Investigador Independiente, Ecuador

References

• Al-Mowallad, E. A. M. S., Huang, X., Lu, Z., Li, X., Wu, K., Zhu, Z., y Liu, G. (2024). Assessment and improvement of daylighting quality in classrooms with double-side windows. Buildings, 14(11), 3501. https://doi.org/10.3390/buildings14113501

• Bekele, M. T., y Atakara, C. (2023). Residential Building Energy Conservation in Mediterranean Climate Zone by Integrating Passive Solar and Energy Efficiency Design Strategies. Buildings, 13(4), 1073. https://doi.org/10.3390/buildings13041073

• Bilbao, A., de Miguel, A., Pérez-Burgos, A., y Román, R. (2008). Energías renovables y su integración en la edificación.

• https://www.researchgate.net/publication/258450471_Energias_Renovables_y_su_Integracion_en_la_Edificacion

• Carmenado Vaquero, L. (2016). Estímulos y reacciones: fachadas dinámicas ante el sol, el viento y la temperatura. Universidad Politécnica de Madrid. https://oa.upm.es/39236/1/TFG_Loreto_Carmenado_Vaquero.pdf

• Cillari, G., Ferraro, M., Griffo, A., y Margani, G. (2021). Passive solar solutions for buildings: Criteria and synergies. Applied Sciences, 11(1), 376. https://doi.org/10.3390/app11010376

• DrajMarsh, A. (2025). Sun Path Diagram 2D Madrid. DrajMarsh. https://drajmarsh.bitbucket.io/sunpath2d.html

• Erell, E., Pearlmutter, D., & Williamson, T. (2012). Urban microclimate: Designing the spaces between buildings. Routledge. https://doi.org/10.4324/9781849775392

• Elaouzy, Y., y El Fadar, A. (2022). Energy, economic and environmental benefits of integrating passive design strategies into buildings: A review. Renewable and Sustainable Energy Reviews, 167, 112828. https://doi.org/10.1016/j.rser.2022.112828

• Fernández García, F., y Rasilla Álvarez, D, (2008). Olas de calor e influencia urbana en Madrid y su área metropolitana. Investigaciones Geográficas. https://www.researchgate.net/publication/251065729_Olas_de_calor_e_influencia_urbana_en_Madrid_y_su_area_metropolitana

• Higueras, E. (1998). Urbanismo Bioclimático, Criterios medio ambientales en la ordenación de asentamientos. Cuadernos de Investigación Urbanística. 1-81. https://es.scribd.com/document/474481268/Urbanismo-bioclimatico-Esther-Higueras#page=36

• Lopez-Astudillo, K. S., Simbaña-Escobar, P. R., y Chérrez-Córdova, E. A. (2025). Optimización basada en datos del desempeño lumínico y térmico de una vivienda multifamiliar. Estudio de caso en Santa Elena, Ecuador. MQRInvestigar , 9(3), e914. https://doi.org/10.56048/MQR20225.9.3.2025.e914

• Madrid climate, weather by month, Average temperature (Spain) - weather spark. (12 de noviembre de 2025). Weather Spark. https://weatherspark.com/y/36848/Average-Weather-in-Madrid-Spain-Year-Round#google_vignette

• Milne, M., Liggett, R., Benson, A., & Bhattacharya, Y. (mayo de 2009). Climate Consultant 4.0 develops design guidelines for each unique climate. En American Solar Energy Society Meeting.

• Myroniuk, K., Furdas, Y., Zhelykh, V., Adamski, M., Gumen, O., Savin, V., y Mitoulis, S.-A. (2024). Passive Ventilation of Residential Buildings Using the Trombe Wall. Buildings, 14(10), 3154. https://doi.org/10.3390/buildings14103154

• Rasilla, D., Allende, F., y Fernández García, F. (2016). La isla de calor urbano de Madrid durante la ola de calor de julio 2015. Repositorio de la Universidad de Cantabria. https://repositorio.aemet.es/bitstream/20.500.11765/8013/1/0047_X-2016-RASILLA.pdf

• Roudsari, M. S., Pak, M. y Smith, A. (2013). Ladybug: a parametric environmental plugin for grasshopper to help designers create an environmentally-conscious design. En Building Simulation 2013 (Vol. 13, pp. 3128-3135). IBPSA.

• Santamouris, M., Sfakianaki, A., y Pavlou, K. (2010). On the efficiency of night ventilation techniques applied to residential buildings. Energy and Buildings, 42(8), 1309-1313.

• Simbaña, P., Paredes, D., Jácome, D., & Piña, O. (2020). The urban impact of sustainable design interventions in Quito: Case study of the implementation of the eco-efficient tool in ‘la carolina’neighborhood in Quito. En XII Seminario Internacional de Investigación en Urbanismo, São Paulo-Lisboa, 2020. Faculdade de Arquitetura da Universidade de Lisboa.

• Simbaña Escobar, P., Rocchio, D., Alvarado, N. y Cherrez, K. (2024). Passive Strategies for thermal comfort in Amazonian Cities: The Case of Tena’s Waterfront. Bitácora Urbano Territorial, 34(3), 55–70. https://doi.org/10.15446/bitacora.v34n3.115029

• Simbaña Escobar, P., Mena-Hernández, S., Córdova, E. C., y Alvarado-Arias, N. (2025). Comparative Thermal Performance and Return on Investment of Glazing Configurations in Building Envelopes: The Case of the Plataforma Gubernamental Norte in Quito, Ecuador. Buildings 2025, 15(19), 3522. https://doi.org/10.3390/BUILDINGS15193522

• Syed Wali Uddin, K. M. I., Ubaidurrahman, M. K. M., Mohiuddin, O. H., y Nauman Khan, R. (2025). Design of sustainable and energy efficient building: Energy analysis using Revit Insight. International Journal for Research in Applied Science & Engineering Technology, 13(5), 2547-2555. https://www.ijraset.com/best-journal/design-of-sustainable-and-energy-efficient-building

• Taherian, H., y Peters, R. W. (2023). Advanced active and passive methods in residential energy efficiency. Energies, 16(9), 3905. https://doi.org/10.3390/en16093905

• Teitelbaum, E., Miller, C., & Meggers, F. (2023). Highway to the Comfort Zone: History of the Psychrometric Chart. Buildings, 13(3), 797. https://doi.org/10.3390/buildings13030797

• Toroxel, J. L., Monteiro Silva, S., y Fernandes, J. (2024). Contribution of glazed balconies as a passive heating system in contemporary buildings in northern Portugal. Sustainability, 16(13), 5658. https://doi.org/10.3390/su16135658