https://hdl.handle.net/10481/2750 Mon, 13 Apr 2026 17:23:33 GMT 2026-04-13T17:23:33Z https://hdl.handle.net/10481/112710 INV-INC300-2025: Informe del proyecto Caracterización de la feminización de la pobreza energética del entorno construido del Área Metropolitana de Granada Bienvenido Huertas, José David; Pinos Navarrete, Aida; Pérez Fargallo, Alexis; Aguilar Aguilera, Antonio Jesús; Serrano Jiménez, Antonio José; Nestares Nieto, Beatriz; Sánchez García, Daniel; Romero Recuero, Irene; Berti, Krizia; De la Hoz Torres, María Luisa; Clavijo Núñez, Susana Informe desarrollado a través del proyecto "Caracterización de la feminización de la pobreza energética del entorno construido del Área Metropolitana de Granada" (INV-INC300-2025) financiado a través del programa de "Ayudas de apoyo y fomento a la investigación en materia de Igualdad, Inclusión y Compromiso Social”, del Plan Propio de Investigación y Transferencia de la Universidad de Granada 2025. https://hdl.handle.net/10481/112710 https://hdl.handle.net/10481/112635 INV-INC300-2025: Conjunto de datos del Área Metropolitana de Granada por secciones censales Bienvenido Huertas, José David; Pinos Navarrete, Aida; Pérez Fargallo, Alexis; Aguilar Aguilera, Antonio Jesús; Serrano Jiménez, Antonio José; Nestares Nieto, Beatriz; Sánchez García, Daniel; Romero Recuero, Irene; Berti, Krizia; De la Hoz Torres, María Luisa; Clavijo Núñez, Susana Conjunto de datos desarrollado a través del proyecto "Caracterización de la feminización de la pobreza energética del entorno construido del Área Metropolitana de Granada" (INV-INC300-2025) financiado a través del programa de "Ayudas de apoyo y fomento a la investigación en materia de Igualdad, Inclusión y Compromiso Social”, del Plan Propio de Investigación y Transferencia de la Universidad de Granada 2025. https://hdl.handle.net/10481/112635 https://hdl.handle.net/10481/112529 Defining socio-climate-energy zones based on photovoltaic potential to support new standards for eliminating energy poverty in Chile Pérez-Fargallo, Alexis; Clavijo Núñez, Susana; Rubio-Bellido, Carlos; Bienvenido Huertas, José David; Serrano-Jiménez, Antonio Countries are facing contexts of high climatic and socio-spatial heterogeneity, where integrated territorial diagnostics to address energy poverty are essential. This research aims to evaluate the extent to which the current thermal zoning in Chile can discriminate among variables related to residential electricity consumption, photovoltaic generation potential, and poverty at the communal scale. Therefore, a replicable methodology has been designed and tested to build a socio-climate-energy zoning. 343 communes have been analyzed, combining information on residential electricity consumption, annual photovoltaic generation potential, and the number of people in poverty to examine their behavior according to the current thermal zoning. The contrast between zones is evaluated by descriptive statistics, correlation analysis, and difference tests. The results show that current thermal zoning, by itself, discriminates among the socio-energy variables considered to a limited extent, including variables such as annual electricity consumption. Subsequently, the generation/consumption relationship is stratified into three ranges, and poverty is stratified into quartiles, creating 12 categories. This new classification allows building socio-climate-energy zoning as an alternative to the current thermal zoning, enabling the identification of vulnerable areas, the planning of photovoltaic energy programs, and, in general, the prioritization of interventions that integrate social vulnerability with local electricity generation and consumption. The association between the two dimensions is contrasted using Pearson's Chi-square test, and the results are represented cartographically. Overall, the proposed framework provides an operational tool for territorial energy planning and the design of differentiated policies, with the potential to adapt to other regions of the Global South. https://hdl.handle.net/10481/112529 https://hdl.handle.net/10481/112481 Execution of large-scale sustainable pavement with recycled materials. Assessment of mechanical behaviour and life cycle Rosales, Manuel; Rosales, Julia; Agrela, Francisco; López Alonso, Mónica; Cuenca Moyano, Gloria María It is important to achieve full-scale applications of recycled materials such as pavement concretes, with recycled aggregates and sustainable cements. The objective of this research is the study and full-scale implementation of a concrete road made from recycled by-products. This concrete road must exhibit a compressive strength in excess of 30 MPa (HA-30). A total of 5 different types of sections were included: a control section with conventional concrete, another with the application of Eco-Hybrid additions to the cement, two sections with replacement of aggregates, one with recycled materials from the processing of Mixed Recycled Aggregates (MRA) and the other with MRA and Biomass Bottom Ash (BBA) - and finally, a section replacing both aggregates with MRA and BBA with the use of Eco-Hybrid additions. Characterisation studies of the different materials and the design of the experimental sections were carried out in the laboratory. Dosages and consistencies were controlled at the plant and the mechanical behaviour in the short and medium term was measured externally. For the technical study of concrete behaviour, in situ sensors were included, obtaining monitoring results through temperature sensors and dimensional changes. In addition to a study of behaviour and durability, a life cycle assessment was made to measure the environmental impact of conventional concrete and mixtures with recycled materials using environmental and monetary parameters. The cement that included alternative supplementary cementitious materials at 25 % of the total showed comparable strength to conventional cement. Aggregate substitution of 35 %- 40 % resulted in a decrease in mechanical properties between 15 % and 25 %. The environmental impact was reduced between by 10–15 % in mixes in which Eco-Hybrid cement was used. This work is part of grant projects PDC2022–133285-C22 MCIN/AEI/10.13039/501100011033/European Union “NextGenerationEU/ PRTR” and PID2019–107238RBC22 funded by MCIN/AEI/10.13039/501100011033. https://hdl.handle.net/10481/112481 https://hdl.handle.net/10481/112303 Climate-Resilient Design of Covered Historic Courtyards in Mediterranean Climates: The Role of Roof Geometry and Passive Strategies Under Future Scenarios Sáez Pérez, María Paz; Cabeza Prieto, Alejandro Covered courtyards are increasingly being adopted as a passive strategy for the climatic rehabilitation and adaptive reuse of historic buildings. However, their thermal behaviour is strongly conditioned by roof geometry, local climate conditions, and future climate warming, aspects that have not yet been comparatively addressed within a climate resilience framework. This study evaluates the energy and thermal performance of three representative roof typologies for covered historic courtyards—glazed dome, glazed flat roof, and south-facing sawtooth roof—across two Mediterranean climates of contrasting severity (cold continental and warm–dry), considering both current and future climatic conditions (2050–2080). Additionally, two design approaches are compared: a baseline design (BD), based exclusively on geometric configuration and standard glazing, and an enhanced passive design (EPD), which incorporates improved glazing, controlled natural ventilation, and seasonal solar control. Dynamic simulations using EnergyPlus/DesignBuilder are employed to analyse heating and cooling demands, free-running thermal behaviour, overheating risk, and the climatic robustness of each solution. The results show that roof geometry constitutes the dominant factor governing the long-term thermal resilience of covered courtyards, particularly under future climate warming scenarios, while enhanced passive strategies significantly mitigate cooling demand and overheating in the most penalised typologies. The south-facing sawtooth roof consistently exhibits the highest climatic robustness under free-running conditions across the analysed scenarios, whereas the glazed dome and flat roof solutions display greater climatic sensitivity and benefit more substantially from the application of enhanced passive design strategies. Overall, the results provide quantitative design criteria to support resilient interventions in historic covered courtyards in Mediterranean climates under climate change. https://hdl.handle.net/10481/112303