Fire Safety Strategies to Reduce Mortality in Dwellings Occupied by Elderly People: The Spanish Case

77% of fatal fires in Spain take place in residential buildings, and more than 60% of deaths are people over 65 years old. The collection of fire loss data in Spain is poorly regulated and it does not have homogeneity. This makes it extremely difficult to study the fire problem and the effectiveness of different safety strategies in general, and more specifically with relation to vulnerable groups, such as the elderly. As first step to assess the measures aimed to reduce mortality in residential buildings, a methodology for collecting fire data has been developed, based on information extracted from the media. Information on 289 fatal dwelling fires has been systematically analyzed in order to identify the prevention and protection strategies more effective to prevent fire deaths. Among the identified measures, they stand out the installation of fire detection and alarm systems in residential buildings, which is not required by law at the present time, and the installation of automatic extinguishing systems, such as household sprinklers. The use of safe heating systems, avoiding old and bad-maintained portable heaters, is a particularly useful prevention strategy for the elderly people

Exergy as a measure of sustainable retrofitting of buildings

This study presents a novel optimization methodology for choosing optimal building retrofitting strategies based on the concept of exergy analysis. The study demonstrates that the building exergy analysis may open new opportunities in the design of an optimal retrofit solution despite being a theoretical approach based on the high performance of a Carnot reverse cycle. This exergy-based solution is different from the one selected through traditional efficient retrofits where minimizing energy consumption is the primary selection criteria. The new solution connects the building with the reference environment, which acts as “an unlimited sink or unlimited sources of energy”, and it adapts the building to maximize the intake of energy resources from the reference environment. The building hosting the School of Architecture at the University of Navarra has been chosen as the case study building. The unique architectural appearance and bespoke architectural characteristics of the building limit the choices of retrofitting solutions; therefore, retrofitting solutions on the façade, roof, roof skylight and windows are considered in multi-objective optimization using the jEPlus package. It is remarkable that different retrofitting solutions have been obtained for energy-driven and exergy-driven optimization, respectively. Considering the local contexts and all possible reference environments for the building, three “unlimited sinks or unlimited sources of energy” are selected for the case study building to explore exergy-driven optimization: the external air, the ground in the surrounding area and the nearby river. The evidence shows that no matter which reference environment is chosen, an identical envelope retrofitting solution has been obtained

Exergy as a measure of sustainable retrofitting of buildings

This study presents a novel optimization methodology for choosing optimal building retrofitting strategies based on the concept of exergy analysis. The study demonstrates that the building exergy analysis may open new opportunities in the design of an optimal retrofit solution despite being a theoretical approach based on the high performance of a Carnot reverse cycle. This exergy-based solution is different from the one selected through traditional efficient retrofits where minimizing energy consumption is the primary selection criteria. The new solution connects the building with the reference environment, which acts as “an unlimited sink or unlimited sources of energy”, and it adapts the building to maximize the intake of energy resources from the reference environment. The building hosting the School of Architecture at the University of Navarra has been chosen as the case study building. The unique architectural appearance and bespoke architectural characteristics of the building limit the choices of retrofitting solutions; therefore, retrofitting solutions on the façade, roof, roof skylight and windows are considered in multi-objective optimization using the jEPlus package. It is remarkable that different retrofitting solutions have been obtained for energy-driven and exergy-driven optimization, respectively. Considering the local contexts and all possible reference environments for the building, three “unlimited sinks or unlimited sources of energy” are selected for the case study building to explore exergy-driven optimization: the external air, the ground in the surrounding area and the nearby river. The evidence shows that no matter which reference environment is chosen, an identical envelope retrofitting solution has been obtained