Abstract
This work aims to estimate the expected hours of Predicted Medium Vote (PMV) thermal comfort in Ecuadorian social housing houses applying energy simulations with Phase Change Materials (PCMs) for very hot-humid climates. First, a novel methodology for characterizing three different types of social housing is presented based on a space-time analysis of the electricity consumption in a residential complex. Next, the increase in energy demand under climate influences is analyzed. Moreover, with the goal of enlarging the time of thermal comfort inside the houses, the most suitable PCM for them is determined. This paper includes both simulations and comparisons of thermal behavior by means of the PMV methodology of four types of PCMs selected. From the performed energy simulations, the results show that changing the deck and using RT25-RT30 in walls, it is possible to increase the duration of thermal comfort in at least one of the three analyzed houses. The applied PCM showed 46% of comfortable hours and a reduction of 937 h in which the thermal sensation varies from “very hot” to “hot”. Additionally, the usage time of air conditioning decreases, assuring the thermal comfort for the inhabitants during a higher number of hours per day.
Highlights
The results of the thermal behavior of the study cases were obtained through energy simulation, and the thermal comfort was evaluated using the predicted medium vote (PMV) method during 2019
This research developed the hours of PMV thermal comfort in social houses in Ecuador by energy simulation with the use of Phase Change Materials (PCMs) for a very hot-humid climate
The spatial analysis did not show a correlation between the selected location and its energy consumption
Summary
Received: 25 November 2020Accepted: 8 January 2021Published: 26 January 2021Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.Licensee MDPI, Basel, Switzerland.Attribution (CC BY) license (https://creativecommons.org/licenses/by/ 4.0/).Worldwide, the construction sector is responsible for over one-third of the overall consumption of electric energy, and it produces nearly 40% of the total direct and indirect CO2 emissions. Moreover, the energy demand of buildings is increasing and is driven by factors such as a wider access to energy in developing countries as well as a greater usage of high energy-consuming appliances [1]. On the other hand, residential buildings consume about
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