Thermal Behavior of a Building with Incorporated Phase Change Materials in the South and the North Wall

Maria Plytaria,Kimon Antonopoulos,Evangelos Bellos,Ioannis Alexopoulos,Christos Tzivanidis

doi:10.3390/computation7010002

Maria Plytaria, Kimon Antonopoulos + Show 3 more

Open Access

https://doi.org/10.3390/computation7010002

Copy DOI

Journal: Computation	Publication Date: Dec 21, 2018
Citations: 13	License type: CC BY 4.0

Affiliation: National Technical University of Athens

Abstract

Energy consumption in the building sector is responsible for a very large amount of electricity consumption worldwide. The reduction of this consumption is a crucial issue in order to achieve sustainability. The objective of this work is to investigate the use of phase change materials (PCMs) in the building walls in order to reduce the heating and the cooling loads. The novelty of this work is based on the investigation of different scenarios about the position of the PCM layer in the south and the north walls. PCMs can improve the thermal performance and the thermal comfort of a building due to their ability to store large amounts of thermal energy in latent form and so to reduce the temperature fluctuations of the structural components, keeping them within the desired temperature levels. More specifically, this work presents and compares the heating loads, the cooling loads and the temperature distribution of a building in Athens (Greece), with and without PCMs in different positions in the south wall and in the north walls. The simulation is performed with the commercial software TRNSYS 17, using the TRNSYS component: type 1270 (PCM Wall). The results proved that the maximum energy savings per year were achieved by the combination of the insulation and the PCM layer in the north and south walls. More specifically, the reductions in the heating and the cooling loads were found to be 1.54% and 5.90%, respectively. Furthermore, the temperature distribution with the use of a PCM layer is the most acceptable, especially during the summer period.

Highlights

The building sector is one of the most energy consuming sectors, and it is responsible for about the 30%–40% of the world’s total energy consumption
Greece is a country with high solar potential, which is in the range of 1400 kWh/m2 to 1800 kWh/m2 per year
Showed that we can reduce the thickness of insulation of walls by 0.04 m, and with the combination of a the results showed that we can reduce the thickness of insulation of walls by 0.04 m, phase change materials (PCMs) layer, we observe a reduction of heating loads by 1.54% and a reduction of cooling loads by 5.90%

Summary

Introduction

The building sector is one of the most energy consuming sectors, and it is responsible for about the 30%–40% of the world’s total energy consumption. The utilization of alternative and renewable energy sources in the building sector is a critical issue which has to be delivered in order to achieve sustainability [1]. Solar energy exploitation is an important weapon for reducing electricity and fossil fuel utilization in the building sector [2]. Solar energy is an abundant energy source which can be converted either to useful heat or electricity. Greece is a country with high solar potential, which is in the range of 1400 kWh/m2 to 1800 kWh/m2 per year. In Athens, the solar potential is about 1600 kWh/m2 [3], and it is a promising value for the cover of the energy loads with the solar energy utilization

Objectives

Methods

Results

Conclusion