A comprehensive review of the thermal performance in energy efficient building envelope incorporated with phase change materials

Abstract

As the world's largest energy consumer, the building sector is under growing pressure to reduce energy consumption and CO2 emissions. To confront this challenge, the thermal performance of building elements, especially for cooling purposes, must be enhanced. One promising solution involves the incorporation of PCMs to augment a building's thermal mass. Unlike traditional building materials that store thermal energy sensibly, PCMs store it in a latent form by undergoing phase transitions at constant temperatures. This unique characteristic allows PCMs to store and release more heat efficiently than sensible heat thermal energy storage materials. As a result, PCMs have emerged as a prominent solution for passive cooling and heating applications in buildings. This paper proposes a systematic review of existing literature, classifying it based on building components and effective PCM integration methods while considering climatic influences. The primary objective is to comprehensively analyze the application of PCMs within building envelopes to enhance indoor thermal comfort. This study explores various methods for assessing the thermal properties of PCMs and PCM composites. Notably, integrating PCMs into building components like walls and roofs has shown remarkable potential in reducing energy consumption within the building envelope. This approach is precious in lightweight construction, where conventional passive design strategies may fall short. This study aims to bridge the existing research gap and provide valuable insights for designing energy-efficient buildings across diverse climates by systematically evaluating the impact of directly incorporating thermal energy storage systems into building components. © 2023 Elsevier Ltd