Experimental and numerical simulation study on the thermal performance of building envelope structures incorporating the solid–solid phase change material
Q. Ye, Labouda Ba, Giao Nguyen, Rafik Absi, Béatrice Ledésert, Gilberte Dosseh, Ronan Hébert
Abstract
• Simplified Integration: Direct incorporating of SS-PCM into hollow construction structures. • Thermal Modeling: A finite element model (FEM) was developed to simulate thermal behavior of hollow bricks with and without PCM. • Design Optimization: Combining experimental data with numerical analysis provides a robust framework for optimizing design and thermal performance. This work is an experimental and numerical study of the thermal performance of building envelope structures incorporating a solid–solid phase change material (S-S PCM), consisting in a cross-linked polyurethane designated as PUX-1500-20. This S-S PCM is capable of storing and releasing thermal energy via phase transitions within the human comfort temperature range, facilitating the temporal and spatial transfer of solar energy for optimizing energy efficiency. The primary aim of this work is to integrate the S-S PCM into hollow bricks used in building envelopes and to evaluate their thermal inertia through both experimental testing and numerical simulation. The experimental results demonstrate that the integration of the PCM effectively delays and decreases the indoor temperature peak. The simulation results also show that the incorporation of the S-S PCM into hollow bricks gives rise to a phase shift of 7 h and a decrement factor of 0.38. In comparison with the thermal behavior of the building envelopes (hollow brick) without PCMs, our results provide convincing evidence of the important thermal inertia of these structures incorporating the PCMs, revealing their significant potential in reducing energy consumption of building.