Arasteh, Hossein, Maref, Wahid et Saber, Hamed H..
2026.
« Computational fluid dynamics analysis of energy and optical performance in fenestration systems incorporating solid-solid phase change materials ».
Journal of Energy Storage, vol. 142.
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Résumé
This study investigates the energy and optical performance of a double-glazed window system incorporating a solid-solid phase change material (DGW-SSPCM) compared to a conventional reference system (DGW-R). Transient CFD simulations were conducted using ANSYS FLUENT for the hottest and coldest days in Montreal, Canada, under sunny and cloudy conditions across four glazing orientations. A 2 mm SSPCM layer was applied to the interior pane, and natural convection (NC) within the glazing air gap was modeled using the solidification/melting and Discrete Ordinates models. Results show that NC has negligible effects during summer due to weak buoyancy-driven airflow, making its inclusion unnecessary for accurate energy and optical analysis under warm conditions. In winter, however, NC significantly impacts the phase change behavior and total energy performance of the system, with heat losses being underestimated by 10 to 23 % when NC is not considered. This behavior is supported by air gap velocity vector analyses, which show well-defined convective loops in winter with air velocities reaching up to 0.14 m/s, Reynolds numbers up to 57, and Rayleigh numbers exceeding 104, while summer flows remain weak and conduction-dominated. While the DGW-SSPCM system offers no substantial energy savings in summer due to nighttime thermal discharge, it achieves winter energy savings of up to 7.6 % and improves indoor thermal comfort. The optical analysis in this study has demonstrated that benefiting from the full cycle of the SSPCM phase transition allows the glazing to remain fully transparent during office hours, making it particularly practical for commercial buildings. The south-facing configuration, incorporating an SSPCM layer with a transition temperature of 15 °C on the interior pane, is identified as the optimal setup. This design ensures full transparency and thermal neutrality throughout the year during office hours, while maximizing latent heat utilization for effective thermal regulation in winter. These findings highlight the potential of SSPCM-integrated glazing systems as a passive strategy for enhancing energy efficiency and indoor comfort in heating-dominated climates, particularly in commercial buildings with daytime occupancy.
| Type de document: | Article publié dans une revue, révisé par les pairs |
|---|---|
| Professeur: | Professeur Maref, Wahid |
| Affiliation: | Génie de la construction |
| Date de dépôt: | 03 déc. 2025 18:46 |
| Dernière modification: | 10 janv. 2026 16:14 |
| URI: | https://espace2.etsmtl.ca/id/eprint/33086 |
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