Akademik Veri Yönetim Sistemi
VIII.INTERNATIONAL ICONTECH SYMPOSIUM ON INNOVATIVE SURVEYS IN POSITIVE SCIENCES, Baku, Azerbaycan, 16 - 18 Mart 2024, ss.619-620, (Özet Bildiri)
The exploration of novel materials aimed at addressing pivotal challenges inherent in energy storage systems has garnered considerable attention within scholarly discourse.
Notably, Phase Change Materials (PCMs) have emerged as a crucial component in the energy sector owing to their capacity to absorb or release substantial heat during the phase transition phenomenon.
Various thermal management applications, encompassing solar heat storage, heat exchangers, and architectural insulation materials, rely extensively on the integration of PCMs.
However, a prerequisite for the effective utilization of such end products lies in the establishment of a stable operational milieu conducive to facilitating phase transitions without the occurrence of leakage, alongside ensuring high thermal conductivity over protracted durations.
In the pursuit of advancing this domain, this study undertakes a multifaceted approach by augmenting PCMs through the application of coatings comprising silica or carboxymethyl cellulose, thereby enhancing their mechanical robustness and suitability for diverse applications.
The fabrication process involves the utilization of dip and spray coating methodologies to realize double-layered microcapsules.
Subsequent evaluation of the thermal storage capabilities and mechanical integrity of the coated microcapsules is conducted via Differential Scanning Calorimetry (DSC) and extrusion processes, respectively.
Keywords: Paraffin, Phase change materials, Thermal conductivity, Thermal energy storage, Differential scanning calorimetry