This work is to examine the employment of curved fins to boost heat recovery in a double-pipe containment system filled with phase change material (PCM). The study utilizes CFD modeling, validated against experimental benchmarks, to evaluate how various geometric parameters of curved fins affect system performance. Findings demonstrate that adjusting the fin angular curvature from 60◦ to 180◦ yielded a 22.1 % decrease in the time required for solidification while simultaneously improving heat recovery efficiency by 32.0 %. When the fin base spacing was increased from 5 mm to 15 mm, the system showed a 14.5 % solidification time saving and a 20.9 % heat recovery improvement. Furthermore, modifying the joining angle between upper fins from 0◦ to 60◦ resulted in both a 25.9 % faster solidification rate and a 34.7 % boost in heat recovery capability. The study reveals that the optimized curved fin design significantly outperforms both traditional longitudinal fin configurations and systems without fins, demonstrating a 65.1 % faster solidification and a 190.5 % superior heat recovery rate compared to systems without fins. These results offer valuable design insights for developing more efficient thermal energy storage systems, with particular relevance for solar energy applications
