What does this research mean for the field?

Triply Periodic Minimal Surface (TPMS) fins significantly reduce charging and discharging times in concrete thermal energy storage systems, achieving reductions of 62% and 77%, respectively. Novelty: ClaimNovelty.NOVEL_FINDING. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

The study aims to evaluate the impact of various fin designs on the heat transfer performance of concrete thermal energy storage systems.

March 10, 2026Open Access

A comparative study of different fin designs for enhancing the performance of concrete thermal energy storage

Key Points

The study aims to evaluate the impact of various fin designs on the heat transfer performance of concrete thermal energy storage systems.
Developed a 3D numerical model for simulating temperature and heat transfer behavior.
Investigated six fin designs: longitudinal fins, annular fins, TPMS fins, curved fins, bifurcated fins, and helical fins.
Analyzed performance indicators such as temperature distribution and efficiency during charge and discharge cycles.
TPMS fins showed the greatest reduction in charging time by 62% and discharging time by 77%.
Longitudinal, annular, curved, and bifurcated fins exhibited similar thermal performance.
The performance enhancements were primarily due to increased contact areas in fin designs.

Abstract

Concrete thermal energy storage (CTES) is gaining increasing attention due to its availability and cost-effectiveness, providing a promising solution to the renewable energy transition. However, technical and design challenges remain, particularly in enhancing the heat transfer performance of CTES for the storage and release of thermal energy. This research investigates the design of CTES systems with various fin designs to improve the heat transfer performance through numerical simulation. An efficient 3D numerical model was developed to accurately predict temperature development and charge/discharge behaviour, with results being validated against existing research. Six fin designs, including longitudinal fins, annular fins, Triply Periodic Minimal Surfaces (TPMS) fins, curved fins, bifurcated fins, and helical fins, were investigated as heat exchanger design configurations. The typical temperature distribution, charging and discharging times, charging and discharging efficiencies, manufacturing costs, and carbon emissions were analysed as performance indicators to evaluate different designs. The TPMS outperforms all other designs, achieving the highest reduction in both charging and discharging times, with reductions of 62% and 77%, respectively. This is not only attributed to the surface area, but also to the increasing contact area between the fin and tube of the TPMS fin design. Additionally, the findings show that utilising fins as heat exchangers may offer comparable or superior performance enhancements compared to improving heat transfer of concrete material. The results of this research are anticipated to provide a basis for further analysis and experimental study to improve the performance of CTES. • A numerical comparison of concrete thermal energy storage with various fin designs • Triply periodic minimal surface fins reduce charging and discharging time the most • Longitudinal, annular, curved, and bifurcated fins show similar thermal performance • Fin–tube and fin–concrete contact areas determine system thermal performance

Read Full Paperexternally

Bookmark

View Full Paper

Cite This Study

Tu et al. (Sun,) studied this question.

synapsesocial.com/papers/69af95de70916d39fea4df1d https://doi.org/https://doi.org/10.1016/j.energy.2026.140677

Bookmark

View Full Paper