Biomimetic optimized vertically aligned annular fins for fast latent heat thermal energy storage

•Biomimetic topology-optimized vertically aligned annular fins are proposed to accelerate heat storage performance.•Optimized biomimetic fins with unique bifurcation structures can shorten melting time by 45.9%.•Temperature uniformity is greatly improved by with average temperature difference reduce...

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Bibliographic Details
Published in:Applied energy 2023-10, Vol.347, p.121435, Article 121435
Main Authors: Liu, Xianglei, Qin, Xinliang, Tian, Yang, Luo, Qingyang, Yao, Haichen, Wang, Jianguo, Dang, Chunzhuo, Xu, Qiao, Lv, Shushan, Xuan, Yimin
Format: Article
Language:English
Subjects:
Biomimetic fins
Latent heat
Thermal energy storage
Topology optimization
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Summary:•Biomimetic topology-optimized vertically aligned annular fins are proposed to accelerate heat storage performance.•Optimized biomimetic fins with unique bifurcation structures can shorten melting time by 45.9%.•Temperature uniformity is greatly improved by with average temperature difference reduced by 75.3%.•The underlying mechanism lies in accelerated melting of PCMs close to the outer bottom boundary. Latent heat thermal energy storage (LHTES) technology has been widely used in balancing energy demand and intermittent energy supply, as well as thermal management in buildings, but suffers from slow heat storage rates. Here, biomimetic topology-optimized vertically aligned annular fins are proposed to accelerate heat storage performance. Taking the maximum average temperature as the optimization objective function, optimized biomimetic fins can shorten the melting time by 45.9% compared with traditional fins as verified by experimental measurements. Such a fast heat storage rate is also superior to that of pitch-varying fins and diameter-varying fins by 18.4% and 23.5%, respectively. Meanwhile, the temperature uniformity is greatly improved by biomimetic fins with a reduction of average temperature difference in phase change materials (PCMs) by 75.3%. The underlying mechanism can be attributed to accelerated melting of PCMs close to the outer bottom boundary due to unique bifurcation structures of topology optimized fins. The fractal dimension of optimized fins is similar to that of leaf vein structures, demonstrating that proposed topology structures are close to Natural’s optimal solutions. This study provides novel biomimetic structures for accelerating thermal energy storage rate and promotes the application of biomimetics in LHTES techniques.
ISSN:0306-2619
DOI:10.1016/j.apenergy.2023.121435