Topology Optimization Design of Phase Change Liquid Cooling Composite Plate
To address the challenges of high flow resistance and poor temperature uniformity in conventional PCM–liquid cooling hybrid heat exchangers—which significantly impair the performance and lifespan of electronic devices—a topology optimization approach was adopted. A dual-objective function, aimed at...
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| author | Xinqiang Xia Jiancheng Luo Jiabao Li Lixia Wei |
| author_facet | Xinqiang Xia Jiancheng Luo Jiabao Li Lixia Wei |
| author_sort | Xinqiang Xia |
| collection | DOAJ |
| description | To address the challenges of high flow resistance and poor temperature uniformity in conventional PCM–liquid cooling hybrid heat exchangers—which significantly impair the performance and lifespan of electronic devices—a topology optimization approach was adopted. A dual-objective function, aimed at minimizing the average temperature and pressure drop, was introduced to reconstruct the cooling channel layout and PCM filling region. A two-dimensional transient thermo-fluid model coupling the solid–liquid phase-change process with coolant flow and heat transfer was established, alongside the development of an experimental platform. A comprehensive comparison was performed against a conventional liquid cooling plate with straight channels. The results showed that the topology-optimized cooling plate exhibited a pressure drop of 15.80 Pa and a pumping power of 1.19 × 10⁻<sup>4</sup> W, representing reductions of 38.28% and 38.02%, respectively. The PCM solidification time was shortened by 6 min. Under these conditions, the convective heat transfer coefficient (<i>h<sub>w</sub></i>) and performance evaluation criterion (<i>j</i>/<i>f</i>) of the optimized plate reached 1319.06 W/(m<sup>2</sup>·K) and 0.56, which corresponded to increases of 60.71% and 47.5%, respectively. The topology-optimized configuration significantly improved temperature uniformity and overall cooling performance. As the inlet velocity increased from 0.05 m/s to 0.2 m/s, <i>h<sub>w</sub></i> increased by 38.65%; however, <i>j</i>/<i>f</i> decreased by 57.14%, due to the limited thermal conductivity of the PCMs, resulting in only a slight reduction in the average PCM temperature. Furthermore, the topology-optimized cooling plate demonstrated stronger steady-state regulation capability under fluctuating thermal loads. This study provides valuable insights and design guidance for the development of high-efficiency hybrid liquid cooling plates. |
| format | Article |
| id | doaj-art-0edcfd0e77c14d0dbc4d705b2d776d5c |
| institution | Kabale University |
| issn | 1996-1073 |
| language | English |
| publishDate | 2025-05-01 |
| publisher | MDPI AG |
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| series | Energies |
| spelling | doaj-art-0edcfd0e77c14d0dbc4d705b2d776d5c2025-08-20T03:47:49ZengMDPI AGEnergies1996-10732025-05-011810265210.3390/en18102652Topology Optimization Design of Phase Change Liquid Cooling Composite PlateXinqiang Xia0Jiancheng Luo1Jiabao Li2Lixia Wei3School of Mechanical Engineering, Guangxi University, Nanning 530004, ChinaSchool of Mechanical Engineering, Guangxi University, Nanning 530004, ChinaSchool of Mechanical Engineering, Guangxi University, Nanning 530004, ChinaSchool of Mechanical Engineering, Guangxi University, Nanning 530004, ChinaTo address the challenges of high flow resistance and poor temperature uniformity in conventional PCM–liquid cooling hybrid heat exchangers—which significantly impair the performance and lifespan of electronic devices—a topology optimization approach was adopted. A dual-objective function, aimed at minimizing the average temperature and pressure drop, was introduced to reconstruct the cooling channel layout and PCM filling region. A two-dimensional transient thermo-fluid model coupling the solid–liquid phase-change process with coolant flow and heat transfer was established, alongside the development of an experimental platform. A comprehensive comparison was performed against a conventional liquid cooling plate with straight channels. The results showed that the topology-optimized cooling plate exhibited a pressure drop of 15.80 Pa and a pumping power of 1.19 × 10⁻<sup>4</sup> W, representing reductions of 38.28% and 38.02%, respectively. The PCM solidification time was shortened by 6 min. Under these conditions, the convective heat transfer coefficient (<i>h<sub>w</sub></i>) and performance evaluation criterion (<i>j</i>/<i>f</i>) of the optimized plate reached 1319.06 W/(m<sup>2</sup>·K) and 0.56, which corresponded to increases of 60.71% and 47.5%, respectively. The topology-optimized configuration significantly improved temperature uniformity and overall cooling performance. As the inlet velocity increased from 0.05 m/s to 0.2 m/s, <i>h<sub>w</sub></i> increased by 38.65%; however, <i>j</i>/<i>f</i> decreased by 57.14%, due to the limited thermal conductivity of the PCMs, resulting in only a slight reduction in the average PCM temperature. Furthermore, the topology-optimized cooling plate demonstrated stronger steady-state regulation capability under fluctuating thermal loads. This study provides valuable insights and design guidance for the development of high-efficiency hybrid liquid cooling plates.https://www.mdpi.com/1996-1073/18/10/2652phase change materialliquid cooling platetopology optimization |
| spellingShingle | Xinqiang Xia Jiancheng Luo Jiabao Li Lixia Wei Topology Optimization Design of Phase Change Liquid Cooling Composite Plate Energies phase change material liquid cooling plate topology optimization |
| title | Topology Optimization Design of Phase Change Liquid Cooling Composite Plate |
| title_full | Topology Optimization Design of Phase Change Liquid Cooling Composite Plate |
| title_fullStr | Topology Optimization Design of Phase Change Liquid Cooling Composite Plate |
| title_full_unstemmed | Topology Optimization Design of Phase Change Liquid Cooling Composite Plate |
| title_short | Topology Optimization Design of Phase Change Liquid Cooling Composite Plate |
| title_sort | topology optimization design of phase change liquid cooling composite plate |
| topic | phase change material liquid cooling plate topology optimization |
| url | https://www.mdpi.com/1996-1073/18/10/2652 |
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