被动冷却
热能储存
材料科学
发射率
相变材料
辐射冷却
潜热
核工程
热的
环境科学
辐射传输
热流密度
联轴节(管道)
低发射率
主动冷却
工作(物理)
涂层
光电子学
储能
瞬态(计算机编程)
热能
余热
相(物质)
太阳增益
热辐射
热管
图层(电子)
热质量
水冷
复合材料
太阳能
电子设备和系统的热管理
热障涂层
传热
显热
机械工程
作者
Wanwan Li,Tong Yang,Xinwei Dong,Yuhang Peng,Ruixiang Li,Huaxian Wan,Qing Zhao,Qiongmin Gao,Xiaohu Wu
标识
DOI:10.1016/j.csite.2025.107482
摘要
Outdoor electrical houses face significant challenges of thermal accumulation under high-temperature conditions, which can lead to equipment failure and threaten grid stability. To address this issue, this study introduces a dual-mode passive thermal management strategy using a phase change-radiative cooling coupled material (PCM-RC) applied to building envelopes. The material combines a shape-stabilized phase change material (PCM) base with high latent heat (106.32 kJ/kg) and a radiative cooling (RC) overlay featuring high solar reflectance (91 %) and strong mid-infrared emissivity (93 %). A silane coupling agent enhances interfacial adhesion between the two functional layers. The RC layer minimizes solar heat gain through high reflectivity and continuous radiative heat dissipation, while the PCM layer provides transient thermal storage through latent heat absorption, thereby delaying indoor temperature rise and attenuating heat flux penetration. Experimental tests under ambient temperatures above 40 °C show that the PCM-RC coating remarkably reduces roof and wall surface temperatures by up to 19.9 °C and 17.3 °C, respectively, compared to conventional enclosures, maintaining indoor electrical equipment within a safe operational temperature range. This work demonstrates a feasible and efficient approach to passive thermal management for electrical infrastructure, with strong potential for application in practical engineering fields involving rigorous thermal regulation and temperature control. • A dual-mode passive cooling strategy coupling phase change and radiative cooling. • Develop PCM-RC hybrid with synergistic thermal storage/radiative cooling functions. • Remarkably reduces roof/wall temperatures by 19.9 °C/17.3 °C. • Equipment temperature is maintained within safe limits without energy consumption. • Scalable thermal management strategy for infrastructure and energy buildings.
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