Qihao Dai , Xinyu Tan , Guiguang Qi , Xiongbo Yang , Bowhen Li , Zheng Guo , Junmei Zhang , Weiwei Hu , Songshan Li , Cadao Nguyen , Xiaobo Chen , Yequan Xiao , Peng Xiang
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引用次数: 0
摘要
被动式日间辐射冷却通过将太阳光和辐射热反射到外层空间而不消耗能源,为冷却解决方案的变革提供了一条大有可为的途径。以往的研究通常只关注单一温度场景,而忽视了目标物体可能存在热源的实际应用的复杂性。在这里,我们通过在光固化单体三环癸烷二甲醇二丙烯酸酯(DCPDA)中加入纳米氮化硼,成功制备了一种多温度场景冷却涂料(CPMTS)。CPMTS 具有出色的宽带热发射率(∼0.955)、反射率(∼0.778,从 300 纳米到 2.5 μm)和热导率(∼0.51 W m-1 K-1)。值得注意的是,在没有 1 W 热源持续加热和有 1 W 热源持续加热的情况下,它分别在 790 W m-2 和 507 W m-2 的太阳辐照下实现了 20.1 °C和 8.8 °C的最大冷却温度。在阴天或夜间也能观察到持续和显著的辐射冷却性能。CPMTS 在实际应用场景中表现出卓越的辐射冷却性能。优异的耐老化性、附着力、稳定性和配色能力使 CPMTS 有望通过喷涂或刷涂实现大规模应用。这项研究为现实世界中不同温度场景下的冷却提供了一种潜在的解决方案。所获得的辐射冷却涂层证明了其在实际应用中的可扩展性和耐用性。
Durable and robust broadband radiative cooling coatings for multi-temperature scenarios
Passive daytime radiative cooling presents a promising avenue for revolutionizing cooling solutions by reflecting sunlight and radiative heat to outer space without consuming energy. Previous studies often focus on a single temperature scenario, neglecting the complexity of real-world applications in which the target object may have heat sources. Here, we have successfully prepared a Cooling Paint for Multi-Temperature Scenarios (CPMTS) by incorporating nanometer boron nitride into the photocured monomer Tricyclodecane Dimethanol Diacrylate (DCPDA). CPMTS exhibits excellent broadband thermal emittance (∼0.955), reflectance (∼0.778, from 300 nm to 2.5 μm), and thermal conductivity (∼0.51 W m−1 K−1). Notably, it achieves a maximum cooling of 20.1 °C and 8.8 °C under ∼790 W m−2 and ∼507 W m−2 of solar irradiation in the absence and presence of a 1 W heat source continuously heating, respectively. Continuous and significant radiative cooling performance has been observed on cloudy days or at night. CPMTS shows excellent radiative cooling performance in practical application scenarios. Excellent ageing resistance, adhesion, stability, and color matching ability make CPMTS expected large-scale application through spray or brush. This research provides a potential solution for cooling in real-world diverse temperature scenarios. The obtained radiative cooling coatings demonstrate scalability and durability in practical applications.
期刊介绍:
Solar Energy welcomes manuscripts presenting information not previously published in journals on any aspect of solar energy research, development, application, measurement or policy. The term "solar energy" in this context includes the indirect uses such as wind energy and biomass
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