目的 针对PDMS涂层机械稳定性不足及热阻限制冷凝效率的问题,开发一种兼具高稳定性和高效冷凝性能的无氟超疏水铜表面,以满足能源、水收集及电子热管理等领域对冷凝换热效率的提升需求。方法 提出了基于红外纳秒激光的一步法制备策略。在H62黄铜基体上涂覆PDMS与铜粉的混合液,利用红外纳秒激光完成基体蚀刻与涂层固化。采用扫描电镜、傅里叶红外光谱等表征表面形貌与化学组成。通过砂纸摩擦、落砂冲击、高温处理及蒸汽暴露实验评估稳定性。搭建冷凝实验系统定量分析传热性能。结果 通过正交试验优化激光参数(扫描间距200 μm、扫描20次、速度150 mm/s),确定PDMS与铜粉最佳质量比为2∶1,激光制备的超疏水复合表面(SHS-Cu)具有微纳复合结构,接触角达158.4°,滚动角仅6°。表面表现出卓越稳定性:45次砂纸摩擦后接触角149°;240 g落砂冲击后接触角147.7°;300 ℃热处理12 h后接触角仍保持151.8°以上;蒸汽环境中稳定运行超过9 h。冷凝性能测试显示,纯PDMS涂层表面传热系数在ΔT=1 K时达到光滑铜板的2.12倍;当掺入铜粉后,复合涂层表面传热系数进一步提升,在ΔT=1 K时分别达到光滑铜板的5.85倍和纯PDMS涂层的2.76倍。结论 通过激光刻蚀法处理PDMS&铜粉混合液,成功制备出高稳定、高效冷凝的超疏水铜表面。该方法一步完成、无氟环保,铜粉构建的导热网络有效降低了界面热阻,微纳结构增强了机械稳定性,突破了传统PDMS涂层在冷凝换热应用中的双重瓶颈,为高性能工业冷凝换热表面开发提供了可行的新方案。
Abstract
To address the poor mechanical stability and high interfacial thermal resistance of conventional polydimethylsiloxane (PDMS) coatings in condensation heat transfer, the work aims to propose a one-step, fluorine-free laser ablation strategy. A mixture of PDMS and copper powder was pre-coated onto an H62 brass substrate, followed by direct infrared nanosecond laser ablation in air. Orthogonal experiments were conducted to optimize laser parameters: scan spacing (100-300 μm), scan passes (5-40), and scan speed (50-250 mm/s). The PDMS-to-copper mass ratio was systematically changed from 2∶0 to 2∶6. The optimal parameters were determined as scan spacing = 200 μm, scan passes = 20, scan speed = 150 mm/s, and PDMS∶Cu = 2∶1. Under these conditions, the fabricated superhydrophobic surface (SHS-Cu) exhibited a hierarchical micro/nanostructure comprising coral-reef-like micro-scale skeletons decorated with nano-scale flocculent features. The static water contact angle (WCA) reached 158.4° and the sliding angle (WSA) was as low as 6°.
Mechanical stability was evaluated by sandpaper abrasion (800# grit, 90 g load, up to 60 cycles) and sand impact (30 g sand from 40 cm height, cumulative up to 240 g). After 45 abrasion cycles, WCA remained 149°. After 60 cycles, it was still 146.6°. After 240 g sand impact, WCA remained 147.7° with a WSA of 18.5°. Thermal stability tests showed that after heat treatment at 300 ℃ for 12 h, WCA stayed above 151.8° and WSA below 9°. In a continuous steam environment, the surface maintained superhydrophobicity (WCA >151.4°, WSA <9°) for over 9 h. After 12 h of steam exposure, WCA dropped to 124.2° and WSA increased to 78.8°, but a subsequent heat treatment at 100 ℃ for 2 h fully restored the superhydrophobic performance.
Condensation heat transfer performance was evaluated with a custom-built experimental system over a subcooling range of ΔT = 1-10 K. At ΔT = 1 K and the pure PDMS-coated surface achieved a heat transfer coefficient 2.12 times that of the smooth copper plate (OS-Cu), confirming the benefit of dropwise condensation. Remarkably, the composite coating with PDMS∶Cu = 2∶1 attained an HTC 5.85 times that of OS-Cu and 2.76 times that of the pure PDMS coating at ΔT = 1 K. This enhancement was attributed to the continuous three-dimensional thermal conductive network formed by copper powder within the PDMS matrix, which effectively reduced interfacial thermal resistance according to the Maxwell-Garnett effective medium model. As subcooling increased, the enhancement factor gradually decreased toward unity, consistent with classical dropwise condensation theory.
In conclusion, the one-step laser ablation of a PDMS/copper powder mixture successfully produces a superhydrophobic copper surface with exceptional mechanical durability, thermal stability, and condensation heat transfer performance. The synergistic mechanism involves: (1) the copper network providing efficient phonon transport to lower thermal resistance, and (2) the laser-induced hierarchical structure trapping air, minimizing solid-liquid contact, and protecting the low-surface-energy components. This fluorine-free, scalable approach offers a promising solution for high-performance condensation heat transfer in power generation, water harvesting, and electronics thermal management.
关键词
激光固化 /
PDMS/铜粉 /
超疏水表面 /
耐磨 /
高效冷凝
Key words
laser curing /
PDMS/Cu powder /
superhydrophobic surface /
wear-resistant /
high-efficiency condensation
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基金
国家自然科学基金资助项目(12272153); 江苏理工学院实践创新计划(XSJCX22_64)
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