江华阳, 吴楠, 吕家杰, 刘钧, 尹昌平, 高世涛. 低冰粘附强度表面设计与制备研究进展[J]. 工程科学学报, 2021, 43(10): 1413-1424. DOI: 10.13374/j.issn2095-9389.2021.01.14.008
引用本文: 江华阳, 吴楠, 吕家杰, 刘钧, 尹昌平, 高世涛. 低冰粘附强度表面设计与制备研究进展[J]. 工程科学学报, 2021, 43(10): 1413-1424. DOI: 10.13374/j.issn2095-9389.2021.01.14.008
JIANG Hua-yang, WU Nan, LÜ Jia-jie, LIU Jun, YIN Chang-ping, GAO Shi-tao. Research progress on the design principle and preparation of low ice adhesion surface[J]. Chinese Journal of Engineering, 2021, 43(10): 1413-1424. DOI: 10.13374/j.issn2095-9389.2021.01.14.008
Citation: JIANG Hua-yang, WU Nan, LÜ Jia-jie, LIU Jun, YIN Chang-ping, GAO Shi-tao. Research progress on the design principle and preparation of low ice adhesion surface[J]. Chinese Journal of Engineering, 2021, 43(10): 1413-1424. DOI: 10.13374/j.issn2095-9389.2021.01.14.008

低冰粘附强度表面设计与制备研究进展

Research progress on the design principle and preparation of low ice adhesion surface

  • 摘要: 表面结冰给通讯、电力等工业领域带来巨大损失,电加热和喷洒乙二醇等主动除冰方法虽然在一定程度上可以解决上述问题,但在能源、人力、环境方面需付出较高代价。为解决这一问题,低成本、低能耗的被动式防/除冰表面被寄予厚望。防/除冰表面主要分为延长结冰时间的防冰表面和低冰粘附强度的除冰表面。由于实际工况的复杂性,除冰表面比防冰表面更具有可实现性。除冰表面主要与低表面能、界面滑动和裂纹产生相关,低冰粘附强度表面按实现机理可分为化学改性低表面能表面、润滑表面、界面滑动表面和裂纹源表面。本文对不同类型低冰粘附表面的低冰粘附强度产生的原因和表面的制备方法进行总结。同时,对冰粘附强度的测量标准进行了说明和讨论,以解释不同的测试方法对防/除冰性能测试结果造成的差异。

     

    Abstract: Ice accretion on a bare surface causes a serious problem in industries and daily life such as communication, electricity, and transportation. At present, the main de-icing method is active de-icing, which includes mechanical de-icing or electric-thermal de-icing and spraying glycol anti-icing agents. These methods have a high cost of manpower, energy, and environment. In addition, active de-icing is not applicable in many scenarios. To solve this problem, icephobic surfaces are expected to be widely used. Icephobic surfaces can be divided into surfaces that prolong the freezing time and surfaces with low ice adhesion. Anti-icing surfaces, represented by superhydrophobic surfaces, can inhibit a stable formation of ice nucleation from delaying ice formation, which enables the supercooled droplets to rebound from the surface to prevent ice formation. However, under high humidity and high atmospheric pressure, the superhydrophobic surface may lose efficiency due to frosting and other reasons. Compared with anti-icing surfaces, de-icing surfaces are more achievable. Thus, this article mainly explores surfaces with low ice adhesion. Passive de-icing mainly refers to the construction of the ice sparing surface on a bare substrate to reduce the adhesion strength of icing. Compared with active de-icing methods, the passive method has advantages of low energy consumption, low cost, and environmental friendliness. The realization of low ice adhesion is mainly related to low surface energy, interface slippage, and crack initiation. According to the realization mechanism, low ice adhesion surfaces can be divided into low surface energy surfaces, lubricated surfaces, interfacial slippage and low shear modulus surfaces, and crack initiators surfaces. The design principles and mechanism of the de-icing surface are explored and summarized in this article. In addition, to eliminate the doubts about the large variations in the reported ice adhesion strength caused by different measurement methods, the measurement standards of ice adhesion are also analyzed and discussed.

     

/

返回文章
返回