期刊论文详细信息
Micro & nano letters
Aluminium alloy processed by square-column composite structure and its anti-icing characteristics
article
Yanling Wan1  Meng Zhang1  Bin Dong1  Huadong Yu1 
[1] National and Local Joint Engineering Laboratory for Precision Manufacturing and Measurement Techniques, Changchun University of Science and Technology
关键词: hydrophobicity;    nanofabrication;    aluminium alloys;    heat transfer;    wetting;    ice;    electrical discharge machining;    drops;    friction;    melting;    aluminium;    contact angle;    nanocomposites;    freezing;    contact area;    aluminium substrate;    contact angle;    icing experiment;    anti-icing performance;    out-of-phase icing time;    water droplets;    anti-icing effect;    superhydrophobic surface;    excellent anti-icing properties;    ice core formation;    sample surface;    icing-melting experiments;    stable wettability;    aluminium alloy;    square-column composite structure;    anti-icing characteristics;    stable anti-icing properties;    wire-cut electrical discharge machining;    air cushion effect;   
DOI  :  10.1049/mnl.2019.0171
学科分类:计算机科学(综合)
来源: Wiley
PDF
【 摘 要 】

To prepare surfaces with stable anti-icing properties, square-column micro/nanocomposite structures were fabricated using wire-cut electrical discharge machining. Smooth and hydrophobic/superhydrophobic surfaces were tested for wettability and were subjected to mechanistic analysis. Droplets were found to produce an ‘air cushion effect’ upon contact with the microstructure, which reduced the contact area between the droplets and the aluminium substrate and increased the contact angle of the droplets on the surface. The icing experiment quantitatively evaluated the anti-icing performance of the surfaces by observing the cooling time and out-of-phase icing time of water droplets. It was found that the anti-icing effect is influenced by the wettability of the material and that the superhydrophobic surface has excellent anti-icing properties. Combined with the one-dimensional heat transfer theory for analysing the mechanism of icing, the results show that the ‘air cushion’ reduces the heat transfer between the solid and liquid and increases the thermodynamic barrier to ice core formation. The stability of the sample surface was tested by icing-melting experiments and friction experiments, and the test piece exhibited stable wettability and anti-icing performance.

【 授权许可】

CC BY|CC BY-ND|CC BY-NC|CC BY-NC-ND   

【 预 览 】
附件列表
Files Size Format View
RO202107100002543ZK.pdf 842KB PDF download
  文献评价指标  
  下载次数:6次 浏览次数:2次