Wind turbine blades are often covered with ice and snow,
which
inevitably reduces their power generation efficiency and lifetime.
Recently, a superhydrophobic surface has attracted widespread attention
due to its potential values in anti-icing/deicing. However, the superhydrophobic
surface can easily transition from Cassie–Baxter to Wenzel
at low temperature, limiting its wide applications. Herein, inspired
by the excellent water resistance and cold tolerance of Trifolium repens L. endowed by its micronano structure
and low surface energy, a fresh structure was prepared by combining
femtosecond laser processing technology and a boiling water treatment
method. The prepared icephobic surface aluminum alloy (ISAl) mainly
consists of a periodic microcrater array, nonuniform microclusters,
and irregular nanosheets. This three-scale structure greatly promotes
the stability of the Cassie–Baxter state. The critical Laplace
pressure of ISAl is up to 1437 Pa, and the apparent water contact
angle (CA) is higher than 150° at 0 °C. Those two factors
contribute to its excellent anti-icing and deicing performances. The
results show that the static icing delay time reaches 2577 s, and
the ice adhesion strength is only 1.60 kPa. Furthermore, the anti-icing
and deicing abilities of the proposed ISAl were examined under the
environment of low temperature and high relative humidity to demonstrate
its effectiveness. The dynamic anti-icing time of ISAl in extreme
environments is up to 5 h, and ice can quickly fall with a speed of
34 r/min when it is in a horizontal rotational motion. Finally, ISAl
has excellent reusability and mechanical durability, with the ice
adhesion strength still being less than 6 kPa and the CA greater than
150° after 15 cycles of icing–deicing tests. The proposed
structure would offer a promising strategy for the efficient anti-icing
and deicing of wind turbine blades.