Hydrophobic recovery of femtosecond laser processed silicone rubber insulator surfaces

Chen, Lie; Nie, Qilu; Hu, Tao; Bennett, Peter; Zhou, Zheng; Yang, Qibiao; Liu, Dun

doi:10.1002/app.50835

Cited by 6 publications

(2 citation statements)

References 34 publications

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“…It is well known that the rough structure has a significant effect on the wetting per formance of the coating [43,44]. The measurements for the apparent contact and sliding angles of the coatings are shown in Figure 3.…”

Section: Wettabilitymentioning

confidence: 99%

Superhydrophobic Epoxy/Fluorosilicone/PTFE Coatings Prepared by One-Step Spraying for Enhanced Anti-Icing Performance

Fan

Yan

et al. 2023

Coatings

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The icing of glass insulators is likely to cause faults such as insulator flashover, which poses a serious threat to the power system. Traditional deicing techniques have the disadvantage of being costly and inefficient. Herein, polytetrafluoroethylenes (PTFEs) as nanoparticles and epoxy and fluorosilicone resins as binders were blended to construct an anti-icing coating. The superhydrophobic (SHP) epoxy/fluorosilicone/PTFE coatings for anti-icing were successfully prepared on glass slides through one-step spraying. The effect of PTFE mass fraction on the microstructure, on the wettability and on the anti-icing properties of the coatings was investigated. The results showed that the coatings with different PTFE mass fractions had different microstructures. When the PTFE mass fraction was 47.2%, the SHP coating exhibited a uniform rough structure with an apparent contact angle as high as 164.7° and a sliding angle as low as 3.2°. Moreover, the water droplets can bounce back five times with a contact time of only 9.5 ms and a rebound height of 4.58 mm. In the low-temperature environment (−10 °C), the SHP coating displayed good anti-frosting, anti-icing and icephobic properties. The delayed frosting time (1499 s) and delayed freezing time (1295.3 s) of the SHP coating were three and five times longer than those of the glass, respectively. The SHP coating presented an ice-adhesion strength (39.8 kPa) that was six times lower than that of glass. The prepared SHP coating demonstrated potential applications for the anti-icing of glass insulators.

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Section: Wettabilitymentioning

confidence: 99%

Superhydrophobic Epoxy/Fluorosilicone/PTFE Coatings Prepared by One-Step Spraying for Enhanced Anti-Icing Performance

Fan

Yan

et al. 2023

Coatings

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show abstract

“…From the perspective of wettability modification of the background surface and preparation of the SHPi grooves, laser processing is a feasible and effective surface technology [22]. It has been successfully applied to various materials for different applications, such as titanium [23], silicone rubber [24,25], and zirconia ceramics [26]. In particular, rapid antigravity transport of water could be realized in the parallel Vshaped microgroove arrays prepared with a femtosecond laser [27].…”

Section: Introductionmentioning

confidence: 99%

Capillary performance of vertically grooved wicks on laser-processed aluminum surfaces with different wettability

Chen

Bennett

et al. 2023

J. Phys. D: Appl. Phys.

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Ultra-thin heat pipes have been widely used for thermal management of electronic components. The capillary performance of the wicking structure is an essential factor that affects its heat transfer capability. In this study, superhydrophilic and superhydrophobic background surfaces were prepared on aluminum sheets using a nanosecond fiber laser. Superhydrophilic grooves with a width of 0.1-0.4 mm were fabricated on surfaces with different wettability by laser processing. The effects of the background wettability on the capillary performance of the grooves were investigated. When the groove widths were 0.1-0.2 mm, the water in the groove rose the fastest on the superhydrophobic background surface. As the groove width increased to 0.3-0.4 mm, the water in the groove on the superhydrophilic surface rose the most rapidly. Furthermore, the water absorption of grooves with the same width on the superhydrophilic background surface was always greater than that of the grooves on the other two surfaces. Therefore, a matching wettable background surface should be selected according to application requirements. A superhydrophobic background surface can be chosen when a faster rise in the speed of the water in the groove is preferred. In contrast, a superhydrophilic background surface is beneficial for improving the water absorption capacity. The water absorption of the groove on the superhydrophilic background surface reaches a maximum of 6.8 mg with a groove width of 0.4 mm, and the capillary performance parameters can reach 4.26e-7 N, which is 100.9 % enhanced over the pristine background surface. Thus, this study provides new ideas for improving the capillary performance of vertically grooved wicks.

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Failure analysis of in-service aged 11 kV silicone rubber composite insulators

Shanmugam,

Noor,

Karakkad

2024

Electr Eng

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Hydrophobic recovery of femtosecond laser processed silicone rubber insulator surfaces

Cited by 6 publications

References 34 publications

Superhydrophobic Epoxy/Fluorosilicone/PTFE Coatings Prepared by One-Step Spraying for Enhanced Anti-Icing Performance

Superhydrophobic Epoxy/Fluorosilicone/PTFE Coatings Prepared by One-Step Spraying for Enhanced Anti-Icing Performance

Capillary performance of vertically grooved wicks on laser-processed aluminum surfaces with different wettability

Failure analysis of in-service aged 11 kV silicone rubber composite insulators

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