不同润湿性航空发动机旋转纺丝器上回流水流特性的实验研究

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Kuiyuan Ma, Guiping Lin, Haichuan Jin, Xiaobin Shen, Xueqin Bu
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引用次数: 0

摘要

航空发动机进气口上的积冰会影响发动机的安全。传统的热风防冰系统利用放出的空气,需要消耗大量能源,从而降低发动机性能并增加排放。超疏水材料在与这些系统结合使用时,已显示出降低能耗的潜力。研究表明,固定部件上的超疏水表面可通过改变回流水的流动行为,显著降低防冰能耗。然而,对于旋转的航空发动机部件,由于离心力和科里奥利力的影响,超疏水表面的效果以及表面润湿性对回流水流的影响仍不清楚。本研究在直流喷雾风洞中对具有不同润湿性的航空发动机旋转旋翼表面的回流水流行为进行了研究。结果表明,与静止表面相比,离心力减少了旋转旋翼上的回流水量,形成了与旋转方向相反的溪流。此外,润湿性对旋转表面上的回流水的流动特性有很大影响。随着接触角的增大,旋转旋转器上的液态水会从连续的薄膜流动过渡到溪流和珠状流动。值得注意的是,超疏水表面可防止水的附着,这表明它具有在旋转部件上防冰的潜力。此外,旋转速度和表面润湿性之间的相互作用增强了效果,旋转速度的增加和接触角的增大都有助于提高液态水的流动速度,从而促进溪流和珠状水流的快速形成和脱离。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Experimental Investigation of Runback Water Flow Behavior on Aero-Engine Rotating Spinners with Different Wettabilities
The accumulation of ice on the aero-engine inlet compromises engine safety. Traditional hot air anti-icing systems, which utilize bleed air, require substantial energy, decreasing engine performance and increasing emissions. Superhydrophobic materials have shown potential in reducing energy consumption when combined with these systems. Research indicates that superhydrophobic surfaces on stationary components significantly reduce anti-icing energy consumption by altering runback water flow behavior. However, for rotating aero-engine components, the effectiveness of superhydrophobic surfaces and the influence of surface wettability on runback water flow remain unclear due to centrifugal and Coriolis forces. This study investigates the runback water flow behavior on aero-engine rotating spinner surfaces with varying wettabilities in a straight-flow spray wind tunnel. The results demonstrated that centrifugal force reduces the amount of runback water on the rotating spinner compared to the stationary surface, forming rivulet flows deflected opposite to the direction of rotation. Furthermore, wettability significantly affects the flow characteristics of runback water on rotating surfaces. As the contact angle increases, the liquid water on the rotating spinner transitions from continuous film flow to rivulet and bead-like flows. Notably, the superhydrophobic surface prevents water adhesion, indicating its potential for anti-icing on rotating components. In addition, the interaction between rotational speed and surface wettability enhances the effects, with both increased rotational speed and larger contact angles contributing to higher liquid water flow velocities, promoting the rapid formation and detachment of rivulet and bead-like flows.
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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