EDL效应下微通道的旁路转换

S. Tardu
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引用次数: 0

摘要

通过直接数值模拟,探讨了双电层(EDL)对线性演化阶段旁通过渡机理的影响。在泊泽维尔流和EDL流中引入了由一对反向旋转涡组成的初始扰动速度场,并在临界雷诺数的一半(泊泽维尔为3000,EDL为300)下短时间内分析了扰动场的时空演化。在宏观和微观流动中,壁面法向和展向摄动速度的发展在数量和质量上都是相似的。通过壁面法向涡量的产生,初始为零的流向速度在EDL作用下增大了两倍。两种气流都形成倾斜的强顺流剪切层。总的来说,扰动演化的相似性表明,EDL流中的三维线性机制导致的结构至少与泊泽维尔流中的结构一样强。
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By-Pass Transition in Microchannels under EDL Effect
The effect of the electric double layer (EDL) on the bypass transition mechanism in the linear evolution stage is explored through direct numerical simulations. An initial perturbation velocity field consisting of a pair of counter-rotating vortices is introduced in Poiseuille and EDL flows and the time-space evolution of the perturbed field is analysed for short times at half the critical Reynolds numbers (3000 for Poiseuille and 300 for EDL). The wall normal and spanwise perturbation velocities development are both quantitatively and qualitatively similar in macro and micro flows. The streamwise velocity, which is initially zero and set up by the generation of the wall normal vorticity is twice larger under the EDL effect. Both flows develop inclined strong streamwise shear layers. Overall is the close similarity of the disturbance evolution showing that the three dimensional linear mechanism in EDL flow lead to the structures that are at least as strong as in Poiseuille flow.
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