Characterization of bi-directionally oscillating dynamic flow and frequency-dependent rectification performance of microdiffusers

Young-Ho Lee, T. Kang, Young‐Ho Cho
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引用次数: 3

Abstract

This paper characterizes a bi-directionally oscillating dynamic flow in a planar microdiffuser in order to evaluate the flow rectification performance of the microdiffuser. In the theoretical study, we present a bidirectionally oscillating flow model, where the boundary layer thickness governs the flow rectification performance of the microdiffuser. In the experimental study, we fabricate two different microdiffuser prototypes, having the neck widths of 100 /spl mu/m (D100) and 300 /spl mu/m (D300), respectively. The prototypes, D100 and D300, show the maximum net flow rates of 116.6 /spl mu/l/min and 344.4 /spl mu/l/min, respectively, for an identical piezoelectric flow actuation using the sinusoidal drive voltage of 100 V p-p at 50 Hz. The flow rates measured from D100 and D300 are approximately 47% of the theoretical values estimated from the conventional unidirectional flow model for the net boundary layer thicker than the neck width. The experimental flow rate of D300, however, decreases from 47% of the theoretical values at the flow frequencies higher than 90 Hz, at which the net boundary layer thickness is reduced to the microdiffuser neck width. It is experimentally verified that the flow rectification performance and the net flow rate of the microdiffuser tend to decrease when the boundary layer thickness is smaller than the diffuser neck width.
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微扩散器双向振荡动态流动特性及频率相关整流性能
本文对平面微扩散器内的双向振荡动态流动进行了表征,以评价微扩散器的整流性能。在理论研究中,我们提出了一个双向振荡流动模型,其中边界层厚度决定了微扩散器的流动整流性能。在实验研究中,我们制作了两种不同的微扩散器原型,其颈宽分别为100 /spl mu/m (D100)和300 /spl mu/m (D300)。原型D100和D300显示,在50 Hz下使用100 V p-p的正弦驱动电压进行相同的压电流驱动时,最大净流量分别为116.6 /spl mu/l/min和344.4 /spl mu/l/min。从D100和D300测得的流量约为传统单向流动模型估算的净边界层厚度大于颈宽的理论值的47%。而当流动频率高于90 Hz时,D300的实验流速从理论值的47%下降,此时净边界层厚度减小到微扩散器颈部宽度。实验证明,当边界层厚度小于扩散器颈宽时,微扩散器的整流性能和净流量有减小的趋势。
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