微通道中焦耳加热诱导输运的浮力驱动流和电热流的竞争效应

IF 2.8 Q2 MECHANICS
Mohammad K. D. Manshadi, A. Beskok
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引用次数: 0

摘要

受到外加电场作用的离子流体经历焦耳加热,焦耳加热随电场和介质离子电导率的增加而增加。焦耳加热引起的温度梯度可以产生由局部密度变化产生的浮力驱动的流动,以及由于流体介电常数和电导率的温度依赖性变化而产生的电热传输。本文研究了在交流电场作用下一对电极在微通道中的焦耳热致输运。由此产生的浮力驱动和交流电热(ACET)流动进行了理论、数值和实验研究。对控制方程进行适当的归一化,得到了电热速度和浮力速度的比值,作为一个新的无量纲参数,这使得构建相图能够预测ACET和浮力驱动流动的主导地位,并将其作为通道大小和电场的函数。利用数值结果验证了不同离子电导率流体和电场下不同高度微通道的相图,并利用微粒子图像测速技术对数值结果进行了验证。结果表明,当通道尺寸小、电势高时,ACET流动占优势,而当通道高度较大时,浮力驱动流动占优势。本研究对微流控装置中焦耳热致输运现象进行了深入的研究,并为合理考虑共同发生的浮力驱动流动的乙酰乙酯基装置的设计和利用提供了途径。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Competing effects of buoyancy-driven and electrothermal flows for Joule heating-induced transport in microchannels
Abstract Ionic fluids subjected to externally applied electric fields experience Joule heating, which increases with the increased electric field and ionic conductivity of the medium. Temperature gradients induced by Joule heating can create buoyancy-driven flows produced by local density changes, as well as electrothermal transport due to the temperature-dependent variations in fluid permittivity and conductivity. This manuscript considers Joule heating-induced transport in microchannels by a pair of electrodes under alternating current electric fields. Resulting buoyancy-driven and alternating current electrothermal (ACET) flows are investigated theoretically, numerically and experimentally. Proper normalizations of the governing equations led to the ratio of the electrothermal and buoyancy velocities, as a new non-dimensional parameter, which enabled the construction of a phase diagram that can predict the dominance of ACET and buoyancy-driven flows as a function of the channel size and electric field. Numerical results were used to verify the phase diagram in various height microchannels for different ionic conductivity fluids and electric fields, while the numerical results were validated using the micro-particle-image velocimetry technique. The results show that ACET flow prevails when the channel dimensions are small, and the electric potentials are high, whereas buoyancy-driven flow becomes dominant for larger channel heights. The present study brings insights into Joule heating-induced transport phenomena in microfluidic devices and provides a pathway for the design and utilization of ACET-based devices by properly considering the co-occurring buoyancy-driven flow.
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CiteScore
2.40
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