表面声波驱动超声技术的流体独立流动测定

Andreas Hefele;Christoph Strobl;Erik Baigar;Georg Kurzmaier;Alexander Reiner;Andreas L. Hörner;Achim Wixforth
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引用次数: 0

摘要

提出了一种在超高压液相色谱(UHPLC)系统的恶劣环境下进行微通道流量测定的不依赖流体的超声方法。流体中的超声波是由瑞利波型分离介质表面声波激发的。LiNbO3 SAW芯片配备了用于SAW激励的交叉换能器,也标记了流体通道的底部,从而允许非常有效的SAW与流体耦合。通道顶板作为纵向超声波在流体中传播的声学反射镜。为了从反射后的超声波传输中推断流体流动,我们采用了双端口矢量网络分析仪的时差相位和飞行时间测量相结合的方法。为了验证和分配我们的实验结果,我们使用了一种适应的时间显式有限元方法。在仿真中,同时考虑压电单晶和流体,通过求解线性Navier-Stokes方程来计算背景流。通过改变超声波传播方向,我们能够以非常高的精度推断出流体体积流量随时间的变化,而不依赖于通道中的实际液体。
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Fluid Independent Flow Determination by Surface Acoustic Wave Driven Ultrasonic Techniques
A fluid-independent ultrasonic approach for flow determination in microchannels in the harsh environment of an ultra high pressure liquid chromatography (UHPLC) system is presented. Ultrasonic waves in the fluid are excited by separate media surface acoustic waves (SAW) of Rayleigh-Wave type. The LiNbO3 SAW chip being equipped with interdigitated transducers for SAW excitation also marks the bottom of the fluid channel and thus allows for very effective SAW coupling to the fluid. The channel ceiling acts as an acoustical mirror for longitudinal ultrasonic waves propagating through the fluid. To deduce the fluid flow from the ultrasonic transmission after reflection, we employ a combination of time differential phase and time of flight measurements with a two port vector network analyzer. To verify and assign our experimental results, we use an adapted time explicit finite element method. In the simulation, both the piezoelectric single crystal and the fluid are included and we solve the linear Navier-Stokes equation to evaluate the background flow. By changing the ultrasonic propagation direction, we are able to deduce the fluid volume flow over time with very high accuracy, independent of the actual liquid in the channel.
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