A thermal-bubble-actuated micronozzle-diffuser pump

IEEE\/ASME Journal of Microelectromechanical Systems Pub Date : 2002-12-16 DOI:10.1109/JMEMS.2002.802909

Jr-Hung Tsai, Liwei Lin

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引用次数: 189

Abstract

A thermal-bubble-actuated micropump by the principles of liquid/vapor phase transition and nozzle-diffuser flow regulation is successfully demonstrated. The micropump consists of a resistive heater, a pair of nozzle-diffuser flow controller and a 1 mm in diameter, 50 /spl mu/m in depth pumping chamber. The actuation mechanism comes from periodically nucleating and collapsing thermal bubbles. A net flow is generated from the nozzle to the diffuser by the nozzle-diffuser flow controller. Two heater designs, single-bubble and dual-bubble actuation mode, have been investigated. In the single-bubble pumping mode, a maximum flow rate of 5 /spl mu/l/min is measured when the driving pulse is 250 Hz at 10% duty cycle under an average power consumption of 1 W. A similar flow rate of 4.5 /spl mu/l/min is achieved in the dual-bubble pumping mode, at the driving pulse of 5% duty cycle at 400 Hz with lower average power consumption, 0.5 W. The static pumping pressure is measured at a maximum value of 377 Pascal when the net volume flow rate is zero. As an application example in a microfluidic device, this valve-less micropump is used in a microfluidic system to enhance the fluid mixing by agitating the flows.

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热气泡驱动的微喷嘴扩散泵

成功地演示了一种基于液/气相变和喷嘴-扩散器流动调节原理的热气泡驱动微泵。该微型泵由一个电阻加热器、一对喷嘴扩散器流量控制器和一个直径为1mm、深度为50 /spl μ m的泵室组成。驱动机制来自周期性的热气泡成核和坍缩。净流由喷嘴-扩散器流量控制器从喷嘴到扩散器产生。研究了单气泡和双气泡驱动两种加热器设计。在单泡泵送模式下，当驱动脉冲为250 Hz，占空比为10%，平均功耗为1w时，测得的最大流量为5 /spl mu/l/min。在5%占空比、400hz的驱动脉冲下，双泡泵送模式的流量为4.5 /spl mu/l/min，平均功耗较低，为0.5 W。当净体积流量为零时，静泵压力的最大值为377帕斯卡。作为微流控装置的应用实例，将该无阀微泵应用于微流控系统中，通过搅拌流体来增强流体的混合。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

$IEEE\/ASME Journal of Microelectromechanical Systems$

IEEE\/ASME Journal of Microelectromechanical Systems

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