Electrokinetic Maneuvering of Bubble-Driven Inertial Micro-Pumping Systems

International journal of micro-nano scale transport Pub Date : 2014-09-05 DOI:10.1260/1759-3093.5.1.13

A. Bandopadhyay, U. Ghosh, D. Pal, K. Chaudhury, S. Chakraborty

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引用次数: 2

Abstract

The pumping of an aqueous electrolyte by means of an asymmetrically placed thermal resistor and electrodes is investigated in this work. This device has no moving parts and provides a continuous and controllable pulsating flow, which make it a very attractive and viable option for use on lab-on-a-chip devices. The electric field induced modulation provides a higher degree of control on the mass flow rate, by means of which one can achieve on-the-fly mass flow rate control. The pumping action is achieved by means of a high-pressure bubble generated by actuating a thermal resistor which is located asymmetrically between two reservoirs. The ends of the channel are connected to fluidic columns. The combined action of an applied electric field and a faster refilling of the shorter arm after bubble collapse essentially drive a net amount of electrolyte through the system. We study the influence of the geometric parameters like the location of the heater, channel width and the channel length apart from the physiochemical parameters like the Debye length and the applied field strength on the mass flow rate achieved through this device.

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气泡驱动惯性微泵系统的电动操纵

本文研究了用不对称放置的热敏电阻和电极泵送水电解质的方法。该设备没有移动部件，并提供连续可控的脉动流，这使其成为芯片实验室设备上非常有吸引力和可行的选择。电场感应调制提供了更高程度的质量流量控制，通过它可以实现对质量流量的实时控制。泵送作用是通过驱动位于两个储层之间不对称的热敏电阻产生高压气泡来实现的。通道的两端连接到流控柱。外加电场和短臂在气泡破裂后更快的再填充的共同作用，本质上驱动了系统中电解质的净量。研究了除德拜长度、外加场强等理化参数外，加热器位置、通道宽度、通道长度等几何参数对装置质量流量的影响。

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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International journal of micro-nano scale transport

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