Title :
Electrolytic-Bubble-Based Flow Sensor for Microfluidic Systems
Author :
Wang, Jianbin ; Sullivan, Matthew ; Hua, Susan Z.
Author_Institution :
State Univ. of New York, Buffalo
Abstract :
Accurate measurement and control of flow properties are essential for microfluidic lab-chips. In this paper, we demonstrate an electrolytic-bubble-based approach to directly measure flow rate in microfluidic arteries. By simultaneously generating two gas bubbles electrochemically along a channel, we can measure the pressure difference (and thus flow rate) in real time. A prototype chip that measures flow rate was fabricated on silicon. The sensor was characterized for a functional microfluidic system with inlet pressure ranging from 108 to 135 kPa. The flow-meter performance was compared with computational fluid dynamics simulations and was also calibrated against other direct experiments. The impedance-based flow-rate measurements are easily achieved on a chip with a simple electronic circuit. The described approach can be integrated into any fluid circuit, particularly microfluidic channels that are too small to use off-shelf flow meters.
Keywords :
bubbles; computational fluid dynamics; electrolytic devices; flow measurement; flow sensors; flowmeters; lab-on-a-chip; microchannel flow; computational fluid dynamics; electrolytic bubble; flow property control; flow rate measurement; flow sensor; flowmeter; fluid circuit; gas bubbles; microfluidic arteries; microfluidic channels; microfluidic lab-chips; microfluidic systems; pressure 108 kPa to 135 kPa; simple electronic circuit; Arteries; Computational fluid dynamics; Fluid flow measurement; Microfluidics; Pressure measurement; Prototypes; Semiconductor device measurement; Sensor phenomena and characterization; Sensor systems; Silicon; Bubbles; impedance measurement; microelectromechanical devices; microsensors;
Journal_Title :
Microelectromechanical Systems, Journal of
DOI :
10.1109/JMEMS.2007.906078
