2018
DOI: 10.3390/mi9080375
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Design and Fabrication of a Microfluidic Viscometer Based on Electrofluidic Circuits

Abstract: This paper reports a microfluidic viscometer based on electrofluidic circuits for measuring viscosities of liquid samples. The developed micro-device consists of a polydimethylsiloxane (PDMS) layer for electrofluidic circuits, a thin PDMS membrane, another PDMS layer for sample pretreatment, and a glass substrate. As the sample flows inside the microfluidic channel, its viscosity causes flow resistance and a pressure drop along this channel. This pressure drop, in turn, generates a hydraulic pressure which def… Show more

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Cited by 11 publications
(7 citation statements)
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“…During the experiments in this study, changes in the resistance values of the string-type strain gauges were extremely small and difficult to determine directly. Therefore, a conversion circuit was used to convert the changes in resistance values into voltage signals; the Wheatstone bridge is the most commonly used resistance conversion circuit and one that is the most suitable circuit for measuring small resistance changes [16]. However, commercially available resistors often contain errors.…”
Section: Resultsmentioning
confidence: 99%
“…During the experiments in this study, changes in the resistance values of the string-type strain gauges were extremely small and difficult to determine directly. Therefore, a conversion circuit was used to convert the changes in resistance values into voltage signals; the Wheatstone bridge is the most commonly used resistance conversion circuit and one that is the most suitable circuit for measuring small resistance changes [16]. However, commercially available resistors often contain errors.…”
Section: Resultsmentioning
confidence: 99%
“…The authors noted that on similar viscometers [48,49,50] for Newtonian fluids, errors of 3-10 %, 4-7 %, 5-24 %, respectively, were obtained in comparison with commercial viscometers. Tzeng et al [51] presented another microfluidic viscometer based on electrofluidic circuits. The viscosity of the tested fluid sample is estimated by its flow resistance, which is a function of pressure drop, flow rate, and the geometry of the microfluidic channel.…”
Section: Literature Reviewmentioning
confidence: 99%
“…After performing an accurate calibration, the authors employed their microfluidic rheometer to measure the viscosity values of Newtonian glycerol solutions, as well as non-Newtonian solutions such as whole blood at different temperatures (25 • C and 37 • C), finding good agreement with conventional bulk measurements (Figure 2f). A similar system was also introduced by Tzeng and Sun [24] for the measurement of glycerol-water solutions at different volume concentrations. A portable microfluidic rheometer called Viscopette was introduced by Lee et al [19] (Figure 2g).…”
Section: Micro-electro-mechanical Systems (Mems)mentioning
confidence: 99%