Experiments on liquid flow through non-circular micro-orifices

Stefano Cassineri; Andrea Cioncolini; Liam Smith; Michele Curioni; Fabio Scenini

doi:10.3390/mi11050510

Experiments on liquid flow through non-circular micro-orifices

Stefano Cassineri, Andrea Cioncolini^*, Liam Smith, Michele Curioni, Fabio Scenini

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Microfluidics is an active research area in modern fluid mechanics, with several applications in science and engineering. Despite their importance in microfluidic systems, micro-orifices with non-circular cross-sections have not been extensively investigated. In this study, micro-orifice discharge with single-phase liquid flow was experimentally investigated for seven square and rectangular cross-section micro-orifices with a hydraulic diameter in the range of 326-510 μm. The discharge measurements were carried out in pressurized water (12 MPa) at ambient temperature (298 K) and high temperature (503 K). During the tests, the Reynolds number varied between 5883 and 212,030, significantly extending the range in which data are currently available in the literature on non-circular micro-orifices. The results indicate that the cross-sectional shape of the micro-orifice has little, if any, effect on the hydrodynamic behavior. Thus, existing methods for the prediction of turbulent flow behavior in circular micro-orifices can be used to predict the flow behavior in non-circular micro-orifices, provided that the flow geometry of the non-circular micro-orifice is described using a hydraulic diameter.

Original language	English
Article number	510
Journal	Micromachines
Volume	11
Issue number	5
DOIs	https://doi.org/10.3390/mi11050510
State	Published - 1 May 2020
Externally published	Yes

Keywords

Discharge
Experiment
MEMS
Micro-electro-mechanical system
Micro-fluidics
Micro-orifice
Non-circular
Rectangular
Square
Turbulent flow

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10.3390/mi11050510

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title = "Experiments on liquid flow through non-circular micro-orifices",

abstract = "Microfluidics is an active research area in modern fluid mechanics, with several applications in science and engineering. Despite their importance in microfluidic systems, micro-orifices with non-circular cross-sections have not been extensively investigated. In this study, micro-orifice discharge with single-phase liquid flow was experimentally investigated for seven square and rectangular cross-section micro-orifices with a hydraulic diameter in the range of 326-510 μm. The discharge measurements were carried out in pressurized water (12 MPa) at ambient temperature (298 K) and high temperature (503 K). During the tests, the Reynolds number varied between 5883 and 212,030, significantly extending the range in which data are currently available in the literature on non-circular micro-orifices. The results indicate that the cross-sectional shape of the micro-orifice has little, if any, effect on the hydrodynamic behavior. Thus, existing methods for the prediction of turbulent flow behavior in circular micro-orifices can be used to predict the flow behavior in non-circular micro-orifices, provided that the flow geometry of the non-circular micro-orifice is described using a hydraulic diameter.",

keywords = "Discharge, Experiment, MEMS, Micro-electro-mechanical system, Micro-fluidics, Micro-orifice, Non-circular, Rectangular, Square, Turbulent flow",

author = "Stefano Cassineri and Andrea Cioncolini and Liam Smith and Michele Curioni and Fabio Scenini",

note = "Publisher Copyright: {\textcopyright} 2020 by the authors.",

year = "2020",

month = may,

day = "1",

doi = "10.3390/mi11050510",

language = "英语",

volume = "11",

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T1 - Experiments on liquid flow through non-circular micro-orifices

AU - Cassineri, Stefano

AU - Cioncolini, Andrea

AU - Smith, Liam

AU - Curioni, Michele

AU - Scenini, Fabio

PY - 2020/5/1

Y1 - 2020/5/1

N2 - Microfluidics is an active research area in modern fluid mechanics, with several applications in science and engineering. Despite their importance in microfluidic systems, micro-orifices with non-circular cross-sections have not been extensively investigated. In this study, micro-orifice discharge with single-phase liquid flow was experimentally investigated for seven square and rectangular cross-section micro-orifices with a hydraulic diameter in the range of 326-510 μm. The discharge measurements were carried out in pressurized water (12 MPa) at ambient temperature (298 K) and high temperature (503 K). During the tests, the Reynolds number varied between 5883 and 212,030, significantly extending the range in which data are currently available in the literature on non-circular micro-orifices. The results indicate that the cross-sectional shape of the micro-orifice has little, if any, effect on the hydrodynamic behavior. Thus, existing methods for the prediction of turbulent flow behavior in circular micro-orifices can be used to predict the flow behavior in non-circular micro-orifices, provided that the flow geometry of the non-circular micro-orifice is described using a hydraulic diameter.

AB - Microfluidics is an active research area in modern fluid mechanics, with several applications in science and engineering. Despite their importance in microfluidic systems, micro-orifices with non-circular cross-sections have not been extensively investigated. In this study, micro-orifice discharge with single-phase liquid flow was experimentally investigated for seven square and rectangular cross-section micro-orifices with a hydraulic diameter in the range of 326-510 μm. The discharge measurements were carried out in pressurized water (12 MPa) at ambient temperature (298 K) and high temperature (503 K). During the tests, the Reynolds number varied between 5883 and 212,030, significantly extending the range in which data are currently available in the literature on non-circular micro-orifices. The results indicate that the cross-sectional shape of the micro-orifice has little, if any, effect on the hydrodynamic behavior. Thus, existing methods for the prediction of turbulent flow behavior in circular micro-orifices can be used to predict the flow behavior in non-circular micro-orifices, provided that the flow geometry of the non-circular micro-orifice is described using a hydraulic diameter.

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KW - Experiment

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KW - Micro-electro-mechanical system

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KW - Rectangular

KW - Square

KW - Turbulent flow

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U2 - 10.3390/mi11050510

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VL - 11

JO - Micromachines

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ER -

Experiments on liquid flow through non-circular micro-orifices

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