Startseite Technik Cavitation in Negative-pressure Microcapillary Devices with Tapered Constrictions: Experiment and Numerical Simulation
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Cavitation in Negative-pressure Microcapillary Devices with Tapered Constrictions: Experiment and Numerical Simulation

  • Xing Yang , Jiang Li EMAIL logo und Haosheng Chen EMAIL logo
Veröffentlicht/Copyright: 22. September 2012
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International Journal of Nonlinear Sciences and Numerical Simulation
Aus der Zeitschrift International Journal of Nonlinear Sciences and Numerical Simulation Band 13 Heft 5

Abstract

Microcapillary devices with tapered constrictions were fabricated for the study of the features of the cavitation. The cavitation was induced by applying negative pressure at the outlet with opening the inlet to atmospheric pressure, and the experimental results show that the cavitation bubbles generated at the center of the tapered tip flow upstream and adhere on the wall near the orifice, which is explained by the recirculation flow according to the numerical simulation results. The desinent cavitation number keeps constant for a microcapillary device, and the device works in a negative-pressure system is more susceptible to the cavitation than that works in a positive-pressure system. In addition, the effect of the orifice size on the incipient cavitation number and the desinent cavitation number has been studied with five devices with different sizes of the orifices from 50 to 120 microns. Both the incipient and desinent cavitation numbers increase monotonely with the size of the orifice. These results may be helpful to the design of the geometries of the microfluidic devices for various applications.

Keywords: cavitation; microfluidics; computational fluid dynamics (CFD); bubbles
PACS®(2010): 47.35.Pq; 47.55.dp; 47.55.D−
Received: 2011-9-12
Accepted: 2012-3-16
Published Online: 2012-9-22
Published in Print: 2012-9-19

©2012 by De Gruyter

Artikel in diesem Heft

  1. Frontmatter
  3. CD4+ T Cell Counting by Impedance Measurement on a Chip with Fluidic Electrodes
  4. Highly Non-linear Microfluidic Resistor Elements for Flow Rate-dependent Addressing of Microchannels
  5. Microfluidic Preparation of Multicompartment Microcapsules for Isolated Co-encapsulation and Controlled Release of Diverse Components
  6. Joule Heating Effect in Constant Voltage Mode Isotachophoresis in a Microchannel
  7. Cavitation in Negative-pressure Microcapillary Devices with Tapered Constrictions: Experiment and Numerical Simulation
  8. Beating the Jetting Regime
https://doi.org/10.1515/ijnsns-2012-0404
Schlagwörter für diesen Artikel
cavitation; microfluidics; computational fluid dynamics (CFD); bubbles

Artikel in diesem Heft

  1. Frontmatter
  3. CD4+ T Cell Counting by Impedance Measurement on a Chip with Fluidic Electrodes
  4. Highly Non-linear Microfluidic Resistor Elements for Flow Rate-dependent Addressing of Microchannels
  5. Microfluidic Preparation of Multicompartment Microcapsules for Isolated Co-encapsulation and Controlled Release of Diverse Components
  6. Joule Heating Effect in Constant Voltage Mode Isotachophoresis in a Microchannel
  7. Cavitation in Negative-pressure Microcapillary Devices with Tapered Constrictions: Experiment and Numerical Simulation
  8. Beating the Jetting Regime
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