A miniaturized fluid oscillator with no movable parts composed by a switching cavity, one inlet, two outlets and two feedback channels was studied. Examples of these devices have been built before and had shown oscillation of fluid flows ranging from tens of Hz for liquids to thousand of Hz for gases. The present work consists of a study of the flow within the device by means of a computer model. The computer model was built using COMSOL 3.3. It uses conventional Navier-Stokes equations numerically solved by Finite Element Methods. A new level of detail of the qualitative description of the flow within the device is achieved which allows for a better understanding of why some geometries produce better devices than others. It shows that homogeneous oscillation, not only depend on the direct force exerted by the feedback flow on the inlet stream, but also on the disruption of the Coanda's effect that diverts the stream towards one of the output channels. On the other hand, the quantitative part of the study serves to validate the simulation as well as a basis for proposing new empirical models. The quantitative measurements are consistent with a previously known mathematical model that describes the relation between frequency, input velocity and geometrical and physical properties. Ongoing testing with actual devices also supports the proposed operating mechanisms and models.
[1]
James W. Gregory,et al.
Characterization of a Micro Fluidic Oscillator for Flow Control
,
2004
.
[2]
Rogerio Furlan,et al.
Numerical Analysis of a Microfluidic Oscillator Flowmeter Operating with Gases or Liquids
,
2002
.
[3]
Martin Golubitsky,et al.
Order in Disorder. (Book Reviews: Symmetry in Chaos. A Search for Pattern in Mathematics, Art and Nature.)
,
1993
.
[4]
R. Furlan,et al.
Visualization of internal liquid flow interactions in meso planar structures
,
2006
.
[5]
H. Hein,et al.
Numerical investigation of fluidic micro-oscillators
,
1996
.
[6]
Microfluidic oscillator for gas flow control and measurement
,
2005
.