Characteristics and origins of viscoelastic turbulence in a 3-stream contraction-expansion micro-channel
At low Reynolds number (Re < 1), the flow of viscous liquids e.g. water, is laminar. An aqueous solution e.g. water becomes viscoelastic when a small amount of polymer additives (< 1 wt%) is added to it; its flow behavior can become drastically different and turbulent i.e. viscoelastic turbule...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2016
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| Online Access: | https://hdl.handle.net/10356/66041 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | At low Reynolds number (Re < 1), the flow of viscous liquids e.g. water, is laminar.
An aqueous solution e.g. water becomes viscoelastic when a small amount of
polymer additives (< 1 wt%) is added to it; its flow behavior can become drastically
different and turbulent i.e. viscoelastic turbulence. This phenomenon has gained
increasing attention because it violates the conventional school of thought i.e. high-
Re criteria, for creating chaos and disorder in a fluid dynamics system. As the
polymer molecules are invisible, the indirect deduction of molecular behavior via
motion analyses of tracer additives has been adopted as the main investigative
approach in viscoelastic turbulent flows. Based on this approach, reported works
attribute viscoelastic turbulence to the release of elastic energy by the polymer
molecules, which had been extended due to strong velocity gradients in the flow
field. The release of energy occurs over a range of time scales which is dependent
on the characteristic time scales of the molecules and bulk viscoelastic liquid.
Although the reported characteristic time scales vary significantly, their effects on
the structure of the viscoelastic turbulent flow field have not been investigated.
Despite the significant number of investigations based on the conventional
approach, the underlying mechanisms in viscoelastic turbulence remains elusive;
several outstanding questions on viscoelastic flows remain unresolved e.g. the high
Weissenberg number problem, and the drag reduction theory debate. “How do the
polymer molecules change the flow field so drastically when they are only present
in minute amounts?”. This fundamental question has yet to be clearly answered.
Although fluorescent-tagged DNA molecules are commercially available, because
they are costly and impractical for large-scale dynamic flow field investigations,
their usage has been mostly limited to tracer additives or stress probes.
Here, a viscoelastic turbulent flow field generated by a 3-stream flow through a
contraction-expansion micro-channel was investigated. Based on the conventional
approach i.e. tracer additives, the results show that the generated turbulence exhibits
characteristics of 2-D turbulent flows, from which information on the molecular and
bulk properties of the viscoelastic liquid could be extracted. In addition, a highspeed
molecular imaging technique was developed to observe the polymer
molecular conformation changes (i.e. extension and relaxation) in a turbulent flow.
The technique is capable of image grabbing speeds of more than 1000 frames per
second. The developed molecular fluorescein tagging technique has a much lower
cost as compared to fluorescein-labeling of DNA, hence making it more feasible for
large scale investigations. With the developed technique, the dynamic molecular
conformation changes could be correlated with the statistical properties of the flow
field obtained based on the conventional approach. |
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