MULTISCALING ANALYSIS OF FLUIDIC SYSTEMS: MIXING AND MICROSTRUCTURE CHARACTERIZATION

MULTISCALING ANALYSIS OF FLUIDIC SYSTEMS: MIXING AND MICROSTRUCTURE CHARACTERIZATION

Bibliographic Details
Main Author: Camesasca, Marco
Language:English
Published: Case Western Reserve University School of Graduate Studies / OhioLINK 2006
Subjects:
Mixing
Polymer Processing Operations
Microchannels and Micromixers
Chaotic Advection
Chaos and Fluid Dynamics
R&233
nyi and Shannon Entropy
Information and Statistical Entropy
Fractal Dimensions
Generalized Dimensions
Online Access:http://rave.ohiolink.edu/etdc/view?acc_num=case1144350255
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spelling ndltd-OhioLink-oai-etd.ohiolink.edu-case11443502552021-08-03T05:31:59Z MULTISCALING ANALYSIS OF FLUIDIC SYSTEMS: MIXING AND MICROSTRUCTURE CHARACTERIZATION Camesasca, Marco Mixing Polymer Processing Operations Microchannels and Micromixers Chaotic Advection Chaos and Fluid Dynamics R&233 nyi and Shannon Entropy Information and Statistical Entropy Fractal Dimensions Generalized Dimensions Fluidic Systems are present in a variety of fields and applications and multiscaling analysis is an important tool both at the macroscopic scale for the optimization of industrial processes, such as mixing colorants in a polymer matrix or mixing of gases in an engine, as well as at the microscopic level when dealing with microfluidics such as micro-reactors and micro-mixers. In this thesis a multiscaling approach to the analysis of the efficiency of mixing of fluidic systems for multi-component flows is developed and a microstructure characterization based on the concept of multi-fractal behavior is introduced. Generically, mixing is a unit operation that involves manipulating a heterogeneous physical system with the intent to make it more homogeneous. The concept of entropy as the measure of the level of homogeneity of a system is applied and various ways to employ the entropy to characterize the state of mixing in a multi-component system at different scale of observations are explored. Computer simulations of fluidic systems are employed to trace the motion of passive tracers used to visualize the behavior of the fluids and to evaluate the overall mixing efficiency. First the quality of such approach on commonly known systems, such as extruder devices and microchannels, is verified then the use of chaotic advection as a tool to increase mixing efficiency is introduced. To create a time dependence of the flow field, necessary to induce chaotic behavior, a non periodic patterning of one of the walls of the systems is proposed, such that the three components of the velocity field are coupled. The behavior of those chaotic systems is shown to generate interfaces with fractal structures. Since fractal and multi-fractal characteristics can be of great interest in relation with the material properties of the final compound a quantification of this multiscale property is done by calculating the generalized fractal dimensions. There is a certain correspondence between mixing systems and fractal behavior and it is shown that in the case of mixing fluids distinguished only by color, better mixers generate structures with higher fractal dimensions. 2006-04-07 English text Case Western Reserve University School of Graduate Studies / OhioLINK http://rave.ohiolink.edu/etdc/view?acc_num=case1144350255 http://rave.ohiolink.edu/etdc/view?acc_num=case1144350255 unrestricted This thesis or dissertation is protected by copyright: all rights reserved. It may not be copied or redistributed beyond the terms of applicable copyright laws.
collection NDLTD
language English
sources NDLTD
topic Mixing
Polymer Processing Operations
Microchannels and Micromixers
Chaotic Advection
Chaos and Fluid Dynamics
R&233
nyi and Shannon Entropy
Information and Statistical Entropy
Fractal Dimensions
Generalized Dimensions
spellingShingle Mixing
Polymer Processing Operations
Microchannels and Micromixers
Chaotic Advection
Chaos and Fluid Dynamics
R&233
nyi and Shannon Entropy
Information and Statistical Entropy
Fractal Dimensions
Generalized Dimensions
Camesasca, Marco
MULTISCALING ANALYSIS OF FLUIDIC SYSTEMS: MIXING AND MICROSTRUCTURE CHARACTERIZATION
author Camesasca, Marco
author_facet Camesasca, Marco
author_sort Camesasca, Marco
title MULTISCALING ANALYSIS OF FLUIDIC SYSTEMS: MIXING AND MICROSTRUCTURE CHARACTERIZATION
title_short MULTISCALING ANALYSIS OF FLUIDIC SYSTEMS: MIXING AND MICROSTRUCTURE CHARACTERIZATION
title_full MULTISCALING ANALYSIS OF FLUIDIC SYSTEMS: MIXING AND MICROSTRUCTURE CHARACTERIZATION
title_fullStr MULTISCALING ANALYSIS OF FLUIDIC SYSTEMS: MIXING AND MICROSTRUCTURE CHARACTERIZATION
title_full_unstemmed MULTISCALING ANALYSIS OF FLUIDIC SYSTEMS: MIXING AND MICROSTRUCTURE CHARACTERIZATION
title_sort multiscaling analysis of fluidic systems: mixing and microstructure characterization
publisher Case Western Reserve University School of Graduate Studies / OhioLINK
publishDate 2006
url http://rave.ohiolink.edu/etdc/view?acc_num=case1144350255
work_keys_str_mv AT camesascamarco multiscalinganalysisoffluidicsystemsmixingandmicrostructurecharacterization
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