Description
The evolution of single hairpin vortices and multiple interacting hairpin vortices are studied in direct numerical simulations of channel flow at Re-tau=395. The purpose of this study is to observe the effects of increased Reynolds number and varying initial conditions on the growth of hairpins and the conditions under which single hairpins autogenerate hairpin packets. The hairpin vortices are believed to provide a unified picture of wall turbulence and play an important role in the production of Reynolds shear stress which is directly related to turbulent drag. The structures of the initial three-dimensional vortices are extracted from the two-point spatial correlation of the fully turbulent direct numerical simulation of the velocity field by linear stochastic estimation and embedded in a mean flow having the profile of the fully turbulent flow. The Reynolds number of the present simulation is more than twice that of the Re-tau=180 flow from earlier literature and the conditional events used to define the stochastically estimated single vortex initial conditions include a number of new types of events such as quasi-streamwise vorticity and Q4 events. The effects of parameters like strength, asymmetry and position are evaluated and compared with existing results in the literature. This study then attempts to answer questions concerning how vortex mergers produce larger scale structures, a process that may contribute to the growth of length scale with increasing distance from the wall in turbulent wall flows. Multiple vortex interactions are studied in detail.
Details
Title
- Dynamics of vortices in numerically simulated turbulent channel flow
Contributors
- Parthasarathy, Praveen Kumar (Author)
- Adrian, Ronald (Thesis advisor)
- Huang, Huei-Ping (Committee member)
- Herrmann, Marcus (Committee member)
- Arizona State University (Publisher)
Date Created
The date the item was original created (prior to any relationship with the ASU Digital Repositories.)
2011
Subjects
- Mechanical Engineering
- Aerospace Engineering
- Physics
- Channel flow
- coherent structures
- Computational Fluid Dynamics
- Fluid Mechanics
- Hairpin vortices
- Turbulence
- Computational Fluid Dynamics
- Turbulence--Mathematical models.
- Boundary layer--Mathematical models.
- Boundary Layer
- Vortex-motion--Mathematical models.
- Vortex-motion
Resource Type
Collections this item is in
Note
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thesisPartial requirement for: M.S., Arizona State University, 2011
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bibliographyIncludes bibliographical references (p. 57-59)
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Field of study: Mechanical engineering
Citation and reuse
Statement of Responsibility
by Praveen Kumar Parthasarathy