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This book presents several new findings in the field of turbulent duct flows, which are important for a range of industrial applications. It presents both high-quality experiments and cutting-edge numerical simulations, providing a level of insight and rigour rarely found in PhD theses.
The scientific advancements concern the effect of the Earth's rotation on large duct flows, the experimental confirmation of marginal turbulence in a pressure-driven square duct flow (previously only predicted in simulations), the identification of similar marginal turbulence in wall-driven flows using simulations (for the first time by any means) and, on a separate but related topic, a comprehensive experimental study on the phenomenon of drag reduction via polymer additives in turbulent duct flows.
In turn, the work on drag reduction resulted in a correlation that provides a quantitative prediction of drag reduction based on a single, measurable material property of the polymer solution, regardless of the flow geometry or concentration. The first correlation of its kind, it represents an important advancement from both a scientific and practical perspective.
List of contents
Introduction.- Literature Review and background theory.- Experimental Methods.- Numerical Methods.- Turbulent Pressure-Driven Flow in a Square Duct at Low Reynolds Numbers.- Turbulent Wall-Driven Flows.- Turbulent Duct Flows with Polymer Additives.- Conclusions and Recommendations.
About the author
Bayode Owolabi is a postdoctoral fellow at the University of Alberta in Canada. He completed a bachelor’s degree in Mechanical Engineering at the Federal University of Technology Akure Nigeria in 2010, after which he was awarded a Commonwealth scholarship for a master’s degree in Energy Generation at the University of Liverpool. In 2015, Bayode was enrolled on the dual PhD programme between the University of Liverpool and National Tsing Hua University Taiwan, and successfully defended his thesis in December 2018. His research interests include wall-bounded turbulent flows, transition to turbulence, polymer drag reduction and rheology.
Summary
This book presents several new findings in the field of turbulent duct flows, which are important for a range of industrial applications. It presents both high-quality experiments and cutting-edge numerical simulations, providing a level of insight and rigour rarely found in PhD theses.
The scientific advancements concern the effect of the Earth’s rotation on large duct flows, the experimental confirmation of marginal turbulence in a pressure-driven square duct flow (previously only predicted in simulations), the identification of similar marginal turbulence in wall-driven flows using simulations (for the first time by any means) and, on a separate but related topic, a comprehensive experimental study on the phenomenon of drag reduction via polymer additives in turbulent duct flows.
In turn, the work on drag reduction resulted in a correlation that provides a quantitative prediction of drag reduction based on a single, measurable material property of the polymer solution, regardless of the flow geometry or concentration. The first correlation of its kind, it represents an important advancement from both a scientific and practical perspective.
