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Flow control through bio-inspired le...

New, Daniel T. H.

Flow control through bio-inspired leading-edge tuberclesmorphology, aerodynamics, hydrodynamics and applications /

Record Type:	Electronic resources : Monograph/item
Title/Author:	Flow control through bio-inspired leading-edge tuberclesedited by Daniel T. H. New, Bing Feng Ng.
Reminder of title:	morphology, aerodynamics, hydrodynamics and applications /
other author:	New, Daniel T. H.
Published:	Cham :Springer International Publishing :2020.
Description:	xiii, 178 p. :ill., digital ;24 cm.
Contained By:	Springer eBooks
Subject:	Vortex-motion.
Online resource:	https://doi.org/10.1007/978-3-030-23792-9
ISBN:	9783030237929$q(electronic bk.)

Flow control through bio-inspired leading-edge tuberclesmorphology, aerodynamics, hydrodynamics and applications /
Flow control through bio-inspired leading-edge tuberclesmorphology, aerodynamics, hydrodynamics and applications /[electronic resource] :edited by Daniel T. H. New, Bing Feng Ng. - Cham :Springer International Publishing :2020. - xiii, 178 p. :ill., digital ;24 cm.

Opportunities from Nature -- Perspectives and Applications -- Experimental Aerodynamics -- Geometry Optimization -- Flow Control on Hydrofoils -- Spanwise Flow -- Noise Attenuation -- Dynamic Effects -- Aeroelasticity.

This book describes and explains the basis of bio-inspired, leading-edge tubercles based on humpback whale flippers as passive but effective flow control devices, as well as providing a comprehensive practical guide in their applications. It first discusses the morphology of the humpback whale flipper from a biological perspective, before presenting detailed experimental and numerical findings from past investigations by various experts on the benefits of leading-edge tubercles and their engineering implementations. Leading-edge tubercle designs and functions have attracted considerable interest from researchers in terms of understanding their role in the underwater agility of these whales, and to exploit their flow dynamics in the development of new and novel engineering solutions. Extensive research over the past recent years has demonstrated that the maneuverability of these whales is at least in part due to the leading-edge tubercles acting as passive flow control devices to delay stall and increase lift in the post-stall regime. In addition to the inherent benefits in terms of aerodynamics and hydrodynamics, investigations into leading-edge tubercles have also broadened into areas of noise attenuation, stability and industrial applications. This book touches upon these areas, with an emphasis upon the effects of lifting-surface types, flow regimes, tubercle geometries, lifting-surface stability and potential industrial applications, among others. As such, it features contributions from key experts in the fields of biology, physics and engineering who have conducted significant studies into understanding the various aspects of leading-edge tubercles. Given the broad coverage and in-depth analysis, this book will benefit academic researchers, practicing engineers and graduate students interested in tapping into such a unique but highly functional flow control strategy.

ISBN: 9783030237929$q(electronic bk.)

Standard No.: 10.1007/978-3-030-23792-9doiSubjects--Topical Terms:

196969
Vortex-motion.

LC Class. No.: QC159 / .F569 2020

Dewey Class. No.: 532.595

Flow control through bio-inspired leading-edge tuberclesmorphology, aerodynamics, hydrodynamics and applications /
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505 0 $a Opportunities from Nature -- Perspectives and Applications -- Experimental Aerodynamics -- Geometry Optimization -- Flow Control on Hydrofoils -- Spanwise Flow -- Noise Attenuation -- Dynamic Effects -- Aeroelasticity.
520 $a This book describes and explains the basis of bio-inspired, leading-edge tubercles based on humpback whale flippers as passive but effective flow control devices, as well as providing a comprehensive practical guide in their applications. It first discusses the morphology of the humpback whale flipper from a biological perspective, before presenting detailed experimental and numerical findings from past investigations by various experts on the benefits of leading-edge tubercles and their engineering implementations. Leading-edge tubercle designs and functions have attracted considerable interest from researchers in terms of understanding their role in the underwater agility of these whales, and to exploit their flow dynamics in the development of new and novel engineering solutions. Extensive research over the past recent years has demonstrated that the maneuverability of these whales is at least in part due to the leading-edge tubercles acting as passive flow control devices to delay stall and increase lift in the post-stall regime. In addition to the inherent benefits in terms of aerodynamics and hydrodynamics, investigations into leading-edge tubercles have also broadened into areas of noise attenuation, stability and industrial applications. This book touches upon these areas, with an emphasis upon the effects of lifting-surface types, flow regimes, tubercle geometries, lifting-surface stability and potential industrial applications, among others. As such, it features contributions from key experts in the fields of biology, physics and engineering who have conducted significant studies into understanding the various aspects of leading-edge tubercles. Given the broad coverage and in-depth analysis, this book will benefit academic researchers, practicing engineers and graduate students interested in tapping into such a unique but highly functional flow control strategy.
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