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Turbulent Drag Reduction by Surfactant Additives - Feng-Chen Li
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Feng-Chen Li:
Turbulent Drag Reduction by Surfactant Additives - neues Buch

ISBN: 9781118181089

ID: 9781118181089

InhaltsangabePreface ix1 Introduction 11.1 Background 11.2 Surfactant Solution 41.2.1 Anionic Surfactant 61.2.2 Cationic Surfactant 61.2.3 Nonionic Surfactant 71.2.4 Amphoteric Surfactant 71.2.5 Zwitterionic Surfactant 71.3 Mechanism and Theory of Drag Reduction by Surfactant Additives 81.3.1 Explanations of the Turbulent DR Mechanism from the Viewpoint of Microstructures 81.3.2 Explanations of the Turbulent DR Mechanism from the Viewpoint of the Physics of Turbulence 101.4 Application Techniques of Drag Reduction by Surfactant Additives 141.4.1 Heat Transfer Reduction of Surfactant Drag-reducing Flow 151.4.2 Diameter Effect of Surfactant Drag-reducing Flow 151.4.3 Toxic Effect of Cationic Surfactant Solution 151.4.4 Chemical Stability of Surfactant Solution 151.4.5 Corrosion of Surfactant Solution 16References 162 Drag Reduction and Heat Transfer Reduction Characteristics of Drag-Reducing Surfactant Solution Flow 192.1 Fundamental Concepts of Turbulent Drag Reduction 192.2 Characteristics of Drag Reduction by Surfactant Additives and Its Influencing Factors 222.2.1 Characteristics of Drag Reduction by Surfactant Additives 232.2.2 Influencing Factors of Drag Reduction by Surfactant Additives 272.3 The Diameter Effect of Surfactant Drag-reducing Flow and Scale-up Methods 312.3.1 The Diameter Effect and Its Influence 312.3.2 Scale-up Methods 322.3.3 Evaluation of Different Scale-up Methods 432.4 Heat Transfer Characteristics of Drag-reducing Surfactant Solutionm Flow and Its Enhancement Methods 472.4.1 Convective Heat Transfer Characteristics of Drag-reducing Surfactant Solution Flow 472.4.2 Heat Transfer Enhancement Methods for Drag-reducing Surfactant Solution Flows 50References 593 Turbulence Structures in Drag-Reducing Surfactant Solution Flow 633.1 Measurement Techniques for Turbulence Structures in Drag-Reducing Flow 643.1.1 Laser Doppler Velocimetry 643.1.2 PIV 663.2 Statistical Characteristics of Velocity and Temperature Fields in Drag-reducing Flow 683.2.1 Distribution of Averaged Quantities 693.2.2 Distribution of Fluctuation Intensities 743.2.3 Correlation Analyses of Fluctuating Quantities 773.2.4 Spectrum Analyses of Fluctuating Quantities 783.3 Characteristics of TurbulentVortex Structures in Drag-reducing Flow 833.3.1 Identification Method of Turbulent Vortex by Swirling Strength 843.3.2 Distribution Characteristics of Turbulent Vortex in the x-y Plane 853.3.3 Distribution Characteristics of Turbulent Vortex in the y-z Plane 873.3.4 Distribution Characteristics of Turbulent Vortex in the x-z Plane 903.4 Reynolds Shear Stress and Wall-Normal Turbulent Heat Flux 96References 1004 Numerical Simulation of Surfactant Drag Reduction 1034.1 Direct Numerical Simulation of Drag-reducing Flow 1044.1.1 A Mathematical Model of Drag-reducing Flow 1044.1.2 The DNS Method of Drag-reducing Flow 1094.2 RANS of Drag-reducing Flow 1114.3 Governing Equation and DNS Method of Drag-reducing Flow 1144.3.1 Governing Equation 1144.3.2 Numerical Method 1174.4 DNS Results and Discussion for Drag-reducing Flow and Heat Transfer 1224.4.1 The Overall Study on Surfactant Drag Reduction and Heat Transfer by DNS 1224.4.2 The Rheological Parameter Effect of DNS on Surfactant Drag Reduction 1604.4.3 DNS with the Bilayer Model of Flows with Newtonian and Non-Newtonian Fluid Coexistence 1734.5 Conclusion and Future Work 178References 1795 Microstructures and Rheological Properties of Surfactant Soluti References 2316 Application Techniques for Drag Reduction by Surfactant Additives 2336.1 Problems That Need to Be Solved in Engineering Applications 2336.1.1 Influencing Factors of Drag-reducing Surfactant Additives on the Heat Transfer Performance of Heat Exchangers and Its Counter-measures 2346.1.2 Influences of Drag-reducing Surfactant Additives on the Environment 2356.1.3 Scale-up Problem 2366.2 Separation Techniques for Surfactant Solution 2376.2.1 Adsorption 2386.2.2 Ultrafiltration 2386.2.3 Reverse Osmosis 2396.3 Drag Reduction Stability of Surfactant Solutions 2396.3.1 Effect of Adsorption 2396.3.2 Effects of Fe(OH)3 2406.3.3 Effects of Cu(OH)2 2416.3.4 Recovery of Drag Reduction 2416.4 Applications of Surfactant Drag Reduction 2426.4.1 Application of Surfactant to Hydronic Heating and Air-Conditioning Systems 2426.4.2 Surfactant Selection in Actual Applications 251References 253Index 255 Turbulent Drag Reduction by Surfactant Additives: InhaltsangabePreface ix1 Introduction 11.1 Background 11.2 Surfactant Solution 41.2.1 Anionic Surfactant 61.2.2 Cationic Surfactant 61.2.3 Nonionic Surfactant 71.2.4 Amphoteric Surfactant 71.2.5 Zwitterionic Surfactant 71.3 Mechanism and Theory of Drag Reduction by Surfactant Additives 81.3.1 Explanations of the Turbulent DR Mechanism from the Viewpoint of Microstructures 81.3.2 Explanations of the Turbulent DR Mechanism from the Viewpoint of the Physics of Turbulence 101.4 Application Techniques of Drag Reduction by Surfactant Additives 141.4.1 Heat Transfer Reduction of Surfactant Drag-reducing Flow 151.4.2 Diameter Effect of Surfactant Drag-reducing Flow 151.4.3 Toxic Effect of Cationic Surfactant Solution 151.4.4 Chemical Stability of Surfactant Solution 151.4.5 Corrosion of Surfactant Solution 16References 162 Drag Reduction and Heat Transfer Reduction Characteristics of Drag-Reducing Surfactant Solution Flow 192.1 Fundamental Concepts of Turbulent Drag Reduction 192.2 Characteristics of Drag Reduction by Surfactant Additives and Its Influencing Factors 222.2.1 Characteristics of Drag Reduction by Surfactant Additives 232.2.2 Influencing Factors of Drag Reduction by Surfactant Additives 272.3 The Diameter Effect of Surfactant Drag-reducing Flow and Scale-up Methods 312.3.1 The Diameter Effect and Its Influence 312.3.2 Scale-up Methods 322.3.3 Evaluation of Different Scale-up Methods 432.4 Heat Transfer Characteristics of Drag-reducing Surfactant Solutionm Flow and Its Enhancement Methods 472.4.1 Convective Heat Transfer Characteristics of Drag-reducing Surfactant Solution Flow 472.4.2 Heat Transfer Enhancement Methods for Drag-reducing Surfactant Solution Flows 50References 593 Turbulence Structures in Drag-Reducing Surfactant Solution Flow 633.1 Measurement Techniques for Turbulence Structures in Drag-Reducing Flow 643.1.1 Laser Doppler Velocimetry 643.1.2 PIV 663.2 Statistical Characteristics of Velocity and Temperature Fields in Drag-reducing Flow 683.2.1 Distribution of Averaged Quantities 693.2.2 Distribution of Fluctuation Intensities 743.2.3 Correlation Analyses of Fluctuating Quantities 773.2.4 Spectrum Analyses of Fluctuating Quantities 783.3 Characteristics of TurbulentVortex Structures in Drag-reducing Flow 833.3.1 Identification Method of Turbulent Vortex by Swirling Strength 843.3.2 Distribution Characteristics of Turbulent Vortex in the x-y Plane 853.3.3 Distribution Characteristics of Turbulent Vortex in the y-z Plane 873.3.4 Distribution Characteristics of Turbulent Vortex in the x-z Plane 903.4 Reynolds Shear Stress and Wall-Normal Turbulent Heat Flux 96References 1004 Numerical Simulation of Surfactant Drag Reduction 1034.1 Direct Numerical Simulation of Drag-reducing Flow 1044.1.1 A Mathematical Model of Drag-reducing Flow 1044.1.2 The DNS Method of Drag-reducing Flow 1094.2 RANS of Drag-reducing Flow 1114.3 Governing Equation and DNS Method of Drag-reducing Flow 1144.3.1 Governing Equation 1144.3.2 Numerical Method 1174.4 DNS Results and Discussion for Drag-reducing Flow and Heat Transfer 1224.4.1 The Overall Study on Surfactant Drag Reduction and Heat Transfer by DNS 1224.4.2 The Rheological Parameter Effect of DNS on Surfactant Drag Reduction 1604.4.3 DNS with the Bilayer Model of Flows with Newtonian and Non-Newtonian Fluid Coexistence 1734.5 Conclusion and Future Work 178References 1795 Microstructures and Rheological Properties of Surfactant Soluti References 2316 Application Techniques for Drag Reduction by Surfactant Additives 2336.1 Problems That Need to Be Solved in Engineering Applications 2336.1.1 Influencing Factors of Drag-reducing Surfactant Additives on the Heat Transfer Performance of Heat Exchangers and Its Counter-measures 2346.1.2 Influences of Drag-reducing Surfactant Additives on the Environment 2356.1.3 Scale-up Problem 2366.2 Separation Techniques for Surfactant Solution 2376.2.1 Adsorption 2386.2.2 Ultrafiltration 2386.2.3 Reverse Osmosis 2396.3 Drag Reduction Stability of Surfactant Solutions 2396.3.1 Effect of Adsorption 2396.3.2 Effects of Fe(OH)3 2406.3.3 Effects of Cu(OH)2 2416.3.4 Recovery of Drag Reduction 2416.4 Applications of Surfactant Drag Reduction 2426.4.1 Application of Surfactant to Hydronic Heating and Air-Conditioning Systems 2426.4.2 Surfactant Selection in Actual Applications 251References 253Index 255 Chemical Engineering Chemie Chemische Verfahrenstechnik Chemistry Fluid Mechanics Maschinenbau Mechanical Engineering Oberflächen- u. Kolloidchemie Strömungsmechanik Surface & Colloid Chemistry, John Wiley & Sons

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Turbulent Drag Reduction by Surfactant Additives - Feng-Chen Li
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Turbulent Drag Reduction by Surfactant Additives - neues Buch

ISBN: 9781118181089

ID: 9781118181089

InhaltsangabePreface ix1 Introduction 11.1 Background 11.2 Surfactant Solution 41.2.1 Anionic Surfactant 61.2.2 Cationic Surfactant 61.2.3 Nonionic Surfactant 71.2.4 Amphoteric Surfactant 71.2.5 Zwitterionic Surfactant 71.3 Mechanism and Theory of Drag Reduction by Surfactant Additives 81.3.1 Explanations of the Turbulent DR Mechanism from the Viewpoint of Microstructures 81.3.2 Explanations of the Turbulent DR Mechanism from the Viewpoint of the Physics of Turbulence 101.4 Application Techniques of Drag Reduction by Surfactant Additives 141.4.1 Heat Transfer Reduction of Surfactant Drag-reducing Flow 151.4.2 Diameter Effect of Surfactant Drag-reducing Flow 151.4.3 Toxic Effect of Cationic Surfactant Solution 151.4.4 Chemical Stability of Surfactant Solution 151.4.5 Corrosion of Surfactant Solution 16References 162 Drag Reduction and Heat Transfer Reduction Characteristics of Drag-Reducing Surfactant Solution Flow 192.1 Fundamental Concepts of Turbulent Drag Reduction 192.2 Characteristics of Drag Reduction by Surfactant Additives and Its Influencing Factors 222.2.1 Characteristics of Drag Reduction by Surfactant Additives 232.2.2 Influencing Factors of Drag Reduction by Surfactant Additives 272.3 The Diameter Effect of Surfactant Drag-reducing Flow and Scale-up Methods 312.3.1 The Diameter Effect and Its Influence 312.3.2 Scale-up Methods 322.3.3 Evaluation of Different Scale-up Methods 432.4 Heat Transfer Characteristics of Drag-reducing Surfactant Solutionm Flow and Its Enhancement Methods 472.4.1 Convective Heat Transfer Characteristics of Drag-reducing Surfactant Solution Flow 472.4.2 Heat Transfer Enhancement Methods for Drag-reducing Surfactant Solution Flows 50References 593 Turbulence Structures in Drag-Reducing Surfactant Solution Flow 633.1 Measurement Techniques for Turbulence Structures in Drag-Reducing Flow 643.1.1 Laser Doppler Velocimetry 643.1.2 PIV 663.2 Statistical Characteristics of Velocity and Temperature Fields in Drag-reducing Flow 683.2.1 Distribution of Averaged Quantities 693.2.2 Distribution of Fluctuation Intensities 743.2.3 Correlation Analyses of Fluctuating Quantities 773.2.4 Spectrum Analyses of Fluctuating Quantities 783.3 Characteristics of TurbulentVortex Structures in Drag-reducing Flow 833.3.1 Identification Method of Turbulent Vortex by Swirling Strength 843.3.2 Distribution Characteristics of Turbulent Vortex in the x-y Plane 853.3.3 Distribution Characteristics of Turbulent Vortex in the y-z Plane 873.3.4 Distribution Characteristics of Turbulent Vortex in the x-z Plane 903.4 Reynolds Shear Stress and Wall-Normal Turbulent Heat Flux 96References 1004 Numerical Simulation of Surfactant Drag Reduction 1034.1 Direct Numerical Simulation of Drag-reducing Flow 1044.1.1 A Mathematical Model of Drag-reducing Flow 1044.1.2 The DNS Method of Drag-reducing Flow 1094.2 RANS of Drag-reducing Flow 1114.3 Governing Equation and DNS Method of Drag-reducing Flow 1144.3.1 Governing Equation 1144.3.2 Numerical Method 1174.4 DNS Results and Discussion for Drag-reducing Flow and Heat Transfer 1224.4.1 The Overall Study on Surfactant Drag Reduction and Heat Transfer by DNS 1224.4.2 The Rheological Parameter Effect of DNS on Surfactant Drag Reduction 1604.4.3 DNS with the Bilayer Model of Flows with Newtonian and Non-Newtonian Fluid Coexistence 1734.5 Conclusion and Future Work 178References 1795 Microstructures and Rheological Properties of Surfactant Soluti References 2316 Application Techniques for Drag Reduction by Surfactant Additives 2336.1 Problems That Need to Be Solved in Engineering Applications 2336.1.1 Influencing Factors of Drag-reducing Surfactant Additives on the Heat Transfer Performance of Heat Exchangers and Its Counter-measures 2346.1.2 Influences of Drag-reducing Surfactant Additives on the Environment 2356.1.3 Scale-up Problem 2366.2 Separation Techniques for Surfactant Solution 2376.2.1 Adsorption 2386.2.2 Ultrafiltration 2386.2.3 Reverse Osmosis 2396.3 Drag Reduction Stability of Surfactant Solutions 2396.3.1 Effect of Adsorption 2396.3.2 Effects of Fe(OH)3 2406.3.3 Effects of Cu(OH)2 2416.3.4 Recovery of Drag Reduction 2416.4 Applications of Surfactant Drag Reduction 2426.4.1 Application of Surfactant to Hydronic Heating and Air-Conditioning Systems 2426.4.2 Surfactant Selection in Actual Applications 251References 253Index 255 Turbulent Drag Reduction by Surfactant Additives: InhaltsangabePreface ix1 Introduction 11.1 Background 11.2 Surfactant Solution 41.2.1 Anionic Surfactant 61.2.2 Cationic Surfactant 61.2.3 Nonionic Surfactant 71.2.4 Amphoteric Surfactant 71.2.5 Zwitterionic Surfactant 71.3 Mechanism and Theory of Drag Reduction by Surfactant Additives 81.3.1 Explanations of the Turbulent DR Mechanism from the Viewpoint of Microstructures 81.3.2 Explanations of the Turbulent DR Mechanism from the Viewpoint of the Physics of Turbulence 101.4 Application Techniques of Drag Reduction by Surfactant Additives 141.4.1 Heat Transfer Reduction of Surfactant Drag-reducing Flow 151.4.2 Diameter Effect of Surfactant Drag-reducing Flow 151.4.3 Toxic Effect of Cationic Surfactant Solution 151.4.4 Chemical Stability of Surfactant Solution 151.4.5 Corrosion of Surfactant Solution 16References 162 Drag Reduction and Heat Transfer Reduction Characteristics of Drag-Reducing Surfactant Solution Flow 192.1 Fundamental Concepts of Turbulent Drag Reduction 192.2 Characteristics of Drag Reduction by Surfactant Additives and Its Influencing Factors 222.2.1 Characteristics of Drag Reduction by Surfactant Additives 232.2.2 Influencing Factors of Drag Reduction by Surfactant Additives 272.3 The Diameter Effect of Surfactant Drag-reducing Flow and Scale-up Methods 312.3.1 The Diameter Effect and Its Influence 312.3.2 Scale-up Methods 322.3.3 Evaluation of Different Scale-up Methods 432.4 Heat Transfer Characteristics of Drag-reducing Surfactant Solutionm Flow and Its Enhancement Methods 472.4.1 Convective Heat Transfer Characteristics of Drag-reducing Surfactant Solution Flow 472.4.2 Heat Transfer Enhancement Methods for Drag-reducing Surfactant Solution Flows 50References 593 Turbulence Structures in Drag-Reducing Surfactant Solution Flow 633.1 Measurement Techniques for Turbulence Structures in Drag-Reducing Flow 643.1.1 Laser Doppler Velocimetry 643.1.2 PIV 663.2 Statistical Characteristics of Velocity and Temperature Fields in Drag-reducing Flow 683.2.1 Distribution of Averaged Quantities 693.2.2 Distribution of Fluctuation Intensities 743.2.3 Correlation Analyses of Fluctuating Quantities 773.2.4 Spectrum Analyses of Fluctuating Quantities 783.3 Characteristics of TurbulentVortex Structures in Drag-reducing Flow 833.3.1 Identification Method of Turbulent Vortex by Swirling Strength 843.3.2 Distribution Characteristics of Turbulent Vortex in the x-y Plane 853.3.3 Distribution Characteristics of Turbulent Vortex in the y-z Plane 873.3.4 Distribution Characteristics of Turbulent Vortex in the x-z Plane 903.4 Reynolds Shear Stress and Wall-Normal Turbulent Heat Flux 96References 1004 Numerical Simulation of Surfactant Drag Reduction 1034.1 Direct Numerical Simulation of Drag-reducing Flow 1044.1.1 A Mathematical Model of Drag-reducing Flow 1044.1.2 The DNS Method of Drag-reducing Flow 1094.2 RANS of Drag-reducing Flow 1114.3 Governing Equation and DNS Method of Drag-reducing Flow 1144.3.1 Governing Equation 1144.3.2 Numerical Method 1174.4 DNS Results and Discussion for Drag-reducing Flow and Heat Transfer 1224.4.1 The Overall Study on Surfactant Drag Reduction and Heat Transfer by DNS 1224.4.2 The Rheological Parameter Effect of DNS on Surfactant Drag Reduction 1604.4.3 DNS with the Bilayer Model of Flows with Newtonian and Non-Newtonian Fluid Coexistence 1734.5 Conclusion and Future Work 178References 1795 Microstructures and Rheological Properties of Surfactant Soluti References 2316 Application Techniques for Drag Reduction by Surfactant Additives 2336.1 Problems That Need to Be Solved in Engineering Applications 2336.1.1 Influencing Factors of Drag-reducing Surfactant Additives on the Heat Transfer Performance of Heat Exchangers and Its Counter-measures 2346.1.2 Influences of Drag-reducing Surfactant Additives on the Environment 2356.1.3 Scale-up Problem 2366.2 Separation Techniques for Surfactant Solution 2376.2.1 Adsorption 2386.2.2 Ultrafiltration 2386.2.3 Reverse Osmosis 2396.3 Drag Reduction Stability of Surfactant Solutions 2396.3.1 Effect of Adsorption 2396.3.2 Effects of Fe(OH)3 2406.3.3 Effects of Cu(OH)2 2416.3.4 Recovery of Drag Reduction 2416.4 Applications of Surfactant Drag Reduction 2426.4.1 Application of Surfactant to Hydronic Heating and Air-Conditioning Systems 2426.4.2 Surfactant Selection in Actual Applications 251References 253Index 255 Chemie Chemical Engineering Maschinenbau Chemistry Chemische Verfahrenstechnik Mechanical Engineering Strömungsmechanik Oberflächen- u. Kolloidchemie Surface & Colloid Chemistry Fluid Mechanics, John Wiley & Sons

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Turbulent Drag Reduction by Surfactant Additives - Li, Feng-Chen; Yu, Bo; Wei, Jin-Jia; Kawaguchi, Yasuo
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Turbulent Drag Reduction by Surfactant Additives - neues Buch

2011, ISBN: 1118181085

ID: 9781118181089

In englischer Sprache. Verlag: John Wiley & Sons, Feng-Chen Li, Harbin Institute of Technology, ChinaProfessor Feng-Chen Li received his Ph.D. from Kyoto University inJapan, before becoming one of the members of the turbulence controlcommunity. A number of new findings have been achieved fromcollaborative work with colleagues and he recently initiated apioneering work on viscoelastic-fluid-based nanofluid. Professor Lihas published over 100 publications, including book chapters,journal papers and contributions at international conferences. Bo Yu, China University of Petroleum (Beijing), ChinaProfessorBo Yu obtained a Ph.D. degree from Xi'an JiaotongUniversity. He has been a full professor of the Department of Oil& Gas Storage and Transportation of China University ofPetroleum at Beijing since 2005. Hiscurrent research interestsinclude: Turbulent Flow; Computational Fluid Dynamics; NumericalHeat Transfer; Non-Newtonian Fluid Dynamics; Long-distanceTransportation Technology of Waxy Crude Oil. Having published morethan 50 international journal papers, he also has many awards. Jin-Jia Wei, Professor, Xi'an Jiao Tong University, ChinaProfessor Jin-Jia WEI obtained a Ph.D. degree from Xi'anJiaotong University in China and another Ph.D degree from KyushuUniversity. In 2005, he became a full professor of State KeyLaboratory of Multiphase Flow in Power Engineering of Xi'anJiaotong University. His current research interests include:Turbulent Drag Reduction by Surfactant Additives and itsApplications for Practical Engineering in the DistrictHeating/Cooling System; Particle-Fluid turbulent flows in pump andpipe system; Enhanced boiling heat transfer; Thermal utilization ofsolar energy; Computational fluid mechanics and Brownian dynamicssimulation. He has published more than150 journal and conferencepapers. Yasuo Kawaguchi, Tokyo University of Science, JapanProfessor Yasuo Kawaguchi obtained his Ph.D. degree from KyotoUniversity in Japan. In April 2005, he became a full professor ofDepartment of Mechanical Engineering, Faculty of Science andTechnology, Tokyo University of Science. His current researchinterests include: Turbulent Drag Reduction by Surfactant Additivesand its Applications for Practical Engineering in the DistrictHeating/Cooling System; Drag reduction of water soluble polymer andis application for economization of ship propulsion; Gas-Solidparticle turbulent flows relating to environmental problem, pumpand pipe system; Application of laser techniques to thermal andfluid flow. He has published more than150 journal and conferencepapers. PC-PDF, 272 Seiten, 272 Seiten, 1., Auflage, [GR: 9682 - Nonbooks, PBS / Technik/Maschinenbau, Fertigungstechnik], [SW: - Maschinenbau und Werkstoffe], [Ausgabe: 1][PU:John Wiley & Sons]

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Turbulent Drag Reduction By Surfactant Additives - Wiley
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Turbulent Drag Reduction By Surfactant Additives - neues Buch

2011, ISBN: 9781118181089

ID: 13411646

Turbulent drag reduction by additives has long been a hot research topic. This phenomenon is inherently associated with multifold expertise. Solutions of drag-reducing additives are usually viscoelastic fluids having complicated rheological properties. Exploring the characteristics of drag-reduced turbulent flows calls for uniquely designed experimental and numerical simulation techniques and. Turbulent drag reduction by additives has long been a hot research topic. This phenomenon is inherently associated with multifold expertise. Solutions of drag-reducing additives are usually viscoelastic fluids having complicated rheological properties. Exploring the characteristics of drag-reduced turbulent flows calls for uniquely designed experimental and numerical simulation techniques and elaborate theoretical considerations. Pertinently understanding the turbulent drag reduction mechanism necessities mastering the fundamentals of turbulence and establishing a proper relationship between turbulence and the rheological properties induced by additives. Promoting the applications of the drag reduction phenomenon requires the knowledge from different fields such as chemical engineering, mechanical engineering, municipal engineering, and so on. This book gives a thorough elucidation of the turbulence characteristics and rheological behaviors, theories, special techniques and application issues for drag-reducing flows by surfactant additives based on the state-of-the-art of scientific research results through the latest experimental studies, numerical simulations and theoretical analyses. Covers turbulent drag reduction, heat transfer reduction, complex rheology and the real-world applications of drag reduction Introduces advanced testing techniques, such as PIV, LDA, and their applications in current experiments, illustrated with multiple diagrams and equations Real-world examples of the topic s increasingly important industrial applications enable readers to implement cost- and energy-saving measures Explains the tools before presenting the research results, to give readers coverage of the subject from both theoretical and experimental viewpoints Consolidates interdisciplinary information on turbulent drag reduction by additives Turbulent Drag Reduction by Surfactant Additives is geared for researchers, graduate students, and engineers in the fields of Fluid. eBooks, , Turbulent Drag Reduction By Surfactant Additives~~EBook~~9781118181089~~Jin-Jia Wei, Yasuo Kawaguchi, Feng-Chen Li, Bo Yu, , Turbulent Drag Reduction By Surfactant Additives, Jin-Jia Wei, 9781118181089, Wiley, 12/30/2011, , , , Wiley

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Turbulent drag reduction by additives has long been a hot researchtopic. This phenomenon is inherently associated with multifoldexpertise. Solutions of drag-reducing additives are usuallyviscoelastic fluids having complicated rheological properties.Exploring the characteristics of drag-reduced turbulent flows callsfor uniquely designed experimental and numerical simulationtechniques and elaborate theoretical considerations. Pertinentlyunderstanding the turbulent drag reduction mechanism necessitiesmastering the fundamentals of turbulence and establishing a properrelationship between turbulence and the rheological propertiesinduced by additives. Promoting the applications of the dragreduction phenomenon requires the knowledge from different fieldssuch as chemical engineering, mechanical engineering, municipalengineering, and so on. This book gives a thorough elucidation ofthe turbulence characteristics and rheological behaviors, theories,special techniques and application issues for drag-reducing flowsby surfactant additives based on the state-of-the-art of scientificresearch results through the latest experimental studies, numericalsimulations and theoretical analyses.* Covers turbulent drag reduction, heat transfer reduction,complex rheology and the real-world applications of dragreduction* Introduces advanced testing techniques, such as PIV, LDA, andtheir applications in current experiments, illustrated withmultiple diagrams and equations* Real-world examples of the topic's increasingly importantindustrial applications enable readers to implement cost- andenergy-saving measures* Explains the tools before presenting the research results, togive readers coverage of the subject from both theoretical andexperimental viewpoints* Consolidates interdisciplinary information on turbulent dragreduction by additivesTurbulent Drag Reduction by Surfactant Additives isgeared for researchers, graduate students, and engineers in thefields of Fluid Mechanics, Mechanical Engineering, Turbulence,Chemical Engineering, Municipal Engineering. Researchers andpractitioners involved in the fields of Flow Control, Chemistry,Computational Fluid Dynamics, Experimental Fluid Dynamics, andRheology will also find this book to be a much-needed reference onthe topic. E-Book

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