Beschreibung
This textbook covers essentials of traditional and modern fluid dynamics, i. e., the fundamentals of and basic applications in fluid mechanics and convection heat transfer with brief excursions into fluid-particle dynamics and solid mechanics. Specifically, it is suggested that the book can be used to enhance the knowledge base and skill level of engineering and physics students in macro-scale fluid mechanics (see Chaps. 1-5 and 10), followed by an int- ductory excursion into micro-scale fluid dynamics (see Chaps. 6 to 9). These ten chapters are rather self-contained, i. e., most of the material of Chaps. 1-10 (or selectively just certain chapters) could be taught in one course, based on the students' background. Typically, serious seniors and first-year graduate students form a receptive audience (see sample syllabus). Such as target group of students would have had prerequisites in thermodynamics, fluid mechanics and solid mechanics, where Part A would be a welcomed refresher. While introductory fluid mechanics books present the material in progressive order, i. e., employing an inductive approach from the simple to the more difficult, the present text adopts more of a deductive approach. Indeed, understanding the derivation of the basic equations and then formulating the system-specific equations with suitable boundary conditions are two key steps for proper problem solutions.
Inhaltsverzeichnis
Part A: Fluid Dynamics Essentials 1 REVIEW OF BASIC ENGINEERING CONCEPTS 1.1 Definitions and Concepts 1.2 The Continuum Mechanics Assumption 1.3 Fluid Flow Descriptions 1.4 Thermodynamic Properties and Constitutive Equations 1.5 Homework Assignments 2 FUNDAMENTAL EQUATIONS AND SOLUTIONS 2.1 Introduction 2.2 The Reynolds Transport Theorem 2.3 Fluid Mass Conservation 2.4 Momentum Conservation 2.5 Energy and Species Mass Conservation Laws 2.6 Homework Assignments 3 INTRODUCTORY FLUID DYNAMICS CASES 3.1 Inviscid Flow along a Streamline 3.2 Quasi-unidirectional Viscous Flows 3.3 Transient One-dimensional Flows 3.4 Simple Porous Media Flow 3.5 One-dimensional Compressible Flow 3.6 Forced Convection Heat & Mass Transfer 3.7 Entropy Generation Analysis 3.8 Homework Assignments REFERENCES (Part A) Part B: Conventional Applications 4 INTERNAL FLOW 4.1 Introduction 4.2 Laminar and Turbulent Pipe Flows 4.3 Basic Lubrication Systems 4.4 Compartmental Modeling 4.5 Homework Assignments 5 EXTERNAL FLOW 5.1 Introduction 5.2 Laminar and Turbulent Boundary-Layer Flows 5.3 Drag and Lift Computations 5.4 Film Drawing and Surface Coating 5.5 Homework Assignments REFERENCES (PART B) Part C: Modern Fluid Mechanics Topics 6 DILUTE PARTICLE SUSPENSIONS 6.1 Introduction 6.2 Modeling Approaches 6.3 Non-Newtonian Fluid Flows 6.4 Particle Transport 6.5 Homework Assignments and Course Projects 7 MICROSYSTEMS AND MICROFLUIDICS 7.1 Introduction 7.2 Microfluidics Modeling Aspects 7.3 Electro-hydrodynamics in Microchannels 7.4 Entropy Generation in Microfluidic Systems 7.5 Nanotechnology and Nanofluid Flow in Microchannels 7.6 Homework Problems and Project Assignments 8 FLUID-STRUCTURE INTERACTION 8.1 Introduction 8.2 Solid Mechanics Review 8.3 Slender-body Dynamics 8.4 Flow-induced Vibration 8.5 Homework Problems and Project Assignments 9 BIOFLUID FLOW AND HEAT TRANSFER 9.1 Introduction 9.2 Modeling Aspects 9.3 Arterial Hemodynamics 9.4 Lung-Aerosol Dynamics 9.5 Bioheat Equation 9.6 Project Assignments 10 COMPUTATIONAL FLUID DYNAMICS AND SYSTEM DESIGN 10.1 Introduction 10.2 Modeling Objectives and Numerical Tools 10.3 Example of Internal Flow 10.4 Example of External Flow 10.5 Example of Mixture Flow 10.6 Project Assignments and Design Tasks REFERENCES (PART C) APPENDICES Review of Tensor Operations, Integral Transformations, and ODE Solutions, plus removable Equation Sheets Fluid Properties, CD-correlations, and MOODY Chart Flow Visualization CD-R (CUP & NSF; ã Stanford University 2004) INDEX
