Fluid Mechanics for Chemical Engineers with Microfluidics, CFD, and COMSOL Multiphysics 5 3rd Edition James O. Wilkes

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Desk of contents(*5*)
Preface xv

 

Half I: Large-scale Fluid Mechanics 1

 

Chapter 1: Overview of Fluid Mechanics 3

1.1 Fluid Mechanics in Chemical Engineering 3

1.2 Basic Concepts of a Fluid 3

1.3 Stresses, Pressure, Velocity, and the Major Laws 5

1.4 Bodily Properties—Density, Viscosity, and Surface Tension 10

1.5 Objects and Methods of Objects 21

1.6 Hydrostatics 26

1.7 Pressure Change Resulting from Rotation 39

Points for Chapter 1 42

 

Chapter 2: Mass, Energy, and Momentum Balances 55

2.1 Basic Conservation Laws 55

2.2 Mass Balances 57

2.3 Energy Balances 61

2.4 Bernoulli’s Equation 67

2.5 Applications of Bernoulli’s Equation 70

2.6 Momentum Balances 78

2.7 Pressure, Velocity, and Transfer Rate Measurement 92

Points for Chapter 2 96

 

Chapter 3: Fluid Friction in Pipes 120

3.1 Introduction 120

3.2 Laminar Flow 123

3.3 Models for Shear Stress 129

3.4 Piping and Pumping Issues 133

3.5 Flow in Noncircular Ducts 150

3.6 Compressible Gas Flow in Pipelines 156

3.7 Compressible Flow in Nozzles 159

3.8 Advanced Piping Techniques 163

Points for Chapter 3 168

 

Chapter 4: Flow in Chemical Engineering Instruments 185

4.1 Introduction 185

4.2 Pumps and Compressors 188

4.3 Drag Force on Solid Particles in Fluids 194

4.4 Flow Through Packed Beds 204

4.5 Filtration 210

4.6 Fluidization 215

4.7 Dynamics of a Bubble-Cap Distillation Column 216

4.8 Cyclone Separators 219

4.9 Sedimentation 222

4.10 Dimensional Analysis 224

Points for Chapter 4 230

 

Half II: Microscopic Fluid Mechanics 247

 

Chapter 5: Differential Equations of Fluid Mechanics 249

5.1 Introduction to Vector Analysis 249

5.2 Vector Operations 250

5.3 Different Coordinate Systems 263

5.4 The Convective Derivative 266

5.5 Differential Mass Balance 267

5.6 Differential Momentum Balances 271

5.7 Newtonian Stress Elements in Cartesian Coordinates 274

Points for Chapter 5 285

 

Chapter 6: Solution Of Viscous-Flow Issues 292

6.1 Introduction 292

6.2 Solution of the Equations of Motion in Rectangular Coordinates 294

6.3 Different Solution Using a Shell Balance 301

6.4 Poiseuille and Couette Flows in Polymer Processing 313

6.5 Solution of the Equations of Motion in Cylindrical Coordinates 325

6.6 Solution of the Equations of Motion in Spherical Coordinates 330

Points for Chapter 6 336

 

Chapter 7: Laplace’s Equation, Irrotational and Porous-Media Flows 357

7.1 Introduction 357

7.2 Rotational and Irrotational Flows 359

7.3 General Two-Dimensional Irrotational Flow 364

7.4 Physical Interpretation of the Stream Function 367

7.5 Examples of Planar Irrotational Flow 369

7.6 Axially Symmetric Irrotational Flow 382

7.7 Uniform Streams and Point Sources 384

7.8 Doublets and Flow Past a Sphere 388

7.9 Single-Phase Flow in a Porous Medium 391

7.10 Two-Phase Flow in Porous Media 394

7.11 Wave Motion in Deep Water 400

Points for Chapter 7 404

 

Chapter 8: Boundary-Layer and Other Nearly Unidirectional Flows 418

8.1 Introduction 418

8.2 Simplified Treatment of Laminar Flow Past a Flat Plate 419

8.3 Simplification of the Equations of Motion 426

8.4 Blasius Solution for Boundary-Layer Flow 429

8.5 Turbulent Boundary Layers 432

8.6 Dimensional Analysis of the Boundary-Layer Problem 434

8.7 Boundary-Layer Separation 437

8.8 The Lubrication Approximation 448

8.9 Polymer Processing by Calendering 457

8.10 Thin Films and Surface Tension 463

Points for Chapter 8 466

 

Chapter 9: Turbulent Flow 480

9.1 Introduction 480

9.2 Physical Interpretation of the Reynolds Stresses 487

9.3 Mixing-Length Theory 488

9.4 Determination of Eddy Kinematic Viscosity and Mixing Length 491

9.5 Velocity Profiles Based on Mixing-Length Theory 493

9.6 The Universal Velocity Profile for Smooth Pipes 495

9.7 Friction Factor in Terms of Reynolds Number for Smooth Pipes 497

9.8 Thickness of the Laminar Sublayer 499

9.9 Velocity Profiles and Friction Factor for Rough Pipe 501

9.10 Blasius-Type Laws and the Energy-Loss Velocity Profile 502

9.11 A Correlation for the Reynolds Stresses 503

9.12 Computation of Turbulence by the k–ε Method 506

9.13 Analogies Between Momentum and Heat Transfer 520

9.14 Turbulent Jets 524

Points for Chapter 9 532

 

Chapter 10: Bubble Motion, Two-Phase Flow, and Fluidization 542

10.1 Introduction 542

10.2 Rise of Bubbles in Unconfined Liquids 542

10.3 Pressure Drop and Void Fraction in Horizontal Pipes 547

10.4 Two-Phase Flow in Vertical Pipes 554

10.5 Flooding 566

10.6 Introduction to Fluidization 570

10.7 Bubble Mechanics 572

10.8 Bubbles in Aggregatively Fluidized Beds 577

Points for Chapter 10 586

 

Chapter 11: Non-Newtonian Fluids 602

11.1 Introduction 602

11.2 Classification of Non-Newtonian Fluids 603

11.3 Constitutive Equations for Inelastic Viscous Fluids 606

11.4 Constitutive Equations for Viscoelastic Fluids 626

11.5 Response to Oscillatory Shear 633

11.6 Characterization of the Rheological Properties of Fluids 636

Points for Chapter 11 644

 

Chapter 12: Microfluidics and Electrokinetic Flow Effects 653

12.1 Introduction 653

12.2 Physics of Microscale Fluid Mechanics 654

12.3 Pressure-Driven Flow Through Microscale Tubes 655

12.4 Mixing, Transport, and Dispersion 656

12.5 Species, Energy, and Charge Transport 658

12.6 The Electrical Double Layer and Electrokinetic Phenomena 661

12.7 Measuring the Zeta Potential 676

12.8 Electroviscosity 678

12.9 Particle and Macromolecule Motion in Microfluidic Channels 678

Points for Chapter 12 683

 

Chapter 13: An Introduction to Computational Fluid Dynamics and ANSYS Fluent 688

13.1 Introduction and Motivation 688

13.2 Numerical Methods 690

13.3 Learning CFD by Using ANSYS Fluent 699

13.4 Practical CFD Examples 703

References for Chapter 13 719

 

Chapter 14: COMSOL Multiphysics for Solving Fluid Mechanics Problems 720

14.1 COMSOL Multiphysics—An Overview 720

14.2 The Steps for Solving Problems in COMSOL 723

14.3 Methods to Run COMSOL 725

14.4 Variables, Constants, Expressions, and Objects 741

14.5 Boundary Conditions 742

14.6 Variables Utilized by COMSOL 743

14.7 Wall Functions in Turbulent-Flow Problems 744

14.8 Streamline Plotting in COMSOL 747

14.9 Specific COMSOL Options Used in the Examples 749

14.10 Drawing Tools 754

14.11 Fluid Mechanics Problems Solvable by COMSOL 756

14.12 Conclusion—Problems and Learning Tools 761

 

Appendix A: Useful Mathematical Relationships 762

 

Appendix B: Solutions to the True/False Assertions 768

 

Appendix C: Some Vector and Tensor Operations 771

 

Primary Index 773

Comsol Multiphysics Index 782

The Authors 784