eBook [PDF] Munson, Young and Okiishi’s Fundamentals of Fluid Mechanics, 8th Edition By Philip Gerhart, Andrew Gerhart, John Hochstein

TABLE OF CONTENTS 1 Introduction 1 Learning Objectives 1 1.1 Some Characteristics of Fluids 3 1.2 Dimensions, Dimensional Homogeneity, and Units 4 1.2.1 Systems of Units 6 1.3 Analysis of Fluid Behavior 1 ...

TABLE OF CONTENTS 1 Introduction 1 Learning Objectives 1 1.1 Some Characteristics of Fluids 3 1.2 Dimensions, Dimensional Homogeneity, and Units 4 1.2.1 Systems of Units 6 1.3 Analysis of Fluid Behavior 11 1.4 Measures of Fluid Mass and Weight 11 1.4.1 Density 11 1.4.2 Specific Weight 12 1.4.3 Specific Gravity 12 1.5 Ideal Gas Law 12 1.6 Viscosity 14 1.7 Compressibility of Fluids 20 1.7.1 Bulk Modulus 20 1.7.2 Compression and Expansion of Gases 21 1.7.3 Speed of Sound 22 1.8 Vapor Pressure 23 1.9 Surface Tension 24 1.10 A Brief Look Back in History 27 1.11 Chapter Summary and Study Guide 29 References 30 2 Fluid Statics 31 Learning Objectives 31 2.1 Pressure at a Point 31 2.2 Basic Equation for Pressure Field 32 2.3 Pressure Variation in a Fluid at Rest 34 2.3.1 Incompressible Fluid 35 2.3.2 Compressible Fluid 37 2.4 Standard Atmosphere 39 2.5 Measurement of Pressure 41 2.6 Manometry 43 2.6.1 Piezometer Tube 43 2.6.2 U-Tube Manometer 44 2.6.3 Inclined-Tube Manometer 46 2.7 Mechanical and Electronic Pressure-Measuring Devices 47 2.8 Hydrostatic Force on a Plane Surface 50 2.9 Pressure Prism 56 2.10 Hydrostatic Force on a Curved Surface 59 2.11 Buoyancy, Flotation, and Stability 61 2.11.1 Archimedes’ Principle 61 2.11.2 Stability 64 2.12 Pressure Variation in a Fluid with Rigid-Body Motion 65 2.12.1 Linear Motion 66 2.12.2 Rigid-Body Rotation 68 2.13 Chapter Summary and Study Guide 70 References 71 3 Elementary Fluid Dynamics—The Bernoulli Equation 73 Learning Objectives 73 3.1 Newton’s Second Law 73 3.2 F = ma along a Streamline 76 3.3 F = ma Normal to a Streamline 80 3.4 Physical Interpretations and Alternate Forms of the Bernoulli Equation 82 3.5 Static, Stagnation, Dynamic, and Total Pressure 85 3.6 Examples of Use of the Bernoulli Equation 89 3.6.1 Free Jets 90 3.6.2 Confined Flows 92 3.6.3 Flowrate Measurement 98 3.7 The Energy Line and the Hydraulic Grade Line 103 3.8 Restrictions on Use of the Bernoulli Equation 106 3.8.1 Compressibility Effects 106 3.8.2 Unsteady Effects 107 3.8.3 Rotational Effects 109 3.8.4 Other Restrictions 110 3.9 Chapter Summary and Study Guide 110 References 111 4 Fluid Kinematics 112 Learning Objectives 112 4.1 The Velocity Field 112 4.1.1 Eulerian and Lagrangian Flow Descriptions 115 4.1.2 One-, Two-, and Three-Dimensional Flows 116 4.1.3 Steady and Unsteady Flows 117 4.1.4 Streamlines, Streaklines, and Pathlines 117 4.2 The Acceleration Field 121 4.2.1 Acceleration and the Material Derivative 121 4.2.2 Unsteady Effects 124 4.2.3 Convective Effects 124 4.2.4 Streamline Coordinates 127 4.3 Control Volume and System Representations 129 4.4 The Reynolds Transport Theorem 131 4.4.1 Derivation of the Reynolds Transport Theorem 133 4.4.2 Physical Interpretation 138 4.4.3 Relationship to Material Derivative 138 4.4.4 Steady Effects 139 4.4.5 Unsteady Effects 140 4.4.6 Moving Control Volumes 141 4.4.7 Selection of a Control Volume 142 4.5 Chapter Summary and Study Guide 143 References 144 5 Finite Control Volume Analysis 145 Learning Objectives 145 5.1 Conservation of Mass—The Continuity Equation 146 5.1.1 Derivation of the Continuity Equation 146 5.1.2 Fixed, Nondeforming Control Volume 148 5.1.3 Moving, Nondeforming Control Volume 154 5.1.4 Deforming Control Volume 156 5.2 Newton’s Second Law—The Linear Momentum and Moment-of-Momentum Equations 159 5.2.1 Derivation of the Linear Momentum Equation 159 5.2.2 Application of the Linear Momentum Equation 160 5.2.3 Derivation of the Moment-of-Momentum Equation 174 5.2.4 Application of the Moment-of-Momentum Equation 175 5.3 First Law of Thermodynamics—The Energy Equation 182 5.3.1 Derivation of the Energy Equation 182 5.3.2 Application of the Energy Equation 185 5.3.3 The Mechanical Energy Equation and the Bernoulli Equation 189 5.3.4 Application of the Energy Equation to Nonuniform Flows 195 5.3.5 Combination of the Energy Equation and the Moment-of-Momentum Equation 198 5.4 Second Law of Thermodynamics—Irreversible Flow 199 5.4.1 Semi-infinitesimal Control Volume Statement of the Energy Equation 199 5.4.2 Semi-infinitesimal Control Volume Statement of the Second Law of Thermodynamics 199 5.4.3 Combination of the Equations of the First and Second Laws of Thermodynamics 200 5.5 Chapter Summary and Study Guide 201 References 203 6 Differential Analysis of Fluid Flow 204 Learning Objectives 204 6.1 Fluid Element Kinematics 205 6.1.1 Velocity and Acceleration Fields Revisited 206 6.1.2 Linear Motion and Deformation 206 6.1.3 Angular Motion and Deformation 207 6.2 Conservation of Mass 210 6.2.1 Differential Form of Continuity Equation 210 6.2.2 Cylindrical Polar Coordinates 213 6.2.3 The Stream Function 213 6.3 The Linear Momentum Equation 216 6.3.1 Description of Forces Acting on the Differential Element 217 6.3.2 Equations of Motion 219 6.4 Inviscid Flow 220 6.4.1 Euler’s Equations of Motion 220 6.4.2 The Bernoulli Equation 220 6.4.3 Irrotational Flow 222 6.4.4 The Bernoulli Equation for Irrotational Flow 224 6.4.5 The Velocity Potential 224 6.5 Some Basic, Plane Potential Flows 227 6.5.1 Uniform Flow 228 6.5.2 Source and Sink 229 6.5.3 Vortex 231 6.5.4 Doublet 234 6.6 Superposition of Basic, Plane Potential Flows 236 6.6.1 Source in a Uniform Stream—Half-Body 236 6.6.2 Rankine Ovals 239 6.6.3 Flow Around a Circular Cylinder 241 6.7 Other Aspects of Potential Flow Analysis 246 6.8 Viscous Flow 247 6.8.1 Stress–Deformation Relationships 247 6.8.2 The Navier–Stokes Equations 248 6.9 Some Simple Solutions for Laminar, Viscous, Incompressible Flows 249 6.9.1 Steady, Laminar Flow Between Fixed Parallel Plates 250 6.9.2 Couette Flow 252 6.9.3 Steady, Laminar Flow in Circular Tubes 254 6.9.4 Steady, Axial, Laminar Flow in an Annulus 257 6.10 Other Aspects of Differential Analysis 259 6.10.1 Numerical Methods 259 6.11 Chapter Summary and Study Guide 260 References 261 7 Dimensional Analysis,Similitude, and Modeling 262 Learning Objectives 262 7.1 The Need for Dimensional Analysis 263 7.2 Buckingham Pi Theorem 265 7.3 Determination of Pi Terms 266 7.4 Some Additional Comments about Dimensional Analysis 271 7.4.1 Selection of Variables 271 7.4.2 Determination of Reference Dimensions 273 7.4.3 Uniqueness of Pi Terms 274 7.5 Determination of Pi Terms by Inspection 275 7.6 Common Dimensionless Groups in Fluid Mechanics 277 7.7 Correlation of Experimental Data 282 7.7.1 Problems with One Pi Term 282 7.7.2 Problems with Two or More Pi Terms 283 7.8 Modeling and Similitude 286 7.8.1 Theory of Models 286 7.8.2 Model Scales 289 7.8.3 Practical Aspects of Using Models 290 7.9 Some Typical Model Studies 292 7.9.1 Flow Through Closed Conduits 292 7.9.2 Flow Around Immersed Bodies 294 7.9.3 Flow with a Free Surface 298 7.10 Similitude Based on Governing Differential Equations 301 7.11 Chapter Summary and Study Guide 304 References 305 8 Viscous Flow In Pipes 307 Learning Objectives 307 8.1 General Characteristics of Pipe Flow 308 8.1.1 Laminar or Turbulent Flow 309 8.1.2 Entrance Region and Fully Developed Flow 311 8.1.3 Pressure and Shear Stress 312 8.2 Fully Developed Laminar Flow 313 8.2.1 From F = ma Applied Directly to a Fluid Element 314 8.2.2 From the Navier–Stokes Equations 318 8.2.3 From Dimensional Analysis 319 8.2.4 Energy Considerations 321 8.3 Fully Developed Turbulent Flow 323 8.3.1 Transition from Laminar to Turbulent Flow 323 8.3.2 Turbulent Shear Stress 325 8.3.3 Turbulent Velocity Profile 329 8.3.4 Turbulence Modeling 333 8.3.5 Chaos and Turbulence 333 8.4 Dimensional Analysis of Pipe Flow 333 8.4.1 Major Losses 334 8.4.2 Minor Losses 339 8.4.3 Noncircular Conduits 349 8.5 Pipe Flow Examples 352 8.5.1 Single Pipes 352 8.5.2 Multiple Pipe Systems 362 8.6 Pipe Flowrate Measurement 366 8.6.1 Pipe Flowrate Meters 366 8.6.2 Volume Flowmeters 371 8.7 Chapter Summary and Study Guide 372 References 373 9 Flow Over Immersed Bodies 375 Learning Objectives 375 9.1 General External Flow Characteristics 376 9.1.1 Lift and Drag Concepts 377 9.1.2 Characteristics of Flow Past an Object 380 9.2 Boundary Layer Characteristics 384 9.2.1 Boundary Layer Structure and Thickness on a Flat Plate 384 9.2.2 Prandtl/Blasius Boundary Layer Solution 388 9.2.3 Momentum Integral Boundary Layer Equation for a Flat Plate 392 9.2.4 Transition from Laminar to Turbulent Flow 397 9.2.5 Turbulent Boundary Layer Flow 399 9.2.6 Effects of Pressure Gradient 403 9.2.7 Momentum Integral Boundary Layer Equation with Nonzero Pressure Gradient 407 9.3 Drag 408 9.3.1 Friction Drag 409 9.3.2 Pressure Drag 410 9.3.3 Drag Coefficient Data and Examples 412 9.4 Lift 426 9.4.1 Surface Pressure Distribution 428 9.4.2 Circulation 434 9.5 Chapter Summary and Study Guide 438 References 439 10 Open-Channel Flow 441 Learning Objectives 441 10.1 General Characteristics of Open-Channel Flow 441 10.2 Surface Waves 443 10.2.1 Wave Speed 443 10.2.2 Froude Number Effects 446 10.3 Energy Considerations 448 10.3.1 Energy Balance 448 10.3.2 Specific Energy 449 10.4 Uniform Flow 452 10.4.1 Uniform Flow Approximations 452 10.4.2 The Chezy and Manning Equations 453 10.4.3 Uniform Flow Examples 456 10.5 Gradually Varied Flow 461 10.6 Rapidly Varied Flow 463 10.6.1 The Hydraulic Jump 464 10.6.2 Sharp-Crested Weirs 469 10.6.3 Broad-Crested Weirs 472 10.6.4 Underflow (Sluice) Gates 475 10.7 Chapter Summary and Study Guide 476 References 478 11 Compressible Flow 479 Learning Objectives 479 11.1 Ideal Gas Thermodynamics 480 11.2 Stagnation Properties 485 11.3 Mach Number and Speed of Sound 487 11.4 Compressible Flow Regimes 492 11.5 Shock Waves 496 11.5.1 Normal Shock 497 11.6 Isentropic Flow 501 11.6.1 Steady Isentropic Flow of an Ideal Gas 502 11.6.2 Incompressible Flow and Bernoulli’s Equation 505 11.6.3 The Critical State 506 11.7 One-Dimensional Flow in a Variable Area Duct 507 11.7.1 General Considerations 507 11.7.2 Isentropic Flow of an Ideal Gas with Area Change 510 11.7.3 Operation of a Converging Nozzle 516 11.7.4 Operation of a Converging–Diverging Nozzle 518 11.8 Constant-Area Duct Flow with Friction 522 11.8.1 Preliminary Consideration: Comparison with Incompressible Duct Flow 522 11.8.2 The Fanno Line 523 11.8.3 Adiabatic Frictional Flow (Fanno Flow) of an Ideal Gas 527 11.9 Frictionless Flow in a Constant-Area Duct with Heating or Cooling 535 11.9.1 The Rayleigh Line 535 11.9.2 Frictionless Flow of an Ideal Gas with Heating or Cooling (Rayleigh Flow) 537 11.9.3 Rayleigh Lines, Fanno Lines, and Normal Shocks 541 11.10 Analogy Between Compressible and Open-Channel Flows 542 11.11 Two-Dimensional Supersonic Flow 543 11.12 Chapter Summary and Study Guide 545 References 548 12 Turbomachines 549 Learning Objectives 549 12.1 Introduction 550 12.2 Basic Energy Considerations 551 12.3 Angular Momentum Considerations 555 12.4 The Centrifugal Pump 557 12.4.1 Theoretical Considerations 558 12.4.2 Pump Performance Characteristics 562 12.4.3 Net Positive Suction Head (NPSH) 564 12.4.4 System Characteristics, Pump-System Matching, and Pump Selection 566 12.5 Dimensionless Parameters and Similarity Laws 570 12.5.1 Special Pump Scaling Laws 572 12.5.2 Specific Speed 573 12.5.3 Suction Specific Speed 574 12.6 Axial-Flow and Mixed-Flow Pumps 575 12.7 Fans 577 12.8 Turbines 578 12.8.1 Impulse Turbines 579 12.8.2 Reaction Turbines 586 12.9 Compressible Flow Turbomachines 589 12.9.1 Compressors 589 12.9.2 Compressible Flow Turbines 593 12.10 Chapter Summary and Study Guide 595 References 596 A Computational Fluid Dynamics 598 B Physical Properties of Fluids 617 C Properties of the U.S. Standard Atmosphere 622 D Compressible Flow Functions for an Ideal Gas 624 E Comprehensive Table of Conversion Factors 632 Questions and Problems Chapter 1 P-1 Chapter 2 P-9 Chapter 3 P-28 Chapter 4 P-43 Chapter 5 P-51 Chapter 6 P-72 Chapter 7 P-82 Chapter 8 P-92 Chapter 9 P-104 Chapter 10 P-114 Chapter 11 P-121 Chapter 12 P-126 Index I-1