Chemical engineering fluid mechanics:
Gespeichert in:
| Hauptverfasser: | , |
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| Format: | Buch |
| Sprache: | English |
| Veröffentlicht: |
Boca Raton ; London ; New York
CRC Press
2022
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| Ausgabe: | Third edition |
| Schriftenreihe: | Engineering - chemical
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| Schlagworte: | |
| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | First issued in paperback 2022 |
| Beschreibung: | xxiii, 555 Seiten Illustrationen, Diagramme |
| ISBN: | 9781032339771 |
Internformat
MARC
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| 245 | 1 | 0 | |a Chemical engineering fluid mechanics |c Ron Darby (Texas A&M University, College Station, Texas), Raj P. Chhabra (Indian Institute of Technology, Kanpur, India) |
| 250 | |a Third edition | ||
| 264 | 1 | |a Boca Raton ; London ; New York |b CRC Press |c 2022 | |
| 300 | |a xxiii, 555 Seiten |b Illustrationen, Diagramme | ||
| 336 | |b txt |2 rdacontent | ||
| 337 | |b n |2 rdamedia | ||
| 338 | |b nc |2 rdacarrier | ||
| 490 | 0 | |a Engineering - chemical | |
| 500 | |a First issued in paperback 2022 | ||
| 650 | 4 | |a Chemical processes | |
| 650 | 4 | |a Fluid mechanics | |
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| 700 | 1 | |a Chhabra, Raj P. |d 1953- |e Verfasser |0 (DE-588)124082580 |4 aut | |
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| 776 | 0 | 8 | |i Erscheint auch als |n Online-Ausgabe |z 978-1-3153-7067-5 |
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Datensatz im Suchindex
| _version_ | 1804184290709209088 |
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| adam_text | Contents Preface.................................................................................................................................................... xvii About Professor Darby.......................................................................................................................... xix Acknowledgments.................................................................................................................................. xxi Unit Conversion Factors...................................................................................................................... xxiii Chapter 1 Basic Concepts....................................................................................................................1 I. Fundamentals............................................................................................................. 1 A. Introduction and Scope...................................................................................... 1 B. Basic Laws.......................................................................................................... 1 C. Experience.......................................................................................................... 2 II. Objective.................................................................................................................... 2 A. A Note on Problem Solving.............................................................................. 3 III. Phenomenological Rate or Transport Laws............................................................4 A.
Fourier’s Law of Heat Conduction.................................................................... 6 B. Fick’s Law of Diffusion..................................................................................... 7 C. Ohm’s Law of Electrical Conductivity............................................................ 7 D. Newton’s Law of Viscosity................................................................................7 1. Momentum Flux and Shear Stress............................................................ 8 2. Vectors and Dyads....................................................................................... 8 3. Newtonian and Non-Newtonian Fluids..................................................... 9 IV. The “System”........................................................................................................... 10 V. Turbulent Macroscopic (Convective) Transport Models...................................... 11 Summary........................................................................................................................... 13 Problems...... ..................................................................................................................... 13 Notation............................................................................................................................. 15 References......................................................................................................................... 16 Chapter 2 Dimensional Analysis and Scale-
Up...............................................................................17 I. II. III. IV. V. VI. VIL Introduction.............................................................................................................. 17 Units and Dimensions............................................................................................. 17 A. Dimensions................................... 17 B. Units................................................................................................................... 19 C. Conversion Factors.......................................................................................... 20 Conservation of Dimensions.................................................................................. 21 A. Numerical Values.............................. ............................................. 22 B. Consistent Units............................................................................................... 23 Dimensional Analysis............................................................................................ 24 A. Pipeline Analysis.......................................................... 25 B. Uniqueness........................................................................................................ 28 C. Dimensionless Variables................................................................. 28 D. Problem Solution.............................................. 29 E. Alternate Groups............................................................................................. 29 Scale-
Up...................................................................................... 30 Dimensionless Groups in Fluid Mechanics......................................................... 34 Accuracy and Precision.................................................................. 34 vii
Contents viii Summary........................................................................................................................... 37 Problems............................................................................................................................ 38 Notation............................................................................................................................. 47 Chapter 3 Fluid Properties in Perspective....................................................................................... 49 Classification of Materials and Fluid Properties..... ............................................. 49 Determination of Fluid Viscous (Rheological) Properties................................... 51 A. Cup and Bob (Couette) Viscometer................................................................ 52 B. Tube Flow (Poiseuille) Viscometer..................... ................................... 55 III. Types of Non-Newtonian Fluid Behavior.............................................................. 57 A. Newtonian Fluid............................................................................................... 59 B. Bingham Plastic Model.................................................................................... 59 C. Power Law Model............................................................................................ 60 D. Structural Viscosity Models.............. ................................... 62 1. Carreau Model.............................................................................. 62 2. Other
Models............................................................................................. 64 IV. Temperature Dependence of Viscosity.................................................................. 64 A. Liquids..................................................... 65 B. Gases............... ........................... 65 V. Density...................................................................................................................... 66 VI. Surface Tension........................................................................................................ 67 Summary........................................................................................... 67 Problems............................................................................................................................ 67 Notation.................. 76 References............. .......................................................................................................... 77 I. II. Chapter 4 Fluid Statics....................................................................................................................... 79 I. II. Stress and Pressure.................................................................................................. 79 The Basic Equation of Fluid Statics........................................................................ 81 A. Constant Density Fluids................................................................................... 82 B. Ideal Gas:
Isothermal.................................................................................. 84 C. Ideal Gas: Isentropic......................................................... 84 D. The Standard Atmosphere...............................................................................85 III. Moving Systems....................................................................................................... 86 A. Vertical Acceleration....................................................................................... 86 B. Horizontally Accelerating Free Surface........................................... 86 C. Rotating Fluid.............................. 87 IV. Buoyancy................................................................................................................... 88 V. Static Forces on Solid Boundaries.......................................................................... 88 Summary........................................................................................................................... 92 Problems............................................................................................................................ 92 Notation................. ........................................................................................................... 99 Chapter 5 Conservation Principles................................................................................................... 101 I . The System............................................................................................................... 101 IL
Conservation of Mass.............................................................................................101 A. Macroscopic Mass Balance...................................... 101 B. Microscopic Mass Balance............................................................................ 103
ix Contents III. Conservation of Energy......... ................................ 104 A. Internal Energy..................................................... .......................................... 105 1. Ideal Gas.................................................................................................... 106 2. Nonideal Gas....................................... 106 3. Solids and Liquids....................................................... 107 B. Enthalpy........................................................... 107 1. Ideal Gas..................................................... 107 2. Nonideal Gas................................................... ......................................... 107 3. Solids and Liquids................................................................................... 108 IV. Irreversible Effects...................................................................................................108 A. Kinetic Energy Correction........................... 110 V. Conservation of Linear Momentum....................................................................... 113 A. One-Dimensional Flow in a Ihbe............... ................................................. 114 B. The Loss Coefficient................................................. 116 C. Conservation of Angular Momentum......... ................................................. 119 D. Moving Boundary Systems and Relative Motion....................................... 120 E. Microscopic Momentum Balance................................................................. 122
Summary........................................................... 125 Problems.......................................................................................................................... 125 Notation................................................................................................ 135 Reference......................................................................................................................... 136 Chapter 6 Pipe Flow..................................................................... I. II. 137 Flow Regimes.......................................... 137 General Relations for Pipe Flows.............. ........ 138 A. Energy Balance.............................................................................................. 138 B. Momentum Balance...................................................................................... 139 C. Continuity....................................................................................................... 140 D. Energy Dissipation.................................................. 140 III. Newtonian Fluids................................................................................................... 140 A. Laminar Flow................................................................................................ 140 B. Turbulent Flow.......................... 142 1. Boundary Layer.............................................. ......................................... 142 2. Thrbulent Momentum Flux..................... 142 3. Mixing Length
Theory............................................................................ 143 4. Friction Loss in Smooth Pipe.................................................................. 145 5. Friction Loss in Rough Ihbes...................... 146 6. Friction Loss in Rough Pipe............... .............. 146 7. Wall Roughness........................................................................................ 148 C. All Flow Regimes........................................... 149 IV. Power Law Fluids.................................................................................................. 149 A. Laminar Flow..................................................... 149 B. Thrbulent Flow............................................................................................... 150 C. All Flow Regimes.......................................... 151 V. Bingham Plastics.................................................................................................... 151 A. Laminar Flow....................................... 152 B. Thrbulent Flow.......................................................................................... 153 C. All Reynolds Numbers................................................................................. 153
Contents x VI. Pipe Flow Problems............................................................................................... 153 A. Unknown Driving Force............................................................................... 154 1. Newtonian Fluid..................................................................................... 154 2. Power Law Fluid.................................................................................... 155 3. Bingham Plastic...................................................................................... 155 B. Unknown Flow Rate..................................................................................... 158 1. Newtonian Fluid..................................................................................... 158 2. Power Law Fluid................................................ 159 3. Bingham Plastic.......................................................................................161 C. Unknown Diameter........................................................................................ 161 1. Newtonian Fluid..................................................................................... 162 2. Power Law Fluid.................................................................................... 162 3. Bingham Plastic...................................................................................... 163 D. Use of Tables................................................................................................... 165 VIL Tube Flow (Poiseuille)
Viscometer.................................................................... 165 VIII. Turbulent Drag Reduction..................................................................................... 166 Summary..........................................................................................................................170 Problems........................................................................................................................... 171 Notation............................................................................................................................ 178 References........................................................................................................................179 Chapter 7 Internal Flow Applications............................................................................................. 181 I. II. III. IV. V. NoncircularConduits............................................................................................ 181 A. Laminar Flows................................................................................................ 181 1. Flow in a Slit............................................................................................ 181 2. Flow in a Film.......................................................................................... 182 3. Annular Flow........................................................................................... 183 B. Turbulent Flows............................................................................................. 183 Most Economical
Diameter................................................................................. 185 A. Newtonian Fluids........................................................................................... 188 B. Non-Newtonian Fluids...................................................................................189 1. Power Law Fluid..................................................................................... 190 2. Bingham Plastic........................................................................................190 Friction Loss in Valvesand Fittings.....................................................................191 A. Loss Coefficient............................................................................................. 191 B. Equivalent L/D Method...... :......................................................................... 191 C. Crane Method............................................ 193 D. 2-K (Hooper) Method................................................................................... 193 E. З-K (Darby) Method...................................................................................... 193 Non-Newtonian Fluids............................................................................................ 194 Pipe Flow Problems with Fittings.......................................................................... 197 A. Unknown Driving Force............................................................................... 197 1. Newtonian Fluid......................................................................................
197 2. Power Law Fluid..................................................................................... 198 3. Bingham Plastic...................................................................................... 198 B. Unknown Flow Rate..................................................................................... 198 1. Newtonian Fluid........................................... 198 2. Power Law Fluid.................................................................................... 199 3. Bingham Plastic...................................................................................... 199
Contents xi Unknown Diameter.......................................... 199 1. Newtonian Fluids.................... 199 2. Power Law Fluid..................................................................................... 200 3. Bingham Plastic............... ............................. 201 VI. Slack Flow............................................................... 201 VII. Pipe Networks................... .................................. 204 Problems................................................ 208 Notation............................................................................... .................. 215 References................................................................................... 216 C. Chapter 8 Pumps and Compressors.......................................................................................... 217 Pumps..................................................................................................................... 217 A. Positive Displacement Pumps....................................................................... 217 B. Centrifugal Pumps................................................... ......... 217 П. Pump Characteristics............................................................................................. 218 III. Pumping Requirements and Pump Selection...................................................... 220 A. Required Head................................... ............................................................220 B. Composite Curves............................................... 221 IV. Cavitation
and NPSH............................................................................................. 223 A. Vapor Lock and Cavitation........................................................................... 223 B. Net Positive Suction Head.......................... 223 C. Specific Speed........................................ 225 D. Suction Specific Speed..................................................................................225 V. Compressors............................................................................................................ 226 A. Isothermal Compression................................................................................228 B. Isentropic Compression.................................................................................228 C. StagedOperation........................................................................................... 229 D. Efficiency......................... 230 Summary.......................................................................................................................... 230 Problems................................................................ 230 Notation...................................................................................... 237 References.......................................................... 237 I. Chapter 9 Compressible Flows......................................................................................................... 239 I. II. Gas Properties.........................................................................................................
239 A. Ideal Gas............. ............................................................ 239 B. The Speed of Sound....................................................................................... 240 Pipe Flow................................................................................................................ 241 A. Isothermal Flow................................................ ............................................. 242 B. Adiabatic Flow.............................................................................................. 244 C. Choked Flow.................................................................................................. 245 1. Isothermal................................................................................................. 245 2. Adiabatic.............................................. 246 D. The Expansion Factor.................................................................................. 246 E. Frictionless Adiabatic Flow........................... 248 F. General Fluid Properties.............................................................................. 250
Contents xii IIL Generalized Gas Flow Expressions: Ideal Gas.................................................. 251 A. Governing Equations.................................................................................... 251 1. Continuity................................................................................................. 251 2. Energy.................................................................................................... 251 3. Momentum...............................................................................................251 B. Applications......................................................................... ........................... 256 C. Solution of High-Speed Ideal Gas Problems..............................................259 1. Unknown Driving Force........................................................................ 259 2. Unknown Flow Rate................................................................................ 259 3. Unknown Diameter.................................................................................260 Summary......................................................................................................................... 260 Problems......................................................................................................................... 260 Notation........................................................................................................................... 264
References....................................................................................................................... 265 Chapter 10 Flow Measurement......................................................... 267 Scope................................................................... ,.................................................. 267 Pitot Tube............................................................................................................... 267 Venturi and Nozzle................................................................................................269 Orifice Meter.......................................................................................................... 271 A. Incompressible Flow..................................................................................... 276 B. Compressible Flow....................................................................................... 277 C. Friction Loss Coefficient.............................................................................. 279 D. Other Geometries ......................................................................................... 280 V. Orifice Problems................................................................................................... 280 A. Unknown Pressure Drop............................................................................... 281 B. Unknown Flow Rate..................................................................................... 281 C. Unknown
Diameter....................................................................................... 281 VI. Noninvasive Techniques....................................................................................... 282 A. Vortex-Shedding Flow Meter...................................................................... 282 B. Magnetic Flow Meter.................................................................................... 282 C. Ultrasonic Flow Meter.................................................................................. 283 D. The Coriolis Flow Meter............................................................................. 284 Summary.........................................................................................................................284 Problems.......................................................................................................................... 285 Notation........................................................................................................................... 288 References............................................................................. 289 I. II. III. IV. Chapter 11 Safety Relief and Control Valves................................................................................ 291 I. Safety Relief Valves............................................................................................... 291 A. Background..................................................................................................... 291 B. Valve
Sizing.................................................................................................... 291 1. Flow Model.................................................................................. ........292 2. Fluid Property Model............................................................................ 293 3. Flow Data............................................................................................... 293 C. Fluid Models................................................................................................... 294 1. Incompressible Fluids............................................................................ 294 2. Ideal Gases........................................................... 295
Contents xiii 3. The Homogeneous Direct Integration Method for Any Single- or Two-Phase Flow............................................... .............. 296 4. Nonequilibrium (Flashing) Flows......................................................... 297 D. The Discharge Coefficient............................................................................ 298 II. Control Valves.......................................................................................................300 A. Valve Characteristics.................................................................................... 301 B. Overview of Control Valve Sizing............................................................... 303 C. The Equation Constant................................................................................. 305 1. Incompressible Fluids............................................................................. 305 D. Valve Coefficients......................................................................................... 306 1. The Valve Sizing Coefficient.................................................................. 306 2. FP·. The Piping Geometry Factor...........................................................308 3. F[ (K„); The Liquid Pressure Recovery Factor.................................... 308 4. F¿ The Valve Style Modifier.................................................................. 309 E. Cavitating and Flashing Liquids.................................................................. 311 1.
Introduction.............................................................................................. 311 2. f rc: The Liquid Critical Pressure Ratio.......................................... 311 3. xT: The Pressure Differential Ratio Factor for a Control Valve without Attached Fittings at ChokedFlow.................................. 313 E Viscous Fluids............................................................................................... 314 G. Compressible Fluids..................................................................................... 316 1. Subsonic Flow......................................................................................... 316 2. Choked Flow............................................................................ 318 H. General (HDI) Method for All Fluids andAllConditions..........................318 I. Valve-System Interaction............................................................................ 323 J. Matching Valve Trim to the System........................................................... 325 Summary.........................................................................................................................327 Problems............................................................................................. 328 Notation........................................................................................................................... 329 References...................................................................................................................... 330 F= Chapter 12 External
Flows................................................................................................................ 333 The Drag Coefficient.............................................................................................. 333 A. Stokes Flow..................................................................................................... 333 B. Form Drag....................................................................................................... 334 C. All Reynolds Numbers.................................................................................. 335 D. Cylinder Drag................................................................................................ 336 E. Boundary Layer Effects................................................................................ 336 II. Falling Particles...................................................................................................... 337 A. Unknown Velocity........................................................................................ 338 B. Unknown Diameter....................................................................................... 339 C. Unknown Viscosity....................................................................................... 340 III. Correction Factors........................................................... 340 A. Wall Effects................................................................................................... 340 B. Effect of Particle Shape................................................................................. 341
C. Drops and Bubbles......................................................................................... 349 IV. Non-Newtonian Fluids........................................................................................... 349 I.
Contents xiv A. Power Law Fluids........................................................................................ 350 1. Unknown Velocity................................................................................. 351 2. Unknown Diameter............................................................................... 352 B. Wall Effects.................................................................................................. 354 C. Carreau Fluids.................................................................. ........... ................ 354 D. Bingham Plastics......................................................................................... 355 Summary................................................................ ....................................................... 357 Problems......................................................................................................................... 357 Notation.......................................................................................................................... 359 References...................................................................................................................... 359 Chapter 13 Fluid-Solid Separations by Free Settling....................... .......................................... 361 I. II. III. Fluid-Solid Separations..................................... ............................................... 361 Gravity Settling................................................................. ................................. 361 Centrifugal
Separation...................................................... .............. ................. 363 A. Separation of Immiscible Liquids............................................................... 366 IV. Cyclone Separations.................................... ....................................................... 369 A. General Characteristics............. .................................................................. 369 B. Aerocyclones................................................................................................. 370 1. Velocity Distribution............................................................................. 370 2. Pressure Drop........................................ ................................................ 372 3. Separation Efficiency............................................................................ 372 4. Other Effects..................... .............................. ...................................... 375 C. Hydrocyclones...............................................................................................375 Summary........................................................................................................................ 378 Problems.................................................................................................... .....................378 Notation.......................................................................................................................... 381
References...................................................................................................................... 382 Chapter 14 Flow in Porous Media.................................................................................................. 383 I. II. III. IV. V. VI. Description of Porous Media........ ........................................................................ 383 A. Hydraulic Diameter.................................................................... ................. 384 B. Porous Medium Friction Factor...................................................................385 C. Porous Medium Reynolds Number............... ..............................................385 Friction Loss in Porous Media.............................................................................. 385 A. Laminar Flow................................................................................................385 B. Ihrbulent Flow...............................................................................................386 C. All Reynolds Numbers................................................................................. 386 Permeability................................................................... ....................................... 386 Multidimensional Flow........................... .............................................................. 387 Packed Columns..................................................................................................... 389
Filtration.................................................................................................................. 394 A. Governing Equations.................................................................................... 394 B. Constant Pressure Operation....................................................................... 395 C. Constant Flow Operation..............................................................................396 D. Cycle Time..................................................................................................... 396
Contents XV E. Plate-and-Frame Filter.............................. 397 F. Rotary Drum Filter..................................... ...397 G. Compressible Cake.................................................... ....398 Summary................................................................................ ,......;................. .............399 Problems............................................................................... 399 Notation.............................................................................. ..................... 405 Réferences.......................................... 406 Chapter 15 Fluidization and Sedimentation.................... 407 I. Fluidization................ ....................................................................................... ....407 A. Governing Equations...................................... 407 B. Minimum Bed Voidage.................................... 409 C. Nonspherical Particles...................................... 409 II. Sedimentation............ ............................................................................................. 410 A. Hindered Settling............................................................................................ 410 B. Fine Particles.................................................................................................. 411 C. Coarse Particles................................................... 413 D. All Flow Regimes........................................................................................... 414 ПІ. Generalized
Sedimentation/Fluidization.............................................................. 415 ГѴ. Thickening............................................................................................................... 416 Summary......................................................................................................................... 420 Problems...........................................................................................................................421 Notation........................................................................................................................... 424 References............................ 425 Chapter 16 Two-Phase Flow.................... 427 I. Scope......................................................................................................................... 427 II. Definitions................................................................................................................ 427 III. Fluid-Solid Two-Phase Pipe Flows....................................................................... 430 A. Pseudohomogeneous Flows........................................................................... 431 B. Heterogeneous Liquid-Solid Flows...............................................................431 C. Pneumatic Solids Transport........................................................................... 435 1. Horizontal Transport............................................................................... 437 2. Vertical Transport........................................ 439 IV. Gas-
Liquid Two-Phase Pipe Flow............................... 439 A. Flow Regimes................................................................................................. 440 B. Homogeneous Gas-Liquid Models.............................................................. 442 1. Omega Method for Homogeneous Equilibrium Flow..........................445 2. Generalized (Homogeneous Direct Integration) Method for All Homogeneous Flow Conditions.......................................... 447 C. Separated Flow Models................................................................................. 447 D. Slip and Holdup.............................................................................................. 450 Summary..........................................................................................................................455 Problems...........................................................................................................................455 Notation............................................................................................................................ 457 References..................................................................... 459
xvi Contents Appendix A: Viscosities and Other Properties of Gases and Liquids.................................... 461 Appendix B: Generalized Viscosity Plot............................... 483 Appendix C: Properties of Gases............................................................................................... 485 Appendix D: Pressure-Enthalpy Diagrams for Various Compounds.................................... 489 Appendix E: Microscopic Conservation Equations in Rectangular, Cylindrical, and Spherical Coordinates............................................................ 497 Appendix F: Standard Steel Pipe Dimensions and Capacities................................................ 501 Appendix G: Flow of Water/Air through Schedule 40 Pipe..................................................... 507 Appendix H: Typical Pump Head Capacity Range Charts..................................................... 517 Appendix I: Fanno Line Tables for Adiabatic Flow of Air in a Constant Area Duct.......... 537 Index.............................................................................................................................................. 545
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Contents Preface. xvii About Professor Darby. xix Acknowledgments. xxi Unit Conversion Factors. xxiii Chapter 1 Basic Concepts.1 I. Fundamentals. 1 A. Introduction and Scope. 1 B. Basic Laws. 1 C. Experience. 2 II. Objective. 2 A. A Note on Problem Solving. 3 III. Phenomenological Rate or Transport Laws.4 A.
Fourier’s Law of Heat Conduction. 6 B. Fick’s Law of Diffusion. 7 C. Ohm’s Law of Electrical Conductivity. 7 D. Newton’s Law of Viscosity.7 1. Momentum Flux and Shear Stress. 8 2. Vectors and Dyads. 8 3. Newtonian and Non-Newtonian Fluids. 9 IV. The “System”. 10 V. Turbulent Macroscopic (Convective) Transport Models. 11 Summary. 13 Problems. . 13 Notation. 15 References. 16 Chapter 2 Dimensional Analysis and Scale-
Up.17 I. II. III. IV. V. VI. VIL Introduction. 17 Units and Dimensions. 17 A. Dimensions. 17 B. Units. 19 C. Conversion Factors. 20 Conservation of Dimensions. 21 A. Numerical Values. . 22 B. Consistent Units. 23 Dimensional Analysis. 24 A. Pipeline Analysis. 25 B. Uniqueness. 28 C. Dimensionless Variables. 28 D. Problem Solution. 29 E. Alternate Groups. 29 Scale-
Up. 30 Dimensionless Groups in Fluid Mechanics. 34 Accuracy and Precision. 34 vii
Contents viii Summary. 37 Problems. 38 Notation. 47 Chapter 3 Fluid Properties in Perspective. 49 Classification of Materials and Fluid Properties. . 49 Determination of Fluid Viscous (Rheological) Properties. 51 A. Cup and Bob (Couette) Viscometer. 52 B. Tube Flow (Poiseuille) Viscometer. . 55 III. Types of Non-Newtonian Fluid Behavior. 57 A. Newtonian Fluid. 59 B. Bingham Plastic Model. 59 C. Power Law Model. 60 D. Structural Viscosity Models. . 62 1. Carreau Model. 62 2. Other
Models. 64 IV. Temperature Dependence of Viscosity. 64 A. Liquids. 65 B. Gases. . 65 V. Density. 66 VI. Surface Tension. 67 Summary. 67 Problems. 67 Notation. 76 References. '. 77 I. II. Chapter 4 Fluid Statics. 79 I. II. Stress and Pressure. 79 The Basic Equation of Fluid Statics. 81 A. Constant Density Fluids. 82 B. Ideal Gas:
Isothermal. 84 C. Ideal Gas: Isentropic. 84 D. The Standard Atmosphere.85 III. Moving Systems. 86 A. Vertical Acceleration. 86 B. Horizontally Accelerating Free Surface. 86 C. Rotating Fluid. 87 IV. Buoyancy. 88 V. Static Forces on Solid Boundaries. 88 Summary. 92 Problems. 92 Notation. . 99 Chapter 5 Conservation Principles. 101 I . The System. 101 IL
Conservation of Mass.101 A. Macroscopic Mass Balance. 101 B. Microscopic Mass Balance. 103
ix Contents III. Conservation of Energy. . 104 A. Internal Energy. . 105 1. Ideal Gas. 106 2. Nonideal Gas. 106 3. Solids and Liquids. 107 B. Enthalpy. 107 1. Ideal Gas. 107 2. Nonideal Gas. . 107 3. Solids and Liquids. 108 IV. Irreversible Effects.108 A. Kinetic Energy Correction. 110 V. Conservation of Linear Momentum. 113 A. One-Dimensional Flow in a Ihbe. . 114 B. The Loss Coefficient. 116 C. Conservation of Angular Momentum. . 119 D. Moving Boundary Systems and Relative Motion. 120 E. Microscopic Momentum Balance. 122
Summary. 125 Problems. 125 Notation. 135 Reference. 136 Chapter 6 Pipe Flow. I. II. 137 Flow Regimes. 137 General Relations for Pipe Flows. . 138 A. Energy Balance. 138 B. Momentum Balance. 139 C. Continuity. 140 D. Energy Dissipation. 140 III. Newtonian Fluids. 140 A. Laminar Flow. 140 B. Turbulent Flow. 142 1. Boundary Layer. . 142 2. Thrbulent Momentum Flux. 142 3. Mixing Length
Theory. 143 4. Friction Loss in Smooth Pipe. 145 5. Friction Loss in Rough Ihbes. 146 6. Friction Loss in Rough Pipe. . 146 7. Wall Roughness. 148 C. All Flow Regimes. 149 IV. Power Law Fluids. 149 A. Laminar Flow. 149 B. Thrbulent Flow. 150 C. All Flow Regimes. 151 V. Bingham Plastics. 151 A. Laminar Flow. 152 B. Thrbulent Flow. 153 C. All Reynolds Numbers. 153
Contents x VI. Pipe Flow Problems. 153 A. Unknown Driving Force. 154 1. Newtonian Fluid. 154 2. Power Law Fluid. 155 3. Bingham Plastic. 155 B. Unknown Flow Rate. 158 1. Newtonian Fluid. 158 2. Power Law Fluid. 159 3. Bingham Plastic.161 C. Unknown Diameter. 161 1. Newtonian Fluid. 162 2. Power Law Fluid. 162 3. Bingham Plastic. 163 D. Use of Tables. 165 VIL Tube Flow (Poiseuille)
Viscometer. 165 VIII. Turbulent Drag Reduction. 166 Summary.170 Problems. 171 Notation. 178 References.179 Chapter 7 Internal Flow Applications. 181 I. II. III. IV. V. NoncircularConduits. 181 A. Laminar Flows. 181 1. Flow in a Slit. 181 2. Flow in a Film. 182 3. Annular Flow. 183 B. Turbulent Flows. 183 Most Economical
Diameter. 185 A. Newtonian Fluids. 188 B. Non-Newtonian Fluids.189 1. Power Law Fluid. 190 2. Bingham Plastic.190 Friction Loss in Valvesand Fittings.191 A. Loss Coefficient. 191 B. Equivalent L/D Method. :. 191 C. Crane Method. 193 D. 2-K (Hooper) Method. 193 E. З-K (Darby) Method. 193 Non-Newtonian Fluids. 194 Pipe Flow Problems with Fittings. 197 A. Unknown Driving Force. 197 1. Newtonian Fluid.
197 2. Power Law Fluid. 198 3. Bingham Plastic. 198 B. Unknown Flow Rate. 198 1. Newtonian Fluid. 198 2. Power Law Fluid. 199 3. Bingham Plastic. 199
Contents xi Unknown Diameter. 199 1. Newtonian Fluids. 199 2. Power Law Fluid. 200 3. Bingham Plastic. . 201 VI. Slack Flow. 201 VII. Pipe Networks. . 204 Problems. 208 Notation. . 215 References. 216 C. Chapter 8 Pumps and Compressors. 217 Pumps. 217 A. Positive Displacement Pumps. 217 B. Centrifugal Pumps. . 217 П. Pump Characteristics. 218 III. Pumping Requirements and Pump Selection. 220 A. Required Head. .220 B. Composite Curves. 221 IV. Cavitation
and NPSH. 223 A. Vapor Lock and Cavitation. 223 B. Net Positive Suction Head. 223 C. Specific Speed. 225 D. Suction Specific Speed.225 V. Compressors. 226 A. Isothermal Compression.228 B. Isentropic Compression.228 C. StagedOperation. 229 D. Efficiency. 230 Summary. 230 Problems. 230 Notation. 237 References. 237 I. Chapter 9 Compressible Flows. 239 I. II. Gas Properties.
239 A. Ideal Gas. . 239 B. The Speed of Sound. 240 Pipe Flow. 241 A. Isothermal Flow. . 242 B. Adiabatic Flow. 244 C. Choked Flow. 245 1. Isothermal. 245 2. Adiabatic. 246 D. The Expansion Factor. 246 E. Frictionless Adiabatic Flow. 248 F. General Fluid Properties. 250
Contents xii IIL Generalized Gas Flow Expressions: Ideal Gas. 251 A. Governing Equations. 251 1. Continuity. 251 2. Energy. 251 3. Momentum.251 B. Applications. . 256 C. Solution of High-Speed Ideal Gas Problems.259 1. Unknown Driving Force. 259 2. Unknown Flow Rate. 259 3. Unknown Diameter.260 Summary. 260 Problems. 260 Notation. 264
References. 265 Chapter 10 Flow Measurement. 267 Scope. ,. 267 Pitot Tube. 267 Venturi and Nozzle.269 Orifice Meter. 271 A. Incompressible Flow. 276 B. Compressible Flow. 277 C. Friction Loss Coefficient. 279 D. Other Geometries . 280 V. Orifice Problems. 280 A. Unknown Pressure Drop. 281 B. Unknown Flow Rate. 281 C. Unknown
Diameter. 281 VI. Noninvasive Techniques. 282 A. Vortex-Shedding Flow Meter. 282 B. Magnetic Flow Meter. 282 C. Ultrasonic Flow Meter. 283 D. The Coriolis Flow Meter. 284 Summary.284 Problems. 285 Notation. 288 References. 289 I. II. III. IV. Chapter 11 Safety Relief and Control Valves. 291 I. Safety Relief Valves. 291 A. Background. 291 B. Valve
Sizing. 291 1. Flow Model. .292 2. Fluid Property Model. 293 3. Flow Data. 293 C. Fluid Models. 294 1. Incompressible Fluids. 294 2. Ideal Gases. 295
Contents xiii 3. The Homogeneous Direct Integration Method for Any Single- or Two-Phase Flow. . 296 4. Nonequilibrium (Flashing) Flows. 297 D. The Discharge Coefficient. 298 II. Control Valves.300 A. Valve Characteristics. 301 B. Overview of Control Valve Sizing. 303 C. The Equation Constant. 305 1. Incompressible Fluids. 305 D. Valve Coefficients. 306 1. The Valve Sizing Coefficient. 306 2. FP·. The Piping Geometry Factor.308 3. F[ (K„); The Liquid Pressure Recovery Factor. 308 4. F¿ The Valve Style Modifier. 309 E. Cavitating and Flashing Liquids. 311 1.
Introduction. 311 2. f rc: The Liquid Critical Pressure Ratio. 311 3. xT: The Pressure Differential Ratio Factor for a Control Valve without Attached Fittings at ChokedFlow. 313 E Viscous Fluids. 314 G. Compressible Fluids. 316 1. Subsonic Flow. 316 2. Choked Flow. 318 H. General (HDI) Method for All Fluids andAllConditions.318 I. Valve-System Interaction. 323 J. Matching Valve Trim to the System. 325 Summary.327 Problems. 328 Notation. 329 References. 330 F= Chapter 12 External
Flows. 333 The Drag Coefficient. 333 A. Stokes Flow. 333 B. Form Drag. 334 C. All Reynolds Numbers. 335 D. Cylinder Drag. 336 E. Boundary Layer Effects. 336 II. Falling Particles. 337 A. Unknown Velocity. 338 B. Unknown Diameter. 339 C. Unknown Viscosity. 340 III. Correction Factors. 340 A. Wall Effects. 340 B. Effect of Particle Shape. 341
C. Drops and Bubbles. 349 IV. Non-Newtonian Fluids. 349 I.
Contents xiv A. Power Law Fluids. 350 1. Unknown Velocity. 351 2. Unknown Diameter. 352 B. Wall Effects. 354 C. Carreau Fluids. . . 354 D. Bingham Plastics. 355 Summary. . 357 Problems. 357 Notation. 359 References. 359 Chapter 13 Fluid-Solid Separations by Free Settling. . 361 I. II. III. Fluid-Solid Separations. . 361 Gravity Settling. . 361 Centrifugal
Separation. . . 363 A. Separation of Immiscible Liquids. 366 IV. Cyclone Separations. . 369 A. General Characteristics. . 369 B. Aerocyclones. 370 1. Velocity Distribution. 370 2. Pressure Drop. . 372 3. Separation Efficiency. 372 4. Other Effects. . . 375 C. Hydrocyclones.375 Summary. 378 Problems. .378 Notation. 381
References. 382 Chapter 14 Flow in Porous Media. 383 I. II. III. IV. V. VI. Description of Porous Media. . 383 A. Hydraulic Diameter. . 384 B. Porous Medium Friction Factor.385 C. Porous Medium Reynolds Number. .385 Friction Loss in Porous Media. 385 A. Laminar Flow.385 B. Ihrbulent Flow.386 C. All Reynolds Numbers. 386 Permeability. . 386 Multidimensional Flow. . 387 Packed Columns. 389
Filtration. 394 A. Governing Equations. 394 B. Constant Pressure Operation. 395 C. Constant Flow Operation.396 D. Cycle Time. 396
Contents XV E. Plate-and-Frame Filter. 397 F. Rotary Drum Filter. .397 G. Compressible Cake. .398 Summary. ,.;. .399 Problems. 399 Notation. . 405 Réferences. 406 Chapter 15 Fluidization and Sedimentation. 407 I. Fluidization. . .407 A. Governing Equations. 407 B. Minimum Bed Voidage. 409 C. Nonspherical Particles. 409 II. Sedimentation. . 410 A. Hindered Settling. 410 B. Fine Particles. 411 C. Coarse Particles. 413 D. All Flow Regimes. 414 ПІ. Generalized
Sedimentation/Fluidization. 415 ГѴ. Thickening. 416 Summary. 420 Problems.421 Notation. 424 References. 425 Chapter 16 Two-Phase Flow. 427 I. Scope. 427 II. Definitions. 427 III. Fluid-Solid Two-Phase Pipe Flows. 430 A. Pseudohomogeneous Flows. 431 B. Heterogeneous Liquid-Solid Flows.431 C. Pneumatic Solids Transport. 435 1. Horizontal Transport. 437 2. Vertical Transport. 439 IV. Gas-
Liquid Two-Phase Pipe Flow. 439 A. Flow Regimes. 440 B. Homogeneous Gas-Liquid Models. 442 1. Omega Method for Homogeneous Equilibrium Flow.445 2. Generalized (Homogeneous Direct Integration) Method for All Homogeneous Flow Conditions. 447 C. Separated Flow Models. 447 D. Slip and Holdup. 450 Summary.455 Problems.455 Notation. 457 References. 459
xvi Contents Appendix A: Viscosities and Other Properties of Gases and Liquids. 461 Appendix B: Generalized Viscosity Plot. 483 Appendix C: Properties of Gases. 485 Appendix D: Pressure-Enthalpy Diagrams for Various Compounds. 489 Appendix E: Microscopic Conservation Equations in Rectangular, Cylindrical, and Spherical Coordinates. 497 Appendix F: Standard Steel Pipe Dimensions and Capacities. 501 Appendix G: Flow of Water/Air through Schedule 40 Pipe. 507 Appendix H: Typical Pump Head Capacity Range Charts. 517 Appendix I: Fanno Line Tables for Adiabatic Flow of Air in a Constant Area Duct. 537 Index. 545 |
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| dewey-ones | 660 - Chemical engineering |
| dewey-raw | 660/.284 |
| dewey-search | 660/.284 |
| dewey-sort | 3660 3284 |
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| discipline | Chemie / Pharmazie Physik |
| discipline_str_mv | Chemie / Pharmazie Physik |
| edition | Third edition |
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| id | DE-604.BV048396054 |
| illustrated | Illustrated |
| index_date | 2024-07-03T20:21:51Z |
| indexdate | 2024-07-10T09:37:00Z |
| institution | BVB |
| isbn | 9781032339771 |
| language | English |
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| physical | xxiii, 555 Seiten Illustrationen, Diagramme |
| publishDate | 2022 |
| publishDateSearch | 2022 |
| publishDateSort | 2022 |
| publisher | CRC Press |
| record_format | marc |
| series2 | Engineering - chemical |
| spelling | Darby, Ron 1932- Verfasser (DE-588)1124102817 aut Chemical engineering fluid mechanics Ron Darby (Texas A&M University, College Station, Texas), Raj P. Chhabra (Indian Institute of Technology, Kanpur, India) Third edition Boca Raton ; London ; New York CRC Press 2022 xxiii, 555 Seiten Illustrationen, Diagramme txt rdacontent n rdamedia nc rdacarrier Engineering - chemical First issued in paperback 2022 Chemical processes Fluid mechanics Chemische Verfahrenstechnik (DE-588)4069941-9 gnd rswk-swf Strömungsmechanik (DE-588)4077970-1 gnd rswk-swf Strömungsmechanik (DE-588)4077970-1 s Chemische Verfahrenstechnik (DE-588)4069941-9 s DE-604 Chhabra, Raj P. 1953- Verfasser (DE-588)124082580 aut Äquivalent Druck-Ausgabe, Hardcover 978-1-498-72442-5 Erscheint auch als Online-Ausgabe 978-1-3153-7067-5 Digitalisierung UB Bayreuth - ADAM Catalogue Enrichment application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=033774716&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
| spellingShingle | Darby, Ron 1932- Chhabra, Raj P. 1953- Chemical engineering fluid mechanics Chemical processes Fluid mechanics Chemische Verfahrenstechnik (DE-588)4069941-9 gnd Strömungsmechanik (DE-588)4077970-1 gnd |
| subject_GND | (DE-588)4069941-9 (DE-588)4077970-1 |
| title | Chemical engineering fluid mechanics |
| title_auth | Chemical engineering fluid mechanics |
| title_exact_search | Chemical engineering fluid mechanics |
| title_exact_search_txtP | Chemical engineering fluid mechanics |
| title_full | Chemical engineering fluid mechanics Ron Darby (Texas A&M University, College Station, Texas), Raj P. Chhabra (Indian Institute of Technology, Kanpur, India) |
| title_fullStr | Chemical engineering fluid mechanics Ron Darby (Texas A&M University, College Station, Texas), Raj P. Chhabra (Indian Institute of Technology, Kanpur, India) |
| title_full_unstemmed | Chemical engineering fluid mechanics Ron Darby (Texas A&M University, College Station, Texas), Raj P. Chhabra (Indian Institute of Technology, Kanpur, India) |
| title_short | Chemical engineering fluid mechanics |
| title_sort | chemical engineering fluid mechanics |
| topic | Chemical processes Fluid mechanics Chemische Verfahrenstechnik (DE-588)4069941-9 gnd Strömungsmechanik (DE-588)4077970-1 gnd |
| topic_facet | Chemical processes Fluid mechanics Chemische Verfahrenstechnik Strömungsmechanik |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=033774716&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
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