Produktbild: A Practical Guide to Compressor Technology

A Practical Guide to Compressor Technology

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Beschreibung

Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

01.09.2006

Verlag

John Wiley & Sons Inc

Seitenzahl

590

Maße (L/B/H)

26/18,3/3,6 cm

Gewicht

1021 g

Auflage

2nd edition

Sprache

Englisch

ISBN

978-0-471-72793-4

Beschreibung

Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

01.09.2006

Verlag

John Wiley & Sons Inc

Seitenzahl

590

Maße (L/B/H)

26/18,3/3,6 cm

Gewicht

1021 g

Auflage

2nd edition

Sprache

Englisch

ISBN

978-0-471-72793-4

Herstelleradresse

Libri GmbH
Europaallee 1
36244 Bad Hersfeld
DE

Email: gpsr@libri.de

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  • Produktbild: A Practical Guide to Compressor Technology
  • PREFACE xiii

    ACKNOWLEDGMENTS xv

    PART I POSITIVE DISPLACEMENT COMPRESSOR TECHNOLOGY 1

    1 Theory 3

    1.1 Symbols 3

    1.2 How a Compressor Works 4

    1.3 First Law of Thermodynamics 8

    1.4 Second Law of Thermodynamics 8

    1.5 Ideal or Perfect Gas Laws 9

    1.5.1 Boyle's Law 9

    1.5.2 Charles' Law 9

    1.5.3 Amonton's Law 9

    1.5.4 Dalton's Law 9

    1.5.5 Amagat's Law 10

    1.5.6 Avogadro's Law 10

    1.5.7 Perfect Gas Formula 10

    1.6 Vapor Pressure 11

    1.7 Gas and Vapor 11

    1.8 Partial Pressures 11

    1.9 Critical Conditions 13

    1.10 Compressibility 13

    1.11 Generalized Compressibility Charts 14

    1.12 Gas Mixtures 15

    1.13 The Mole 15

    1.14 Specific Volume and Density 16

    1.15 Volume Percent of Constituents 16

    1.16 Molecular Weight of a Mixture 16

    1.17 Specific Gravity and Partial Pressure 17

    1.18 Ratio of Specific Heats 17

    1.19 Pseudo-critical Conditions and Compressibility 18

    1.20 Weight-Basis Items 18

    1.21 Compression Cycles 19

    1.22 Power Requirement 20

    1.23 Compressibility Correction 21

    1.24 Multiple Staging 22

    1.25 Volume References 23

    1.26 Cylinder Clearance and Volumetric Efficiency 24

    1.27 Cylinder Clearance and Compression Efficiency 27

    Reference 27

    2 Reciprocating Process Compressor Design Overview 29

    2.1 Crankshaft Design 33

    2.2 Bearings and Lubrication Systems 37

    2.3 Connecting Rods 37

    2.4 Crossheads 38

    2.5 Frames and Cylinders 39

    2.6 Cooling Provisions 45

    2.7 Pistons 47

    2.8 Piston and Rider Rings 47

    2.9 Valves 48

    2.10 Piston Rods 51

    2.11 Packings 55

    2.12 Cylinder Lubrication 55

    2.13 Distance Pieces 56

    2.14 Reciprocating Compressor Modernization 57

    2.14.1 Cylinder Upgrades 59

    2.14.2 Design for Easy Maintenance 59

    2.14.3 Crosshead Designs and Attention to Reliable Lubrication 61

    2.14.4 Materials 62

    3 Reciprocating Compressor Performance and Monitoring Considerations 63

    3.1 Capacity Control 63

    3.1.1 Recycle or Bypass 64

    3.1.2 Suction Throttling 64

    3.1.3 Suction Valve Unloading 65

    3.1.4 Clearance Pockets 67

    3.2 More About Cylinder Jacket Cooling and Heating Arrangements 70

    3.2.1 Methods of Cooling 71

    3.3 Comparing Lubricated and Nonlubricated Conventional Cylinder Construction 73

    3.3.1 Lubricated Cylinder Designs 73

    3.3.2 Nonlubricated Cylinder Design 75

    3.4 Compressor Vent and Buffer Systems 76

    3.5 Compressor Instrumentation 77

    3.5.1 Electric vs. Pneumatic Switches 82

    3.5.2 Switch Set Points 82

    3.5.3 Control Panels 82

    3.5.4 Valve-in-Piston Reciprocating Compressors 83

    3.5.5 Barrel-Frame Reciprocating Compressors 84

    3.6 Condition Monitoring of Reciprocating Compressors 85

    3.6.1 Maintenance Strategies 86

    3.6.2 Justification for Machine Monitoring 86

    3.6.3 What to Monitor and Why 87

    References 97

    4 Labyrinth Piston Compressors 99

    4.1 Main Design Features 99

    4.2 Energy Consumption 101

    4.3 Sealing Problems 104

    5 Hypercompressors 109

    5.1 Introduction 109

    5.2 Cylinders and Piston Seals 111

    5.3 Cylinder Heads and Valves 115

    5.4 Drive Mechanism 117

    5.5 Miscellaneous Problems 119

    5.6 Conclusions 120

    6 Metal Diaphragm Compressors 121

    6.1 Introduction 121

    6.2 Terminology 121

    6.3 Description 122

    7 Lobe and Sliding Vane Compressors 129

    8 Liquid Ring Compressors 135

    9 Rotary Screw Compressors and Filter Separators 141

    9.1 Twin-Screw Machines 141

    9.1.1 Working Phases 141

    9.1.2 Areas of Application 145

    9.1.3 Dry vs. Liquid-Injected Machines 145

    9.1.4 Operating Principles 145

    9.1.5 Flow Calculation 147

    9.1.6 Power Calculation 147

    9.1.7 Temperature Rise 150

    9.1.8 Capacity Control 150

    9.1.9 Mechanical Construction 153

    9.1.10 Industry Experience 154

    9.1.11 Maintenance History 158

    9.1.12 Performance Summary 158

    9.2 Oil-Flooded Single-Screw Compressors 160

    9.3 Selecting Modern Reverse-Flow Filter-Separator Technology 163

    9.3.1 Conventional Filter-Separators vs. SCCs 164

    9.3.2 Removal Efficiencies 165

    9.3.3 Filter Quality 165

    9.3.4 Selecting the Most Suitable Gas Filtration Equipment 166

    9.3.5 Evaluating the Proposed Configurations 167

    9.3.6 Life-Cycle-Cost Calculations 168

    9.3.7 Conclusions 169

    10 Reciprocating Compressor Performance and Sizing Fundamentals 171

    10.1 Theoretical Maximum Capacity 172

    10.2 Capacity Losses 173

    10.3 Valve Preload 174

    10.4 Valve and Gas Passage Throttling 174

    10.5 Piston Ring Leakage 176

    10.6 Packing Leakage 177

    10.7 Discharge Valve Leakage 177

    10.8 Suction Valve Leakage 178

    10.9 Heating Effects 178

    10.10 Pulsation Effects 180

    10.11 Horsepower 181

    10.12 Horsepower Adders 181

    10.13 Gas Properties 182

    10.13.1 Ideal Gas 182

    10.13.2 Real Gas 182

    10.14 Alternative Equations of State 183

    10.15 Condensation 183

    10.16 Frame Loads 183

    10.17 Compressor Displacement and Clearance 184

    10.18 Staging 186

    10.19 Fundamentals of Sizing 187

    10.19.1 Number of Stages 187

    10.19.2 Approximate Horsepower 187

    10.19.3 Cylinder Bore Requirements 188

    10.19.4 Frame Load 188

    10.19.5 Vendor Confirmation 189

    10.20 Sizing Examples 189

    PART II DYNAMIC COMPRESSOR TECHNOLOGY 197

    11 Simplified Equations for Determining the Performance of Dynamic Compressors 205

    11.1 Nonoverloading Characteristics of Centrifugal Compressors 205

    11.2 Stability 205

    11.3 Speed Change 207

    11.4 Compressor Drive 207

    11.5 Calculations 208

    12 Design Considerations and Manufacturing Techniques 215

    12.1 Axially vs. Radially Split 215

    12.2 Tightness 215

    12.3 Material Stress 215

    12.4 Nozzle Location and Maintenance 216

    12.5 Design Overview 217

    12.5.1 Casings 217

    12.5.2 Flow Path 230

    12.5.3 Rotors 234

    12.5.4 Impellers 234

    12.5.5 Axial Blading 242

    12.5.6 Seals 242

    12.6 Bearing Configurations 250

    12.6.1 Radial Bearings 250

    12.6.2 Thrust Bearings 251

    12.6.3 Flexure Pivot Tilt Pad Bearings 253

    12.7 Casing Design Criteria 257

    12.8 Casing Manufacturing Techniques 265

    12.9 Stage Design Considerations 273

    12.10 Impeller Manufacturing Techniques 282

    12.11 Rotor Dynamic Considerations 286

    12.12 Fouling Considerations and Coatings 292

    12.12.1 Polymerization and Fouling 292

    12.12.2 Fouling and Its Effect on Compressor Operation 293

    12.12.3 Coating Case Study 294

    12.12.4 SermaLon Coating 296

    12.12.5 Results 297

    13 Advanced Sealing and Bearing Systems 299

    13.1 Background 299

    13.2 Dry Seals 300

    13.2.1 Operating Principles 300

    13.2.2 Operating Experience 302

    13.2.3 Problems and Solutions 303

    13.2.4 Dry Seal Upgrade Developments 304

    13.2.5 Dry Gas Seal Failures Avoided by Gas Conditioning 304

    13.3 Magnetic Bearings 308

    13.3.1 Operating Principles 308

    13.3.2 Operating Experience and Benefits 310

    13.3.3 Problems and Solutions 311

    13.4 Development Efforts 311

    13.4.1 Thrust-Reducing Seals 312

    13.5 Integrated Designs 314

    13.6 Fluid-Induced Instability and Externally Pressurized Bearings 318

    13.6.1 Instability Considerations 318

    13.6.2 Fluid-Induced Instability 318

    13.6.3 Eccentricity and Stiffness 320

    13.6.4 Externally Pressurized Bearings and Seals 321

    13.6.5 Practical Applications 324

    13.6.6 Rotor Model, Dynamic Stiffness, and Fluid Instability 325

    13.6.7 Root Locus Stability Analysis 327

    13.6.8 More About Externally Pressurized Bearings 328

    13.6.9 Field Data Collection 331

    13.6.10 Test Stand Data 334

    13.6.11 Conclusions 336

    References 336

    Suggested Reading 336

    14 Couplings, Torque Transmission, and Torque Sensing 339

    14.1 Coupling Overview 339

    14.1.1 Low Overhung Moment 341

    14.1.2 Low Residual Unbalance Desired 343

    14.1.3 Long Life and Maintainability 344

    14.1.4 Continuous Lubrication Not a Cure-All 345

    14.1.5 Contoured Diaphragm Coupling 345

    14.2 Coupling Retrofits and Upgrades 347

    14.3 Performance Optimization Through Torque Monitoring 349

    15 Lubrication, Sealing, and Control Oil Systems for Turbomachinery 357

    15.1 Considerations Common to All Systems 357

    15.2 Seal Oil Considerations 359

    16 Compressor Control 363

    16.1 Introduction 363

    16.2 Control System Objectives 363

    16.3 Compressor Maps 364

    16.3.1 Invariant Coordinates 366

    16.4 Performance Control 368

    16.4.1 PI and PID Control Algorithms 370

    16.4.2 Stability Considerations 372

    16.4.3 Integral or Reset Windup 373

    16.5 Performance Limitations 373

    16.5.1 Surge Limit 374

    16.5.2 Stonewall 375

    16.6 Preventing Surge 376

    16.6.1 Antisurge Control Variables 376

    16.6.2 Antisurge Control Algorithms 378

    16.6.3 Controlling Limiting Variables 378

    16.7 Loop Decoupling 379

    16.8 Conclusions 380

    Reference 380

    17 Head-Flow Curve Shape of Centrifugal Compressors 381

    17.1 Compressor Stage 381

    17.2 Elements of the Characteristic Shape 382

    17.2.1 Basic Slope 382

    17.2.2 Blade Angle 384

    17.2.3 Fan Law Effect 385

    17.2.4 Choke Effect 386

    17.2.5 Mach Number 387

    17.2.6 Significance of Gas Weight 387

    17.2.7 Inducer Impeller Effects on Head Output 388

    17.2.8 Surge 389

    17.2.9 Vaned Diffusers 390

    17.2.10 Vaneless Diffusers 390

    17.2.11 Equivalent Tip Speeds 391

    17.3 Conclusions 393

    18 Use of Multiple-Inlet Compressors 395

    18.1 Critical Selection Criteria 395

    18.1.1 Head Rise to Surge, Surge Margin, and Overload Margin 396

    18.1.2 Head per Section 397

    18.1.3 Compressor Parasitic Flows 398

    18.1.4 Excess Margins on Other Process Equipment 399

    18.1.5 Representing Compressor Performance 399

    18.1.6 Practical Levels of Critical Operating Parameters 399

    18.2 Design of a Sideload Compressor 401

    18.2.1 Mixing Area 402

    18.2.2 Aerodynamics 403

    18.2.3 Temperature Stratification 405

    18.3 Testing 405

    18.3.1 Test Setup 406

    18.3.2 Instrumentation 406

    18.3.3 Testing Procedure 406

    18.3.4 Accuracy of Test Results 407

    18.3.5 Evaluation of Results 407

    19 Compressor Performance Testing 409

    19.1 Performance Testing of New Compressors 409

    19.1.1 Re-rate Options 410

    19.1.2 General Guidelines 410

    19.1.3 Gas Sampling 411

    19.1.4 Instrumentation 412

    19.1.5 Sideload Compressors 414

    19.1.6 Calculation Procedures 416

    19.2 Shop Testing and Types of Tests 418

    19.3 Field Testing 420

    19.4 Predicting Compressor Performance at Other Than As-Designed Conditions 432

    19.4.1 How Performance Tests Are Documented 434

    19.4.2 Design Parameters: What Affects Performance 434

    19.4.3 What to Seek from Vendors' Documents 435

    19.4.4 Illustrations and Example 436

    References 441

    20 Procurement, Audit, and Asset Management Decisions 443

    20.1 Incentives to Buy from Knowledgeable and Cooperative Compressor Vendors 443

    20.2 Industry Standards and Their Purpose 444

    20.2.1 Typical Scope of Standards 444

    20.2.2 Disclaimers in Standards 447

    20.2.3 Going Beyond the Standards 447

    20.3 Disadvantages of Cheap Process Compressors 448

    20.4 Audits vs. Reviews 449

    20.4.1 Staffing and Timing of Audits and Reviews 450

    20.4.2 Use of Equipment Downtime Statistics 450

    20.5 Auditing and Reviewing Compressors 451

    20.6 Compressor Inspection: Extension of the Audit Effort 465

    20.6.1 Inspection of a Welded Impeller (Wheel) and the Entire Rotor 466

    20.7 Compressor Installation Specifications 474

    20.7.1 Field Erection and Installation Specifications for Special-Purpose Machinery 475

    References 476

    21 Reliability-Driven Asset Management Strategies 477

    21.1 Strategy for Reciprocating Compressors 477

    21.1.1 Process Operating Window 478

    21.1.2 Breakdown Maintenance 478

    21.1.3 Time-Based Maintenance 478

    21.1.4 Equipment Health Monitoring 479

    21.1.5 Reliability and Maintenance 479

    21.1.6 Asset Management Strategy 479

    21.2 Achieving Compressor Asset Optimization 486

    21.2.1 Input Obtained from Workshops 486

    21.2.2 Conclusions 496

    References 497

    APPENDIX A PROPERTIES OF COMMON GASES 499

    APPENDIX B SHORTCUT CALCULATIONS AND GRAPHICAL 507

    COMPRESSOR SELECTION PROCEDURES

    APPENDIX C BIBLIOGRAPHY AND LIST OF CONTRIBUTORS 551

    INDEX 557