Process Plant Equipment: Operation, Control, and Reliability

PROCESS PLANT EQUIPMENT

PROCESS PLANT EQUIPMENT

Operation, Control, and Reliability

Edited by

MICHAEL D. HOLLOWAY

CHIKEZIE NWAOHA

OLIVER A. ONYEWUENYI

A JOHN WILEY & SONS, INC., PUBLICATION

Cover photography: courtesy of Chikezie Nwaoha

Copyright © 2012 by John Wiley & Sons. All rights reserved.

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Library of Congress Cataloging-in-Publication Data:

Process plant equipment : operation, control, and reliability / edited by

Michael D. Holloway, Chikezie Nwaoha, Oliver A. Onyewuenyi.

p. cm.

Includes index.

ISBN 978-1-118-02264-1 (cloth)

1. Pumping machinery–Maintenance and repair. 2. Pipelines–Maintenance and repair. 3. Valves–Maintenance and repair.

4. Compressors–Maintenance and repair. 5. Storage tanks–Maintenance and repair. 6. Mixing machinery–Maintenance and repair.

7. Boilers–Maintenance and repair. 8. Filters and filtration. I. Holloway, Michael H., 1963– II. Nwaoha, Chikezie, 1984– III.

Onyewuenyi, Oliver A., 1952–

TJ900.P725 2012

621.8–dc23

2011028229

Printed in the United States of America

10 9 8 7 6 5 4 3 2 1

For the memory of

Denton Ward

student and friend

CONTENTS

Contributors xxiii

Preface xxiv

SECTION I PROCESS EQUIPMENT OPERATION

1 Introduction 3

Michael D. Holloway

2 Valves 9

Ali Ahammad Shoukat Choudhury, Chikezie Nwaoha, and Sharad Vishwasrao

2.1 Types of Control Valves, 10

2.1.1 Linear-Motion Control Valves, 10

2.1.2 Rotary-Motion Control Valves, 11

2.1.3 Nonreturn Valves, 12

2.1.4 Relief Valves, 12

2.2 Control Valve Actuators, 12

2.2.1 Pneumatic Valve Actuators, 12

2.2.2 Electric Valve Actuators, 13

2.2.3 Hydraulic Valve Actuators, 13

2.3 Control Valve Sizing and Selection, 13

2.3.1 Selecting a Valve Type, 14

2.3.2 Sizing and Selection: Letting the Computer Do It All, 15

2.4 Common Problems of Control Valves, 15

2.4.1 Control Valve Cavitation, 15

2.4.2 Control Valve Leakage, 16

2.4.3 Control Valve Nonlinearities, 17

2.5 Diagnosing Control Valve Problems, 19

2.6 Control Valve Reliability and Selection, 20

2.7 Control Valve Maintenance, 22

2.7.1 Detecting Control Valve Stiction, 23

vii

viii CONTENTS

2.8 Control Valve Troubleshooting, 24

References, 24

3 Pumps 27

Craig Redmond

3.1 Types of Pumps, 28

3.1.1 Positive-Displacement Pumps, 28

3.1.2 Dynamic Pumps, 30

3.2 Pump Applications, 34

3.2.1 Flooded Suction Applications, 34

3.2.2 Suction Lift Applications, 35

3.2.3 Staged Pumping, 35

3.2.4 Solids-Handling Applications, 36

3.3 Pump Sizing and Selection, 37

3.3.1 System Head Curve, 37

3.3.2 Pump Peformance Curves, 38

3.3.3 Actual Pump Sizing and Selection, 39

3.3.4 Net Positive Suction Head, 40

3.3.5 Net Positive Suction Head Available, 40

3.4 Pump Maintenance, 40

3.4.1 Bearing Lubrication, 41

3.4.2 Seal Maintenance, 41

3.4.3 Maintaining Performance, 43

3.4.4 Winterizing and Long-Term Storage, 43

3.4.5 Cold Temperature Installations, 43

3.5 Pump Troubleshooting, 44

4 Pipes 45

Shaohui Jia

4.1 Types of Pipes, 45

4.1.1 Seamless Pipe, 45

4.1.2 Welded Pipe, 45

4.2 Pipe Selection, 46

4.2.1 Pipe Strength, 46

4.2.2 Pipe Toughness, 46

4.2.3 Pipe Weldability, 48

4.2.4 Piping Material, 48

4.3 Pipeline Network Design and Optimization, 48

4.4 Pipeline Failure, 50

4.4.1 Pipe External Corrosion, 51

4.4.2 Pipe Internal Corrosion, 52

4.4.3 Stress Corrosion Cracking, 53

4.5 Pipeline Inspection and Leak Detection, 54

4.5.1 Pipeline Inspection, 54

4.5.2 Pipeline Inspection Tools, 55

4.5.3 Pipeline Leak Detection, 56

4.6 Pipe Maintenance, 58

4.6.1 Pipeline Coatings, 58

4.6.2 Pipeline Repair, 59

4.7 Pipe Troubleshooting, 60

References, 61

CONTENTS ix

5 Cooling Towers 63

Zaki Yamani Zakaria and Chikezie Nwaoha

5.1 Cooling Tower Operation, 63

5.1.1 Cooling Tower Psychrometrics, 63

5.1.2 Principles of Cooling, 65

5.1.3 Heat Exchange, 67

5.1.4 Components of Cooling Towers, 67

5.2 Types of Cooling Towers, 69

5.2.1 Natural-Draft Cooling Towers, 69

5.2.2 Mechanical-Draft Cooling Towers, 72

5.3 Common Problems of Cooling Towers, 74

5.3.1 Scale Deposits, 74

5.3.2 Delignification of Wood, 74

5.3.3 Poor Pump Performance, 75

5.3.4 Poor Airflow, 75

5.3.5 Makeup Water, 75

5.3.6 Clogging of Distribution Nozzles, 75

5.4 Measuring Cooling Tower Performance, 75

5.4.1 Performance Assessment, 76

5.5 Cooling Tower Maintenance, 77

References, 79

6 Filters and Membranes 81

Flora Tong and Chikezie Nwaoha

6.1 Types of Filters, 81

6.1.1 Gas Filters, 82

6.1.2 Liquid Filters, 83

6.2 Mechanisms of Filtration, 87

6.2.1 Depth Straining, 87

6.2.2 Surface Straining, 87

6.2.3 Depth Filtration, 87

6.2.4 Cake Filtration, 87

6.3 Filter Selection, 87

6.3.1 Chemical Compatibility, 87

6.3.2 Accurate Pore Size, 87

6.4 Particle-Size Measurement Techniques, 88

6.4.1 Image Analysis, 88

6.4.2 Direct Mechanical Measurement, 88

6.4.3 Ultrasonics, 88

6.4.4 Laser Scattering Technology, 88

6.5 Filter Location, 89

6.5.1 Pressure Line Filters, 89

6.5.2 Suction Line Filters, 89

6.5.3 Return Line Filters, 89

6.6 Membrane Filtration, 89

6.6.1 Ultrafiltration, 90

6.6.2 Microfiltration, 94

6.6.3 Reverse Osmosis, 95

6.6.4 Nanofiltration, 102

6.7 Filter Maintenance, 103

6.7.1 Preparation for Maintenance, 104

References, 104

x CONTENTS

7 Sealing Devices 107

Matt Tones and Jim Drago

7.1 Gaskets, 107

7.1.1 Gasket Materials, 107

7.1.2 Gasket and Seal Construction, 113

7.1.3 Principles of Gasket Operation, 119

7.1.4 Gasket and Metal Seal Applications, 120

7.1.5 Gasket Selection, 123

7.2 Compression Packings, 125

7.2.1 Packing Materials, 126

7.2.2 Packing Construction, 128

7.2.3 Packing Selection, 129

7.2.4 Packing Installation, 130

7.3 Mechanical Seals, 131

7.3.1 Considerations for Using Mechanical Seals, 132

7.3.2 Types of Mechanical Seals, 134

7.3.3 Mechanical Seal Applications, 137

7.3.4 Environmental Controls, 140

7.3.5 Failure Analysis, 142

7.3.6 Troubleshooting Mechanical Seals, 144

7.4 Expansion Joints, 147

7.4.1 Joint Construction, 148

7.4.2 Principles of Joint Operation, 149

7.4.3 Joint Selection, 149

7.4.4 Industrial Use of Expansion Joints, 152

7.4.5 Joint Installation, 155

7.4.6 Joint Troubleshooting, 156

7.5 General Sealing Device Selection, 157

7.5.1 Product Selection, 157

7.5.2 Understanding the Forces, 157

7.5.3 STAMPS Criteria, 158

References, 161

8 Steam Traps 163

Jacob E. Uche and Chikezie Nwaoha

8.1 Steam Trap Operation, 163

8.2 Types of Steam Traps, 164

8.2.1 Thermodynamic Steam Traps, 164

8.2.2 Mechanical Steam Traps, 166

8.2.3 Thermostatic Steam Traps, 169

8.3 Steam Trap Installation, 172

8.3.1 Outlets of Steam-Using Equipment, 172

8.3.2 On Steam Lines, 172

8.4 Steam Trap Checking, 172

8.4.1 Sight Method, 173

8.4.2 Sound Method, 174

8.4.3 Temperature Method, 174

8.4.4 Fluid Conductivity Method, 174

8.5 Common Problems of Steam Traps, 175

8.5.1 Air Binding, 175

8.5.2 Dirt, 175

8.5.3 Improper Sizing, 175

CONTENTS xi

8.5.4 Steam Trap Leakage, 175

8.5.5 Steam Locking, 176

8.5.6 Water Hammer, 176

8.5.7 Erosion of Seat and Valve Sealing Faces, 176

8.5.8 Life Expectancy, 176

8.6 Steam Trap Selection, 176

8.7 Steam Trap Applications, 178

8.7.1 Protection Service, 178

8.7.2 Process Service, 178

8.7.3 Other Applications, 178

8.8 Steam Trap Sizing, 178

8.8.1 Basic Considerations, 179

8.9 Steam Trap Maintenance, 181

References, 181

9 Process Compressors 183

N. Sitaram and Chikezie Nwaoha

9.1 Types of Compressors, 183

9.2 Continuous Compression Compressors, 184

9.2.1 Ejectors, 184

9.2.2 Dynamic, Rotodynamic, or Turbocompressors, 185

9.3 Intermittent Compression Compressors, 186

9.3.1 Positive-Displacement Compressors

(Intermittent Flow), 186

9.3.2 Rotary Compressors (Continuous Flow), 187

9.4 Centrifugal Compressors, 189

9.4.1 Major Components of Centrifugal Compressors, 189

9.4.2 Thermodynamics of Centrifugal Compressors, 195

9.4.3 Energy Transfer in Centrifugal Compressors, 196

9.4.4 Slip in Centrifugal Impellers, 197

9.4.5 Losses and Efficiencies, 198

9.4.6 Performance, Stall, and Surge, 199

9.4.7 Drivers, 201

9.5 Reciprocating Piston Compressors, 202

9.5.1 Compressor Operation, 202

9.5.2 Thermodynamic Laws, 203

9.5.3 Compression Cycles, 203

9.5.4 Power Requirements, 204

9.5.5 Multistage Compression, 204

9.5.6 Cylinder Clearance and Volumetric Efficiency, 205

9.5.7 Valve Losses, 206

9.5.8 Major Components of Reciprocating Piston

Compressors, 206

9.5.9 Drivers, 207

9.6 Compressor Troubleshooting, 209

References, 210

Further Reading, 211

10 Conveyors 213

Okenna Obi-Njoku

10.1 Industrial Use of Conveyors, 213

10.2 Types of Conveyors, 214

10.2.1 Belt Conveyors, 214

10.2.2 Bucket Conveyors, 215

xii CONTENTS

10.2.3 Cart-on-Track Conveyors, 215

10.2.4 Chute Conveyors, 216

10.2.5 Gravity Wheel Conveyors, 216

10.2.6 Monorails, 216

10.2.7 Chain Conveyors, 216

10.2.8 Pneumatic Conveyors, 217

10.2.9 Roller Conveyors, 217

10.2.10 Screw Conveyors, 218

10.2.11 Slat Conveyors, 218

10.2.12 Sortation Conveyors, 219

10.2.13 Vane-Type Throwing Machines, 219

10.2.14 Tow Conveyors, 219

10.2.15 Trolley Conveyors, 219

10.2.16 Vertical Conveyors, 220

10.2.17 Vibrating Conveyors, 220

10.2.18 Troughed Belt Conveyors, 220

10.2.19 Magnetic Belt Conveyors, 220

10.2.20 Power-and-Free Conveyors, 220

10.3 Conveyor Selection, 221

10.4 Conveyor Safety, 221

10.5 Conveyor Maintenance, 222

10.6 Summary, 222

References, 223

11 Storage Tanks 225

Marcello Ferrara and Chikezie Nwaoha

11.1 Types of Storage Tanks, 225

11.1.1 Aboveground Tanks, 225

11.1.2 Underground Tanks, 226

11.2 Storage Tank Classification, 227

11.2.1 Aboveground Tanks, 227

11.2.2 Underground Tanks, 227

11.3 Construction Materials, 227

11.3.1 Tank Materials, 227

11.3.2 Protective Coatings, 228

11.3.3 Insulation, 229

11.4 Common Problems of Storage Tanks, 229

11.4.1 Corrosion, 229

11.4.2 Vapor Losses, 230

11.4.3 Storage Tank Fires, 231

11.5 Storage Tank Maintenance, 233

11.5.1 Tank Blanketing, 233

11.5.2 Holiday Detection, 233

11.5.3 Tank Cleaning, 234

11.6 Tank Appurtenances, 241

11.6.1 Mixers, 241

11.6.2 Dikes, 241

11.6.3 Insulators, 241

11.6.4 Platforms and Ladders, 242

11.6.5 Gauging Devices, 242

11.6.6 Valves, 242

11.6.7 Manways, 243

11.6.8 Diffusers, 243

CONTENTS xiii

11.6.9 Water Cannons, 243

11.6.10 Vents, 243

11.6.11 Grounding, 243

11.6.12 Supporting Structures, 243

11.7 Storage Tank Maintenance, 243

References, 244

12 Mixers 245

Jayesh Ramesh Tekchandaney

12.1 Mixing Concepts: Theory and Practice, 246

12.1.1 Batch and Continuous Mixing, 246

12.1.2 Selection of Mixing Equipment, 247

12.1.3 Design of Mixing Equipment, 247

12.1.4 Scale-Up of Mixing Equipment, 247

12.2 Fluid Mixing, 248

12.2.1 Fluid Mixing Applications, 248

12.2.2 Mixing Regimes, 249

12.2.3 Power Consumption in Agitated Vessels, 249

12.2.4 Flow Characteristics, 251

12.2.5 Liquid Agitation Equipment, 253

12.3 Solid Blending, 264

12.3.1 Properties of Solids Affecting Blending, 264

12.3.2 Types of Blend Structures, 265

12.3.3 Mechanisms of Solid Blending, 265

12.3.4 Segregation Mechanisms, 265

12.3.5 Scale-Up of Solid Mixers, 266

12.3.6 Solid Blending Equipment, 266

12.4 Mixing High-Viscosity Materials and Pastes, 274

12.4.1 Dispersive, Distributive, and Convective Mixing, 275

12.4.2 Power for Viscous Mixing, 275

12.4.3 Scale-Up of High-Viscosity Mixers, 275

12.4.4 Heat Transfer, 275

12.4.5 Equipment for Mixing High-Viscosity Materials

and Pastes, 275

12.5 Mechanical Components in Mixing Equipment, 284

12.5.1 Motors, 284

12.5.2 Mixer Speed Reducers, 285

12.5.3 Couplings, 287

12.5.4 Bearings, 288

12.5.5 Shaft Seals, 289

12.5.6 Variable-Speed Operation Devices, 291

12.5.7 Mixer Installation, Startup, and Maintenance, 292

12.5.8 Mixer Specifications, 295

References, 295

13 Boilers 297

Celestine C. G. Nwankwo

13.1 Types of Boilers, 298

13.1.1 Water Tube Boilers, 299

13.1.2 Fire Tube Boilers, 300

13.1.3 Pot Boilers, 300

13.1.4 Saddle Boilers, 301

13.1.5 Packaged Boilers, 301

xiv CONTENTS

13.1.6 Fluidized-Bed Combustion Boilers, 301

13.1.7 Stoker-Fired Boilers, 302

13.1.8 Pulverized Fuel Boilers, 302

13.1.9 Waste Heat Boilers, 302

13.1.10 Thermic Fluid Heaters, 302

13.1.11 Superheated Steam Boilers, 302

13.2 Boiler Accessories, 303

13.2.1 Fittings and Accessories at the Boiler Unit, 303

13.2.2 Steam Accessories, 303

13.2.3 Combustion Accessories, 304

13.3 Boiler Selection, 305

13.3.1 Costs, 305

13.3.2 Boiler Sizing, 305

13.3.3 Heating and Heating Fuels, 306

13.4 Common Problems of Boilers, 306

13.4.1 Scaling, 306

13.4.2 Corrosion, 307

13.4.3 Boiler Water Carryover, 308

13.5 Boiler Failure Analysis and Welding Defects, 308

13.5.1 Boiler Failure Analysis, 308

13.5.2 Welding Defects, 309

13.6 Boiler Maintenance, 313

13.6.1 Boiler Upgrading and Retrofitting, 315

13.6.2 Boiler Feed Water Treatment, 316

13.6.3 Boiler Stack Economizer, 317

13.6.4 Boiler Blowdown Control, 317

13.7 Boiler Troubleshooting, 319

13.7.1 Combustion Problems, 319

13.7.2 Draft Fan and Burner Problems, 320

13.7.3 Fuel Pump and Fuel Pressure Problems, 320

13.8 Boiler Chemicals, 321

13.8.1 Phosphates, 322

13.8.2 Lime Softening and Sodium Trioxocarbonate, 322

13.8.3 Chelates, 322

13.8.4 Polymers, 323

13.8.5 Oxygen Scavengers, 324

13.8.6 Neutralizing Amines, 325

13.8.7 Filming Amines, 325

13.9 Boiler Efficiency and Combustion, 325

13.9.1 Heat Losses, 326

13.9.2 Types of Burners, 326

13.9.3 Burner Control Systems, 327

References, 327

Further Reading, 328

SECTION II PROCESS PLANT RELIABILITY

14 Engineering Economics for Chemical Processes 331

Alberto R. Betancourt-Torcat, L. A. Ricardez-Sandoval, and Ali Elkamel

14.1 Time Value of Money, 331

14.2 Cash Flow Analysis, 333

14.2.1 Compound Interest Factors for Single Cash Flows, 333

CONTENTS xv

14.2.2 Compound Interest Factors for Annuities, 334

14.2.3 Arithmetic and Geometric Gradient Series, 334

14.3 Profitability Analysis, 336

14.3.1 Payback Period, 336

14.3.2 Minimum Acceptable Rate of Return, 336

14.3.3 Present and Annual Worth Analysis, 336

14.3.4 Internal Rate of Return, 337

14.4 Cost Estimation and Project Evaluation, 340

14.4.1 Capital Investment, 340

14.4.2 Cost Indexes, 341

14.4.3 Capital Cost Estimates, 342

14.4.4 Production Costs and Estimations, 348

14.4.5 Estimation of Revenues and Cash Flow, 352

References, 353

15 Process Component Function and Performance Criteria 355

Robert Free

15.1 Material Classification, 355

15.2 General Physical Quantities and Considerations, 356

15.2.1 Important Definitions, 356

15.2.2 State Quantities, 357

15.2.3 Phase, 357

15.2.4 Isolation, 357

15.2.5 Flammability, 359

15.2.6 Viscosity, 359

15.2.7 Volatility, 361

15.2.8 Corrosive Substances, 361

15.2.9 Conductivity, 361

15.2.10 Composition, 362

15.2.11 Morphology, 363

15.2.12 Solid-Specific Considerations, 363

15.2.13 Coefficient of Friction, 365

15.3 Material Transfer and Conveyance Equipment, 366

15.4 Conveyors, 367

15.4.1 Conveyor Belts, 367

15.4.2 Overhead Conveyors, 377

15.4.3 Roller Conveyors, 382

15.4.4 Chute Conveyors, 388

15.4.5 Screw Conveyors, 389

15.4.6 Other Conveyor Types, 392

15.5 Pumps, 394

15.5.1 Head and Pressure: Fluid Flow Systems, 394

15.5.2 Pump Construction and Operation, 395

15.5.3 Selection by Application, 398

15.5.4 Reliability, Maintenance, and Process Development, 399

15.5.5 Additional Information, 400

15.6 Valves, 400

15.6.1 Valve Construction and Function, 401

15.6.2 Selection Specification, 404

15.6.3 Additional Information, 405

15.7 Pipes, 405

15.7.1 Pipe Standards, 406

xvi CONTENTS

15.7.2 Pipe Classification, 406

15.7.3 Common Pipe Materials, 408

15.7.4 Pipe Sizing, 410

15.7.5 Additional Information, 410

15.8 Conclusions, 410

References, 410

Corporation Web Sites, 411

16 Failure Analysis and Interpretation of Components 413

Michael D. Holloway

16.1 Assessing the Situation, 413

16.2 Failure Defined, 414

16.3 Taking Advantage of Failure, 415

16.4 Sources of Failure, 416

16.5 Failure of Materials and of Machines, 416

16.6 Types of Forces, 417

16.7 Strength, 418

16.7.1 Stress and Strain, 418

16.7.2 Yield, 419

16.8 Creep (Deformation), 419

16.9 Fatigue (Material), 420

16.9.1 Rate of Fatigue, 421

16.9.2 Fracture, 421

16.10 Wear, 422

16.11 Property Changes, 423

16.12 Temperature, 423

16.13 Oxidation: Molecular Transitions and Chemical Influences, 425

16.13.1 Corrosion, 425

16.13.2 Corrosion in Nonmetals, 425

16.13.3 Galvanic Corrosion, 426

16.14 Deposit Formation, 426

16.15 Factors that Affect Deposit Formation, 428

16.15.1 Concentration and Pressure, 428

16.15.2 Particle Size and Contaminant Type, 428

16.15.3 Adsorption, 429

16.16 Documenting Failure, 429

16.16.1 Root Cause Investigation, 430

16.16.2 Failure Examination, 432

References, 432

17 Mechanical Integrity of Process Vessels and Piping 435

Oliver A. Onyewuenyi

17.1 Perspectives on Mechanical Integrity, Fitness for Service, and

Condition Monitoring, 437

17.1.1 Mechanical Integrity, 437

17.1.2 Condition Monitoring, 438

17.1.3 Fitness for Service, 438

17.2 Types of Flaws and Damage Mechanisms, 439

17.2.1 Flaws or Discontinuities Versus Defects, 439

17.2.2 Types of Flaws, 440

17.2.3 Weld Flaws, 440

17.2.4 In-Service Flaws and Environmentally Assisted Flaws, 440

CONTENTS xvii

17.2.5 In-Service Degradation and Susceptibility of Various

Alloys, 440

17.2.6 HAC and SCC Susceptibility of Various Alloy Systems, 441

17.3 Inspection, Characterization, and Monitoring of Flaws, 442

17.3.1 General Metal Loss and Local Thinned Area Corrosion, 442

17.3.2 Pitting and Crevice Corrosion, 443

17.3.3 HIC, SOHIC, and Blister Damage, 443

17.3.4 Cracklike and Sharp Flaws, 443

17.3.5 Online Condition Monitoring of Damage, 443

17.4 Fracture Mechanics and Fitness-for-Service Assessment, 443

17.4.1 Applicable Codes and Standards, 444

17.4.2 When FFS is Needed, 444

17.4.3 FFS Assessment Procedure, 446

17.5 Control and Prevention of Brittle Fracture, 452

17.5.1 Definitions, 452

17.5.2 Brittle Versus Ductile Fracture, 452

17.5.3 Industry and Regulatory Codes and Standards for Brittle

Fracture Control, 453

17.5.4 Determination of the Minimum Metal Temperature, 453

17.5.5 Determination of the Lower Design Temperature, 453

17.5.6 Toughness Requirements, 455

17.5.7 Brittle Fracture Risk Assessment of Existing Systems, 455

17.5.8 Assessment Approaches, 456

17.5.9 LDT and Design Code–Based Assessments, 456

17.5.10 FFS-Based Assessments, 458

17.5.11 Assessment per API 579-1 and ASME FFS-1 Part 3, 458

17.5.12 Full FFS Assessment, 458

17.6 Case Histories and Examples of FFS Applications to Cracks in

Process Plant Pressure Vessels, 459

References, 464

18 Design of Pressure Vessels and Piping 467

Maher Y. A. Younan

18.1 Modes of Failure, 467

18.1.1 Failure Under Static Loading, 467

18.1.2 Failure Under Dynamic Loading, 468

18.1.3 Failure Under Other Types of Loading, 469

18.2 Basic Stress Analysis, 469

18.2.1 Allowable Stresses, 470

18.3 Design of Pressure Vessels, 470

18.3.1 Geometric Considerations, 470

18.3.2 Design of Vessels Under Internal Pressure, 471

18.3.3 Nozzles or Branch Connections, 472

18.3.4 Design of Formed Heads, 474

18.3.5 Vessels and Pipes Subjected to External Pressure, 475

18.3.6 Design of Vessel Supports, 478

18.3.7 Design by Rule Versus Design by Analysis, 479

18.4 Design of Piping Systems, 481

18.4.1 Wall Thickness for Internal Pressure, 481

18.4.2 Pipe Span Calculations, 482

18.4.3 Pipe Supports, 483

18.4.4 Expansion and Flexibility, 483

18.4.5 Code Compliance, 485

References, 486