Description

Book Synopsis

A comprehensive resource covering the foundational thermal-fluid sciences and engineering analysis techniques used to design and develop internal combustion engines

Internal Combustion Engines: Applied Thermosciences, Fourth Edition combines foundational thermal-fluid sciences with engineering analysis techniques for modeling and predicting the performance of internal combustion engines.

This new 4th edition includes brand new material on:

  • New engine technologies and concepts
  • Effects of engine speed on performance and emissions
  • Fluid mechanics of intake and exhaust flow in engines
  • Turbocharger and supercharger performance analysis
  • Chemical kinetic modeling, reaction mechanisms, and emissions
  • Advanced combustion processes including low temperature combustion
  • Piston, ring and journal bearing friction analysis

The 4th Edition expands on the combined analytical and

Table of Contents

Preface xi

Acknowledgements xiii

About the Companion Website xv

1. Introduction to Internal Combustion Engines 1

1.1 Introduction 1

1.2 Historical Background 4

1.3 Engine Cycles 6

1.4 Engine Performance Parameters 10

1.5 Engine Configurations 21

1.6 Examples of Internal Combustion Engines 25

1.7 Alternative Powertrain Technology 29

1.8 Further Reading 33

1.9 References 33

1.10 Homework 33

2. Ideal Gas Engine Cycles 35

2.1 Introduction 35

2.2 Gas Cycle Energy Addition 36

2.3 Constant Volume Energy Addition 37

2.4 Constant Pressure Energy Addition 41

2.5 Limited Pressure Cycle 44

2.6 Miller Cycle 45

2.7 Ideal Four-Stroke Process and Residual Fraction 49

2.8 Finite Energy Release 58

2.9 References 75

2.10 Homework 75

3. Thermodynamic Properties of Fuel–Air Mixtures 79

3.1 Introduction 79

3.2 Properties of Ideal Gas Mixtures 79

3.3 Liquid–Vapor–Gas Mixtures 86

3.4 Stoichiometry 90

3.5 Chemical Equilibrium 93

3.6 Low Temperature Combustion Modeling 96

3.7 Chemical Equilibrium Using Lagrange Multipliers 101

3.8 Chemical Equilibrium Using Equilibrium Constants 104

3.9 Isentropic Compression and Expansion 111

3.10 Chemical Kinetics 114

3.11 References 120

3.12 Homework 121

4. Thermodynamics of Combustion 123

4.1 Introduction 123

4.2 First-Law Analysis of Combustion 123

4.3 Second-Law Analysis of Combustion 129

4.4 Fuel–Air Otto Cycle 133

4.5 Four-Stroke Fuel–Air Otto Cycle 137

4.6 Limited-Pressure Fuel–Air Cycle 141

4.7 Two-Zone Finite-Energy Release Model 146

4.8 Compression Ignition Engine Fuel–Air Model 153

4.9 Comparison of Fuel–Air Cycles with Actual Spark and Compression Ignition Cycles 156

4.10 Further Reading 160

4.11 Homework 160

5. Intake and Exhaust Flow 163

5.1 Introduction 163

5.2 Flow Through Intake and Exhaust Valves 163

5.3 Intake and Exhaust Manifold Flow 185

5.4 Airflow in Two-Stroke Engines 190

5.5 Superchargers and Turbochargers 199

5.6 Further Reading 219

5.7 References 219

5.8 Homework 221

6. Fuel and Air Flow in the Cylinder 225

6.1 Introduction 225

6.2 Fuel Injection – Spark Ignition 225

6.3 Fuel Injection – Compression Ignition 228

6.4 Fuel Sprays 233

6.5 Gaseous Fuel Injection 241

6.6 Prechambers 246

6.7 Carburetion 249

6.8 Large-Scale In-Cylinder Flow 252

6.9 In-Cylinder Turbulence 258

6.10 Further Reading 268

6.11 References 269

6.12 Homework 270

7. Combustion Processes in Engines 273

7.1 Introduction 273

7.2 Combustion in Spark-Ignition Engines 274

7.3 Abnormal Combustion (Knock) in Spark-Ignition Engines 286

7.4 Combustion in Compression Ignition Engines 290

7.5 Low Temperature Combustion 302

7.6 Further Reading 311

7.7 References 311

7.8 Homework 313

8. Emissions 317

8.1 Introduction 317

8.2 Nitrogen Oxides 318

8.3 Carbon Monoxide 329

8.4 Hydrocarbons 332

8.5 Particulates 335

8.6 Emissions Regulation and Control 342

8.7 Further Reading 350

8.8 References 350

8.9 Homework 351

9. Fuels 355

9.1 Introduction 355

9.2 Refining 356

9.3 Hydrocarbon Chemistry 357

9.4 Thermodynamic Properties of Fuel Mixtures 360

9.5 Gasoline Fuels 370

9.6 Alternative Fuels for Spark-Ignition Engines 373

9.7 Diesel Fuels 383

9.8 Further Reading 389

9.9 Homework 391

10. Friction and Lubrication 393

10.1 Introduction 393

10.2 Friction Coefficient 393

10.3 Engine Oils 396

10.4 Friction Power and Mean Effective Pressure 399

10.5 Friction Measurements 400

10.6 Friction Scaling Parameters 403

10.7 Piston and Ring Friction 404

10.8 Journal Bearings 418

10.9 Valve Train Friction 423

10.10 Accessory Friction 427

10.11 Pumping Mean Effective Pressure 428

10.12 Overall Engine Friction Mean Effective Pressure 429

10.13 Further Reading 432

10.14 References 432

10.15 Homework 433

11. Heat and Mass Transfer 435

11.1 Introduction 435

11.2 Engine Cooling Systems 436

11.3 Engine Energy Balance 437

11.4 Heat Transfer Measurements 441

11.5 Heat Transfer Modeling 444

11.6 Heat Transfer Correlations 449

11.7 Radiation Heat Transfer 455

11.8 Heat Transfer in the Exhaust System 459

11.9 Mass Loss or Blowby 460

11.10 Further Reading 463

11.11 References 463

11.12 Homework 464

12. Engine Instrumentation and Testing 467

12.1 Introduction 467

12.2 Instrumentation 468

12.3 Combustion Analysis 475

12.4 Exhaust Gas Analysis 480

12.5 Control Systems in Engines 491

12.6 Vehicle Emissions Testing 493

12.7 Further Reading 495

12.8 References 495

12.9 Homework 496

13. Overall Engine Performance 499

13.1 Introduction 499

13.2 Effect of Engine Size, Bore, and Stroke 499

13.3 Effect of Engine Speed 502

13.4 Effect of Air–Fuel Ratio and Load 503

13.5 Engine Performance Maps 506

13.6 Effect of Ignition and Injection Timing 510

13.7 Effect of Compression Ratio 512

13.8 Vehicle Performance Simulation 513

13.9 Further Reading 513

13.10 References 513

13.11 Homework 514

Appendices 517

A Conversion Factors and Physical Constants 517

B Physical Properties of Air 519

C Thermodynamic Property Tables for Various Ideal Gases 521

D Curve-Fit Coefficients for Thermodynamic Properties of Various Fuels and Ideal Gases 529

E Detailed Thermodynamic and Fluid Flow Analyses 533

E.1 Thermodynamic Derivatives 533

E.2 Numerical Solution of Equilibrium Combustion Equations 535

E.3 Isentropic Compression/Expansion with Known ΔP 538

E.4 Isentropic Compression/Expansion with Known Δv 538

E.5 Constant Volume Combustion 539

E.6 Quality of Exhaust Products 540

E.7 Finite Difference Form of the Reynolds Slider Equation 542

E.8 Reference 542

F Computer Programs 543

F.1 Volume.m 544

F.2 Velocity.m 544

F.3 BurnFraction.m 545

F.4 FiniteHeatRelease.m 545

F.5 FiniteHeatMassLoss.m 547

F.6 CIHeatRelease.m 550

F.7 FourStrokeOtto.m 552

F.8 RunFarg.m 553

F.9 farg.m 554

F.10 fuel.m 557

F.11 RunEcp.m 559

F.12 ecp.m 560

F.13 AdiabaticFlameTemp.m 570

F.14 OttoFuelAir.m 571

F.15 FourStrokeFuelAir.m 573

F.16 TwoZoneFuelAir.m 577

F.17 Fuel_Injected.m 583

F.18 LimitPressFuelAir.m 588

F.19 ValveFlow.m 592

F.20 Droplet.m 603

F.21 Kinetic.m 610

F.22 Soot.m 613

F.23 TwoZoneNO.m 614

F.24 RingPressure.m 621

F.25 Friction.m 624

F.26 HeatTransfer.m 625

Index 631

Internal Combustion Engines

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A Hardback by Allan T. Kirkpatrick

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    View other formats and editions of Internal Combustion Engines by Allan T. Kirkpatrick

    Publisher: John Wiley & Sons Inc
    Publication Date: 25/09/2020
    ISBN13: 9781119454502, 978-1119454502
    ISBN10: 1119454506
    Also in:
    Technology, Engineering & Agriculture Mechanical engineering and materials

    Description

    Book Synopsis

    A comprehensive resource covering the foundational thermal-fluid sciences and engineering analysis techniques used to design and develop internal combustion engines

    Internal Combustion Engines: Applied Thermosciences, Fourth Edition combines foundational thermal-fluid sciences with engineering analysis techniques for modeling and predicting the performance of internal combustion engines.

    This new 4th edition includes brand new material on:

    • New engine technologies and concepts
    • Effects of engine speed on performance and emissions
    • Fluid mechanics of intake and exhaust flow in engines
    • Turbocharger and supercharger performance analysis
    • Chemical kinetic modeling, reaction mechanisms, and emissions
    • Advanced combustion processes including low temperature combustion
    • Piston, ring and journal bearing friction analysis

    The 4th Edition expands on the combined analytical and

    Table of Contents

    Preface xi

    Acknowledgements xiii

    About the Companion Website xv

    1. Introduction to Internal Combustion Engines 1

    1.1 Introduction 1

    1.2 Historical Background 4

    1.3 Engine Cycles 6

    1.4 Engine Performance Parameters 10

    1.5 Engine Configurations 21

    1.6 Examples of Internal Combustion Engines 25

    1.7 Alternative Powertrain Technology 29

    1.8 Further Reading 33

    1.9 References 33

    1.10 Homework 33

    2. Ideal Gas Engine Cycles 35

    2.1 Introduction 35

    2.2 Gas Cycle Energy Addition 36

    2.3 Constant Volume Energy Addition 37

    2.4 Constant Pressure Energy Addition 41

    2.5 Limited Pressure Cycle 44

    2.6 Miller Cycle 45

    2.7 Ideal Four-Stroke Process and Residual Fraction 49

    2.8 Finite Energy Release 58

    2.9 References 75

    2.10 Homework 75

    3. Thermodynamic Properties of Fuel–Air Mixtures 79

    3.1 Introduction 79

    3.2 Properties of Ideal Gas Mixtures 79

    3.3 Liquid–Vapor–Gas Mixtures 86

    3.4 Stoichiometry 90

    3.5 Chemical Equilibrium 93

    3.6 Low Temperature Combustion Modeling 96

    3.7 Chemical Equilibrium Using Lagrange Multipliers 101

    3.8 Chemical Equilibrium Using Equilibrium Constants 104

    3.9 Isentropic Compression and Expansion 111

    3.10 Chemical Kinetics 114

    3.11 References 120

    3.12 Homework 121

    4. Thermodynamics of Combustion 123

    4.1 Introduction 123

    4.2 First-Law Analysis of Combustion 123

    4.3 Second-Law Analysis of Combustion 129

    4.4 Fuel–Air Otto Cycle 133

    4.5 Four-Stroke Fuel–Air Otto Cycle 137

    4.6 Limited-Pressure Fuel–Air Cycle 141

    4.7 Two-Zone Finite-Energy Release Model 146

    4.8 Compression Ignition Engine Fuel–Air Model 153

    4.9 Comparison of Fuel–Air Cycles with Actual Spark and Compression Ignition Cycles 156

    4.10 Further Reading 160

    4.11 Homework 160

    5. Intake and Exhaust Flow 163

    5.1 Introduction 163

    5.2 Flow Through Intake and Exhaust Valves 163

    5.3 Intake and Exhaust Manifold Flow 185

    5.4 Airflow in Two-Stroke Engines 190

    5.5 Superchargers and Turbochargers 199

    5.6 Further Reading 219

    5.7 References 219

    5.8 Homework 221

    6. Fuel and Air Flow in the Cylinder 225

    6.1 Introduction 225

    6.2 Fuel Injection – Spark Ignition 225

    6.3 Fuel Injection – Compression Ignition 228

    6.4 Fuel Sprays 233

    6.5 Gaseous Fuel Injection 241

    6.6 Prechambers 246

    6.7 Carburetion 249

    6.8 Large-Scale In-Cylinder Flow 252

    6.9 In-Cylinder Turbulence 258

    6.10 Further Reading 268

    6.11 References 269

    6.12 Homework 270

    7. Combustion Processes in Engines 273

    7.1 Introduction 273

    7.2 Combustion in Spark-Ignition Engines 274

    7.3 Abnormal Combustion (Knock) in Spark-Ignition Engines 286

    7.4 Combustion in Compression Ignition Engines 290

    7.5 Low Temperature Combustion 302

    7.6 Further Reading 311

    7.7 References 311

    7.8 Homework 313

    8. Emissions 317

    8.1 Introduction 317

    8.2 Nitrogen Oxides 318

    8.3 Carbon Monoxide 329

    8.4 Hydrocarbons 332

    8.5 Particulates 335

    8.6 Emissions Regulation and Control 342

    8.7 Further Reading 350

    8.8 References 350

    8.9 Homework 351

    9. Fuels 355

    9.1 Introduction 355

    9.2 Refining 356

    9.3 Hydrocarbon Chemistry 357

    9.4 Thermodynamic Properties of Fuel Mixtures 360

    9.5 Gasoline Fuels 370

    9.6 Alternative Fuels for Spark-Ignition Engines 373

    9.7 Diesel Fuels 383

    9.8 Further Reading 389

    9.9 Homework 391

    10. Friction and Lubrication 393

    10.1 Introduction 393

    10.2 Friction Coefficient 393

    10.3 Engine Oils 396

    10.4 Friction Power and Mean Effective Pressure 399

    10.5 Friction Measurements 400

    10.6 Friction Scaling Parameters 403

    10.7 Piston and Ring Friction 404

    10.8 Journal Bearings 418

    10.9 Valve Train Friction 423

    10.10 Accessory Friction 427

    10.11 Pumping Mean Effective Pressure 428

    10.12 Overall Engine Friction Mean Effective Pressure 429

    10.13 Further Reading 432

    10.14 References 432

    10.15 Homework 433

    11. Heat and Mass Transfer 435

    11.1 Introduction 435

    11.2 Engine Cooling Systems 436

    11.3 Engine Energy Balance 437

    11.4 Heat Transfer Measurements 441

    11.5 Heat Transfer Modeling 444

    11.6 Heat Transfer Correlations 449

    11.7 Radiation Heat Transfer 455

    11.8 Heat Transfer in the Exhaust System 459

    11.9 Mass Loss or Blowby 460

    11.10 Further Reading 463

    11.11 References 463

    11.12 Homework 464

    12. Engine Instrumentation and Testing 467

    12.1 Introduction 467

    12.2 Instrumentation 468

    12.3 Combustion Analysis 475

    12.4 Exhaust Gas Analysis 480

    12.5 Control Systems in Engines 491

    12.6 Vehicle Emissions Testing 493

    12.7 Further Reading 495

    12.8 References 495

    12.9 Homework 496

    13. Overall Engine Performance 499

    13.1 Introduction 499

    13.2 Effect of Engine Size, Bore, and Stroke 499

    13.3 Effect of Engine Speed 502

    13.4 Effect of Air–Fuel Ratio and Load 503

    13.5 Engine Performance Maps 506

    13.6 Effect of Ignition and Injection Timing 510

    13.7 Effect of Compression Ratio 512

    13.8 Vehicle Performance Simulation 513

    13.9 Further Reading 513

    13.10 References 513

    13.11 Homework 514

    Appendices 517

    A Conversion Factors and Physical Constants 517

    B Physical Properties of Air 519

    C Thermodynamic Property Tables for Various Ideal Gases 521

    D Curve-Fit Coefficients for Thermodynamic Properties of Various Fuels and Ideal Gases 529

    E Detailed Thermodynamic and Fluid Flow Analyses 533

    E.1 Thermodynamic Derivatives 533

    E.2 Numerical Solution of Equilibrium Combustion Equations 535

    E.3 Isentropic Compression/Expansion with Known ΔP 538

    E.4 Isentropic Compression/Expansion with Known Δv 538

    E.5 Constant Volume Combustion 539

    E.6 Quality of Exhaust Products 540

    E.7 Finite Difference Form of the Reynolds Slider Equation 542

    E.8 Reference 542

    F Computer Programs 543

    F.1 Volume.m 544

    F.2 Velocity.m 544

    F.3 BurnFraction.m 545

    F.4 FiniteHeatRelease.m 545

    F.5 FiniteHeatMassLoss.m 547

    F.6 CIHeatRelease.m 550

    F.7 FourStrokeOtto.m 552

    F.8 RunFarg.m 553

    F.9 farg.m 554

    F.10 fuel.m 557

    F.11 RunEcp.m 559

    F.12 ecp.m 560

    F.13 AdiabaticFlameTemp.m 570

    F.14 OttoFuelAir.m 571

    F.15 FourStrokeFuelAir.m 573

    F.16 TwoZoneFuelAir.m 577

    F.17 Fuel_Injected.m 583

    F.18 LimitPressFuelAir.m 588

    F.19 ValveFlow.m 592

    F.20 Droplet.m 603

    F.21 Kinetic.m 610

    F.22 Soot.m 613

    F.23 TwoZoneNO.m 614

    F.24 RingPressure.m 621

    F.25 Friction.m 624

    F.26 HeatTransfer.m 625

    Index 631

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