| Preface | p. xv |
| Authors | p. xi |
| Welding Metallurgy | p. 1 |
| Solidification in Resistance Spot Welding | p. 1 |
| Metallurgical Characteristics of Metals | p. 4 |
| Steels | p. 5 |
| Solid Transformations in Steels | p. 5 |
| Transformations in HAZ of a Steel Weld | p. 8 |
| Effect of Carbon Content | p. 12 |
| Aluminum Alloys | p. 15 |
| Classifications and Properties | p. 16 |
| Resistance Welding Aluminum Alloys | p. 18 |
| Magnesium Alloys | p. 21 |
| Properties and Applications of Mg Alloys | p. 21 |
| Welding Mg Alloys | p. 22 |
| Resistance Welding Mg Alloys | p. 23 |
| Copper Alloys | p. 27 |
| Strengthening of Cu Alloys | p. 28 |
| Classifications of Electrodes | p. 29 |
| Copper Electrode and Coating/Sheet Interaction | p. 30 |
| Embrittlement of Weldment | p. 34 |
| Liquid Metal Embrittlement | p. 36 |
| Hydrogen Embrittlement | p. 40 |
| Intermetallic-Compound Embrittlement | p. 42 |
| Cracking | p. 45 |
| Solidification Cracking | p. 45 |
| Liquation Cracking | p. 47 |
| Corrosion Cracking | p. 47 |
| References | p. 48 |
| Electrothermal Processes of Welding | p. 53 |
| Electrical Characteristics of Resistance Welding | p. 53 |
| Bulk Resistance | p. 54 |
| Contact Resistance | p. 55 |
| Total Resistance | p. 57 |
| Shunting | p. 59 |
| Thermal Characteristics of Resistance Welding | p. 60 |
| Electrode Life | p. 62 |
| Welding Galvanized Steels | p. 62 |
| Welding Aluminum Alloys | p. 64 |
| Experiment | p. 65 |
| Rapid Electrode Life Determination | p. 65 |
| Electrode Life Test | p. 66 |
| Relation between 60-Weld Electrodes and Electrode Life | p. 70 |
| Heat Balance | p. 72 |
| Law of Thermal Similarity | p. 72 |
| Heat Balance | p. 73 |
| Modified Heat Balance Theory | p. 75 |
| Experimental Verification | p. 80 |
| Electric Current Waveform | p. 82 |
| Single-Phase AC | p. 84 |
| Constant Current | p. 87 |
| Half-Sine Current Profile | p. 87 |
| Sinusoidal Current Profile | p. 89 |
| Experiments | p. 90 |
| Single-Phase DC | p. 92 |
| Three-Phase DC | p. 93 |
| Medium-Frequency DC | p. 94 |
| References | p. 97 |
| Weld Discontinuities | p. 101 |
| Classification of Discontinuities | p. 101 |
| External Discontinuities | p. 101 |
| Internal Discontinuities | p. 107 |
| Void Formation in Weld Nuggets | p. 111 |
| Gas Bubbles | p. 111 |
| Effect of Volume Shrinkage | p. 115 |
| Cracking in Welding AA6U111 Alloys | p. 116 |
| Cracking in Welding AA5754 Alloys | p. 119 |
| Liquation Cracking in Aluminum Alloys | p. 120 |
| Mechanisms of Cracking | p. 122 |
| Metallurgical Effect | p. 123 |
| Thermomechanical Effect | p. 125 |
| Thermal Stress during Heating | p. 126 |
| Thermal Stress during Cooling | p. 127 |
| Influence of Other Factors | p. 130 |
| Cracking Suppression | p. 130 |
| Effect of Specimen Width and Electrode Geometry | p. 131 |
| Effect of Welding Sequence | p. 131 |
| Effect of Washer Clamping | p. 132 |
| Effect of Current Shunting | p. 133 |
| References | p. 135 |
| Mechanical Testing | p. 137 |
| Introduction | p. 137 |
| Shop Floor Practices | p. 139 |
| Chisel Test | p. 139 |
| Peel (Roller) Test | p. 140 |
| Bend Test | p. 140 |
| Instrumented Tests | p. 141 |
| Static Tests | p. 142 |
| Tension Test | p. 142 |
| Tension-Shear Test | p. 144 |
| Combined Tension and Shear Test | p. 152 |
| Dynamic Tests | p. 153 |
| Fatigue Test | p. 154 |
| Impact Test | p. 160 |
| A New Impact Tester | p. 164 |
| Torsion Test | p. 169 |
| Twisting | p. 169 |
| Torsional Shear Test | p. 169 |
| References | p. 170 |
| Resistance Welding Process Monitoring and Control | p. 173 |
| Introduction | p. 173 |
| Data Acquisition | p. 174 |
| Process Monitoring | p. 176 |
| Signals Commonly Monitored during Welding | p. 176 |
| Electric Voltage | p. 179 |
| Electric Current | p. 179 |
| Dynamic Resistance | p. 179 |
| Electrode Displacement | p. 181 |
| Electrode Force | p. 183 |
| Acoustic Emission | p. 185 |
| Pneumatic Pressure Fluctuation | p. 186 |
| Adaptive Noise Cancellation | p. 187 |
| Relationship between-Monitored Signals and Welding Processes | p. 190 |
| Effect of Process Conditions | p. 190 |
| Fault Identification | p. 192 |
| Expulsion Detection | p. 194 |
| Process Control | p. 196 |
| Lobe Diagrams | p. 197 |
| Effect of Process Parameters and Weld Setup Variables | p. 197 |
| Probabilistic Expulsion Boundaries in Lobe Diagrams | p. 199 |
| Effect of Electrode Force | p. 200 |
| 3-D Lobe Diagrams | p. 202 |
| Constant-Power Density | p. 203 |
| Hypothesis | p. 204 |
| Algorithm | p. 204 |
| Algorithm Implementation | p. 205 |
| Gain Scheduling | p. 206 |
| Experimental Results | p. 207 |
| Artificial Neural Network Modeling | p. 208 |
| A Case Study of Using ANN for RSW Quality Control | p. 211 |
| Current Stepping | p. 214 |
| References | p. 216 |
| Weld Quality and Inspection | p. 219 |
| Weld Quality | p. 219 |
| Weld Attributes | p. 219 |
| Geometric Attributes | p. 219 |
| Weld Performance | p. 220 |
| Process Characteristics | p. 221 |
| Weld Quality Requirements | p. 221 |
| Relations between Weld Attributes and Strength | p. 224 |
| Destructive Evaluation | p. 232 |
| Peel Test | p. 233 |
| Chisel Test | p. 233 |
| Metallographic Test | p. 233 |
| Nondestructive Evaluation | p. 235 |
| Ultrasonic A-Scan | p. 236 |
| A Case Study on R&R of an Ultrasonic A-Scanner | p. 238 |
| Ultrasonic B-Scan | p. 244 |
| Examining Various Welds Using a B-Scan System | p. 246 |
| Identification of Cold Welds | p. 248 |
| Relationship between Weld Attributes and Weld Strength | p. 253 |
| References | p. 255 |
| Expulsion in Resistance Spot Welding | p. 257 |
| Influence of Expulsion on Spot Weld Quality | p. 257 |
| Expulsion Process and Detection | p. 262 |
| Expulsion Prediction and Prevention | p. 263 |
| Geometry Comparison Model | p. 264 |
| Force Balance Model | p. 265 |
| The Principle | p. 265 |
| Evaluation of Effective Electrode Force | p. 266 |
| Pressures and Forces in Liquid Nugget | p. 269 |
| Expulsion through Molten Liquid Network in HAZ | p. 276 |
| Expulsion Characteristics of AZ91D | p. 277 |
| Effect of Electrode Force | p. 280 |
| Expulsion through a Network of Liquid Grain Boundaries | p. 281 |
| Statistical Modeling | p. 282 |
| Modeling Procedure | p. 284 |
| Statistical Analysis | p. 286 |
| Summary | p. 288 |
| Examples | p. 288 |
| Application of Force Balance Model | p. 289 |
| Calculation of Pressures and Forces | p. 289 |
| Experimental Verification | p. 292 |
| Perspective Applications | p. 294 |
| Examples of the Use of Statistical Model | p. 295 |
| Experiments | p. 295 |
| Discussion | p. 298 |
| References | p. 304 |
| Influence of Mechanical Characteristics of Welding Machines | p. 307 |
| Introduction | p. 307 |
| Mechanical Characteristics of Typical Spot Welders | p. 308 |
| Influence of Machine Stiffness | p. 310 |
| Effect on Electrode Force | p. 311 |
| Effect on Electrode Displacement | p. 311 |
| Effect on Electrode Touching Behavior | p. 313 |
| Effect on Weld Formation | p. 313 |
| Expulsion | p. 313 |
| Effect on Weld Strength | p. 314 |
| Effect on Electrode Alignment | p. 315 |
| Stiffness and Damping Ratio Estimation | p. 315 |
| Influence of Friction | p. 320 |
| Effect on Electrode Force | p. 321 |
| Effect on Electrode Displacement | p. 321 |
| Effect on Microstructure | p. 322 |
| Effect on Tensile-Shear Strength | p. 322 |
| Influence of Moving Mass | p. 324 |
| A Dynamic Force Analysis | p. 324 |
| Effect on Weld Quality | p. 327 |
| Follow-Up in a Welding Cycle | p. 328 |
| Thermal Expansion | p. 328 |
| Effect of a Pneumatic Cylinder | p. 329 |
| Theoretical Analysis | p. 330 |
| Experiment Results | p. 333 |
| Squeeze Time and Hold Time Measurement | p. 335 |
| Other Factors | p. 338 |
| Electrode Alignment and Workpiece Stack-Up | p. 338 |
| Electrode Force | p. 341 |
| Materials | p. 342 |
| References | p. 343 |
| Numerical Simulation in Resistance Spot Welding | p. 347 |
| Introduction | p. 347 |
| Comparison between Finite Difference and Finite Element Methods | p. 348 |
| Discretization | p. 348 |
| Geometry | p. 348 |
| Formulation | p. 349 |
| Accuracy and Others | p. 350 |
| Methods of RSW Process Simulation | p. 350 |
| Coupled Electrical-Thermal-Mechanical Analysis | p. 352 |
| A General (Three-Dimensional) Finite Element Model | p. 352 |
| Formulation of Electrical Process | p. 352 |
| Formulation of Heat Transfer Process | p. 353 |
| Boundary Conditions | p. 353 |
| Formulation of Thermomechanical Analysis | p. 354 |
| Simulation of Melting and Solidification | p. 354 |
| Finite Element Formulation | p. 355 |
| Two-Dimensional Finite Element Modeling | p. 356 |
| Formulation for Electrical Analysis | p. 356 |
| Formulation for Thermal Analysis | p. 357 |
| Finite Element Formulation | p. 357 |
| Axisymmetric Problems | p. 358 |
| Simulation of Contact Properties and Contact Area | p. 358 |
| Simulation of Other Factors | p. 362 |
| Effect of Zinc Coating | p. 362 |
| Effect of Electric Current Profile | p. 362 |
| Modeling of Microstructure Evolution | p. 363 |
| Effect of Cooling Rate | p. 364 |
| Microstructure Evolution in HAZ | p. 364 |
| Simulation of Microstructure of a Nugget | p. 365 |
| An Example of Simulating Microstructure Evolution in a Spot Weldment | p. 368 |
| Examples of Numerical Simulation of RSW Processes | p. 369 |
| Case Study I: Effect of Electrode Face Geometry | p. 369 |
| Case Study II: Differences between Using Coupled and Uncoupled Algorithms | p. 371 |
| Case Study III: Effect of Electrode Axial Misalignment | p. 372 |
| Case Study IV: Effect of Angular Misahgnment of Domed Electrodes | p. 373 |
| References | p. 376 |
| Statistical Design, Analysis, and Inference in Resistance Welding Research | p. 379 |
| Introduction | p. 379 |
| Basic Concepts and Procedures | p. 380 |
| Data Collection | p. 380 |
| Statistical Modeling and Data Analysis | p. 381 |
| Inference and Decision Making | p. 381 |
| Experiment with Continuous Response | p. 383 |
| Statistical Design | p. 383 |
| Factorial Designs | p. 383 |
| Orthogonal Arrays | p. 383 |
| Second-Order Designs | p. 384 |
| Robust Parameter Designs | p. 384 |
| Nested Designs | p. 384 |
| Use of Blocks | p. 385 |
| Analysis and Modeling | p. 386 |
| Use of Graphs | p. 386 |
| Multiple Regression Model | p. 387 |
| Residual Analysis | p. 389 |
| Location-Dispersion Modeling for Variance Reduction | p. 389 |
| Inference and Decision Making | p. .390 |
| Factor Screening | p. 390 |
| Treatment Comparison | p. : |
| Combination of Experiments | p. 393 |
| Response Surface Exploration | p. 395 |
| Variance Reduction | p. 397 |
| Two-Stage Sliding-Level Experiments | p. 398 |
| Experiment Design | p. 399 |
| Analysis and Modeling | p. 400 |
| Analysis of Current Range | p. 402 |
| Analysis of Button Size | p. -. |
| Inference and Decision Making | p. 405 |
| Experiments with Categorical Responses | p. 407 |
| Experiment Design | p. 408 |
| Analysis and Modeling | p. 408 |
| Inference and Decision Making | p. 409 |
| Statistical Analysis | p. 409 |
| Coding System and Transformations | p. 410 |
| Use of Pseudo-Data | p. 412 |
| Analysis and Results | p. 413 |
| Inference and Decision Making | p. 416 |
| Computer Simulation Experiments | p. 416 |
| Experiment Design | p. 417 |
| Analysis and Modeling | p. 417 |
| Planning of Numerical Experiments | p. 418 |
| Results and Inference | p. 421 |
| Summary | p. 425 |
| References | p. 425 |
| Index | p. 427 |
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