Newark : , : John Wiley & Sons, Incorporated, , 2025

©2026

3-527-84537-2

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1 online resource (211 pages)

de Sousa MarquesEduardo André

Camilo CarbasRicardo João

da SilvaLucas Filipe Martins

669.722

Inglese

Cover -- Title Page -- Copyright -- Contents -- Preface -- List of Abbreviations -- Chapter 1 Aluminum Alloys: Fundamentals of Welding Metallurgy -- 1.1 Introduction -- 1.1.1 Aluminum-Copper Alloys -- 1.1.2 Aluminum-Zinc-Magnesium Alloys -- 1.1.3 Aluminum-Magnesium-Silicium -- 1.1.4 Aluminum-Lithium Alloys -- 1.2 Weldability -- 1.2.1 Aluminum Oxide -- 1.2.2 Hydrogen and Pore Formation -- 1.2.2.1 Effects of Porosity on the Mechanical Behavior -- 1.2.3 Hot Cracking -- 1.3 Thermal Cycle and Its Effect on the Weld Zone -- 1.4 Welding of Aluminum to Other Metals -- References -- Chapter 2 Arc Welding Processes -- 2.1 Introduction -- 2.2 Processes -- 2.2.1 TIG Welding -- 2.2.2 Plasma Arc Welding -- 2.2.3 MIG Welding -- 2.3 Modifications to the Processes -- 2.3.1 Negative‐Pole and Positive‐Pole TIG Welding -- 2.3.2 Keyhole TIG (K‐TIG) Welding -- 2.3.3 Activated‐Flux TIG (A‐TIG) Welding -- 2.3.4 Double‐Wire MIG Welding -- 2.3.5 Indirect Electric Arc -- 2.3.6 Cold Metal Transfer (CMT) Welding -- 2.3.7 Positive‐Pole Plasma Welding -- 2.3.8 Hyperbaric Welding -- 2.4 Hybrid Welding -- 2.4.1 Plasma‐MIG Welding -- 2.4.2 TIG‐MIG Welding -- 2.5 Protective Gases -- 2.6 Filler Material -- 2.7 Grain Refinement in the Weld -- 2.8 Grain Structure -- 2.9 Defects

During Arc Welding -- 2.9.1 Segregation -- 2.9.2 Smut -- 2.9.3 Pores -- 2.9.4 Hot Cracking -- 2.10 Welding of Dissimilar Metals -- 2.11 Simulation of the Arc Welding Processes -- References -- Chapter 3 Beam Welding Processes -- 3.1 Introduction -- 3.2 Laser Systems -- 3.3 Defects Formation During Laser Welding of Al Alloys -- 3.3.1 Mechanism of Pore Formation -- 3.3.2 Hot Cracking in Laser Welding -- 3.4 Shielding Gases in Laser Welding -- 3.5 Modifications to Laser Welding of Al -- 3.5.1 Multi‐spot Laser Beam Welding -- 3.5.2 Micro‐laser Welding -- 3.5.3 Pulsed Laser Beam Welding.

3.5.4 Hybrid Laser Welding -- 3.5.5 Oscillation Laser Beam Welding -- 3.5.6 Vibration‐Assisted Laser Beam Welding -- 3.5.7 Hot‐Wire Laser Welding -- 3.6 Special Cases of Al Welding -- 3.6.1 Additive Manufacturing -- 3.6.2 Cast Aluminum -- 3.6.3 Welding of Aluminum to Dissimilar Materials -- 3.7 Simulation of Laser Welding -- References -- Chapter 4 Resistance Welding Process -- 4.1 Introduction -- 4.2 Weld Zones -- 4.2.1 Nugget Zone -- 4.2.2 Thermo‐Mechanically Affected Zone (TMAZ) -- 4.3 Defects During RSW of Al Alloys -- 4.4 RSW of Dissimilar Aluminum Alloys -- 4.5 RSW of Al to Dissimilar Metals -- 4.6 Modifications to RSW for Welding Al Alloys -- 4.7 Simulation of the Process -- 4.8 Evaluation of the Joints -- References -- Chapter 5 Solid‐State Welding Process -- 5.1 Introduction -- 5.2 FSW of Al Alloys -- 5.3 FSW of Al‐Matrix Composites -- 5.4 FSW of Al to Dissimilar Materials -- 5.5 Joint Design -- 5.6 Simulation of the Process -- References -- Index -- EULA.

A must-have guide to welding aluminium alloys for optimized performance and precision Aluminium alloys, widely used across industries due to their high specific strength and corrosion resistance, require precise joining methods to maintain their structural integrity.