Advances in brazing : science, technology and applications

Brazing processes offer enhanced control, adaptability and cost-efficiency in the joining of materials. Unsurprisingly, this has lead to great interest and investment in the area. Drawing on important research in the field, Advances in brazing provides a clear guide to the principles, materials, methods and key applications of brazing.Part one introduces the fundamentals of brazing, including molten metal wetting processes, strength and margins of safety of brazed joints, and modeling of associated physical phenomena. Part two goes on to consider specific materials, such as super alloys, filler metals for high temperature brazing, diamonds and cubic boron nitride, and varied ceramics and intermetallics. The brazing of carbon-carbon (C/C) composites to metals is also explored before applications of brazing and brazed materials are discussed in part three. Brazing of cutting materials, use of coating techniques, and metal-nonmetal brazing for electrical, packaging and structural applications are reviewed, along with fluxless brazing, the use of glasses and glass ceramics for high temperature applications and nickel-based filler metals for components in contact with drinking water.With its distinguished editor and international team of expert contributors, Advances in brazing is a technical guide for any professionals requiring an understanding of brazing processes, and offers a deeper understanding of the subject to researchers and engineers within the field of joining.

Contributor contact details Preface Part I: Fundamentals of brazing Chapter 1: The wetting process in brazing Abstract: 1.1 Introduction 1.2 Wetting of solids by liquid metals and oxides 1.3 Wetting versus brazing: general considerations 1.4 Brazing of metals and ceramics by non-reactive and reactive alloys 1.5 Conclusion Chapter 2: Strength and margins of brazed joints Abstract: 2.1 Introduction 2.2 Applicability of common failure criteria to analysis of brazed joints 2.3 Alternative approach for developing failure assessment diagrams (FADs) 2.4 Conclusion 2.5 Acknowledgements Chapter 3: Modeling of the sequence of phenomena in brazing Abstract: 3.1 Introduction 3.2 Modeling brazing systems 3.3 Finite element analysis of residual stresses in brazed structures 3.4 Micro-scale brazing phenomena modeling 3.5 Conclusions Part II: Materials used in brazing Chapter 4: Brazing of superalloys and the intermetallic alloy (I(3)-TiAl) Abstract: 4.1 Introduction 4.2 Brazing of superalloys on a nickel base 4.3 Brazing of titanium aluminides 4.4 Conclusion 4.5 Future trends Chapter 5: High-temperature brazing: filler metals and processing Abstract: 5.1 Introduction 5.2 Features of base metal (BM) alloys used in high-temperature brazing 5.3 Brazing filler metals (BFMs) for joining high-temperature base metals 5.4 High-temperature base metal brazing 5.5 Metallurgical paths of joint formation 5.6 Industrial applications Chapter 6: Brazing of diamonds and cubic boron nitride Abstract: 6.1 Introduction 6.2 Physical properties of diamond and cubic boron nitride (CBN) 6.3 Diamond's interaction with metals 6.4 Diamond graphitization during annealing and brazing 6.5 Wetting of diamond by metals and alloys 6.6 Wetting of cubic boron nitride (CBN) 6.7 Brazing filler metals and techniques for diamond joining 6.8 Mechanical testing of diamond joints 6.9 Brazing of cubic boron nitride (CBN) 6.10 Brazed cubic boron nitride (CBN) products 6.11 Conclusion Chapter 7: Brazing of oxide, carbide, nitride and composite ceramics Abstract: 7.1 Introduction 7.2 Difficulties of brazing with ceramics and solutions 7.3 Brazing of oxide ceramics 7.4 Brazing of nitride ceramics 7.5 Brazing of carbide ceramics 7.6 Brazing of carbon-carbon (C/C) composites 7.7 Conclusion Chapter 8: Brazing of nickel, ferrite and titaniumaEURO"aluminum intermetallics Abstract: 8.1 Introduction 8.2 Physical properties and brazing properties of Ni-Al system intermetallics 8.3 Physical properties and brazing properties of Fe-Al intermetallics 8.4 Physical properties and brazing properties of Ti-Al intermetallics 8.5 Brazing between Ti-Al intermetallics 8.6 Conclusion Chapter 9: Brazing of aluminium and aluminium to steel Abstract: 9.1 Introduction 9.2 Brazing aluminium and its alloys using reactive fluxes 9.3 Brazing of aluminium to stainless steel 9.4 Arc flux brazing of aluminium to galvanised steels 9.5 Soldering of aluminium 9.6 Conclusion and future trends Chapter 10: Controlled atmosphere brazing of aluminum Abstract: 10.1 Introduction 10.2 Applications of controlled atmosphere brazing (CAB) of aluminum 10.3 Materials involved in controlled atmosphere brazing (CAB) of aluminum 10.4 Oxide and flux 10.5 Controlled atmosphere brazing (CAB) process 10.6 Corrosion in controlled atmosphere brazing (CAB) brazed heat exchangers Chapter 11: Active metal brazing of advanced ceramic composites to metallic systems Abstract: 11.1 Introduction 11.2 Brazing dissimilar materials 11.3 Brazing ceramic-matrix composites 11.4 Conclusions 11.5 Acknowledgment Chapter 12: Brazing of metal and ceramic joints Abstract: 12.1 Introduction 12.2 Brazing of metal and ceramic 12.3 Brazing of metallized ceramics 12.4 Active brazing of metal-ceramic compounds 12.5 Influencing the mechanical properties of brazed metal-ceramic compounds 12.6 Preparation for and execution of the brazing process 12.7 Examination methods for brazed metal-ceramic compounds 12.8 Example of an active-brazed metal-ceramic compound 12.9 Induction brazing of metal-ceramic compounds 12.10 Conclusion 12.11 Acknowledgements Chapter 13: Brazing of carbonaEURO"carbon (C/C) composites to metals Abstract: 13.1 Introduction 13.2 Carbon-carbon composites 13.3 Brazing filler alloys for brazing of Carbon-carbon composites and metals 13.4 Anisotropy of Carbon-carbon composites and their brazing with metals 13.5 Indirect methods for brazing Carbon-carbon composites to metals 13.6 Conclusion Part III: Applications of brazing and brazed materials Chapter 14: Brazing of cutting materials Abstract: 14.1 Introduction 14.2 Cutting materials 14.3 The main factors controlling the quality of joints 14.4 Brazing filler metals 14.5 Induced stresses in brazed joints 14.6 Case studies 14.7 Conclusion and future trends Chapter 15: Coating techniques using brazing Abstract: 15.1 Introduction 15.2 Fundamentals of brazed coatings 15.3 Classification of brazed coatings 15.4 Functional coatings 15.5 Conclusion Chapter 16: MetalaEURO"nonmetal brazing for electrical, packaging and structural applications Abstract: 16.1 Introduction 16.2 Designing and specifying a brazement 16.3 Metallization schemes 16.4 Brazing method selection 16.5 Performing the brazing operation 16.6 Testing the brazements 16.7 Test results and analysis for select material sets 16.8 Future trends 16.9 Sources of further information and advice Chapter 17: Glasses and glass-ceramics as brazing materials for high-temperature applications Abstract: 17.1 Introduction 17.2 Glass and glass-ceramic sealants for solid oxide fuel cells 17.3 Glass and glass-ceramic joining for SiC-based materials Chapter 18: Brazing of nickel-based filler metals for pipes and other components in contact with drinking water Abstract: 18.1 Introduction: brazing filler metals for corrosion-resistant applications 18.2 Materials and components in drinking water installations 18.3 Current drinking water regulations and standards 18.4 Test rig and samples 18.5 Test results 18.6 Conclusion Chapter 19: Fluxless brazing of aluminium Abstract: 19.1 Introduction 19.2 Definition of fluxless brazing 19.3 Controlled atmosphere brazing process limitations 19.4 Background chemistry and metallurgy influencing fluxless brazing 19.5 Fluxless brazing processes 19.6 Conclusion: a summary of fluxless brazing processes Index