What a long story welding is! Seeing the light of day at the end of the 19th century in the mind of scientists, it passed quickly into the hands of technicians, first of all with the oxyacetylene technique, then with arc welding and resistance welding techniques. Other processes (we will not quote them all in this introduction) then followed and the 20th century ended with laser welding which had its origins in the 1980s.
However, it must be said that only since the 1950s has welding been the main means of assembly, as riveting was the most used method up to that point.
In fact, after abandoning this method to some extent, scientists renewed their involvement in the 1930s. In France, at the time, Albert Portevin set out Les bases scientifiques de la soudure autogène and a higher education teaching programme began in 1931 at L’Institut de soudure. In the 1930s welding was implicated in bridge failures, notably in Germany and Belgium, then during World War II came the failure of Liberty ships constructed in great numbers thanks to the technique of welding. Other later catastrophic failures affected pressure vessels. It is in this context that in 1948 L’Institut international de la soudure (IIS/IIW) was founded. It met the need for international collaboration, in particular with regard to safety and research, expressed by different national bodies and by the whole welding world, from scientists to users. Today in 2008, the IIS/IIW holds its 61st annual meeting: 16 commissions, with sub-commissions and study groups, cover the whole field of welding, from design to performance and safety, including teaching and research. This demonstrates the importance of this collaboration and the richness of its contribution.
Welding can be regarded, like the language of Aesop, as the best and worst of things. Indeed, it makes it possible to bond almost all materials, from metals to plastics, with continuity; however, this does not imply homogenity. The processes and hence possibilities are very numerous depending on the types of assemblies to be made, the properties required and evident economic constraints to be respected. At the same time welding can be regarded as the weak link of the majority of constructions as it is often called into question when problems arise. In the examples cited above (bridges, Liberty ships, pressure vessels) it is the welding that is called into question each time — often it must be added linked to a parent metal whose resistance to a sudden failure is insufficient.
The phenomena that occur during welding are both numerous and complex. In particular, the influence of extremely rapid thermal cycles and at high temperature on the physical, metallurgical and mechanical properties of welded materials always requires a better understanding.
In order to produce this work, the multiplicity of knowledge, scientific as well as technical, to be put in practice has led us to have recourse to a range of authors to share the task. The disadvantage is of course a certain disparity between the various chapters, as well as the risk of some repetitions. On the other hand, its richness is derived from this very fact as this work brings together the contributions of numerous French specialists well known in their specific field. It presents an entity as complete as possible on the knowledge available today on welding, without of course claiming to be exhaustive (for example, the welding of the plastics is outside its scope).
In a first part of 7 chapters, which deals with metallurgy and mechanics of welding, Chapters 1 and 2 present all the processes of welding, from the traditional processes with and without filler, with and without mechanical action, to the recent processes with high energy, electron beam and laser. Chapter 3 deals with the whole of the thermal, metallurgical and mechanical phenomena, which occur in the heat affected zone (HAZ) of the base material. Here the transformation phases with all the consequences they have on the structures and their properties are presented, as well as the phenomena of cracking, in particular cold cracking, which is a recurring theme of this work.
Chapter 4 is similar but deals with the question of molten metal in the weld, with other phenomena of cracking that are called into play.
The different types of filler products are then dealt with in Chapter 5 depending on the process used. The progress made in the manufacture of these products in order to improve the properties of the weld and resistance to cracking is explained.
Chapters 6 and 7 illustrate the problems of failure in service of welded constructions, the former dealing with resistance to fatigue, with solutions suggested both for materials and for the execution of the welds, the latter dealing with brittle failure, with, after setting out the methods of evaluation of the toughness and the evolution of the harmfulness of defects, proposals relating to the composition of the parent material, the quality of the filler metal and the importance of welding conditions.
The second part, Chapters 8 to 14, focuses on the applications of welding for various materials and in various industries.
First of all, Chapter 8 is devoted to the welding of thin sheets, both bare and coated, mainly used in the automotive market with the appropriate processes of welding. The importance of new steels with a very low percentage of carbon is underlined.
The subject of Chapter 9 is the welding of steel mechanical components in the automotive industry, with less traditional processes calling upon a minimum of molten metal.
The welding of steel structures is the subject of Chapter 10. The steels used and the techniques of welding with the precautions required in order to avoid defects are presented.
Chapter 11 concerns the welding of pressure vessels. It deals with examples of large components such as pressurized water reactors (PWRs) in the French nuclear industry and analyzes the various processes of welding and coatings used according to the parts of the vessel.
The majority of the preceding chapters refer to welding carbon and low-alloy steels, so Chapters 12 and 13 are devoted to other types of alloys. First of all, the welding of stainless steels is presented in detail, and for various families (martensitic, ferritic, austenitic and austeno-ferritic) with the concomitant problems of cracking and embrittlement, as well as the remedies and advice suggested according to the processes selected. Then, the welding of aluminum alloys is tackled with the various welding techniques used, the problems encountered and the rules to respect in order to obtain welds of good quality.
Chapter 14 is devoted to standardization developments in welding dealing with the general organization of quality and standards for non-destructive testing.
We extend our thanks to all those authors who have agreed to contribute to this work and especially those who work in the industry and who have been willing in their free time to contribute to this collection of the know-how and current research in the different fields of welding.