High Quality Tube and Pipe Production by Hybrid Welding

Executive summary:

Hybrid laser-arc welding offers many advantages compared with conventional arc or laser welding. The process does, however, require a high level of control if high-quality welds are to be produced. This project tackles the issues of weld quality and productivity improvement for manufacturing tubes and pipes through the development of advanced sensors for the hybrid laser-arc welding process. Hybrid process development must be performed for each material to be welded, with the main focus in this project being on austenitic stainless steels and carbon-manganese (C-Mn) steels. By developing and integrating sensors that monitor weld quality and allow process modification, the project will increase the quality and productivity of European tube and pipe manufacture beyond the state of the art, enabling it to overcome foreign competition.

There is a large industry in Europe for pipe and tube manufacture with many users of the finished product around the world. Competition in manufacture outside Europe is high, and increasing, particularly from Far East countries. In current manufacture, conventional arc welding processes, such as metal inert gas / metal active gas (MIG / MAG) and submerged arc welding, are mainly used to produce finished pipe and tube over a range of materials, diameters and wall thicknesses. Some of the problems facing tube manufacturers include production of too much scrap product due to process inconsistencies, lack of online quality control, inconsistent equipment operation, inconsistent joint preparation and presentation, low productivity and reliance on the skill of operators to change process parameters to maintain weld quality, particularly during changeovers, i.e. when tube material, diameter and / or wall thickness is changed. The European tube and pipe manufacturing industry needs to increase both the productivity and the quality of its products, to become more competitive and to safeguard employment in a fast-changing market.

The time required to weld a tube contributes significantly to the cost of the finished product; indeed for some tube types the welding time is 50 % of the total manufacturing cycle time. For this reason, the welding task becomes a critical path in the whole production process, not only for economic reasons, but also because this can influence delivery time. This, in particular, is becoming more and more important as users require 'just-in-time' sourcing of product and components. Furthermore, customers are now demanding better weld quality, as the need for a 'fit-for-purpose' product is better recognised and costs of failure escalate. Mechanical failures, the third most frequent cause of spills for oil lines, are often the result of weld imperfections that can be traced back to the welding during manufacture. In operation, many pipes and tubes contain hazardous substances and the consequences of a weld failure are therefore very significant, not only in economic terms, but also in terms of the environment, and for human and other life forms.

The small and medium-sized enterprise (SME) partners in this project include end users in the pipe manufacturing sector, manufacturers of sensor equipment, and software system integrators. Some of these already have involvement with the tube and pipe manufacturing sector, whereas others wish to increase their involvement with this sector. They have a common need to generate new markets with the introduction of new and competitive products. The approaches to the concepts of monitoring and hybrid laser-arc welding of pipes and tubes resulting from this project are therefore equipment-independent, maximising the scope for industrial use of the technology.