Global trends force industry to manufacture lighter, safer, more environmentally-friendly, more performant, and cheaper products. Due to excellent thermal and electrical conductivity, copper is widely used in heating and cooling equipment and electrical devices, but due to the rising demand the copper price increased. Solving the conflict between the technological benefits and the disadvantages regarding cost and weight is possible by substituting current full copper parts by copper-aluminium hybrid parts. In JOIN’EM, such components were produced by electromagnetic welding (EMW). In this process the joint is formed due to high-speed collision of parts without largely heating them, so that thermally induced disadvantages of conventional technologies are avoided and high-quality dissimilar material combinations can be joined.
In order to allow industrial implementation of the process, strategies for the process and tool design were developed for tubular and sheet metal parts (see figure). Designing durable and efficient tools is an indispensable prerequisite for the industrial implementation of the technology and is therefore addressed in the project, too. A multi-scale simulation strategy supporting the process and tool design was developed. It allows determining acting loads on workpiece and tool coil, deformation of the workpieces, impact conditions, joint formation, and fatigue of the most relevant coil components.
The applicability of the process design strategy is validated on industrial case studies from different application fields. Process and equipment design strategies are evaluated in an industrial setting. This includes automation and quality control, economic efficiency calculations, life-cycle, and recycling issues in order to demonstrate and quantify the advantages of EMW. It was shown the EMW parts are absolutely comparable with current state of the art solutions in terms of technical properties, while they even feature advantages in terms of costs and environmental impact.