Magnetic pulse welding is a solid state welding process that uses magnetic forces to weld two workpieces together. The welding mechanism is most similar to that of explosion welding. Magnetic pulse welding started in the early 1970s, when the automotive industry began to use solid state welding. The biggest advantage using magnetic pulse welding is that the formation of brittle intermetallic phases is avoided. Therefore, dissimilar metals can be welded, which cannot be effectively joined by fusion welding. With magnetic pulse welding high quality welds in similar and dissimilar metals can be made in microseconds without the need for shielding gases or welding consumables.
Process
Magnetic pulse welding is based on a very short electromagnetic pulse, which is obtained by a fast discharge of capacitors through low inductance switches into a coil. The pulsed current with a very high amplitude and frequency produces a high-density magnetic field, which creates an eddy current in one of the work pieces. Repulsive Lorentz forces are created and a high magnetic pressure well beyond the material yield strength causing acceleration and one of the work pieces impacts onto the other part with a collision velocity up to. During magnetic pulse welding a high plastic deformation is developed along with high shear strain and oxide disruption thanks to the jet and high temperatures near the collision zone. This leads to solid state weld due to the microstructure refinement, dislocation cells, slip bends, micro twins and local recrystallization.
Principles
In order to get a strong weld, several conditions have to be reached:
Jetting condition: the collision has to be subsonic compared to the local material's speed of sound to generate a jet.
High pressure regime: the impact velocity has to be sufficient to obtain a hydrodynamic regime, otherwise the parts will only be crimped or formed.
No fusion during the collision: If the pressure is too high, the materials can locally melt and re-solidify. This can cause a weak weld.
The main difference between magnetic pulse welding and explosive welding is that the collision angle and the velocity are almost constant during the explosive welding process, while in magnetic pulse welding they continuously vary.
Advantages of MPW
Allows welding of designs which with other processes are challenging or not possible.
High precision obtainable by adjustment of magnetic field, weld parameters can be changed electronically.
Zero distortion can be achieved depending on part materials & geometry.
Almost zero residual stresses.
No corrosion development in the welding area.
Disadvantages
Challenging to apply to welds that are not roughly circular.
Geometry of parts may have to be changed to allow the magnetic pulse process.
If the parts cannot be slid into and out of the pulse coil a more complex multi-part coil must be designed.
Pulse coil may have to be re-designed if materials or dimensions are changed.
Brittle components can be fractured by the shock.
May produce an EMP effect on any electronics present inside or near the part.
Initial investment cost may outweigh the lower price-per-weld for low volume parts.
Numerical simulations of MPW
Various numerical investigations were carried out to predict the interface behavior of the MPW and the in-flight behavior of the flyer to determine the collision conditions. Generally, the flyer velocity prior to the impact governs the interfacial phenomena. This is the characteristic parameter that should be known based on the process and adjustable process parameters. Although, Experimental measurements using laser velocimetry methods provide an accurate assessment of the flyer velocity,, numerical computation offers a better description of the flyer velocity in terms of spatial and temporal distribution. Moreover, a multi-physics computation of the MPW process take into account of the electrical current through the coil and compute the physical behavior for an electromagnetic-mechanical coupled problem. Sometime, these simulations also allow to include the thermal effect during the process. A 3D example model used for LS-DYNA® simulation is also described in, and it also provides some details of the physical interactions of the process, the governing equations, the resolution procedure, and both boundary and initial conditions. The model is used to show the capability of 3D computation to predict the process behavior and particularly, the flyer kinematics and macroscopic deformation.
