Particle Ejection by Jetting and Related Effects in Impact Welding Processes

Bellmann, J.; Lueg-Althoff, J.; Niessen, B.; Böhme, M.; Schumacher, E.; Beyer, E.; Leyens, C.; Tekkaya, A. E.; Groche, P.; Wagner, M. F.-X.; Böhm, S.

doi:10.3390/met10081108

Particle Ejection by Jetting and Related Effects in Impact Welding Processes (bibtex)

by J. Bellmann, J. Lueg-Althoff, B. Niessen, M. Böhme, E. Schumacher, E. Beyer, C. Leyens, A. E. Tekkaya, P. Groche, M. F.-X. Wagner, S. Böhm

Abstract:

Collision welding processes are accompanied by the ejection of a metal jet, a cloud of particles (CoP), or both phenomena, respectively. The purpose of this study is to investigate the formation, the characteristics as well as the influence of the CoP on weld formation. Impact welding experiments on three different setups in normal ambient atmosphere and under vacuum-like conditions are performed and monitored using a high-speed camera, accompanied by long-term exposures, recordings of the emission spectrum, and an evaluation of the CoP interaction with witness pins made of different materials. It was found that the CoP formed during the collision of the joining partners is compressed by the closing joining gap and particularly at small collision angles it can reach temperatures sufficient to melt the surfaces to be joined. This effect was proved using a tracer material that is detectable on the witness pins after welding. The formation of the CoP is reduced with increasing yield strength of the material and the escape of the CoP is hindered with increasing surface roughness. Both effects make welding with low-impact velocities difficult, whereas weld formation is facilitated using smooth surfaces and a reduced ambient pressure under vacuum-like conditions. Furthermore, the absence of surrounding air eases the process observation since exothermic oxidation reactions and shock compression of the gas are avoided. This also enables an estimation of the temperature in the joining gap, which was found to be more than 5600 K under normal ambient pressure.

Reference:

Bellmann, J., Lueg-Althoff, J., Niessen, B., Böhme, M., Schumacher, E., Beyer, E., Leyens, C., Tekkaya, A. E., Groche, P., Wagner, M. F.-X., Böhm, S.: Particle Ejection by Jetting and Related Effects in Impact Welding Processes, Metals 10, 1108, 2020.

Bibtex Entry:

@Article{Bellmann2020,
  author    = {Bellmann, J. and Lueg-Althoff, J. and Niessen, B. and Böhme, M. and Schumacher, E. and Beyer, E. and Leyens, C. and Tekkaya, A. E. and Groche, P. and Wagner, M. F.-X. and Böhm, S.},
  journal   = {Metals},
  title     = {Particle Ejection by Jetting and Related Effects in Impact Welding Processes},
  year      = {2020},
  month     = {aug},
  number    = {8},
  pages     = {1108},
  volume    = {10},
  abstract  = {Collision welding processes are accompanied by the ejection of a metal jet, a cloud of particles (CoP), or both phenomena, respectively. The purpose of this study is to investigate the formation, the characteristics as well as the influence of the CoP on weld formation. Impact welding experiments on three different setups in normal ambient atmosphere and under vacuum-like conditions are performed and monitored using a high-speed camera, accompanied by long-term exposures, recordings of the emission spectrum, and an evaluation of the CoP interaction with witness pins made of different materials. It was found that the CoP formed during the collision of the joining partners is compressed by the closing joining gap and particularly at small collision angles it can reach temperatures sufficient to melt the surfaces to be joined. This effect was proved using a tracer material that is detectable on the witness pins after welding. The formation of the CoP is reduced with increasing yield strength of the material and the escape of the CoP is hindered with increasing surface roughness. Both effects make welding with low-impact velocities difficult, whereas weld formation is facilitated using smooth surfaces and a reduced ambient pressure under vacuum-like conditions. Furthermore, the absence of surrounding air eases the process observation since exothermic oxidation reactions and shock compression of the gas are avoided. This also enables an estimation of the temperature in the joining gap, which was found to be more than 5600 K under normal ambient pressure.},
  doi       = {10.3390/met10081108},
  publisher = {{MDPI} {AG}},
}