Final Report Abstract

The objective of this project was to investigate the reasons and find possible countermeasures for the process instabilities in laser micro-welding of copper when using near-infrared lasers. Simulations with literature data confirmed an expected mutual amplification between the disadvantageous effects of the temperature-dependent absorptance and thermal conductivity. They further showed that the temperature-dependent function of the absorptance is the key reason for the low process reproducibility. These simulations still required a correction factor of 1.7 for agreement with experiments. Measurements of the temperature-dependent reflectance in nitrogen atmosphere were conducted in an integrating sphere setup developed by us. We further corrected the measurements regarding a reflectance drift and the timedependance of redox reactions. With these new input data, a correction factor was no longer needed in the simulations. Experiments and simulations with the corrected reflectance data showed that a thermal reduction of oxides on the sample surface leads to smaller process windows during the production of laser micro-spot melts, while elevated initial temperatures and a ramp-up pulse shape increase the process window and thus stabilize the process on reduced and untreated samples.

Publications

• Simulation of the influence of temperature-dependent material parameters on the temperature evolution in laser micro-spot welding of copper. International Congress on Applications of Lasers & Electro-Optics, M604.
  Mattern, Manuel & Ostendorf, Andreas
  
• Temporal temperature evolution in laser micro-spot welding of copper considering temperature-dependent material parameters. Materials Research Express, 5(6), 066545.
  Mattern, Manuel; Weigel, Thomas & Ostendorf, Andreas
  
• Temperature-dependent reflectivity of unpolished rolled copper for near infrared lasers. OA in: Proceedings of Lasers in Manufacturing Conference
  Mattern M. & Ostendorf A.
  
• Combined experimental and theoretical approach to improve measurement accuracy of temperature-dependent reflectance of copper.
  Mattern, Manuel; Kukreja, Lalit Mohan & Ostendorf, Andreas
  
• Temperature-dependent reflectance of copper with different surface conditions measured at 1064 nm.
  Mattern, Manuel; Kukreja, Lalit Mohan & Ostendorf, Andreas