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Influence of complex geometries on the properties of laser-hardened surfaces

Laser surface hardening provides for many advantages in terms of flexible production due to very localized and controlled energy input into the material. Laser processing offers the possibility to treat surfaces in order to locally strengthen the areas that are prone to fatigue cracking. It is well known that laser energy absorption depends on many parameters, e.g., the surface structure and the surface orientation. The incident angle of the laser beam plays a key role in this regard. When complex geometries like crankshaft fillets are treated, the surface cannot be considered a series of flat surfaces. Obviously, this leads to locally varying degrees of energy absorption. In the present work, curved surface structures were chosen in order to analyze the impact of the geometrical characteristics on surface and subsurface material properties after laser treatment. Microstructure evolution generally was found to be similar for flat and curved geometries. However, even if higher absorption in the groove due to the illumination at larger incident angles was expected, the outer parts of the curved geometry were not fully hardened. Thus, the increased effective length of the complex geometry-treated and the larger heat-affected volume are expected to have a more dominant influence on the final appearance of the subsurface microstructure. Eventually, for austenitization of the complete illuminated surface volume, the energy density needs to be increased.

Citation
In: The International Journal of Advanced Manufacturing Technology Volume 107 / Issue 9-10 (2020-04-25) , S. 4255-4260; eissn:1433-3015
Collections
@article{doi:10.17170/kobra-202304207850,
  author    ={Volpp, Jörg and Dewi, Handika Sandra and Fischer, Andreas and Niendorf, Thomas},
  title    ={Influence of complex geometries on the properties of laser-hardened surfaces},
  keywords ={620 and 660 and Laser and Oberflächeneigenschaft and Härte and Mikrostruktur and Eigenspannung and Mikrolegierter Stahl},
  copyright  ={http://creativecommons.org/licenses/by/4.0/},
  language ={en},
  journal  ={The International Journal of Advanced Manufacturing Technology},
  year   ={2020-04-25}
}