%0 Journal Article %1 Faas2018Prediction %A Faas, Sebastian %A Bielke, Uwe %A Weber, Rudolf %A Graf, Thomas %D 2018 %J Applied Physics A %K steelsend:unibiblio myown accumulation laser peer from:sebastianfaas heat %N 9 %P 612 %R 10.1007/s00339-018-2040-4 %T Prediction of the surface structures resulting from heat accumulation during processing with picosecond laser pulses at the average power of 420 W %U https://doi.org/10.1007/s00339-018-2040-4 %V 124 %X Heat accumulation due to successive laser pulse (HAP) incident on the same spot and heat accumulation due to successive scans (HAS) of the laser beam over the same spot significantly influences the process result, especially when the resulting temperature of the workpiece exceeds the melting temperature. In particular, heat accumulation is one of the dominating effects during short-pulse laser functionalization of surfaces and strongly affects the resulting surface structures. Within this study, a novel heat accumulation model is introduced to calculate the temperature increase in the workpiece for the whole process including the effects of HAP and HAS in which the latter is differentiated between heat accumulation due to multiple passes (HAS-I) and heat accumulation due to multiple layers (HAS-II). With the new model, the surface structure was successfully predicted when using an ultra-short pulsed (USP) laser with an average power of 420 W for laser surface structuring of polished AISI 316L.

@article{Faas2018Prediction, abstract = {Heat accumulation due to successive laser pulse (HAP) incident on the same spot and heat accumulation due to successive scans (HAS) of the laser beam over the same spot significantly influences the process result, especially when the resulting temperature of the workpiece exceeds the melting temperature. In particular, heat accumulation is one of the dominating effects during short-pulse laser functionalization of surfaces and strongly affects the resulting surface structures. Within this study, a novel heat accumulation model is introduced to calculate the temperature increase in the workpiece for the whole process including the effects of HAP and HAS in which the latter is differentiated between heat accumulation due to multiple passes (HAS-I) and heat accumulation due to multiple layers (HAS-II). With the new model, the surface structure was successfully predicted when using an ultra-short pulsed (USP) laser with an average power of 420 W for laser surface structuring of polished AISI 316L.}, added-at = {2018-08-15T08:42:28.000+0200}, author = {Faas, Sebastian and Bielke, Uwe and Weber, Rudolf and Graf, Thomas}, biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2b8543ce3fb7daf2711b9dd09a19b127f/ifsw}, day = 14, doi = {10.1007/s00339-018-2040-4}, interhash = {6dc03563324f048eae4ae2b0ec69c80f}, intrahash = {b8543ce3fb7daf2711b9dd09a19b127f}, issn = {1432-0630}, journal = {Applied Physics A}, keywords = {steelsend:unibiblio myown accumulation laser peer from:sebastianfaas heat}, month = aug, number = 9, pages = 612, timestamp = {2018-08-15T06:42:28.000+0200}, title = {Prediction of the surface structures resulting from heat accumulation during processing with picosecond laser pulses at the average power of 420 W}, url = {https://doi.org/10.1007/s00339-018-2040-4}, volume = 124, year = 2018 }