Details

Autor(en) / Beteiligte

• Madhukar, Yuvraj K.
• Mullick, Suvradip
• Shukla, Dinesh K.
• Kumar, Shailesh
• Nath, Ashish K.

Titel

Effect of laser operating mode in paint removal with a fiber laser

Ist Teil von

• Applied surface science, 2013-01, Vol.264, p.892-901

Ort / Verlag

Amsterdam: Elsevier B.V

Erscheinungsjahr

2013

Quelle

Alma/SFX Local Collection

Beschreibungen/Notizen

• ► Paint removal characteristics with CW and modulated power fiber laser are presented. ► Higher line energy yielded relatively poor paint removal efficiency. ► Poor efficiency attributed to absorption loss in laser produced plume. ► Shorter pulse-on time and sufficient time between two pulses to allow plume to die down yielded better process efficiency. The laser paint removal behavior with the continuous wave (CW) beam and repetitive pulses has been investigated using an Yb:fiber laser. The specific energy, which is defined as the amount of laser energy needed to remove unit volume of paint prior to the onset of substrate damage and is a measure of the process efficiency, was found to be dependent on the laser processing parameters. In CW mode the specific energy reduced with the increase of laser scan speed and corresponding increase of laser power. In case of repetitive pulsed mode the specific energy was found to depend on the pulse on-time as well as on the time interval between two successive pulses. At 1kHz repetition rate, the specific energy reduced with the increase of duty cycle and corresponding increase in scanning speed, but at relatively low frequencies of 50–150Hz and 50% overlap between two pulses specific energy was found to increase with increasing duty cycle. Irrespective of the mode of operation specific energy increased with the increase of average line energy. During the laser paint irradiation a plume of burning fume was formed over the surface and the variation in specific energy with laser processing parameters has been attributed to the absorption of laser radiation in the plume. Since the dimension of plume and fume particle density in it will depend on the laser energy absorbed in paint, the absorption loss in plume will depend on the laser parameters. This was confirmed by measuring the plume temperature for different laser processing conditions. Based on this and considering that the actual specific energy absorbed by paint should be constant, the absorption characteristic of plume was modeled applying Beer Lambert's law.