Investigations on the active compensation of the focal shift in scanning systems using a temperature signal

Falk Nagel; Andreas Patschger; Jean Pierre Bergmann; Jens Bliedtner

doi:10.1364/AO.57.003561

Applied Optics
Vol. 57,
Issue 13,
pp. 3561-3569
(2018)
•https://doi.org/10.1364/AO.57.003561

Investigations on the active compensation of the focal shift in scanning systems using a temperature signal

Falk Nagel, Andreas Patschger, Jean Pierre Bergmann, and Jens Bliedtner

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Falk Nagel, Andreas Patschger, Jean Pierre Bergmann, and Jens Bliedtner, "Investigations on the active compensation of the focal shift in scanning systems using a temperature signal," Appl. Opt. 57, 3561-3569 (2018)

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Abstract

For the purpose of realizing a fast and cost-efficient manipulation of the laser beam in production applications, such as welding, marking, and cutting, scanner systems in combination with F-Theta objectives are state-of-the-art. Owing to the absorption of the laser beam power and the resulting heat load acting on the optical system, a change of the focal plane (the so-called focal shift) occurs, significantly affecting the behavior during the application process. A linear correlation between the temperature on the optical surface of a standard F-Theta objective and the focal shift was determined whereby the coefficient of determination $R^{2}$ is higher than 0.99. Furthermore, two industrial welding applications were investigated using this standard objective, and the resulting temperature distribution along the optical surfaces was also investigated. The results show that a single measurement point appears to be sufficient to obtain a capable input signal for a compensation method. A compensation device was implemented and a sufficient reduction of the focal shift was realized for the examined time range.

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Laser Source	Rofin $FL x 50$
Fiber core diameter	50 μm
$M^{2}$ (500 W)	11.2
SPP measured with Primes	$3.83 mm \times mrad$
Type of the collimation	Optoscand, fused silica
Focal length of the collimation lens	100 mm
Resulting spot diameter of the collimated beam (calculated)	23.4 mm
Resulting Rayleigh length (measured at 500 W)	2.9 mm

First Lens ( $y = m \cdot x + 0$ )
$m$	$0.0544 \pm 0.001$
$R^{2}$	0.998
Protective Window
$m$	$0.0303 \pm 0.001$
$R^{2}$	0.994

	First Lens	Protective Window
Coefficient of determination $R^{2}$	0.998	0.994
Slope $b_{1}$	0.167	0.232
Intersection $a$	−0.221	−0.051
Variance of residues $S_{R}^{2}$	0.071	0.116

Rear Package Tray	Properties
Number of step welds	$34 x$ C-shaped weld
Welding speed	$100 mm / s$ ( $6 m / \min$ )
Loading and fixing time for work piece	60 s
Positioning of robot	5 s
Resulting cycle	$(0.4 s + 0.25 s) \cdot 17 + 2.5 s + (0.4 s + 0.25 s) \cdot 17$
Door assembly
Number of step welds	$45 x line weld path$
Welding speed	$100 mm / s$
Positioning velocity (by robot)	$200 mm / s$
Loading and fixing time for work piece	60 s
Positioning of robot	5 s
Resulting cycle	$(0.3 s + 0.5 s) \cdot 45$

Laser Source	Rofin $FL x 50$
Fiber core diameter	50 μm
$M^{2}$ (500 W)	11.2
SPP measured with Primes	$3.83 mm \times mrad$
Type of the collimation	Optoscand, fused silica
Focal length of the collimation lens	100 mm
Resulting spot diameter of the collimated beam (calculated)	23.4 mm
Resulting Rayleigh length (measured at 500 W)	2.9 mm

Abstract

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Figures (21)

Tables (4)

Equations (4)

Applied Optics