Method and device for scanning a workpiece surface of a metal workpiece

The invention claimed is: 1. A method for scanning a workpiece surface of a metal workpiece prior to performing a welding operation on the workpiece surface, comprising: prior to performing a welding operation on the workpiece, moving a blowtorch having a welding wire electrode relative to the workpiece surface to determine scanning values; and repeatedly moving a wire end of the welding wire electrode towards the workpiece surface, in each case moving the wire end until contact of the wire end with the metal workpiece at multiple scanning positions on the workpiece surface is detected, and then moving the wire end of the welding wire electrode away from the workpiece at the scanning position, detecting, by means of the blowtorch, scanning values at the multiple scanning positions, including detecting scanning values multiple times at one or more of the multiple scanning positions, to determine scanning measurement errors in the scanning values. 2. The method according to claim 1 , wherein the wire end of the welding wire electrode projects out of the blowtorch and is moved forwards and backwards with at least one of an adjustable movement profile and an adjustable movement frequency. 3. The method according to claim 1 , wherein the blowtorch having the welding wire electrode is moved on a scanning path relative to the workpiece surface of the metal workpiece to determine first scanning values at scanning positions and subsequently on the same scanning path to determine second scanning values at the scanning positions. 4. The method according to claim 3 , wherein the first scanning values determined along the scanning path and the second scanning values determined along the scanning path are compared to determine scanning measurement errors. 5. The method according to claim 1 , wherein the welding wire electrode is conveyed by drive rollers as a function of the determined scanning measurement errors to reduce scanning measurement errors. 6. The method according to claim 1 , wherein the welding wire electrode is conveyed by drive rollers and a movement of the welding wire electrode is detected to monitor a force transmission exerted on the welding wire electrode by the drive rollers at a contact point of a wire surface of the welding wire electrode. 7. The method according to claim 6 , wherein a surface abrasion brought about by the drive rollers at the contact point of the wire surface of the welding wire electrode is automatically detected on the basis of the detected wire movement of the welding wire electrode, and the welding wire electrode is conveyed to a different contact point by the drive rollers to reduce resulting scanning measurement errors. 8. The method according to claim 1 , wherein the welding wire electrode is conveyed by drive rollers driven by an electric motor, in which at least one of the motor speed and a motor current signal is monitored to detect the wire movement of the welding wire electrode. 9. The method according to claim 1 , wherein the welding wire electrode is conveyed by drive rollers and a surface abrasion of the wire surface of the welding wire electrode, brought about by the drive rollers at a contact point of the welding wire electrode, is detected from a distinctive noise in at least one of a motor speed signal a motor current signal. 10. The method according to claim 1 , wherein, after one or more of a predetermined scanning operating time elapses, a predetermined scanning distance is achieved and a predetermined number of scanning values is achieved, the welding wire electrode projecting from the blowtorch and used for scanning the workpiece surface is conveyed out of the blowtorch by a predetermined length and then cut to length. 11. The method according to claim 1 , wherein, after surface abrasion of the wire surface of the welding wire electrode is detected, the welding wire electrode projecting out of the blowtorch and used for scanning the workpiece surface is conveyed out of the blowtorch by a predetermined length and then cut to length. 12. The method according to claim 1 , wherein mechanical contact of the wire end of the welding wire electrode with the workpiece surface of the workpiece is detected electrically. 13. The method according to claim 1 , wherein mechanical contacting of the workpiece surface by the wire end of the welding wire electrode is detected by evaluating at least one of a motor speed signal and a motor current signal of the electric motor provided for driving the drive rollers. 14. The method according to claim 1 , wherein at least one of a movement profile and a movement frequency of the welding wire electrode are is adjusted as a function of a material of the welding wire electrode. 15. The method according to claim 1 , wherein the wire end of the welding wire electrode forms a tool reference point, TCP, which is calibrated by means of a calibrating body to reduce scanning measurement errors. 16. The method according to claim 1 , wherein an electrical voltage applied to the wire end of the welding wire electrode is set to a defined value before the workpiece surface is scanned, and during the scanning of the workpiece surface of the workpiece the electric voltage is applied, unregulated, to the wire end of the welding wire electrode, in such a way that, after electric contact of the wire end with the workpiece surface is detected from an electric current flowing as a result of an electric short circuit, the thermal stress on the welding wire electrode is kept low. 17. A scanning device for a welding apparatus for scanning a workpiece surface of a metal workpiece, wherein the scanning device is suitable for moving a blowtorch having a welding wire electrode relative to the workpiece surface to be scanned of the workpiece to determine scanning values, and in doing so repeatedly moving a wire end of the welding wire electrode initially towards the workpiece surface, in each case until contact with the metal workpiece at a scanning position on the workpiece surface of the metal workpiece is detected, and subsequently moving the wire end of the welding wire electrode back, wherein the scanning device is configured and operable to detect scanning values at scanning positions on the workpiece surface of the metal workpiece multiple times to determine scanning measurement errors in the scanning values automatically.