Method for identifying joining points of workpieces and laser machining head comprising a device for carrying out this method

The invention claimed is: 1. A method for identifying joining positions of workpieces prior to welding, comprising the steps of: capturing images of a joint by means of a camera; determining measurement data for the joining positions associated with a course of the joint from the images of the joint; removing some of the measurement data from the measurement data associated with the course of the joint, the removing depending on components to be welded and being not random; fitting a mathematical model of the joint course to the measurement data after the removing step; providing a curve defined by the mathematical model; and positioning a welding laser during a laser welding process along said curve. 2. The method according to claim 1 , further comprising illuminating the workpieces coaxially to a viewing beam path of the camera. 3. The method according to claim 1 , wherein a viewing beam path of the camera for capturing the images of the joint is coaxially coupled into a beam path of a laser beam used for welding. 4. The method according to claim 1 , wherein the step of the removing some of the measurement data from the measurement data associated with the course of the joint comprises removing some of the measurement data using a comb profile having spaced apart windows, a width of the windows and distances thereof in said comb profile being selected according to the workpieces. 5. The method according to claim 1 , further comprising: supplementing unidentified joining positions in the course of the joint by linear interpolation. 6. The method according to claim 1 , wherein the steps of removing and fitting are repeatedly performed, and the method further comprising determining a number of outliers for each fitted model. 7. The method according to claim 6 , further comprising removing from the measurement data the outliers that have been determined for the fitted model with the fewest outliers, and redetermining the mathematical model by fitting to the measurement data after removing the outliers that have been determined for the fitted model with the fewest outliers. 8. A laser machining head comprising a housing through which a working laser beam path with a collimating optics and a focusing optics is provided, and a device, which is configured for performing the method according to claim 1 comprises: a camera for capturing images of a joint of workpieces, a viewing beam path of which being coaxially coupled into a working laser beam path; and an illumination device, an illumination beam path which is coaxially coupled to the viewing beam path and the working laser beam path, wherein the device is configured for; obtaining measurement data for the joining positions from the images of the joint, removing some of the measurement data from the measurement data associated with a course of the joint and fitting a mathematical model of the joint course to the measurement data after the removing step, the removing depending on components to be welded and being not random, wherein the mathematical model provides a curve for positioning a welding laser during a laser welding process along said curve. 9. The laser machining head according to claim 8 , wherein the viewing beam path of the camera and the illumination beam path of the illumination device are coupled into a portion of the working laser beam path between the collimating optics and the focusing optics. 10. The laser machining head according to claim 8 , wherein the illumination device includes an LED light source and a collimating optics. 11. The laser machining head according to claim 10 , wherein the LED light source includes an LED board having an LED chip with integrated lens, the LED light source further includes a lens with a numerical aperture adapted to an aperture angle of the emitted illumination light. 12. The laser machining head according to claim 11 , wherein the LED light source comprises a LED, and that an absorber is arranged, in the beam direction, downstream of a partially transmissive mirror for coupling the illumination beam path of the illumination device into the viewing beam path of the camera. 13. The laser machining head according to claim 8 , further comprising a diaphragm for adjusting the aperture disposed in the viewing beam path of the camera. 14. A method for identifying joining positions of workpieces prior to welding, comprising the steps of: capturing images of a joint by means of a camera; determining measurement data for the joining positions associated with a course of the joint from the images of the joint; determining a 4th degree polynomial as a mathematical model of the joint course by fitting to a part of the measurement data; providing a curve defined by the mathematical model; and positioning a welding laser during a laser welding process along said curve removing some of the measurement data from the measurement data associated with the course of the joint, the removing depending on components to be welded and being not random; and wherein the step of determining the mathematical model of the joint course comprises; fitting the mathematical model of the joint course to the measurement data after the removing step; and wherein the step of the removing some of the measurement data from the measurement data associated with the course of the joint comprises removing some of the measurement data using a comb profile having spaced apart windows, a width of the windows and distances thereof in said comb profile being selected according to the workpieces. 15. The method according to claim 14 , further comprising illuminating the workpieces coaxially to a viewing beam path of the camera. 16. The method according to claim 14 , wherein a viewing beam path of the camera for capturing the images of the joint is coaxially coupled into a beam path of a laser beam used for welding. 17. The method according to claim 14 , further comprising supplementing unidentified joining positions in the course of the joint by linear interpolation. 18. The method according to claim 14 , wherein the steps of removing and fitting are repeated performed, and the method further comprising determining a number of outliers for each fitted model. 19. The method according to claim 18 , further comprising removing from the measurement data the outliers that have been determined for the fitted model with the fewest outliers, and redetermining the mathematical model by fitting to the measurement data after removing the outliers that have been determined for the fitted model with the fewest outliers.