Method for teaching/testing a motion sequence of a welding robot, welding robot and control system for same

The invention claimed is: 1. A method of welding with a welding robot along a motion sequence, the method comprising the steps of a) teaching the welding robot the motion sequence without performing a welding process by: moving a movably mounted welding wire out of a welding head to a length; moving the welding head to a first position at a workpiece when a power supply of the welding head is deactivated; after positioning at the first position, starting a wire-touch sensing process in a welding device, the wire-touch sensing process comprising the steps of: applying a test voltage between the welding wire and the workpiece, wherein the test voltage or the therefrom resulting current flow is provided to be lower than an arc-forming voltage required for forming an arc or an arc-forming current required for forming the arc; subsequently, continuing a manual positioning process with the welding head; and retracting the welding wire to prevent bending of the welding wire and to interrupt a current flow between the welding wire and the workpiece when the welding wire touches the workpiece and the current flow or a drop of the test voltage is detected, and b) after teaching the welding robot the motion sequence, welding with the welding robot along the motion sequence. 2. The method according to claim 1 , wherein the welding wire is again moved to the workpiece or to the length that is predetermined after the interruption. 3. The method according to claim 1 , wherein when the welding head is adjusted, the welding wire is repeatedly moved to and back from the the workpiece, that is a contour of the workpiece is sensed, as long as the length has not been achieved. 4. The method according to claim 1 , wherein a speed of feeding back the welding wire is selected as to be always higher than a speed of the forward motion of a manually controlled welding torch. 5. The method according to claim 1 , wherein a current source limits an amount of power in such a way that a short-circuit does not result in a melting of the welding wire and the workpiece, but a contacting of both of them is recognized as soon as possible, with however a further monitoring, open-loop and closed-loop functions for an actual welding process, such as a release of the short-circuit, a wire feed, a protective gas supply, and a cooling circuit of the welding device remaining deactivated. 6. The method according to claim 1 , wherein a distance between the welding head and the workpiece later during the welding process, corresponds to that distance, at which the welding wire moved out to the length that is predetermined touches the workpiece. 7. The method according to claim 1 , wherein after the wire-touch sensing process has started, the welding wire is moved out until the current flow is detected. 8. The method for teaching the welding robot according to claim 1 , comprising the following steps: I) applying the test voltage between the welding wire and the workpiece by activating the wire-touch sensing process, II) moving the welding head at the workpiece along the motion sequence, III) moving the movably mounted welding wire out of the welding head until the current flow is detected in that electric circuit wherein the welding wire and the workpiece are positioned, and IV) retracting the welding wire by a retraction distance that is predetermined and repeating steps I) to IV). 9. The method according to claim 1 , wherein the length by which the welding wire is moved out of or back into the welding head is measured or set via a device selected from a group consisting of an input device, an output device and an input/output device or defined by touching the workpiece. 10. The method according to claim 1 , wherein the test voltage or the therefrom resulting current flow is provided to be lower than a welding wire melting voltage required for melting the welding wire or a welding wire melting current required for melting the welding wire. 11. The method according to claim 1 , further comprising the steps of: moving the welding head in an area of a finished welding seam or a welding seam to be produced perpendicularly to a course of the finished welding seam or the welding seam to be produced, storing or determining position information for at least one of the welding head and the welding wire whenever the current flow or the drop of the test voltage is detected in an electric circuit, and calculating at least one of a width of the welding seam, a height of the welding seam, a welding head location of the welding head relative to the welding seam and a welding wire location of the welding wire relative to the welding seam on the basis of the position information store or determined. 12. The method according to claim 1 , wherein during an evaluation of the welding wire feeding process, a longest stickout is determined, to which a central position of the welding seam corresponds. 13. The method according to claim 1 , wherein an alarm is triggered, whenever the current flow or the drop of voltage is not detected although this should have to be expected on the basis of the position of the welding head or the welding wire and a position of the workpiece. 14. The method according to claim 1 , wherein: the test voltage is applied between an electrically conductive part of the welding head and the workpiece and the welding head is stopped or retracted whenever the current flow or the drop of the test voltage is detected in an electric circuit wherein said conductive part and the workpiece are positioned. 15. A method of welding comprising the steps of: a) automatically detecting a central position of an intended weld bead without performing a welding process by: positioning a welding head at a workpiece; after the positioning, starting a wire-touch sensing process in a welding device, the wire-touch sensing process comprising the steps of: applying a test voltage between a welding wire and the workpiece, wherein the test voltage or the therefrom resulting current flow is provided to be lower than a voltage required for forming an arc or a current required for forming the arc; feeding the welding wire in a direction of the workpiece; and retracting the welding wire for preventing bending of the welding wire and for interrupting a current flow between the welding wire and the workpiece whenever the welding wire touches the workpiece and the current flow is detected; subsequently, tracing a preprogrammed track running perpendicular to an axis of the intended weld bead; and when the welding head is adjusted, repeatedly moving the welding wire to the workpiece and back from the workpiece to sense a contour of the workpiece and calculating the central position on a basis of values of wire lengths which have been fed; and b) after detecting the central position, welding the workpiece and forming the weld bead running perpendicular to the preprogrammed track. 16. The method according to claim 15 , comprising the following steps: moving a movably mounted welding wire out of the welding head to a length and moving the welding head to a position at the workpiece wherein after positioning at the position, the wire-touch sensing process is started in the welding device, wherein the test voltage is applied between the welding wire and the workpiece and subsequently, a manual positioning process is continued with the welding head, with the welding wire being retracted to interrupt the current flow when the current flow between the welding wire and the workpiece or a drop of the test voltage is detected, wherein a control sy