Coupling structure and method for feeding compressed air to welding device using same

The invention claimed is: 1. A coupling structure of a welding device ( 1 ) for welding a workpiece ( 2 ) having a welding torch ( 3 ), a coupling element ( 4 ) and a welding wire stop ( 7 ), wherein the welding torch ( 3 ) is mechanically coupled by the coupling element ( 4 ) to a hose bundle ( 5 ) for supplying the welding torch ( 3 ) at least with compressed air or with a protective gas, wherein the compressed air applied to the coupling element ( 4 ) is diverted by a diverting valve ( 10 ) provided in the coupling element ( 4 ) for actuating the welding wire stop ( 7 ), said welding wire stop ( 7 ) being adapted to clamp a welding wire ( 6 ) supplied in the welding wire guide and wherein the diverting valve ( 10 ) provided in the coupling element ( 4 ) is switchable between two valve positions by a controllable electromagnet ( 30 ), wherein in a first valve position of the diverting valve ( 10 ) the compressed air applied to the coupling element ( 4 ) is fed to the welding torch ( 3 ), and wherein in a second valve position of the diverting valve ( 10 ), the compressed air applied to the coupling element ( 4 ) is diverted to the welding wire stop ( 7 ) within the coupling element ( 4 ), wherein the controllable electromagnet ( 30 ) is activated such that a mechanical latching component ( 24 ) engagable with an annular recess ( 23 ) in an outer surface of a hollow cylindrical control slide ( 22 ) of the diverting valve ( 10 ) is released and the diverting valve ( 10 ) is moved from the first valve position to the second valve position to divert the compressed air. 2. The coupling structure as claimed in claim 1 , wherein the coupling element ( 4 ) of the welding device ( 1 ) has a gas spigot ( 8 ) for attachment to the hose bundle ( 5 ) of the welding device ( 1 ), wherein the gas spigot ( 8 ) is connected to a gas switch-over valve ( 15 ) which can be actuated and which can be switched over between a compressed air source ( 20 ) and a protective gas source ( 18 ) for supplying the welding torch ( 3 ) with compressed air or protective gas. 3. The coupling structure as claimed in claim 2 , wherein, during welding operation of the welding device ( 1 ), the gas switch-over valve ( 15 ) is switched in such a way that protective gas from the protective gas source ( 18 ) is applied to the gas spigot ( 8 ) of the coupling element ( 4 ) through a line ( 16 ) of the hose bundle ( 5 ), and the diverting valve ( 10 ) within the coupling element ( 4 ) is switched to the first valve position. 4. The coupling structure as claimed in any one of the preceding claim 2 or 3 , wherein, during blow-out operation of the welding device ( 1 ), the gas switch-over valve ( 15 ) is switched in such a way that compressed air from the compressed air source ( 20 ) is applied to the gas spigot ( 8 ) of the coupling element ( 4 ) through a line ( 16 ) of the hose bundle ( 5 ), and the diverting valve ( 10 ) within the coupling element ( 4 ) is switched to the first valve position. 5. The coupling structure as claimed in any one of the preceding claim 2 or 3 , wherein, during actuator-actuating operation of the welding device ( 1 ), the gas switch-over valve ( 15 ) is switched in such a way that compressed air from the compressed air source ( 20 ) is applied to the gas spigot ( 8 ) of the coupling element ( 4 ) through a line of the hose bundle ( 5 ), and the switch-over valve ( 10 ) within the coupling element ( 4 ) is switched to the second valve position, wherein the applied compressed air is diverted to actuate the welding wire stop within the coupling element ( 4 ). 6. The coupling structure as claimed in claim 5 , wherein the compressed air diverted during actuator-actuating operation of the welding device ( 1 ) is diverted to the welding wire stop within the coupling element ( 4 ) through a bore ( 29 ) in the housing ( 21 ) of the coupling element ( 4 ). 7. The coupling structure as claimed in any one of the preceding claims 1 to 3 , wherein an integrated valve control ( 13 ) is provided in the coupling element ( 4 ) for controlling the electromagnet ( 30 ) of the diverting valve ( 10 ), wherein the integrated valve control ( 13 ) for diverting the compressed air during actuator-actuating operation of the welding device ( 1 ) activates the electromagnet ( 30 ) provided in the coupling element ( 4 ) such that the mechanical latching component ( 24 ) is released and the diverting valve ( 10 ) is moved from the first valve position to the second valve position to divert the compressed air. 8. The coupling structure as claimed in claim 7 , wherein the mechanical latching component ( 24 ) is a ball which, when the diverting valve ( 10 ) is in the first valve position, engages with the annular recess ( 23 ) in an outer surface of the hollow cylindrical control slide ( 22 ) of the diverting valve ( 10 ) and is fixed by a movable armature ( 32 ) which is connected to the gas spigot ( 8 ) of the coupling element ( 4 ) such that, during welding operation of the welding device ( 1 ), the applied protective gas and, during blow-out operation of the welding device ( 1 ), the applied compressed air pass through the hollow cylindrical control slide ( 22 ) via an opening ( 27 ) provided in the hollow cylindrical control slide ( 22 ) and an outlet opening ( 12 ) to the welding torch ( 3 ) of the welding device ( 1 ). 9. The coupling structure as claimed in claim 8 , wherein, during activation of the electromagnet ( 30 ) of the diverting valve ( 10 ) for a transition to actuator-actuating operation of the welding device ( 1 ), the ball ( 24 ) falls into an annular groove ( 35 ) in a cylinder head ( 34 ) of the movable armature ( 32 ) of the electromagnet ( 30 ) such that the ball ( 24 ) no longer engages with the annular recess ( 23 ) in the outer surface of the hollow cylindrical control slide ( 22 ), and the hollow cylindrical control slide ( 22 ) of the diverting valve ( 10 ) is moved by the pressure of the compressed air from the first valve position to the second valve position of the diverting valve ( 10 ) for diverting the compressed air. 10. The coupling structure as claimed in any one of the preceding claims 1 to 3 , wherein a valve control ( 13 ) integrated in the coupling element ( 4 ) is connected to a control ( 14 ). 11. Method for welding a workpiece ( 2 ) by means of a welding torch ( 3 ), comprising the steps of: mechanically coupling the welding torch ( 3 ) by a coupling element ( 4 ) to a hose bundle ( 5 ) for supplying the welding torch ( 2 ) at least with compressed air or with a protective gas; guiding compressed air applied to the coupling element ( 4 ) by controlling a controllable electromagnet ( 30 ) to switch a diverting valve ( 10 ) between first and second valve positions, wherein, in the first valve position, the compressed air is fed to a gas outlet ( 12 ) of the coupling element ( 4 ) and, in the second valve position, the compressed air is fed to a welding wire stop ( 7 ) within the coupling element ( 4 ); wherein controlling the controllable electromagnet ( 30 ) includes activating the controllable electromagnet ( 30 ) such that a mechanical latching component ( 24 ) engagable with an annular recess ( 23 ) in an outer surface of a hollow cylindrical control slide ( 22 ) of the diverting valve ( 10 ) is released and the diverting valve ( 10 ) is moved from the first valve position to the second valve position to feed the compressed air to the welding wire stop ( 7 ); clamping a welding wire ( 6 ) supplied in a welding wire guide using the welding wire stop ( 7 ) when the diverting valve ( 10 ) is in the second valve position; and using the compressed air applied to the coupling element to the welding torch ( 3 ) for remo