Machining unit for machining a workpiece using a thermal machining beam, having a coupling device

What is claimed is: 1. A machining unit for machining a workpiece using a thermal machining beam wherein the thermal machining beam can be directed onto a workpiece by the machining unit along a beam incidence axis to a machining location, the machining unit comprising: an optical system for directing and focusing the thermal machining beam onto the workpiece; a machining nozzle through which the focused thermal machining beam is guided; a rotary drive device disposed between the optical system and the machining nozzle and arranged to rotate about the beam incidence axis, wherein the thermal machining beam passes through the rotary drive device; at least one auxiliary module configured to aid workpiece machining, which is coupled to the rotary drive device to rotate about the beam incidence axis under control of the rotary drive device; and a coupling device having a coupling arranged to attach the at least one auxiliary module to a coupling drive configured to move the coupling between a coupled position and an uncoupled position, wherein, when the coupling is in the coupled position, the at least one auxiliary module is either coupled to the rotary drive device and uncoupled from the coupling or coupled to the coupling and uncoupled from the rotary drive device. 2. The machining unit of claim 1 , wherein the at least one auxiliary module comprises an infeed device by which an additive or an auxiliary medium can be fed to the machining location where the thermal machining beam acts on the workpiece. 3. The machining unit of claim 1 , wherein the at least one auxiliary module comprises a nozzle assembly for a shield gas or an operating gas. 4. The machining unit of claim 1 , wherein the at least one auxiliary module comprises an infeed device for a welding additive. 5. The machining unit of claim 4 , wherein the welding additive is an auxiliary wire. 6. The machining unit of claim 1 , wherein when the at least one auxiliary module is coupled to the rotary drive device, the coupling device can be uncoupled from the at least one auxiliary module. 7. The machining unit of claim 1 , wherein the coupling device comprises a loading arm that can be coupled to the auxiliary module. 8. The machining unit of claim 7 , wherein the loading arm is arranged to pivot. 9. The machining unit of claim 1 , wherein the machining unit comprises second auxiliary modules that are arranged to be rotated about the beam incidence axis by the rotary drive device. 10. The machining unit of claim 1 , wherein the machining unit comprises a second auxiliary module that is arranged to move by the coupling device or a second coupling device between a position coupled to the rotary drive device and a position uncoupled from the rotary drive device. 11. The machining unit of claim 10 , wherein no auxiliary module, only the first, only the second, or both, auxiliary module/modules is/are couplable to the rotary drive device for the rotational positioning about the beam incidence axis. 12. The machining unit of claim 1 , wherein the rotary drive device comprises a safety coupling at an interface to the at least one auxiliary module. 13. The machining unit of claim 1 , wherein the rotary drive device comprises a rotary lead-through for an additive or an auxiliary medium, which are feedable from the at least one auxiliary module to the machining location. 14. The machining unit of claim 1 , wherein the at least one auxiliary module is arranged to be rotated endlessly about the beam incidence axis by the rotary drive device. 15. The machining unit of claim 1 , wherein the coupling drive comprises a linear drive. 16. A machining device comprising: a machining unit for machining a workpiece using a thermal machining beam wherein the thermal machining beam can be directed onto a workpiece by the machining unit along a beam incidence axis to a machining location, the machining unit comprising: an optical system for directing and focusing the thermal machining beam onto the workpiece; a machining nozzle through which the focused thermal machining beam is guided; a rotary drive device disposed between the optical system and the machining nozzle and arranged to rotate about the beam incidence axis, wherein the thermal machining beam passes through the rotary drive device; at least one auxiliary module configured to aid workpiece machining, which is coupled to the rotary drive device to rotate about the beam incidence axis under control of the rotary drive device, and a coupling device having a coupling arranged to attach the at least one auxiliary module to a coupling drive configured to move the coupling between a coupled position and an uncoupled position, wherein, when the coupling is in the coupled position, the at least one auxiliary module is either coupled to the rotary drive device and uncoupled from the coupling or coupled to the coupling and uncoupled from the rotary drive device; a motion drive device by which the machining unit conjointly with the optical system, the auxiliary module, and the coupling device, is movable relative to the workpiece; and a nozzle magazine from which nozzles for the auxiliary module are interchangeable by the coupling device.