Flow-through centrifuge and method for bringing about an operational state of a flow-through centrifuge

What is claimed is: 1. A flow-through centrifuge comprising a) a stationary housing, b) a rotor which is rotated about a rotor axis for centrifugation and to which a medium is supplied during centrifugation and/or from which a medium is discharged during centrifugation, c) a connecting strand which is held at one end portion adjacent the stationary housing and which is held at the other end portion adjacent the rotor, so that the two end portions are rotated relative to one another at a first rotational speed, the two end portions being arranged coaxially with respect to the rotor axis of the rotor and the connecting strand serving to supply a medium to the rotor and/or to discharge a medium from the rotor, d) a connecting strand guide along or through which the connecting strand extends, the connecting strand guide guiding the connecting strand for passing the rotor on the radial outer side, e) a driving arrangement or transmission arrangement comprising a planetary gearset driving the rotor at the first rotational speed and the connecting strand guide at a second rotational speed, the first rotational speed differing from the second rotational speed, the planetary gearset comprising a planetary belt pulley which is rotatably supported on a rotating planet carrier, f) a belt which transmits a torque of the planetary belt pulley in the planetary gearset, g) a belt tensioning unit supporting the planet carrier, the belt tensioning unit rotating together with the planet carrier and the belt tensioning unit being configured to provide an adjustment of a distance of the planet carrier from the rotor axis. 2. The flow-through centrifuge of claim 1 wherein the one end portion of the connecting strand is fixed to the stationary housing, and the other end portion of the connecting strand is fixed to the rotor. 3. The flow-through centrifuge of claim 1 wherein the planetary belt pulley and a second planetary belt pulley are connected to one another in a rotationally fixed manner and rotatably supported on the planet carrier, and the belt tensioning unit is arranged and configured to provide an adjustment of the distances of the planetary belt pulley and the second planetary belt pulley from the rotor axis in common. 4. The flow-through centrifuge of claim 3 wherein a) the planetary gearset comprises aa) a first sun belt pulley and a second sun belt pulley and ab) the planetary belt pulley and the second planetary belt pulley which are non-rotatably connected to one another, the first sun belt pulley being in driving connection with the planetary belt pulley via a first belt and the second planetary belt pulley being in driving connection with the second sun belt pulley via a second belt, b) the first sun belt pulley is driven at the first rotational speed, the planet carrier is driven at the second rotational speed, the second sun belt pulley drives the rotor and the planet carrier is rotated together with the connecting strand guide. 5. The flow-through centrifuge of claim 1 wherein the belt tensioning unit comprises at least one linear guide by which the planet carrier is guided relative to at least one of the connecting strand guide or a compensating body of a compensating rotor. 6. The flow-through centrifuge of claim 5 wherein the linear guide comprises a guiding rod guided in a guiding recess. 7. The flow-through centrifuge of claim 1 wherein the belt tensioning unit comprises an adjustment device by means of which it is possible to change the distance of the planet carrier from the rotor axis. 8. The flow-through centrifuge of claim 7 wherein a stop is provided which defines a maximum distance of the planet carrier from the rotor axis. 9. The flow-through centrifuge of claim 8 wherein the stop is adjustable. 10. The flow-through centrifuge of claim 7 wherein the adjustment device comprises an adjusting screw. 11. The flow-through centrifuge of claim 10 comprising a counter nut which secures a set position of the adjusting screw. 12. The flow-through centrifuge of claim 1 wherein a stop is provided which defines a maximum distance of the planet carrier from the rotor axis. 13. The flow-through centrifuge of claim 12 wherein the stop is adjustable. 14. The flow-through centrifuge of claim 1 wherein at least one compensating mass is provided on a compensating body, a distance of the at least one compensating mass from the rotor axis and/or a weight of the at least one compensating mass depending on an operating position of the belt tensioning unit. 15. A method for bringing about an operational state of a flow-through centrifuge comprising a driving arrangement and/or transmission arrangement with a planetary gearset, in which a planetary belt pulley is rotatably supported on a rotating planet carrier, a torque of the planetary belt pulley is transmitted via a belt, and the planet carrier and the planetary belt pulley are driven at different rotational speeds, the planet carrier being supported by a belt tensioning unit which rotates together with the planet carrier and the belt tensioning unit being configured to allow an adjustment of a distance of the planet carrier from a rotor axis, the method comprising a method step of adjusting the distance of the planet carrier from the rotor axis by the belt tensioning unit until a predetermined belt tension of the belt is brought about. 16. The method of claim 15 wherein after the distance of the planet carrier from the rotor axis has been changed, a balancing is performed wherein a distance of at least one balancing mass from the rotor axis and/or a weight of at least one balancing mass is adapted dependent on an operational position of the belt tensioning unit.