Yarn return unit for returning a yarn as well as a workstation of a textile machine comprising a yarn return unit

The invention claimed is: 1. A method for identifying a spinning rotor on a rotor spinning machine from other different types of spinning rotors, wherein the spinning rotor is mounted in a suspended manner in an at least a radially acting magnetic bearing and rotates in the bearing during a spinning operation, the method comprising: identifying at least one system variable that varies between different types of spinning rotors; detecting the system variable; comparing the detected system variable to at least one reference value; wherein the system variable is one or a combination of: an energy consumption of the magnetic bearing; a radial position of the spinning rotor; or a resonant frequency of the spinning rotor; and based on the comparison of the detected system variable and the reference value, one or a combination of the following physical characteristics of the spinning rotor that differentiate one type of spinning rotor from a different type of spinning rotor are determined: a mass of the spinning rotor, a volume of the spinning rotor, a material of the spinning rotor, and dimensions of a size or shape of the spinning rotor. 2. The method as in claim 1 , wherein at least the radial position of the spinning rotor is actively influenced by the magnetic bearing. 3. The method as in claim 2 , wherein the radial position of the spinning rotor is detected by at least one sensor or by the magnetic bearing. 4. The method as in claim 2 , wherein the radial position of the spinning rotor is varied in such a way that the energy consumption of the magnetic bearing is minimized and, thereafter, the radial position is compared to at least one radial position reference value. 5. The method as in claim 2 , wherein the spinning rotor is brought into a defined radial position and, thereafter, the energy consumption of the magnetic bearing is compared to at least one energy consumption reference value. 6. The method as in claim 1 , wherein the spinning rotor is caused, by the magnetic bearing, to oscillate and the resonant frequency of the spinning rotor is determined from a subsidence behavior of the oscillation and, thereafter, the resonant frequency is compared to at least one resonant frequency reference value. 7. The method as in claim 1 , wherein the resonant frequency of the spinning rotor is determined during an acceleration of the spinning rotor based on an increase of an amplitude of an oscillation of the spinning rotor and, thereafter, the resonant frequency is compared to at least one resonant frequency reference value. 8. The method as in claim 1 , further comprising establishing a functional scope of the spinning operation based on the comparison of the system variable with the reference value. 9. A rotor spinning machine, comprising: at least one workstation, the workstation comprising a spinning rotor mounted in a suspended manner in a radially acting magnetic bearing such that the spinning rotor rotates within the magnetic bearing during a spinning operation; the workstation further comprising a control system configured to identify of the spinning rotor from other different types of spinning rotors by comparing a system variable that varies between different types of spinning rotors with a reference value; wherein the system variable is one or a combination of: an energy consumption of the magnetic bearing; a radial position of the spinning rotor; or a resonant frequency of the spinning rotor; and based on the comparison of the detected system variable and the reference value, the control system configured to determine one or a combination of the following physical characteristics of the spinning rotor that differentiate the spinning rotor from other different types of spinning rotors: a mass of the spinning rotor, a volume of the spinning rotor, a material of the spinning rotor, and dimensions of a size or shape of the spinning rotor. 10. The rotor spinning machine as in claim 9 , wherein the magnetic bearing comprises an electromagnetic bearing with at least one electromagnet. 11. The rotor spinning machine as in claim 9 , wherein the control system is connected to a sensor that is configured to detect a position or a movement of the spinning rotor. 12. The rotor spinning machine as in claim 9 , wherein the magnetic bearing additionally acts in an axial direction on the spinning rotor. 13. The rotor spinning machine as in claim 9 , further comprising an additional axial bearing that acts in an axial direction on the spinning rotor. 14. The rotor spinning machine as in claim 9 , wherein the control system is connected to an article management system. 15. The rotor spinning machine as in claim 9 , wherein the control system comprises or is connected to a memory that stores the reference values.