Multistage ejector

What is claimed is: 1. A multistage ejector, comprising: a nozzle arrangement having at least three nozzles arranged in series in a direction of a longitudinal axis, the nozzles adapted to provide passage of a throughflow of a fluid, a fluid gap being provided between adjacent nozzles, at least two of the at least three nozzles are interconnected monolithically to form a nozzle string, a sleeve including an inside and an outside, the sleeve having a first radial opening and a second radial opening opposing the first radial opening, wherein the first and second radial openings are each configured to pass from the inside of the sleeve to the outside of the sleeve, the nozzle string being arranged at least partially in the sleeve; a check valve for closing and freeing the first and second radial openings, the check valve including a slotted annular band having a first portion and a second portion extending circumferentially around the nozzle string, wherein the first and second portions are aligned with the first and second radial openings, respectively, and wherein the slotted annular band is connected monolithically via an axial tab to a discontinuous locking ring, the discontinuous locking ring including a slotted region configured to engage with a radial tongue in the nozzle string defining a rotational position of the check valve relative to the nozzle string, wherein the discontinuous locking ring is disposed between two spaced apart flanges for axially securing the check valve from displacement; and a fastening mechanism rotationally detachable and axially fastening the sleeve and the nozzle string to each other, the fastening mechanism being a positively locking fastening mechanism. 2. The ejector of claim 1 , wherein the fastening mechanism fastens the nozzle string and the sleeve to each other in a rotationally secured manner relative to each other. 3. The ejector of claim 1 , wherein the at least three nozzles comprise a driver nozzle and at least two receiver nozzles, wherein the at least two receiver nozzles form the monolithic nozzle string. 4. The ejector of claim 1 , wherein the nozzle arrangement has at least four nozzles comprising a driver nozzle and at least three receiver nozzles, wherein the at least three receiver nozzles form the monolithic nozzle string. 5. The ejector of claim 1 , wherein the fastening mechanism is a latching connection. 6. The ejector of claim 1 , wherein the fastening mechanism is a combination of a plug-in and twist connection and a latching connection. 7. The ejector of claim 1 , wherein the fastening mechanism is arranged on the nozzle string at a distance from an end of said nozzle string so that the nozzle string projects beyond the sleeve. 8. The ejector of claim 1 , wherein the fastening mechanism has at least one radially projecting tongue on the nozzle string and at least one recess on the sleeve, the at least one recess extends parallel to the longitudinal axis, and the at least one recess adjoins a further recess on the sleeve which extends in a circumferential direction around the longitudinal axis. 9. The ejector of claim 1 , wherein the nozzle string has a flange abutting against an end face of the sleeve when the nozzle string is being connected to the sleeve. 10. The ejector of claim 1 , wherein the nozzle string includes the radial tongue integrally formed in and projecting radially outward from a center of the nozzle string and between free ends of the discontinuous locking ring, and wherein the radial tongue prevents rotation of the check valve around the longitudinal axis. 11. The ejector of claim 10 , wherein the two spaced apart flanges are integrally formed on an outer side of the nozzle string forming a seat contacting at least one surface of the discontinuous locking ring. 12. The ejector of claim 1 , wherein the fastening mechanism is a plug-in and twist connection. 13. The ejector of claim 12 , wherein the fastening mechanism is a bayonet connection. 14. The ejector of claim 1 , wherein two or more axial bridges are formed between each of the at least two of the at least three nozzles providing the monolithic interconnection. 15. The ejector of claim 14 , wherein the two or more axial bridges are formed in the direction of the longitudinal axis of the nozzle arrangement. 16. The ejector of claim 15 , wherein the two or more axial bridges are formed on peripheral surfaces of the at least two of the at least three nozzles. 17. The ejector of claim 16 , wherein two axial bridges of the two or more axial bridges are disposed opposite one another radially about the fluid gap. 18. The ejector of claim 17 , wherein the multistage ejector includes an inlet side disposed on a first end of the nozzle arrangement and an outlet side disposed on a second and opposite end of the nozzle arrangement, and wherein a portion of the two or more axial bridges connecting a first nozzle to a second nozzle in the nozzle string tapers outwardly from a peripheral surface of the first nozzle in a direction of the outlet side. 19. The ejector of claim 17 , wherein a third axial bridge is disposed between the two axial bridges on one side. 20. The ejector of claim 19 , wherein the check valve is axially offset from the fluid gap provided between adjacent nozzles in the nozzle string such that the check valve is not radially overlapping any portion of the fluid gap.