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A turbocompressor flow structure comprises a ring chamber which is arranged concentrically to an axis of a turbocompressor in an area of free blade/vane ends of a rotor blade ring/vane ring and is adjacent radially to a main flow channel. A ring chamber is provided which is bordered by a front upstr

A turbocompressor flow structure comprises a ring chamber which is arranged concentrically to an axis of a turbocompressor in an area of free blade/vane ends of a rotor blade ring/vane ring and is adjacent radially to a main flow channel. A ring chamber is provided which is bordered by a front upstream wall, a rear downstream wall and a wall that runs essentially axially. Baffle elements are arranged in the ring chamber and the ring chamber permits flow penetration in a circumferential direction in a front and/or rear area. At least one opening is provided in the area of the wall that runs essentially axially or in the area of the upstream wall and permits flow penetration out of the ring chamber, at least one compressor chamber being provided to accommodate this outgoing flow.

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What is claimed is: 1. Flow structure for a turbocompressor of a gas turbine, having at least one ring chamber which is arranged concentrically with respect to an axis of the turbocompressor in an area of free blade/vane ends of a rotor blade ring/vane ring and is adjacent radially to a main flow c

What is claimed is: 1. Flow structure for a turbocompressor of a gas turbine, having at least one ring chamber which is arranged concentrically with respect to an axis of the turbocompressor in an area of free blade/vane ends of a rotor blade ring/vane ring and is adjacent radially to a main flow channel, whereby the ring chamber is bordered by a front upstream wall, a rear downstream wall and a wall extending essentially axially, whereby baffle elements are arranged in the ring chamber and whereby the ring chamber permits flow penetration in a circumferential direction, wherein in the area of at least one of the walls, at least one opening is provided which permits flow penetration out of the ring chamber, wherein there is at least one compressor chamber to receive this emerging flow, and wherein the baffle elements on one end border flow channels running mainly in an axial direction and on another end they border at least one flow channel running in the circumferential direction, whereby the opening or each opening is provided on an upstream end of the flow channels running in the axial direction in the wall extending essentially axially. 2. The flow structure as claimed in claim 1, whereby the opening or each opening allows flow penetration in the radial direction out of the ring chamber and into the compressor chamber. 3. Flow structure as claimed in claim 1, wherein the compressor chamber has an outlet opening through which air flowing out of the ring chamber and into the compressor chamber can be removed from the compressor chamber. 4. Flow structure as claimed in claim 1, wherein the compressor chamber is radially adjacent to the ring chamber. 5. Flow structure according to claim 1, wherein the compressor chamber surrounds the ring chamber on a radially outer side of the ring chamber. 6. Flow structure according to claim 1, wherein the compressor chamber surrounds the ring chamber on a radially inner side of the ring chamber. 7. Flow structure as claimed in claim 1, wherein ends of the baffle elements facing the main flow channel run on and/or near a contour of the main flow channel and overlap axially with free blade/vane ends or are adjacent axially to an area of the free blade/vane ends. 8. Flow structure as claimed in claim 7, wherein ends of the baffle elements facing the main flow channel are at a distance from the free blade/vane ends of the turbocompressor in the radial direction so that in normal operation of the turbocompressor the baffle elements do not come in contact with the free blade/vane ends. 9. Flow structure as claimed in claim 1, wherein the ring chambers, the baffle elements and the compressor chambers are integrated into a casing of the turbocompressor. 10. Flow structure as claimed in claim 1, wherein an axial center of the ring chamber is situated upstream from the axial center of the respective rotor blade ring/vane ring. 11. Flow structure as claimed in claim 10, wherein the axial center of the ring chamber is situated on a respective main flow channel wall upstream from the axial center of the free blade/vane ends of the respective rotor blade ring/vane ring. 12. Turbocompressor in axial design, having at least one flow structure as claimed in claim 11. 13. Aircraft engine having a turbocompressor as claimed in claim 12. 14. Stationary gas turbine having a turbocompressor as claimed in claim 12. 15. Turbocompressor in diagonal design, having at least one flow structure as claimed in claim 11. 16. Aircraft engine having a turbocompressor as claimed in claim 15. 17. Stationary gas turbine having a turbocompressor as claimed in claim 15. 18. Turbocompressor in radial design, having at least one flow structure as claimed in claim 11. 19. Aircraft engine having a turbocompressor as claimed in claim 18. 20. Stationary gas turbine having a turbocompressor as claimed in claim 18. 21. Flow structure for a turbocompressor of a gas turbine, having at least one ring chamber which is arranged concentrically with respect to an axis of the turbocompressor in an area of free blade/vane ends of a rotor blade ring/vane ring and is adjacent radially to a main flow channel, whereby the ring chamber is bordered by a front upstream wall, a rear downstream wall and a wall extending essentially axially, whereby baffle elements are arranged in the ring chamber and whereby the ring chamber permits flow penetration in a circumferential direction, wherein in the area of at least one of the walls, at least one opening is provided which permits flow penetration out of the ring chamber, wherein there is at least one compressor chamber to receive this emerging flow, and wherein the baffle elements are inclined by an angle β in the circumferential direction as seen in an axial direction of observation or they are curved in the circumferential direction. 22. Flow structure according to claim 21, wherein the angle β is selected so that the admission of flow into the ring chamber from the main flow channel is facilitated from an aerodynamic standpoint. 23. Flow structure for a turbocompressor of a gas turbine, having at least one ring chamber which is arranged concentrically with respect to an axis of the turbocompressor in an area of free blade/vane ends of a rotor blade ring/vane ring and is adjacent radially to a main flow channel, whereby the ring chamber is bordered by a front upstream wall, a rear downstream wall and a wall extending essentially axially, whereby baffle elements are arranged in the ring chamber and whereby the ring chamber permits flow penetration in a circumferential direction, wherein in the area of at least one of the walls, at least one opening is provided which permits flow penetration out of the ring chamber, wherein there is at least one compressor chamber to receive this emerging flow, and wherein the baffle elements are designed like blades/vanes having a three-dimensional curvature, a varying thickness and defined profile sections. 24. Flow structure for a turbocompressor of a gas turbine, having at least one ring chamber which is arranged concentrically with respect to an axis of the turbocompressor in an area of free blade/vane ends of a rotor blade ring/vane ring and is adjacent radially to a main flow channel, whereby the ring chamber is bordered by a front upstream wall, a rear downstream wall and a wall extending essentially axially, whereby baffle elements are arranged in the ring chamber and whereby the ring chamber permits flow penetration in a circumferential direction, wherein in the area of at least one of the walls, at least one opening is provided which permits flow penetration out of the ring chamber, wherein there is at least one compressor chamber to receive this emerging flow, and wherein the ring chambers, the baffle elements and the compressor chambers are integrated into a hub of the turbocompressor. 25. Gas turbine turbocompressor assembly comprising: a main flow channel, rotatable rotor blades and fixed vanes extending into said main flow channel, a ring chamber disposed radially adjacent the main flow channel, said ring chamber being bordered by a front upstream wall, a rear downstream wall and an axially extending wall, baffle elements disposed in the ring chamber to guide air from the main flow channel into the ring chamber, a compressor chamber disposed radially adjacent the ring chamber at a radial side of the ring chamber opposite from the main flow channel, and at least one opening in said ring chamber which permits flow of a portion of the air from the ring chamber to said compressor chamber, wherein the baffle elements on one end border flow channels running mainly in an axial direction and on another end they border at least one flow channel running in a circumferential direction, whereby the opening or each opening is provided on an upstream end of the flow channels running in the axial direction in the wall extending essentially axially. 26. Gas turbine turbocompressor assembly according to claim 25, wherein the compressor chamber surrounds the ring chamber on a radially outer side of the ring chamber. 27. Gas turbine turbocompressor assembly according to claim 25, wherein the compressor chamber surrounds the ring chamber on a radially inner side of the ring chamber. 28. Gas turbine turbocompressor assembly according to claim 25, wherein ends of the baffle elements facing the main flow channel run on and/or near a contour of the main flow channel and overlap axially with free blade/vane ends or are adjacent axially to an area of the free blade/vane ends.