Dynamoelectric machine having cooling of the slip ring system

The invention claimed is: 1. A dynamoelectric machine, in particular a double-fed asynchronous machine, said dynamoelectric machine comprising: a stator; a shaft; a rotor interacting with the stator, said rotor being arranged fixedly on the shaft for conjoint rotation and comprising a winding system; and a slip ring system designed to enable the winding system of the rotor to be contacted electrically and comprising a slip ring body including slip rings which are arranged axially behind one another and spaced apart from one another in an insulated manner and which are assigned to an electrical phase, said slip ring body being connected fixedly to the shaft for conjoint rotation and having between an inner side of the slip ring body and the shaft at least one section designed to form a cavity which is open axially on both sides and is designed as a circumferential cutout so that the slip ring body lies at least on two circumferentially running boundary elements which are spaced apart axially from one another and which are connected through shrink fit in one piece with an inside of the slip ring body and/or of the shaft, wherein the shaft is designed at least in a region of the slip ring system as a hollow shaft which has a hollow shaft portion assigned to the slip ring system for routing feed lines to the winding system of the rotor, and wherein axial recesses are provided on the cavity axially on an inside and axially on an outside for enabling introduction of a cooling medium flow axially into the cavity and discharge of the cooling medium flow into an outlet region, with first ones of the axial recesses being formed about an entire circumference of one of the two circumferentially running boundary elements for introduction of the cooling medium flow, and with second ones of the axial recesses being formed about an entire circumference of the other one of the two circumferentially running boundary elements for discharge of the cooling medium flow. 2. The dynamoelectric machine of claim 1 , wherein the slip ring system comprises an electrical energy transmission unit in the form of a brush unit which includes one or more brushes assigned to a corresponding one of the slip rings per electrical phase, said brush unit comprising a brush holder for arrangement of the one or more brushes. 3. The dynamoelectric machine of claim 1 , wherein the boundary elements are designed as rings or webs. 4. The dynamoelectric machine of claim 1 , wherein in a region of the cavity, the shaft has a reduced diameter portion over a predefined axial length and/or the slip ring body has a widened diameter portion. 5. The dynamoelectric machine of claim 1 , wherein the cavity is designed to form a labyrinth-like and/or meandering structure in the cavity so as to increase a dwell time of the cooling medium flow. 6. The dynamoelectric machine of claim 1 , wherein the cooling medium flow is an air flow. 7. The dynamoelectric machine of claim 6 , further comprising an external fan or an integral fan designed to generate the air flow. 8. A wind power plant, comprising a dynamoelectric machine, said dynamoelectric machine comprising a stator, a shaft, a rotor Interacting with the stator, said rotor being arranged fixedly on the shaft for conjoint rotation and comprising a winding system, and a slip ring system designed to enable the winding system of the rotor to be contacted electrically and comprising a slip ring body including slip rings which are arranged axially behind one another and spaced apart from one another in an insulated manner and which are assigned to an electrical phase, said slip ring body being connected fixedly to the shaft for conjoint rotation and having between an inner side of the slip ring body and the shaft at least one section designed to form a cavity which is open axially on both sides and is designed as a circumferential cutout so that the slip ring body lies at least on two circumferentially running boundary elements which are spaced apart axially from one another and which are connected through shrink fit in one piece with an inside of the slip ring body and/or of the shaft, wherein the shaft is designed at least in a region of the slip ring system as a hollow shaft which has a hollow shaft portion assigned to the slip ring system for routing feed lines to the winding system of the rotor, and wherein axial recesses are provided on the cavity axially on an inside and axially on an outside for enabling introduction of a cooling medium flow axially into the cavity and discharge of the cooling medium flow into an outlet region, with first ones of the axial recesses being formed about an entire circumference of one of the two circumferentially running boundary elements for introduction of the cooling medium flow, and with second ones of the axial recesses being formed about an entire circumference of the other one of the two circumferentially running boundary elements for discharge of the cooling medium flow. 9. The wind power plant of claim 8 , wherein the slip ring system comprises an electrical energy transmission unit in the form of a brush unit which includes one or more brushes assigned to a corresponding one of the slip rings per electrical phase, said brush unit comprising a brush holder for arrangement of the one or more brushes. 10. The wind power plant of claim 8 , wherein the boundary elements are designed as rings or webs. 11. The wind power plant of claim 8 , wherein in a region of the cavity, the shaft has a reduced diameter portion over a predefined axial length and/or the slip ring body has a widened diameter portion. 12. The wind power plant of claim 8 , wherein the cavity is designed to form a labyrinth-like and/or meandering structure in the cavity so as to increase a dwell time of the cooling medium flow. 13. The wind power plant of claim 8 , wherein the cooling medium flow is an air flow. 14. The wind power plant of claim 13 , wherein the dynamoelectric machine comprises an external fan or an integral fan designed to generate the air flow.