Rotary union for a tire-inflation system

The invention claimed is: 1. A rotary union for a tire inflation system, comprising: an axle housing; a wheel axle rotatably mounted in the axle housing, the wheel axle having a wheel mounting flange for attachment of a wheel rim, wherein the wheel axle is received at least in portions by a passage socket that is connected for conjoint rotation to the wheel axle and supported by a radial bearing relative to a bearing seat within the axle housing, wherein a compressed air duct is disposed inside a cylindrical wall of the passage socket, the compressed air duct being connected at one end to a pressure connector mounted on the axle housing and at the other end to a tire connector mounted on the passage socket, wherein the passage socket is sealed rotationally movably with respect to an adjacent inner side of the axle housing in such a manner that an air-tightly enclosed connecting chamber is formed between the pressure connector and the compressed air duct; wherein the connecting chamber is formed as a cavity inside the axle housing and the cavity adjoins an inner end face of the passage socket. 2. The rotary union of claim 1 , wherein the cavity surrounds the wheel axle. 3. The rotary union of claim 2 , wherein, proceeding from the cavity, the passage socket extends in a direction of an exterior end face of the axle housing. 4. The rotary union of claim 1 , further comprising an additional pressure connector mounted on the axle housing. 5. The rotary union of claim 4 , wherein the additional pressure connector opens into an annular channel communicating with the compressed air duct and is formed by an elastic seal ring pair between a cylindrical outer side of the passage socket and a cylindrical inner side of the axle housing. 6. The rotary union of claim 5 , further comprising an additional compressed air duct running inside the cylindrical wall of the passage socket. 7. The rotary union of claim 6 , wherein each of the compressed air ducts is associated with the separate additional pressure connector or tire connector. 8. The rotary union of claim 6 , wherein the compressed air ducts are arranged equally along a periphery of the cylindrical wall of the rotary passage socket. 9. The rotary union of claim 1 , wherein the tire connector is mounted on an outer collar formed on the passage socket. 10. A tire inflation system for adjusting a tire inflation pressure present in a vehicle tire, comprising: a rotary union including an axle housing; a wheel axle rotatably mounted in the axle housing, the wheel axle having a wheel mounting flange for attachment of a wheel rim, wherein the wheel axle is received at least in portions by a passage socket that is connected for conjoint rotation to the wheel axle and supported by a radial bearing relative to a bearing seat within the axle housing, wherein a compressed air duct is disposed inside a cylindrical wall of the passage socket, the compressed air duct being connected at one end to a pressure connector mounted on the axle housing and at the other end to a tire connector mounted on the passage socket, wherein the passage socket is sealed rotationally movably with respect to an adjacent inner side of the axle housing in such a manner that an air-tightly enclosed connecting chamber is formed between the pressure connector and the compressed air duct; wherein the connecting chamber is formed as a cavity inside the axle housing and the cavity adjoins an inner end face of the passage socket. 11. The tire inflation system of claim 10 , wherein the cavity surrounds the wheel axle. 12. The tire inflation system of claim 11 , wherein, proceeding from the cavity, the passage socket extends in a direction of an exterior end face of the axle housing. 13. The tire inflation system of claim 10 , further comprising an additional pressure connector mounted on the axle housing. 14. The tire inflation system of claim 13 , wherein the additional pressure connector opens into an annular channel communicating with the compressed air duct and is formed by an elastic seal ring pair between a cylindrical outer side of the passage socket and a cylindrical inner side of the axle housing. 15. The tire inflation system of claim 14 , further comprising an additional compressed air duct running inside the cylindrical wall of the passage socket. 16. The tire inflation system of claim 15 , wherein each of the compressed air ducts is associated with the separate additional pressure connector or tire connector. 17. The tire inflation system of claim 15 , wherein the compressed air ducts are arranged equally along a periphery of the cylindrical wall of the rotary passage socket. 18. The tire inflation system of claim 10 , wherein the tire connector is mounted on an outer collar formed on the passage socket. 19. A rotary union for a tire inflation system, comprising: an axle housing; a wheel axle rotatably mounted in the axle housing, the wheel axle having a wheel mounting flange for attachment of a wheel rim, a passage socket connected for conjoint rotation to the wheel axle and supported by a radial bearing relative to a bearing seat within the axle housing, and a plurality of compressed air ducts disposed inside a cylindrical wall of the passage socket, the plurality of compressed air ducts being connected at one end to a pressure connector mounted on the axle housing and at the other end to a tire connector mounted on the passage socket, wherein the passage socket is sealed rotationally movably with respect to an adjacent inner side of the axle housing in such a manner that an air-tightly enclosed connecting chamber is formed between the pressure connector and the compressed air duct, wherein the connecting chamber is formed as a cavity inside the axle housing, the cavity adjoins an inner end face of the passage socket, and the cavity surrounds the wheel axle in a toroidal shape, wherein at least one of the plurality of pressure connectors opens into an annular channel communicating with the compressed air duct and is formed by an elastic seal ring pair between a cylindrical outer side of the passage socket and a cylindrical inner side of the axle housing. 20. The rotary union of claim 19 , wherein the compressed air ducts are arranged equally along a periphery of the cylindrical wall of the rotary passage socket. 21. The rotary union of claim 1 , wherein the cavity surrounds the wheel axle in a toroidal shape. 22. The tire inflation system of claim 10 , wherein the cavity surrounds the wheel axle in a toroidal shape.