Rotating x-ray anode

The invention claimed is: 1. A rotary x-ray anode for generating x-radiation, the x-ray anode comprising: an annular basic body of carbon-based material, said basic body having, with reference to an axis of rotation of the rotary x-ray anode, a radially inner opening with a radial inner surface; an annular focal track coating arranged on a focal track side of said basic body; a metallic connecting component arranged radially on an inside relative to said basic body and configured to connect said basic body to a drive shaft, a radially inner portion of said metallic connecting component being formed by a metallic shaft connection component; said metallic connecting component having a radially outer portion formed by a tubular metallic adapter, said adapter having a frustoconical basic shape with a cone angle between >90° and <180° or between >180° and <270°, said adapter having a radial outer surface connected by a material bond to at least a portion of said radial inner surface of said basic body, and wherein a materially bonded connecting zone formed between said basic body and said adapter extends over at least 75 area percent along said radial inner surface of said basic body; and said metallic shaft connection component being connected on a radially outer circumference to the radial inner surface of said tubular metallic adapter, and said radially inner portion of said metallic shaft connection component being configured for connection to the drive shaft. 2. The rotary x-ray anode according to claim 1 , wherein an outer circumference of said adapter decreases in an axial direction. 3. The rotary x-ray anode according to claim 1 , wherein said adapter is rotationally symmetrical. 4. The rotary x-ray anode according to claim 1 , wherein said metallic shaft connection component has a circular-disk-shaped basic shape and is arranged in a plane perpendicular to an axial direction. 5. The rotary x-ray anode according to claim 1 , wherein said metallic shaft connection component has a frustoconical basic shape with a cone angle between 90° and 100° or between 260° and 270°. 6. The rotary x-ray anode according to claim 1 , wherein said metallic shaft connection component is connected to said radial inner surface of said adapter in a range of 40% to 60% of a height of said adapter in an axial direction. 7. The rotary x-ray anode according to claim 1 , wherein said metallic shaft connection component has a thin-walled configuration with a thickness in an axial direction of less than 10 mm. 8. The rotary x-ray anode according to claim 1 , wherein a maximum thickness of said metallic shaft connection component in an axial direction is less than 20% of a height of said adapter in the axial direction. 9. The rotary x-ray anode according to claim 1 , wherein said adapter has a thin-walled configuration with a thickness in a radial direction of less than 5 mm. 10. The rotary x-ray anode according to claim 1 , wherein said adapter and said annular basic body are soldered to one another. 11. The rotary x-ray anode according to claim 1 , wherein said metallic connecting component includes a heat restrictor being an intermediate component or an intermediate layer of a material with low thermal conductivity. 12. The rotary x-ray anode according to claim 1 , wherein said metallic connecting component comprises at least one metal selected from the group consisting of tungsten, molybdenum, and copper, an alloy based on tungsten, molybdenum or copper, a tungsten-copper, a molybdenum-copper, or a copper composite material. 13. The rotary x-ray anode according to claim 1 , wherein the focal track side carrying said focal track coating in a radially outer region of said annular basic body is beveled.