The present invention relates to an X-ray tube for generating X-radiation and a method for manufacturing an X-ray tube, and an X-ray system for diagnostic use comprising an X-ray tube and in particular to a method for manufacturing an X-ray system, which comprises an X-ray tube.
A rotating anode X-ray tube generates X-radiation in a diagnostic system, wherein the anode of the X-ray tube heats up upon operation and cools during exposure and afterwards.
The thermal heat flow and thermal cycling causes thermo mechanical distortion of the tube components. Therefore, the tube components have to be designed such that reliable operation is guaranteed under all specified conditions.
Many modern high performance X-ray tubes use hydrodynamic bearings to support the rotating anode and to dissipate the heat from the anode by direct conduction cooling towards an external cooling fluid. The loading capacity of these hydrodynamic bearings is a strong function of the gap size between the active surfaces of the rotating and stationary bearing members. The gap size is typically in the range of only 5 to 20 um, while the range of bearing diameters is typically 2 to 10 cm, its length 5 cm to 15 cm. So the gap is of relatively small size. Given a certain speed of rotation, large gaps as well as low viscosity of the bearing fluid (hot liquid metal) both cut down the loading capacity (bearing stiffness).
Therefore, it would be desirable to provide an improved device and method for stabilising the gap of the bearing. These needs may be met by the subject matter according to one of the independent claims. Advantageous embodiments of the present invention are described in the dependent claims.
According to the invention the size of the bearing gap is stabilized against thermo mechanical distortion using controlled matching expansion of the bearing members. This can be achieved by using at least some parts of the members materials of different thermal expansion coefficients cth. (E.g. the material of the bearing member which is at lower temperature during operation is selected to have a higher cth compared to the material of the member at higher temperature). Another solution is to use mechanical piston-like force generation e.g. by hydraulic means. The advantages are e.g. a reduction of friction losses in cold state and a prevention of rotation instability in hot state.
According to a first aspect of the invention an X-ray tube for generating X-radiation is proposed. The X-ray tube for generating X-radiation comprises a rotary structure, which comprises a rotating anode, a stationary structure for rotatably supporting the rotary structure, a bearing, which is arranged between the rotary structure and the stationary structure, wherein the bearing comprises a gap between the rotary structure and the stationary structure, means for stabilising the dimensions of the gap with respect to distortions because of thermo-mechanical causes.
The X-ray tube and the anode will be heated during operation by electron beam, which impinges on the target to generate X-ray. Therefore, a circulating cooling fluid system is arranged to compensate and to stabilise the temperature of the tube. There are regions of different temperature within the tube. Different temperatures lead to different expansion of the gap of bearing between the stationary part of the tube and the rotary part of the tube. In case the key gap dimensions vary locally (especially in case of different sizes of the cross-section) problems may arise during operation of the X-ray tube. Therefore, the tube according to the invention has means for compensating the above mentioned effect, which results in approximately constant key dimensions of the gap of bearing.
According to a second aspect of the invention it is provided a method for manufacturing the tube, wherein means for stabilising the dimensions of the gap are arranged.
According to a third aspect of the invention it is proposed an X-ray system for diagnostic use comprising the tube, wherein the X-ray system is adapted to stabilise the dimensions of the gap.
According to a fourth aspect of the invention it is proposed a method for manufacturing the X-ray system, wherein means for stabilising the dimensions of the gap are arranged in such a way that the X-ray system is adapted to stabilise the dimensions of the gap.
According to the present invention it is provided an X-ray tube, wherein the tube comprises a wall as a mechanical limitation for the gap, wherein the means for stabilising comprise an inlay, which is inserted in the wall, wherein the inlay has a different thermal expansion coefficient with respect to at least a part of the wall.
There are regions of different temperature because of the arrangement of a heat source (the anode) and a heat sink (the circulating cooling fluid). Therefore, the expansion of the material can also be different. This could result in a deformation of the gap. In order to avoid this effect it is proposed to arrange material, which expands little, at sites, which are hot and to arrange material, which expands in a higher degree, at sites, which are relatively cold. This can be done by inserting inlays into the tube.
According to an exemplary embodiment it is provided a tube, wherein the inlay is arranged adjacent to the gap. This is advantageously because in this case the effect of the inlays on the gap can be enhanced.
According to another exemplary embodiment it is provided a tube, wherein the inlay has a large thermal expansion coefficient, wherein the inlay is arranged in a relatively cold surrounding.
According to an exemplary embodiment it is provided a tube, wherein the inlay has a small thermal expansion coefficient, wherein the inlay is arranged in a relatively hot surrounding.
According to another exemplary embodiment it is provided a tube, wherein the inlay comprises a sandwich structure of different materials, wherein materials with a close thermal expansion coefficient compared to the thermal expansion coefficient of the wall will be arranged adjacent to the wall, wherein materials with a thermal expansion coefficient, which is substantially different compared to the thermal expansion coefficient of the wall will be arranged far away to the wall.
According to an exemplary embodiment it is provided a tube, wherein the inlay is adapted to stabilise the dimensions of the gap because of an appropriate shape. The inlay could have a shape which is adapted to the gap. In this case the shape of the inlay improves the stabilising character of the inlay in order to stabilise the dimensions of the gap.
According to a further exemplary embodiment it is provided a tube, wherein the wall is adapted to be deformed by means for deforming for stabilising the dimensions of the gap. The stationary part of the X-ray tube comprises a bearing axis.
This axis has to be hollow in order to contain the circulating cooling fluid system. In case the walls of the bearing axis are thin enough it is possible to deform these walls in order to compensate deformations of the bearing gap.
According to an exemplary embodiment it is provided a tube, wherein the means for deforming comprise a lever for applying a mechanical force on the wall.
According to another exemplary embodiment it is provided a tube, wherein the means for deforming comprise means for applying fluid pressure on the wall.
According to a further exemplary embodiment it is provided a tube, wherein the wall has a thickness of about 1 to 20 mm.
According to an exemplary embodiment it is provided a tube, wherein the means for stabilising comprise a channel for directing the flow of heat, wherein the channel is arranged in such a way that the deformation of the gap is uniform.
It should be noted that the above features may also be combined. The combination of the above features may also lead to synergetic effects, even if not explicitly described in detail.
These and other aspects of the present invention will become apparent from and elucidated with reference to the embodiments described hereinafter.
Exemplary embodiments of the present invention will be described in the following with reference to the following drawings.
Summarizing the above mentioned it can be stated that the heating of the anode 504 causes thermal gradients inside the hydrodynamic bearing. Unequal expansion of its members may cause a significant distortion of the gap size and negatively affect bearing stability and loading capacity. Low viscosity of the heated bearing fluid adds negatively to this. Usually, the bearing members are of the same material. By design, they may be shaped such, that the bearing is stable under all thermal conditions. But usually, this results in an unusable loading capacity and excessive friction losses at cold state.
The inlays 707, 708 in the bearing members 702, 703 can be used for compensation. Upon heating, they expand differently from the bulk and maintain the gap size. There could be different embodiments with the help of the inlays, e.g. using inlays with a large (compared to the bulk material) cth on the cold side, using inlays with a small cth on the hot side. Further, both embodiments can be combined.
For optimal shaping of the gap 701, the form of the inlays 707, 708 can be matched with the local heat flux pattern. With the help of this principle radial and axial bearings can be stabilized. A further option could be for chemical stability against the bearing fluid, to cover the inlays 707, 708 e.g. with the bulk material.
The effect of using the compensation inlays 807, 808, which consist of sandwich structures of different materials and forms, is to avoid cracking caused by residual intrinsic stress from the manufacturing process (e.g. brazing or Plasma Vapor Deposition). The different materials may be ordered by their thermal expansion coefficient and/or their mutual adhesion. Those having characteristics close to the bulk bearing material may be located closest to the latter.
Therefore, the compensation inlays 907, 908 may be formed such that upon heating the bearing gap 901 is formed locally in a desired way. When hot, the gap 901 may get a minimal size in those areas where the bearing is loaded most. E.g. to handle gyroscopic forces, this is needed at the outer edges of the set of radial bearings.
According to this embodiment of the invention the inner hollow axis 1002 may be expanded also mechanically. The actuated piston 1009 pushes levers 1007, 1008, which push out the inner surface of the hollow axis 1002. The force on the piston 1009 may be generated through a device 1005 which expands upon rising temperature. (material with large cth). This may serve as an automatic expansion control. The piston 1009 may also be driven by hydrodynamic pressure of the cooling fluid, e.g. using an aperture. The aperture would be attached to the piston 1009. The amount of oil flow controls the pressure drop across the aperture and with it the force on the piston 1009. According to the invention mechanical and thermal compensation may also be combined.
A static fluid pressure Pfluid can be applied to the bearing axis 1102. When the inner wall of the axis 1102 is thin enough (ca. 1 mm), this pressure Pfluid can drive the expansion of the inner axis 1102. The local thickness of the wall is chosen such, that the local expansion optimally matches the thermal expansion of the outer rotating bearing member. Usually the inner surface of the bearing axis 1102 is cooled with a circulating fluid, driven by fluid pump 1107. The heat is then dissipated to the ambient by an external heat exchanger. The static pressure Pfluid can also be applied in such a case. The whole fluid circuit is then put under this static pressure Pfluid in addition to the dynamic pressure generated by the driving pump 1107. Usually the fluid will be fluent (water, oil), but the invention comprises also other forms of fluids (air under pressure).
This embodiment leads to the effect that the heat conduction will be channeled through the anode 1204 in such a way that there is only uniform bearing gap deformation. The pattern is achieved through shaping of the parts and/or selection of materials. Shaft cooling is done in such a way to prevent non-uniform gap deformation, i.e. the gap 1201 may be distorted, but symmetrically in the radial bearings 1209, 1208, such that both radial bearings 1209, 1208 still have the same stiffness.
It should be noted that the term ‘comprising’ does not exclude other elements or steps and the ‘a’ or ‘an’ does not exclude a plurality. Also elements described in association with the different embodiments may be combined.
It should be noted that the reference signs in the claims shall not be construed as limiting the scope of the claims.
Number | Date | Country | Kind |
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08167235 | Oct 2008 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2009/054594 | 10/19/2009 | WO | 00 | 7/27/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/046837 | 4/29/2010 | WO | A |
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20110280376 A1 | Nov 2011 | US |