1. Field of the Invention
The present invention concerns an x-ray anode of the type having an emission layer and a carrier with carrier material to support the emission layer.
2. Description of the Prior Art
X-ray tubes include an x-ray anode and a cathode that are arranged in a vacuum enclosure. Electrons are thermally liberated from the cathode and accelerated by high voltage toward the anode where they are decelerated in an emission layer and generate x-rays. A large portion of the kinetic energy of the electrons is converted into heat that severely heats the x-ray anode during its operation. The power capacity of x-ray tubes is limited by this thermal loading of the x-ray anode. Various designs are known to increase the thermal capacity. For x-ray anodes executed as fixed (stationary) anodes, it is known to conduct heat from the x-ray anode via intermediate structures into a heat storage (heat accumulator or heat reservoir) made, for example, from graphite. For x-ray anodes executed as rotary anodes, the electron beam is directed onto a point on the surface of the plate-shaped x-ray anode at a distance R from the center point. By a fast rotation of the x-ray anode in operation, the heat is distributed along the focal ring described by the point and can additionally distribute during a rotation of the x-ray anode before the point is struck again by the electron beam. Cooling of the rotary anode with coolant is additionally known. A significantly higher capacity can be achieved than with fixed anodes. For rotary piston radiators it is known to rotate the entire x-ray tube in a bath of coolant and to thereby dissipate the heat from the x-ray anode.
It is common to all forms of x-ray anodes that the heat must be dissipated from the emission layer and conducted into a heat storage or a coolant. A carrier for supporting of the emission layer that is executed as an intermediate layer or directly as a heat storage, serves for this purpose. The emission layer is directly or indirectly applied.
From DE 10 2004 003 370 A1 it is known to produce this carrier from a combination made of a copper alloy for heat dissipation and a molybdenum alloy to impart the necessary stability. A very good heat dissipation can be achieved for highly heat-conductive graphite, but the problem exists that the coefficient of heat expansion of the graphite is not adapted to that of the emission layer. This leads to the situation that given a high loading of the x-ray anode small tears (fissures) arise due to the different expansion of the emission layer and the heat conductor. Such tears lead to a destruction of the x-ray anode.
To solve this problem it is known from DE 10 2005 015 920 A1 to insert a carrier made from one or more intermediate layers of carbon fiber material between the heat conductor (made from a carbon substance) and the emission layer, the carrier being backed with high melting point (refractory) metals. By varying the quantity of carbon fibers to metal, the coefficient of heat expansion can be adjusted in a certain range and thus a more densely stepped gradient of the coefficient of heat expansion can be achieved over a number of intermediate layers of the carrier. In this very stable solution, however, the heat conductivity of the carrier is unsatisfactory in a high capacity range of the x-ray anode.
An object of the invention to specify an x-ray anode that combines a high capacity for heat dissipation with a coefficient of heat expansion suitable for connection with the emission layer.
This object is achieved in accordance with the invention by an x-ray anode of the aforementioned type in which the carrier material is a metallized carbon fiber material with a portion in which the fibers are specifically directed. A high heat conductivity in the longitudinal direction and an adapted coefficient of heat expansion in the radial direction of the carbon fibers is achieved by the fiber alignment.
The invention is based on the insight that carbon fibers exhibit a significantly higher heat conductivity in the longitudinal direction than in the radial direction. By arranging the carbon fibers in a desired heat conduction direction, a significantly higher heat conduction can be achieved in this direction than with undirected carbon fibers. Moreover, the invention is based on the further consideration that carbon fibers exhibit a significantly smaller coefficient of heat expansion in the longitudinal direction than in the radial direction. By corresponding inclination of the carbon fibers in the carrier material relative to a rotation axis of the x-ray anode, a coefficient of heat expansion of the carrier material thus can be varied and be set to a desired value. A thermo-mechanical adaptation of the carrier material to the emission layer can be achieved and tear formation can be avoided. A long lifespan in combination with a high mechanical stability of the x-ray anode is achieved. The x-ray anode can be operated with a high rotation speed of, for example, 15,000 revolutions/min without having to forego a high conductivity.
The x-ray anode can be an arbitrary x-ray anode such as a fixed anode, a rotary anode or an anode in a rotary piston radiator. The carbon fiber material can have one or more directed portions. In the directed portion at least a predominant part of the carbon fibers exhibits a provided preferred direction. The preferred direction can be set according to a functional dependence on the location within the carrier. The preferred direction corresponds to the longitudinal direction of the carbon fibers. The directed portions in combination form the predominant part of all carbon fibers in the carrier material, in particular over 90% of all carbon fibers. The average length of the carbon fibers is advantageously greater than 1 mm in order to make an alignment easier. As used herein “Carbon fibers” means all fibers with a carbon content over 90%, advantageously over 95% for graphite fibers. By the metallization the carbon fibers are provided with the metal directly or by one or more bonding layers around the fibers (for example made from a carbide creator). The carbon fibers are advantageously wetted by the metal.
In an embodiment of the invention the directed portion is aligned toward the emission layer. A high heat dissipation away from the emission layer in the longitudinal direction of the carbon fibers can be achieved by the alignment of the carbon fibers of the directed portion relative to the emission layer, making use of the high heat conductivity of the carbon fibers in their longitudinal direction. A heat conductivity of the carrier material can be achieved that is greater than that of a highly heat-conductive metal (for example copper). The directed portion is appropriately directed parallel to the rotation axis, so a good heat dissipation can be achieved in a rotary anode and in an anode of a rotary piston radiator.
The metallization of the carbon fiber material can be achieved in a simple manner when the carbon fiber material is impregnated (saturated) with metal. Moreover, the metal can be distributed particularly homogeneously in the carbon fiber material. A highly heat-conductive metal (for example copper or silver) as well as a highly heat-conductive metal alloy are suitable as a metal. Since carbon fibers can only be wetted with metal with difficulty, it is advantageous to add an additive metal that supports wetting (in particular cobalt or a carbide creator) to the highly heat-conductive metal or the metal alloy. It is likewise advantageous when the carbon fibers are externally provided with an activation layer, for example made from a metal carbide such as Mo, W and/or Cr carbide, or an etcher such as, for example, cobalt.
In a further embodiment of the invention the carbon fiber material is composed of at least one first carbon fiber type and a second carbon fiber type different from the first. A higher degree of freedom can be achieved in the adjustment of the coefficient of heat expansion in connection with a high heat conductivity and mechanical stability of the x-ray anode.
The first carbon fiber type is characterized by a higher heat conductivity relative to the second carbon fiber type, and the second carbon fiber type is characterized by a higher mechanical stability (and therewith a lower brittleness) relative to the first carbon fiber type. One task can be assigned to each type, so the tasks can be resolved substantially independently by the two carbon fiber types. The heat conductivity of the first carbon fiber type is appropriately at least 400 Wm−1K−1 in the fiber direction. The second carbon fiber type should have a high tensile strength and be less sensitive to brittleness and notching than the first carbon fiber type. It can be designed arbitrarily with regard to its heat conductivity.
The different properties of the carbon fibers in the longitudinal direction and in the radial direction can be utilized particularly well when the carbon fiber material exhibits two portions aligned in different preferred directions relative to one another. A predominant portion of each of the two carbon fiber types is appropriately aligned in a preferred direction and the preferred directions of the two portions are different from one another. Direction-related properties and type properties of the carbon fibers can be used separate from one another to adjust desired properties of the carrier material. The goal of achieving high stability is appropriately associated with one of the types and the goal to achieve the desired coefficient of heat expansion in the provided direction is assigned to the other type.
Due to the low coefficient of heat expansion in the longitudinal direction of the fibers in relation to the coefficient of heat expansion in the radial direction, the alignment of the carbon fibers of the coefficient of heat expansion of the carrier can be set in a direction-related manner via the alignment of the carbon fibers. Given a definition of an arbitrary reference direction, for example parallel to a rotation axis of the x-ray anode, a heat expansion of the carrier in the reference direction is smallest when the carbon fibers are aligned parallel to the reference direction. By an angling of the carbon fibers away from the parallel direction, the heat expansion in the reference direction becomes greater and greater the further that the carbon fibers are angled. If the carbon fibers are arranged tangential to the reference direction, the heat expansion in the reference direction is greatest.
A carrier with aligned carbon fibers whose alignment is tilted at a desired angle relative to a reference direction, for example relative to the rotation axis of the x-ray anode and (appropriately) additionally relative to a radial direction of the x-ray anode can be produced in a simple manner when the portion that is directed around the reference direction is arranged as a rolled mat. The mat thus can be arranged in tube form, for example along the radial outer periphery of the carrier, or appropriately exists radially in a rolled-up mat form from the inside outwards. After arranging the mat in this manner, it can be provided with metal, for example encapsulated (cast) with metal.
The x-ray anode exhibits a rotation axis, and the directed portion of the carbon fiber material is aligned in a helical track around the rotation axis. This arrangement can be produced particularly simply by the mat arrangement described above. The directed portion is advantageously at least predominantly formed from carbon fibers of the second carbon fiber type. For this purpose it is sufficient when a number of carbon fibers in combination form the helical track.
A high stability of the carrier can be achieved by a further directed portion, with the two directed portions being aligned in two helical tracks running counter to one another around the rotation axis. The carbon fibers of the two directed portions thus form a mesh.
In a further preferred embodiment of the invention the carrier has a first carbon fiber-containing layer lying nearest to the emission layer and a carbon fiber-containing layer further removed from the emission layer. The first layer contains a lesser proportion of carbon fiber than the second layer. In the first layer, to support a high heat conductivity, a least a portion of mechanically reinforced carbon fibers can be foregone in order to quickly dissipate as much heat as possible from the emission layer. For example, the first layer contains fewer carbon fibers of the second type than the second layer or no carbon fibers of the second type, but rather only carbon fibers of the first type aligned toward the emission layer.
A particularly resilient bonding of the carrier with the emission layer can be achieved when the carrier material is cast on the emission layer. The metal impregnating the carbon fiber material is preferably as a solder that bonds the carrier material with the emission layer, so the manufacturing can be kept simple. The soldering process can be simple and reliable due to an additive metal promoting the soldering process. For the intended wetting, it is particularly advantageous for the employed metal to chemically dissolve both in carbon and in the solder.
A thermally resilient and durable bonding of the carrier with the emission layer is achieved when the carrier material exhibits a coefficient of expansion adapted to the emission layer in the radial direction. Such an adaptation is realized when the coefficients of expansion of the emission layer and of the carrier material maximally differ by 1×10−6/° K in the radial direction.
The carbon fibers are divided into two carbon fiber types that differ in terms of their properties. The type 1 is characterized by a high heat conductivity in the axial direction. The type 2 shows a large coefficient of heat expansion in the radial direction and its carbon fibers are less sensitive to brittleness and scoring than the carbon fibers of the type 1. The heat conductivity of the type 2 in the axial direction is less than that of the type 1 and essentially plays no role. Some properties at room temperature are, in detail:
The carbon fibers in the portion 22 are exclusively carbon fibers of the type 1 and are aligned parallel to the rotation axis 8 and thus towards the emission layer 3. The task to dissipate as much heat as possible from the emission layer 4 per unit of time is assigned to them. The carbon fibers of the portions 24, 26, 28, 30 are exclusively carbon fibers of the type 2 to which the task is assigned to ensure a desired coefficient of heat expansion in the radial direction 34 (
To explain the alignments,
Due to the large difference of the coefficient of heat expansion of the carbon fibers of the type 2 in the axial and radial direction of the carbon fibers, the coefficient of heat expansion of the carrier material in the radial direction of the x-ray anode 2 can be adjusted within predetermined limits, dependent on the helical angles α1, α2 of the carbon fibers of the portions 24, 26, 28, 30, and be adapted to the coefficient of heat expansion of the emission layer 4 or another layer. The coefficient of heat expansion of the carrier material in the radial direction of the x-ray anode 2 is hereby additionally dependent on the quantity of the carbon fibers of the portions 22, 24, 26, 28, 30 relative to the quantity of the metal surrounding the carbon fibers. In the exemplary embodiment shown in
To achieve a particularly good head dissipation from the emission layer 4, the carrier 6 is provided with a first carbon fiber-containing layer 42 situated next to the emission layer 4, under which first carbon fiber-containing layer 42 is arranged a second carbon fiber-containing layer 44 further removed from the emission layer 4, which second carbon fiber-containing layer 44 exhibits a higher carbon fiber proportion than the first layer 42. The carbon fibers of the type 2 imparting mechanical stability and setting the coefficient of heat expansion are reduced in the upper layer 42 so that the heat conductivity can ensue there undisturbed by the carbon fibers of the portion 22 and the metal.
During an x-ray operation electrons are accelerated from a cathode (not shown) onto the x-ray anode 2 and strike (as indicated by an arrow 46) in a radial outer region of the x-ray anode 2 on the emission layer 4. During this the x-ray anode 2 rotates with a frequency of 250 Hz around the rotation axis 8. By the rotation the electrons strike on a focal ring of the emission layer 4 that lies above the outer ring 18. In the focal ring x-ray radiation and a large amount of heat are generated by braking processes, which heat heats the emission layer 4. The heat is transferred through the thin end wall 16 to the carrier material of the outer ring 18 and is primarily conducted away from the emission layer 4 by the carbon fibers of the portion 22 that are parallel to the rotation axis 8. This emission layer 4 expands due to the heating of the emission layer 4. The carbon fibers of the portions 22, 24, 26, 28, 30 are thus selected in terms of quantity and arrangement such that the carrier material exhibits a coefficient of heat expansion adapted to the emission layer 4 in the radial direction, which coefficient of heat expansion is equal to that of the emission layer 4 in a range of 0.5×0−6/° K. The carbon fibers of the portions 24, 26 additionally provide for a mechanical stability that protects the x-ray anode 2 from out-of-balances even at high rotation speeds. Since the carbon fibers do not creep up to a temperature of 2200° C., a long-term stability is provided with regard to the geometry and an out-of-balance development is countered. The quantities of the carbon fibers of the portions 24, 26 relative to the portions 28, 30 can be varied depending on the requirement for heat expansion and mechanical stability.
To produce the x-ray anode 2, the core 10 is centered in the housing 12 so that an annular interstice is formed between core 10 and outer wall 14. A plurality of layers of carbon fiber material 20 in tissue or meshwork form are subsequently applied on the outer wall 14 and on the core 10, which layers form the portions 24, 26 and a part of the portion 22. The carbon fibers that form the portions 28, 30 and the further part of the portion 22 can then be placed inside in a loose meshwork. The carbon fibers can be inserted as tissue or meshwork mats in which the carbon fibers are already arranged in the desired preferred directions 36, 38, 40. A number of mats differing from one another are placed inside one another in alternation in order to form the meshwork with the helical tracks running opposite one another. To make wetting of the carbon fibers with metal easier, these are coated with Cr carbide, W carbide or Mo carbide or a combination of at least two of these carbides or with cobalt.
After completion of the meshwork, this is impregnated with a metal with very good heat conductivity, for example copper or silver. The metal now metalizing the current deflector 20 hereby serves as a solder to bond the carrier material with the end wall 16 of the housing 12 on which the emission layer 4 is applied. As an alternative or for further improvement of the wetting, the metal can be provided with a slight alloying of an additive metal that is a carbide creator and/or improves the bonding with the carbon fibers or the carbides and the soldering process with the end wall 16. To avoid voids (hollow spaces) in the carrier material, the carrier material is isostatically pressed with the liquid metal while hot.
To produce the x-ray anode 48, the emission layer 4 is provided with a metallic layer 58 that acts as a solder given a casting of metal 60 that should saturate the carbon fiber material 56. The carbon fiber material 56 made from two mats wound expanding in the radial direction is applied on this layer 58 with, if applicable, a preliminary auxiliary housing. The mats respectively comprise a layer made from carbon fibers of the portion 22 aligned in the axial direction in the carrier 50, which carbon fibers are aligned with a helical angle α1, α2 of respectively 19° relative to the tangential direction 34. Given a rolling of both mats, a repeating layer series of four layers results, namely a layer with portion 22, a layer with helically-arranged carbon fibers of the portion 52, again a layer with portion 22 and a layer with carbon fibers of the portion 54 arranged helically in the opposite direction, such that the carbon fibers of the portions 52, 54 form a mesh in helical form running in opposite directions. The carbon fibers can be coated with a carbide or metal and are subsequently saturated with the metal 60 as described with regard to
Although modifications and changes may be suggested by those skilled in the art, it is the intention of the inventor to embody within the patent warranted hereon all changes and modifications as reasonably and properly come within the scope of his contribution to the art.
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