RU2195739C2 - X-ray tube anode - Google Patents

Abstract

FIELD: medical diagnostics and therapy, non- destructive tests and research work, inspection of materials. SUBSTANCE: anode has target and base. Target-base interface in vicinity of electron beam action with plane crossing electron beam axis is proposed to be made in the form of ellipse whose half-axes are to be chosen so that target-base interface represented isotherm with temperature not over that of base for maximal power of X-ray tube. EFFECT: enhanced service life and loading capacity of tube anode. 5 cl, 2 dwg

Description

 The invention relates to the field of X-ray technology, and more particularly to anodes of X-ray tubes (RT), and can be used in medicine for diagnosis and therapy, in technical devices for non-destructive testing of products and scientific research for X-ray analysis of materials.

 The main problem in the operation of anodes of X-ray tubes is the formation of cracks in the focal track due to the significant unevenness of its heating, as well as due to the difference in thermal expansion coefficients (CTE) of the materials of the anode base and its target. This leads to a decrease in the power of x-ray radiation and, as a consequence, to a decrease in the resource of the anode.

 A rotating anode of an X-ray tube is known in which, to prevent cracking of the target, a large number of slots are formed on its surface symmetrically with respect to the axis of symmetry of the anode (EPO Application No. 0323365, p. 30.12.88, op. 05.07.89, MKI H 01 J 35 / 10).

 However, the known design still does not allow to sufficiently get rid of the stresses arising in the target. In addition, with such a design, the power of the X-ray tube is proportional to the area of the slits in the target, and this design is also difficult to manufacture.

 A stationary anode of an X-ray tube is known in which the anode base has a peripheral wall with end surfaces located opposite each other, where a groove with an upward and deflecting wall is made in order to improve contact between the target and the base (EPO Patent No. 0709873, p. 27.10. 95 g., Published on 05/01/96, MKI H 01 J 35/08).

 The disadvantage of this design is the destruction of the metal materials of the target and the base in the zone of influence of the electron beam at high operating powers, due to the mismatch of the KTP of the target and base materials, as well as due to the significant non-uniformity of the heating of the anode.

 The authors' task is to increase the service life, increase the load capacity of the anode.

 To solve this problem, the authors propose in the anode of the x-ray tube, consisting of a base and a target, the interface between the target and the base in the zone of influence of the electron beam in the section of the plane passing through the axis of the electron beam, to perform in the form of an ellipse, with the semi-axis of the ellipse chosen so that the boundary between the target and the base was an isotherm with a temperature value not exceeding the allowable base temperature for the maximum power of the x-ray tube. The anode of the x-ray tube can be made stationary, and the interface between the target and the base is made in the form of an ellipsoid. The anode can be made rotating, and the section plane passing through the axis of the electron beam passes through the axis of rotation of the anode. The target and / or base can be made single-crystal. The target can be made two-layer, and the material of the layer exposed to the electron beam has a greater yield strength than the material of the layer adjacent to the base.

 Implementation of the interface between the target and the base in the form of an ellipse in cross section by a plane passing through the axis of the electron beam allows one to reduce stresses in the target caused by the difference in the CTE of the base and target materials. This is because, with this form, the boundaries of the influence of various components of the stress tensor on the stress state of the target cancel each other out. For example, when the KTE of the base material exceeds the target material, the radial stresses in the target are tensile, and axial stresses are compressive. The reduction of stresses in the target allows to increase the load capacity of the anode in comparison with the prototype.

 When the interface is an isotherm, a uniform temperature distribution also reduces stresses in the area of this boundary, which ensures that the target-base contact is better than the prototype, thereby increasing the anode resource.

 The calculated and experimental data obtained by the authors showed that the shape of the isothermal interface between the target and the base in cross section by a plane passing through the axis of the electron beam is close to an ellipse. The implementation of the border in the form of an isotherm with a temperature value not exceeding the allowable base temperature for the maximum power of the x-ray tube allows the anode to be used in all passport modes of the x-ray tube and, in addition, saves expensive target material (in the given analogue and prototype, the radius of the target relative to the center of the electron beam significantly exceeds the same radius in the proposed anode).

 For a particular anode of an X-ray tube, the semi-axis of the ellipse is determined by calculating, for example, by the finite element method, the temperature field of the anode in the maximum power mode taking into account the geometric dimensions of the anode, the properties of materials depending on temperature, the power of the X-ray tube, and the size of the focal spot.

 The data obtained by the authors show that, in the case of a stationary anode, the execution of the interface between the target and the base in the form of an ellipsoid allows one to obtain a decrease in the maximum temperature (if the thermal conductivity of the base exceeds the corresponding coefficient of the target) and a significant decrease in the voltage level in the zone of influence of the electron beam and the boundary between the target and the base. In the case of a rotating anode, a similar effect allows one to make the interface between the target and the base in the form of an ellipse in cross section by a plane passing through both the axis of the electron beam and the axis of rotation of the anode.

 The execution of the target and / or the base single-crystal, as shown by experimental calculations, allows you to increase the permissible operating temperature of the anode due to an increase in the temperature of recrystallization of the layers of the base and the target, as well as a significant reduction in the interdiffusion of the substrate and target materials. Monocrystalline refractory metal has greater ductility and strength than polycrystalline, which allows to increase the resource of the anodes. In addition, single-crystal material has a higher thermal conductivity than polycrystalline, and an increase in thermal conductivity of the target material and / or the adjacent layer provides better cooling of the focal track of the anode.

 The implementation of the target layer adjacent to the base of the material, the yield strength of which is less than the yield strength of the material of the target layer exposed to the electron beam, can reduce the plastic deformation of the target that occurs during uneven heating during operation of the anode. The plastic deformation of the target on the surface irradiated by electrons is reduced due to plastic deformation of the target layer adjacent to the base.

 Choosing the optimal values of the semiaxes of the ellipse in the cross section at the interface between the target and the base, as shown by calculation and experimental studies, it is possible, for given operating modes of the x-ray tube, to avoid overheating of the focal track zone and the zone of connection of the substrate layers, in addition, to select the minimum target thickness, which leads to a simplification of the manufacture of the anode and a decrease in its cost due to the lower consumption of target material.

 Figure 1 shows a stationary anode, figure 2 - a rotating anode, where: 1 - the base, 2 - the target, 3 - the electron beam, 4 - the axis of the rotating anode; a - semi-axis of the ellipse in depth, b - radial axis.

 Examples of specific performance.

1. The basis for the stationary anode is made of copper with a diameter of 14 mm, a height in the central part of 5 mm, with an inclination angle of the working surface of 20 ^o . In the central part of the working surface, a depression is made in the form of an ellipsoid with a semiaxis of 0.4 mm in depth and 0.643 mm in radius, then a tungsten target is applied from the vapor-gas phase into this depression. The diameter of the focal spot is 0.579 mm, the maximum operating power of the X-ray tube is 420 W (continuous mode), the anode end opposite the working surface is cooled with water. The permissible temperature of the copper base is 700 ^o C.

As the analysis of calculations performed by the finite element method showed, when operating such an anode, the maximum temperature is lower than the maximum temperature of the prototype of the same overall dimensions with a target thickness of 0.4 mm, a radius of 2 mm by 150 ^o C, the stress intensity in the center of the focal spot is less than the similar stress intensity of the prototype 3 times, the stress intensity at the interface between the target and the base is 40% lower than in the prototype.

2. The basis for the rotating anode of the x-ray tube is made of molybdenum, its diameter is 90 mm, the thickness of the central part is 5.5 mm, and the taper angle of the working surface is 16 ^o . On the focal track corresponding to the effective focus size of 1 • 1 mm, a toroidal groove is made having an ellipse in the radial section with semi-axes in the depth of 2.116 mm and in the radius of 1.2 mm. Then, a tungsten target is applied from the vapor-gas phase to the obtained depression. The maximum operating power of the anode is 40 kW (with an exposure of 0.1 s), the allowable substrate temperature was taken equal to 1500 ^o C.

 The stress intensity on the surface of the focal track of such an anode is ~ 26% lower than the corresponding stress intensity of a similar in overall dimensions anode with a tungsten coating thickness of 1.2 mm deposited on the entire conical surface; the stress intensity at the target-base interface in the focal track zone in the inventive anode is ~ 20% less than the corresponding intensity of the anode with the target deposited on the entire conical surface.

 The inventive design of the anode provides in comparison with the prototype increased load capacity and service life of the x-ray tube.

Claims (5)

 1. The anode of the x-ray tube, consisting of a base and a target, characterized in that the interface between the target and the base in the zone of influence of the electron beam in section by a plane passing through the axis of the electron beam is made in the form of an ellipse, while the semiaxes of the ellipse are chosen so that the boundary The separation of the target and the base is an isotherm with a temperature value not exceeding the allowable temperature of the base for the maximum power of the x-ray tube.  2. The anode of the x-ray tube according to claim 1, characterized in that the anode is stationary, and the interface is made in the form of an ellipsoid.  3. The anode of the x-ray tube according to claim 1, characterized in that the anode is made rotating, wherein the section plane passing through the axis of the electron beam passes through the axis of rotation of the anode.  4. The anode of the x-ray tube according to claim 1, characterized in that the target and / or the base are single-crystal.  5. The anode of the x-ray tube according to claim 1, characterized in that the target is two-layer, and the material of the layer exposed to the electron beam has a greater yield strength than the material of the layer adjacent to the base.

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