RU2754863C1 - X-ray radiation source - Google Patents

Abstract

FIELD: medical equipment.SUBSTANCE: invention relates to X-ray tubes with a rotating anode on a hydrodynamic support and can be used for X-ray apparatuses of a wide profile with high radiation power. The X-ray radiation source is comprised of a sealed vacuum chamber with an outlet window for the emergence of the X-ray beam, a cathode unit, a rotating hollow anode unit with a disk-shaped rotor on the peripheral part whereof a target is placed. A stationary liquid heat exchanger is placed inside the anode unit, a liquid metal lubricant from gallium or alloys thereof and a sealing apparatus are placed in the cavity between the inner surface of the rotor of the anode and the outer surface of the stationary heat exchanger. The sealing apparatus consists of two coaxial rings, wherein the inner ring is located on the outer surface of the heat exchanger and the outer one is located on the inner surface of the rotor of the anode, wherein the rings of the sealing apparatus are made either of materials inert to gallium or alloys thereof and not wetted by liquid metal. An annular capillary channel is located between the rings of the sealing apparatus.EFFECT: increased continuous operation time and power of the X-ray radiation source, increased operating resource, stability of operation and protection of the internal surfaces of the X-ray radiation source from chemical interaction with active liquid metals, increased reliability and simplified design.2 cl, 2 dwg

Description

The invention relates to X-ray tubes with a rotating anode on a hydrodynamic support and can be used for a wide-profile X-ray apparatus with high-power radiation.

Known X-ray tube containing a vacuum flask and placed inside it a cathode and anode. The cathode emitter and anode are made of refractory material. The rotating anode is connected to the vacuum flask by means of a ball bearing support (Patent RU 2377686, 04/29/2008, MKI H01J 35/04).

The disadvantage of the known device is the limitation of the power due to the limited heat capacity of the rotating disk anode. There is practically no possibility of heat dissipation to the outside of the vacuum bulb through the bearing support due to the low efficiency of heat transfer through the ball bearing support. In addition, the presence of ball bearing supports introduces radial and axial beats of the rotating rotor, which violates the geometric stability of the focal track, which, with micron dimensions of the focus, reduces the technical characteristics of the X-ray tube.

Known X-ray tube containing a rotating anode, made in the form of an inverted bowl, which is partially immersed in a bath with fusible metal and rests on a bearing mounted on a support cooled by a refrigerant (USSR author's certificate No. 531218, class H 01J 35/10, 1974) ...

The structural diagram of the known technical solution assumes the presence of a stationary system for pumping out the X-ray tube, since the presence of Teflon seals in the vacuum vessel excludes the technological operation of high-temperature degassing of the X-ray tube to achieve a high vacuum in it before the operation of filling the tube with liquid metal of the coolant. In addition, the sealing rings on the rotating anode do not provide complete sealing of the inner cavity of the anode and the vacuum cavity with the cathodes, which leads to the penetration of liquid metal particles into the vacuum container, the deposition of metal particles on the high-voltage insulators of the X-ray tube, a decrease in the electrical insulation characteristics of the insulators and subsequent high-voltage breakdown, and tube failure. The presence of a stationary pumping system complicates and increases the cost of the X-ray system. The use of incomplete filling of the anode volume with liquid metal, the presence of blades and a central bearing support lead to the occurrence of radial and axial beats during the rotation of the anode, which, in turn, leads to defocusing of the X-ray tube and a decrease in its technical characteristics. In addition, the structural scheme of cooling the anode of this X-ray tube excludes the possibility of any spatial positioning during use, which also reduces the performance of the X-ray tube.

The closest in technical essence and the achieved positive effect to the claimed invention is an X-ray source containing a sealed vacuum chamber with an exit window for the output of the X-ray beam, a cathode assembly, a rotating hollow anode assembly with a disk-shaped rotor, on the peripheral part of which a liquid metal target is placed and placed inside the anode unit of a stationary liquid heat exchanger, liquid metal lubricant made of gallium or its alloys, placed in the cavity between the inner surface of the anode rotor and the outer surface of the stationary heat exchanger and a sealing device between them (Patent RU 2709183, 04/26/2019, IPC H01J 35/00) ...

One of the disadvantages of the known device, taken as a prototype, is the presence of a liquid metal target formed by centrifugal force during the rotation of the anode. Since one of the objectives of the invention is to increase the power of the X-ray source, this implies a decrease in the size of the focal spot, an increase in the density of electrons in the electron beam and an increase in the accelerating voltage. When the size of the focal spot is less than 50 μm, overheating of the liquid metal of the anode will occur in the focal track, its intense evaporation and the ejection of microdroplets (clusters) into the cavity of the vacuum chamber. The effect of hydrodynamic impact of a high-energy electron beam on the surface of a heated liquid mirror of the target with the formation of a cavity will also manifest itself, which at high anode speeds will lead to the formation of a focal groove on the surface of the target. This will lead to a change in the "electron beam - target" optical system and, consequently, to a distortion of the X-ray radiation flux. Cooling in the vacuum space of the evaporated particles of the liquid metal target of the anode leads to their deposition not only on the protective CNT membrane, but also on the surface of the high-voltage insulator of the X-ray source, which entails a decrease in the electrical insulation characteristics of the insulator, its subsequent high-voltage breakdown and the failure of the X-ray source. Particles of the metal of a liquid metal target deposited on the anode can cause contamination of the X-ray spectrum of the X-ray tube with lines of foreign elements. Released metal vapors are ionized by both an electron beam and an electric field of an accelerating voltage, which leads to the formation of a space charge in the cathode region and a high-voltage breakdown of the interelectrode space between the cathode and the anode or the space between the cathode and the high-voltage insulator. In addition, the device is characterized by a high inertness in operation, since its shutdown requires gradual cooling of the liquid metal target until it becomes solid while maintaining high anode revolutions. In addition, a labyrinth seal made in the form of annular grooves of a labyrinth seal for retaining a liquid-metal lubricant in the gap between the inner surface of the anode and the outer surface of the radiator does not work effectively, since the throttling phenomenon is incorporated in the operation of the labyrinth seal, i.e. reduction of gas consumption due to the loss of kinetic energy of the flow during sudden gas expansion. Since the metal in the lubricant is liquid and does not expand, the labyrinth seal does not work. This leads to the ingress of the liquid metal of the lubricant into the vacuum cavity and, together with the vapors and particles of the liquid target, to a deterioration of the vacuum and deposition on the surface of the high-voltage insulator. This negative phenomenon excludes the design of the tap-off version of the X-ray source and, in order to reduce the negative effect of vacuum contamination by metal vapors, forces the use of a stationary high-vacuum pumping system, which complicates and increases the cost of the X-ray source and excludes its use in non-stationary conditions. Leakage of liquid-metal lubricant leads to deterioration of the conditions for heat transfer from the anode to the liquid heat-transfer agent of the heat exchanger, jamming of the rotating anode and the failure of the X-ray source. Also in the known invention there is a negative moment, which consists in the fact that the liquid metal target is formed in the form of a layer of molten metal belonging to the group of Sn, Li, In, Ga, Pb, Bi and their alloys, on the surface of the annular trough of the rotating anode node. Gallium and its alloys are highly corrosive metals, especially when heated, interacting with almost all metals. This can lead to deformation or destruction of the annular groove of the anode, as well as the ingress of products of chemical reactions into the vacuum volume, which will also lead to failure of the X-ray source.

The problem to be solved by the present invention is to increase the time of continuous operation and power of the X-ray source by optimizing its design and thermodynamic cooling processes, increasing the working life and stability of work by increasing the time of maintaining high vacuum and electrical insulating characteristics of the high-voltage insulator, protecting internal surfaces of the X-ray source from chemical interaction with active liquid metals, increasing the reliability and simplifying the design.

1. An X-ray source containing a sealed vacuum chamber with an exit window for the exit of the X-ray beam, a cathode unit, a rotating hollow anode unit with a disk-shaped rotor, on the peripheral part of which a target is located, and a stationary liquid heat exchanger located inside the anode unit, liquid metal lubricant made of gallium or its alloys located in the cavity between the inner surface of the anode rotor and the outer surface of the stationary heat exchanger and a sealing device between them, characterized in that the target is made of solid metal in the form of a ring of appropriate shape, the rotating anode and the heat exchanger are made of a material inert to gallium or its alloys, or the inner surface of the anode rotor and the outer surface of the stationary heat exchanger are provided with a protective film coating chemically resistant to gallium or its alloys.

2. An X-ray source according to claim 1, characterized in that the sealing device consists of two coaxial rings, the inner ring being located on the outer surface of the heat exchanger, and the outer ring on the inner surface of the anode rotor, while the rings of the sealing device are made either of inert materials to gallium or its alloys and at the same time not wetted by liquid metal, or from materials inert to gallium or its alloys, but covered with a film that is not wetted by liquid metal.

, где3. X-ray source according to PP. 1-2, characterized in that an annular capillary channel is placed between the rings of the sealing device, and the length of the capillary channel is selected from the ratio: H ≥ 4.4

, where

σ is the coefficient of surface tension of the liquid metal of the lubricant;

θ is the angle of wetting of the capillary channel wall with liquid metal;

ρ is the density of the liquid metal;

g is the acceleration of gravity;

b is the thickness of the annular capillary channel.

FIG. 1 is a schematic perspective view of an X-ray source, FIG. 2 shows the sealing device.

The X-ray source contains a sealed vacuum chamber 1, an exit window 2 transmitting X-rays 3, a cathode assembly 4 generating an electron flow 5, a rotating anode assembly 6 consisting of a rotor 7, a target 8, an electric motor shaft 9 and an inner sealing ring 10. Inner sealing ring 10 made of materials inert to gallium or its alloys and, at the same time, not wetted by liquid metal, for example, from graphite, or from materials inert to gallium or its alloys, but covered with a film not wetted by liquid metal, for example, quartz glass coated with gallium oxide (Ga ₂ O ₃ ). Inside the rotating anode unit is a stationary liquid heat exchanger 11 with an inlet 12 and an outlet 13 for supplying a liquid heat carrier 14 and an external sealing ring 15. The rotor 7 and heat exchanger 11 are made of a material inert to gallium or its alloys, for example, from tungsten, or internal the surface of the rotor 7 and the outer surface of the stationary heat exchanger 11 are provided with a protective film coating chemically resistant to gallium or its alloys, such as tungsten. The outer sealing ring 15 is made of materials inert to gallium or its alloys and, at the same time, not wetted by liquid metal, for example, from graphite, or from materials inert to gallium or its alloys, but covered with a film not wetted by liquid metal, for example, quartz glass coated with oxide gallium (Ga ₂ O ₃ ). The direction of movement of the heat transfer fluid is shown by arrows in FIG. 1. Outside the vacuum chamber 1 there is a stator 16. Between the inner surface of the rotor 7 and the outer surface of the stationary heat exchanger 11 is a liquid-metal lubricant 17. The inner surface of the rotor 7 and the outer surface of the stationary heat exchanger 11, in contact with the liquid-metal lubricant 17, are provided with protective layers 18 and 19, for example from tungsten (see Fig. 2). An annular capillary channel of length H and height b is placed between the outer sealing ring 15 and the inner sealing ring 10, and the rings are provided with non-wetting layers 20 and 21, for example, of gallium oxide (Ga ₂ O ₃ ).

Example. A powerful tap-type X-ray source has been developed, in which the rotor 7 and the heat exchanger 11 are made of oxygen-free copper. Anode 8 is made of tungsten. Running water is used as a heat transfer fluid 14 to cool the heat exchanger 11. For the liquid metal lubricant, the galinstan alloy was chosen, consisting of 68.5% gallium (Ga), 21.5% indium (In) and 10% tin (Sn). The melting point of the alloy is - 19 ° C, the boiling point is more than 1300 ° C, which significantly exceeds the melting point of copper and allows you to increase the thermal power of the X-ray source. Thus, under normal operating conditions of the X-ray source, the alloy is in a liquid state. Liquid-metal grease in the proposed device is used not only as a working fluid of a liquid friction bearing during the rotation of the anode, but also as an intermediate heat carrier for transferring excess heat from the hot anode 8 to the circulating water 14 of the heat exchanger 11. The inner surface of the copper rotor 7 and the outer surface of the copper stationary heat exchanger 11, in contact with liquid metal lubricant 17 are equipped with protective layers 18 and 19 made of tungsten and have a thickness of 5 ÷ 8 microns, which in the operating temperature range excludes the negative impact of high chemical activity of gallium to copper. Since gallium and its alloys have an extremely low saturated vapor pressure of the order of 10 ^-6 Pa, this, accordingly, makes it possible to use it in electric vacuum devices with a vacuum of at least 10 ^-6 Pa. The outer sealing ring 15 and the inner sealing ring 10 are made of quartz glass and covered with non-wetting layers 20 and 21 of gallium oxide (Ga ₂ O ₃ ) with a thickness of 1 ÷ 3 microns. This makes it possible to exclude leakage of liquid metal lubricant into the vacuum cavity of the X-ray source, contamination of the high-voltage insulator and internal surfaces, and jamming of the anode rotating at a high speed.

Thus, the present invention makes it possible to significantly increase the continuous operation time and power of the X-ray source by optimizing its design and thermodynamic cooling processes, to increase the working life and stability of operation by increasing the time of maintaining high vacuum and electrical insulation characteristics of the high-voltage insulator, protecting the inner surfaces of the X-ray source. radiation from chemical interaction with active liquid metals, increasing the reliability and simplifying the design.

The proposed device is intended for a number of applications, including materials science, X-ray technical diagnostics, biomedical and medical diagnostics, microscopy.

Claims (4)

1. An X-ray source containing a sealed vacuum chamber with an exit window for the exit of the X-ray beam, a cathode unit, a rotating hollow anode unit with a disk-shaped rotor, on the peripheral part of which a target is located, and a stationary liquid heat exchanger located inside the anode unit, liquid metal lubricant made of gallium or its alloys, placed in a cavity between the inner surface of the anode rotor and the outer surface of the stationary heat exchanger, and a sealing device between them, and the rotating anode and the heat exchanger are made of a material inert to gallium or its alloys, or the inner surface of the anode rotor and the outer surface the stationary heat exchanger is equipped with a protective film coating chemically resistant to gallium or its alloys, characterized in that the sealing device consists of two coaxial rings, with the inner ring located on the outer surface of the heat exchanger, and the outer one on the inner surface the surface of the anode rotor, while the rings of the sealing device are made either from materials inert to gallium or its alloys and at the same time not wetted by liquid metal (hydrophobic), or from materials inert to gallium or its alloys, but covered with a film inert to gallium and not wetted by liquid metal, while an annular capillary channel is placed between the rings of the sealing device, and the length of the capillary channel is selected from the ratio: H ≥ 4.4

, where σ is the coefficient of surface tension of the liquid metal of the lubricant; θ is the angle of wetting of the capillary channel wall with liquid metal; ρ is the density of the liquid metal; g is the acceleration of gravity; b is the thickness of the annular capillary channel. 2. The X-ray source according to claim 1, characterized in that the inner surface of the anode rotor and the outer surface of the stationary heat exchanger are made hydrophobic to gallium and its alloys.

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