RU2384912C1 - Pulsed x-ray tube - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to pulsed X-ray tubes with explosive emission, designed for use in small X-ray devices for detecting defects in metal structures, as well as detecting high-speed processes with development time of the order of 10^-9 -10^-8 s. The pulsed X-ray tube has a metal casing in form of a cylindrical cup, a window joined to the casing for outlet of X-rays made from a metal with gas absorbing properties, a target placed in the casing at a distance from the window, and an insulating element with a cathode. The casing of the tube is made from a metal with high thermal conductivity, for example copper. The target is placed on the inner surface of the bottom of the cylindrical cup and the window is made in form of a spherical segment or a hemisphere whose edges encircle the bottom of the cylindrical cup.

EFFECT: high durability with good X-ray parametres.

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Description

The invention relates to pulsed X-ray tubes with explosive emission, intended for use in small-sized X-ray apparatus for defectoscopy of metal structures, as well as for recording fast processes with a development time of about 10 ^-9 -10 ^-8 s.

Known sharp-focus pulsed x-ray tube, consisting of a cathode, including a washer made of heat-resistant dielectric, on which there is a comb formed by a metal washer having radial slots diverging from the center, with an inner diameter larger than the inner diameter of the dielectric washer, an anode for braking electron beam and the generation of x-ray radiation, made in the form of a rod ending in a conical surface, the top of which has the shape of a hemisphere and passes is mounted along the axis of the hole of the dielectric washer so that the end of the anode protrudes beyond the plane of the dielectric washer on which the comb is mounted, at a distance h = r, where r is the radius of the hemisphere, current lead for supplying a high pulse voltage, and a sealed housing made of insulating material, with a window for outputting x-ray radiation [RF Patent No. 2174726, H01J 35/00, H05G 1/02, 10/10/2001].

Such a design makes it possible to ensure spatial uniformity of radiation, its stable repetition from pulse to pulse, which is achieved by a variety of electron sources, evenly spaced around the circumference at the points of contact of the metal teeth of the comb with a dielectric washer, where a high electric field intensity arises when voltage is applied, which causes a discharge micro-gaps between the metal and the dielectric. The disadvantage of this X-ray tube is its short life when working in pulsed devices for defectoscopy of metal structures with a deterioration in X-ray characteristics during operation (the focal spot increases and the radiation intensity decreases). This is due to the lack of good heat dissipation from the anode, since the X-ray tube is made in a metal-glass design and all metal parts except the anode and cathode are made of precision alloy (29NK), which has the same coefficient of linear thermal expansion (KLTE) with glass, with very low thermal conductivity (20 times less than copper). Therefore, during prolonged operation, a strong overheating of the anode is observed, which enhances the erosion of the anode material and thereby worsens the X-ray parameters of the device. This design has a getter that works inefficiently because of its low temperature, since it is installed far from the discharge gap in the low-temperature region of the device, and the high temperature of the anode due to the low thermal conductivity of the materials used is not transmitted to the getter. In addition, the x-ray tube has large overall dimensions that do not allow it to be matched with elements of a high-pulse pulse generator with a subnanosecond front, which significantly reduces the output x-ray characteristics.

Known pulsed x-ray tube containing a metal case with a wide target of a metal atom with a large atomic number located on the inner surface of the window for outputting x-ray radiation, a cathode and an insulating element of glass in the form of a hollow truncated cone, the base of which is soldered to the body [E. Alexandrovich G.V., Belkin N.V., Kanunov M.A., Razin A.A. Small-sized pulsed x-ray tube with a self-healing auto-cathode. Sat Physics and technology of pulsed sources of ionizing radiation for the study of fast processes. / Ed. Makeeva N.G. - Sarov, VNIIEF, 1996, p.251].

This X-ray tube has a high impedance (100-200 Ohms) due to the relatively large dimensions of the interelectrode gap. It has found application in pulsed X-ray machines of the Arinam, Peony series and others for radiography of metal structures with a thickness of not more than 20 mm. With an increase in the average power in the x-ray tube, overheating occurs and, as a result, malfunctions up to the through burn through of its shell due to overheating of the target, which has close contact with the shell window. The durability of such an X-ray tube is limited and depends on the mode of its operation. In this x-ray tube, as in the previous case, the issue of heat removal from the target having close contact with the sheath (window) of the device is not resolved. Since the design of the x-ray tube is made in a metal-glass design, the shell is made of a precision alloy having a CTE, almost the same as glass, and a low thermal conductivity. In addition, in the x-ray tube due to gas evolution during operation, the vacuum deteriorates, which also reduces the service life and worsens the x-ray parameters.

Closest to the proposed invention is a pulsed X-ray tube containing a metal housing in the form of a cylindrical glass, a window for outputting X-ray radiation connected to the housing, made of a material having the properties of a getter, a target located in the housing at a distance from the window, and an internal insulating element with cathode [RF Patent No. 2160480, H01J 35/00, H01J 35/02, H05G 1/02, 12/10/2000 - prototype].

The specified X-ray tube, which has a low impedance due to the small overall dimensions, is used in medicine for intracavitary irradiation with soft X-ray radiation with a quantum energy of 50-100 keV. The disadvantages of such an X-ray tube include: a low service life due to poor heat removal from the anode and inefficient getter operation, a small opening angle of the X-ray radiation pattern, since the body of the X-ray tube closes its focus, and the window is far from the target and has the shape of a plane. The window of the x-ray tube is made of a material having the properties of a getter (titanium). However, as a result of the fact that the window is separated from the target by a material with low thermal conductivity, the window temperature is insufficient to ensure effective gas absorption during operation of the device. This drawback limits longevity and degrades X-ray performance.

The objective of the invention is to provide a pulsed x-ray tube with high durability while providing high x-ray parameters.

The specified technical result is achieved in that in a known pulsed X-ray tube containing a metal body in the form of a cylindrical glass, a window for outputting X-ray radiation connected to the body made of metal having the properties of a getter, a target located in the body at a distance from the window, and insulating an element with a cathode, the housing is made of metal with high thermal conductivity, such as copper, while the target is located on the inner surface of the bottom of the cylindrical glass, and the window configured as a ball or a hemisphere, the edge of which covers the bottom of the cylindrical cup.

Increased durability with high X-ray performance in this design of a pulsed X-ray tube is achieved by significantly improving heat removal from the target, which reduces erosion of the target material by providing tight contact of the target with a body made of metal with high thermal conductivity, such as copper, as well as by increasing the efficiency of gas absorption during operation by providing a contact window made of a material having the properties of gas lottery, with the most heated part of the body, contributing to the rapid heating of the getter material, and the choice of the shape of the window in the form of a spherical segment or hemisphere, significantly increasing the getter area.

In addition, the location of the target inside the spherical segment or hemisphere increases the opening of the radiation pattern and creates a more uniform spatial distribution of radiation intensity.

The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information, made it possible to establish that no analogue was found, characterized by features identical to all the essential features of the claimed invention. Comparison with the prototype allowed us to identify a set of essential features in relation to the perceived technical result set forth in the claims.

Therefore, the claimed invention meets the requirement of "novelty" under the current law.

To check the inventive step, an additional search was carried out for known solutions, the results of which show that the claimed invention does not explicitly follow from the prior art for a specialist, since technical solutions have not been identified in which the durability of a pulsed X-ray tube would be increased by manufacturing its body made in the form of a cylindrical cup made of a material with high thermal conductivity, such as copper, the location of the target on the inner surface of the bottom of the cylindrical Tacanas execution window and for outputting X-radiation as a ball or a hemisphere, the edge of which covers the bottom of the cylindrical cup.

Therefore, the claimed invention meets the requirement of "inventive step" under applicable law.

The claimed invention is illustrated in the drawing.

The drawing shows one of the options proposed pulsed x-ray tube.

A pulsed x-ray tube (see drawing) contains a metal case 1 in the form of a cylindrical cup made of copper, on the bottom 2 of which a target 3 is fixed on the inside of the tube axis, which is an anode of a material with a large atomic number, for example, tantalum, cathode 4, made in in the form of a thin tube of material with a large atomic number, connected to the terminal 5 passing through an insulating element 6 in the form of a hollow truncated cone facing the inside of the metal housing 1, a window 7 for outputting x-ray radiation made of titanium in the form of a spherical segment, the edge of which covers the bottom 2 of the cylindrical cup of the housing 1. The upper base of the insulating element 6 is connected to the terminal 5, the lower one to the edge of the cylindrical cup of the housing 1. An axial hole is made in the terminal 5 for pumping the x-ray tube and a ram 8 is provided. After pumping out the x-ray tube to the required degree of vacuum, a cold otpang of the ram 8 is carried out, followed by fixation of the bite.

A pulsed x-ray tube operates as follows.

When a high-voltage voltage pulse is applied to cathode 4 (while anode 3 is grounded), a high electric field is created in the interelectrode space, which causes explosive emission of electrons from the micropoints of cathode 4 with the formation of a stream of electrons moving to anode 3 (target). In the collision of electrons with the target and their deceleration, x-ray radiation is generated. During the operation of the X-ray tube, the target is strongly heated. The manufacture of an x-ray tube body made of copper with high thermal conductivity reduces local heating of the target at its focus, which significantly reduces erosion of the target material and thereby increases durability.

The location of the window of the x-ray tube made of titanium, which is a good getter, on the case so that the edge of the window covers the bottom of the cylindrical cup with a target located on it, having a maximum heating temperature during operation, creates conditions for increasing the temperature of the getter window, increasing the efficiency of the gas absorption process , which also increases the durability of the x-ray tube.

When a window is made in the form of a spherical segment or a hemisphere, x-rays emanating from the focus pass through the window almost perpendicular to its surface and have almost the same attenuation in all directions of the aperture angle of the radiation pattern.

Based on the claimed invention, a pulsed x-ray tube IRTP-240 was developed. The X-ray tube was tested in a commercially available apparatus “Arina-7” at a tube voltage of U = 200 kV, a capacitance of C = 50 pF and a pulse frequency of f = 10 Hz. During 10 ⁷ pulses, the X-ray intensity measured by the Arina-7 apparatus after radiography of steel 45 mm thick and the focal spot remained practically unchanged and amounted to 70 mR and 2.5 mm, respectively. The resource of the X-ray tube IMA-5-320D is less than 10 ⁶ pulses, and the diameter of its focal spot changes during operation from 2.5 to 8 mm. The X-ray tube IMA-2-150D in this mode works for no more than 2 hours, since the X-ray tube is depressurized due to burning of the target with the shell by the electron beam. In addition, revealing the radiation pattern of the developed pulsed x-ray tube is wide enough (about 130 °) with almost the same level of x-ray radiation, which makes it possible for panoramic transmission of metal structures.

Tests of the developed pulsed X-ray tube showed that, compared with the commercially available X-ray tubes IMA-5-320D, IMA-2-150D, it has higher X-ray characteristics and also has an excess of the guaranteed minimum operating time by more than an order of magnitude.

Thus, the claimed technical solution allows you to create a pulsed x-ray tube with high durability and x-ray characteristics used in pulsed x-ray apparatus for defectoscopy and registration of fast processes with a time resolution of 10 ^-9 -10 ^-8 s.

Claims (1)

A pulsed x-ray tube containing a metal housing in the form of a cylindrical glass, a window for outputting x-ray radiation connected to the housing, made of metal having the properties of a getter, a target located in the housing at a distance from the window, and an insulating element with a cathode, characterized in that the housing made of metal with high thermal conductivity, such as copper, while the target is located on the inner surface of the bottom of the cylindrical glass, and the window is made in the form of a spherical segment or floor bowl, the bottom edge of which covers the cylindrical sleeve.