RU2548585C1 - Mobile radiographic system and betatron-type radiation source for radiographic system - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: radiographic system for imaging fast processes in a test object comprises at least one radiographic multi-pulse radiation source with a corresponding recording system, which includes at least one movable unit with a small-size radiation source and an explosion-proof chamber in which the test object is placed, wherein components of the system can change their arrangement. The radiation source comprises a betatron, a device for emitting an electron beam towards a target and an injector, which consists of an electron beam pulse former, a voltage multiplier, arranged according to the Arkadyev-Marx scheme, and an electron beam guiding device, wherein the electron current pulse former used is a double forming line, and the voltage multiplier is selected small-size by using electrical energy storages in the form of compact capacitors with high density of stored energy.

EFFECT: high illuminating power and resolution of the system, reduced measurement error.

4 cl, 1 dwg

Description

The invention relates to the field of pulsed x-ray technology, in particular to methods and devices for obtaining images of fast-moving, in particular, explosive, processes in optically opaque objects of research, and can be used in radiography of dynamic objects of large optical thickness.

Known radiographic complex - installation DARHT [1, article "Confirmation of the operation of ammunition without nuclear tests" by Harold Davis, DARHT project, April 2008, LA-UR-08-04937]. The DARHT installation is a two-axis radiographic setup for hydrodynamic testing, which allows you to receive radiographic images in the process of hydrodynamic testing, otherwise called "hydrotest". The DARHT setup, with its two registration axes, allows one to obtain four images on one axis and a separate image along the orthogonal axis in sequence, over a short period of time, which gives a total of 5 images of the object of study.

The main element of the DARHT installation is two linear accelerators located at an angle of 90 degrees relative to each other with an output energy of 17.5 MeV and 20 MeV, respectively, and a current in the accelerator beam of 2.1 kA, divided by 4 pulses, and 1.9 kA, respectively. The main systems of accelerators are the injector and accelerating cells. Accelerating cells with a diameter of 0.6 m and 2 m in the amount of 64 and 74, respectively, for each axis determine the size of the accelerators, the length of which is about 100 meters. All tests at this installation are carried out using an explosion-proof chamber (VZK), inside which is the object of study. The installation also uses collimators, and registrars collect information in the form of images of the studied objects.

The disadvantages of this radiographic complex include stationarity, the large size of the complex, including due to the dimensions of the irradiating sources (accelerators), the need to build special protective structures for it, and the large financial costs for the construction and operation of this complex. In addition, this DARHT setup is limited to five images of the object of study in a single experiment.

Closest to the claimed invention is a radiographic (in particular, X-ray) installation for obtaining an image of a fast-moving process [2, RF patent for utility model 87810, 10/20/2009], which implements a method for recording a radiographic image of fast-moving processes in heterogeneous objects of research, which consists in providing radiography areas of the object of study with different optical thicknesses in their respective different energy ranges. This installation is essentially a radiographic complex.

The radiographic complex contains the main BIM x-ray source (betatron type radiation source) [3, report "UNCORED BETATRON BIM-M A SOURSE OF BREMSSTRAHLUNG FOR FLASH RADIOGRAPHY" Yu.P. Kuropatkin, V.D. Mironenko, V.N. Suvorov, D.I. Zenkov. B.F. Tkachenko PULSE POWER Conference 1998. St. Petersburg, pp. 1669-1673], forming a radiation pulse with a duration substantially shorter than the duration of the recorded process. BIM consists of a betatron proper, an electron beam dumping device on the target, and an injector, which includes a 12-stage voltage multiplier assembled according to the Arkadyev-Marx scheme based on 0.1 μF capacitors and sizes 460 × 155 × 330 mm, a pulse shaper electron beam, consisting of a single forming line and sequentially located behind it a transmission line, and an electronic beam wiring device. The radiation source is connected with its life support systems.

The dimensions of the stationary platform on which the BIM is assembled is 7 × 3 m. In addition, the complex contains at least one additional source of x-ray radiation with a different energy spectrum from the main one, which differs from the above by at least an order of magnitude in boundary energy. The energy ranges of the sources are set in accordance with the optical thickness of the denser region of the object of study and less dense. Opposite the radiation sources behind the research object located on a stationary base, the corresponding registration systems are installed. The radiation sources are spatially separated with the possibility of obtaining images in different angles without overlapping the energy ranges of radiation from sources. The X-ray unit is equipped with a radiation source synchronization system and collimators.

The disadvantages include the large size of the radiation sources, the stationarity of such an installation. For its operation, the construction of special protective structures is necessary. The minimum distance from the radiation source to the object of study is strictly fixed and is about 5 meters. When conducting explosive experiments, problems arise in protecting the environment. In addition, the registrars are located in a special explosion-proof structure, the thickness of which helps to increase the distance from the object of study to the registrar and, as a result, weaken the shadow image on the radiograph of the object and reduce the information content of the experiment. The maximum number of images that can be obtained using this setting is 7.

The creation of a mobile radiographic complex will allow us to quickly, with the least financial and labor costs, increase the intensity at the research point by at least 2 ÷ 2.5 times, which will provide better radiography of the areas of the research object with large optical thicknesses and increase the information content of the experiment. In addition, it will allow optimizing the geometry of the experiment by changing the position of the radiation source and the registrar relative to the object of study, and together with the choice of the necessary energy range of the radiation source, it will allow radiography of the areas of the object of study with different optical thicknesses.

The technical result when creating the complex is to increase the translucent at least 2 ÷ 2.5 times and the resolution of the claimed complex, while reducing the measurement error, without harming the environment, by ensuring its mobility during the experiments.

In addition, the inventive complex allows you to increase the number of images compared to the prototype.

The technical result for the radiation source is to ensure its small size for the purpose of use as part of a mobile radiographic complex.

The technical result for the radiographic complex is achieved due to the fact that, in contrast to the known radiographic complex for obtaining images of fast processes in the research object, containing at least one radiographic multi-pulse radiation source with its corresponding registration system, the proposed complex includes at least one mobile module with a small-sized radiation source and an explosion-proof chamber with the object of study located in it, When in use, the components of the complex are arranged to change the mutual position.

The technical result for a betatron type radiation source as part of a radiographic complex is achieved due to the fact that, in contrast to the known betatron type radiation source containing a betatron, the electron beam dumping device on the target and the injector, consisting of an electron beam pulse shaper, a voltage multiplier assembled from the Arkadyev-Marx circuit, and the electron beam wiring device, in the proposed source, the double forming line serves as an electron beam pulse shaper and the voltage multiplier is selected small due to the use of capacitors as compact energy storage devices with compact dimensions and high density of stored energy.

In addition, in the radiographic complex, the experiment can be optimized by changing the geometry of the experiment by ensuring the mobility of the components of the complex, which will achieve a higher radiation intensity at the point of study with an increase in resolution and a decrease in measurement error.

In addition, in a radiographic complex, autonomy of a small-sized radiation source can be ensured when using an autonomous power source.

The physical basis of the claimed invention is as follows. In the prototype, the minimum distance from the radiation source to the object of study is strictly fixed and is 5 meters. This value depends on the wall thickness of the protective structure where the radiation source is located, on the assembly structure of the object of study and on the power of the explosive device used in the experiment. As you know, the radiation intensity is inversely proportional to the square of the distance from the radiation source.

In contrast to the prototype, in the claimed invention, the minimum distance from the radiation source to the object of study placed in the OCC, due to the mobility realized through the use of at least one mobile module with a small radiation source, will be about 1 meter. At the same time, using an IBD with an object of study located in it will make it possible to bring the recorder closer to the object. There is no need for a protective structure for registrars, which allows them to be brought closer to the object of study.

By reducing the distance from the radiation source to the object of study, the radiation intensity at the point of the object of study will grow at least 2 ÷ 2.5 times and, as a result, the transmitting ability of the claimed complex will increase. At the same time, by reducing the distance from the object of study to the registrar, the contrast of the shadow image on the radiogram of the object will also increase. Optimization of the geometry of the experiment by the position of the radiation source and the registrar relative to the object of study will provide better radiograms of the areas of the object of study with large optical thicknesses, will increase the resolution, as well as reduce the measurement error.

Such a complex with one radiation source is capable of generating up to three pulses and, accordingly, obtaining up to three images of the object of study in one experiment. Depending on the number of radiation sources of the complex, the maximum number of images of the object of study in one experiment will be a multiple of three.

The use of IBDs to place the object of study during explosive experiments is associated with environmental protection requirements. The camera localizes all hazardous materials, which makes the proposed approach to solving the problem favorable from an environmental point of view. In addition, the localization of the consequences of the experiment with the object of study reduces the time intervals between experiments due to a significant reduction in the time required to clean the experimental area.

In the radiation source, the peculiarities of its implementation in comparison with the prototype in terms of the electron beam shaper are due to the fact that replacing the sequence of a single generating and transmitting lines forming a shaper, which is structurally a system of two consecutive cylindrical capacitors, by a double forming line, structurally which is a system of two concentric cylindrical capacitors, leads to a reduction in the dimensions of the shaper. In the part concerning the voltage multiplier, the replacement of the pulse voltage generator (multiplier) according to the prototype with a small generator (multiplier) due to the use of capacitors with small (compact) sizes, but with a high density of stored energy, as well as due to the original design multiplier will also lead to a decrease in its dimensions. The overall result is a reduction in the size of the injector and, accordingly, the radiation source. The proposed changes in the radiation source will make it possible to use it as part of a mobile radiographic complex.

In FIG. schematically depicts a mobile radiographic complex for obtaining images of fast processes in an explosive x-ray experiment.

As an example of the specific implementation of FIG. depicts a mobile radiographic complex where 1, 2 - mobile vans based on trailers MA3-5224V; 3 - extendable platform; 4 - the folding wall of a van 1; 5 - small-sized source of hard x-ray radiation of the BIM type (according to the prototype - the main source); 6 - capacitor bank; 7 - technological equipment; 8 - explosion-proof chamber (VZK); 9 - object of study; 10 - collimators; 11 - image recorder.

A small-sized BIM radiation source containing the betatron proper, an electron beam reset device on the target and an injector, which includes an electron beam pulse shaper, a voltage multiplier assembled according to the Arkadyev-Marx scheme, and an electron beam wiring device [4, RF Patent for the invention 2356193, 05/20/2009] with life support systems of composite units of the radiation source differs from the main source according to the prototype in that a double forming line is used as a shaper, and multiply the voltage tester is taken small-sized [5. RF patent for the invention 2317637, 02.20.2008], where the original design of the layout of the elements is used, and KMK capacitors 100-0.017 with a capacity of 0.017 μF and compact dimensions of 245 × 120 × 85 mm with a high energy storage density of 45 were selected as electric energy storage % more than in the prototype. This parameter depends on the ratio of the electric capacitance of the capacitor to its geometric volume. The larger this value, the higher the density of the stored energy of the capacitor. Thus, the improvement of the injector design in terms of the use of a double forming line as an electron beam shaper and as a pulse voltage generator (multiplier) of the proposed type of multiplier made it possible to substantially reduce by approximately 3 times the overall dimensions of the radiation source compared to with a prototype, which made it possible to reduce the size of the platform on which the betatron installation (BIM) is assembled, and use as part of The claimed complex is a mobile module with a small-sized radiation source.

In the implementation of the physical experiment, mobile vans (1, 2) and VZK (8) with the object of study (9) are placed on the experimental site. Before the experiment, the wall (4) of the van (1) is tilted to a horizontal position and mounted on the adjustable supports included in the van. On this horizontal surface, which serves as the base, a platform (3) extends along its guides with a small-sized radiation source (5) placed on it at the required distance from the SCZ (8). A collimator system (10) is located in the immediate vicinity of the VZK. Images of the object of study are recorded by means of a registration system (11). In van 2 there is a betatron switching capacitor bank (6) and technological equipment (7). Management, control, reception and processing of data from a physical experiment is carried out from a stationary or mobile control panel. Vans (1, 2) and the control panel are connected by detachable cable lines. The primary source of electrical power for the mobile radiographic complex can be both a stationary power grid and a mobile stand-alone power supply, which will make the complex fully autonomous. One explosion-proof chamber can be served by several mobile radiographic radiation sources.

Thus, the technical result when creating the complex is to increase the translucent at least 2 ÷ 2.5 times and the resolution of the claimed complex, while reducing the measurement error, without harming the environment, ensuring its mobility due to the small size of the components during the experiments.

In addition, the maximum number of images of the object of study in one experiment is multiplied by the number of mobile radiographic radiation sources of the complex and is a multiple of three.

Claims (4)

1. Radiographic complex for obtaining images of fast processes in the object of study, containing at least one radiographic multi-pulse radiation source with its corresponding registration system, characterized in that the complex includes at least one mobile module with a small-sized radiation source and explosion-proof camera with the object of research located in it, established with the possibility of changing the relative position. 2. The radiographic complex according to claim 1, characterized in that the experiment is optimized by changing the geometry of the experiment. 3. The radiographic complex according to claim 1, characterized in that the small-sized radiation source is autonomous. 4. A radiation source containing a betatron, a device for dumping an electron beam onto a target and an injector, consisting of an electron beam pulse shaper, a voltage multiplier assembled according to the Arkadyev-Marx scheme, and an electron beam wiring device, characterized in that the electron beam pulse shaper is double the forming line, and the voltage multiplier is selected small due to the use of capacitors with compact dimensions and high density Sai energy.