RU2515053C1 - Method of obtaining radiographic image of fast processes in inhomogeneous test object and radiographic system for realising said method - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: method of obtaining a radiographic image of fast processes in an inhomogeneous test object involves radiography of regions of the test object with different optical thicknesses in corresponding different energy ranges, wherein the method involves spatial-time tomography of the test object, facilitated by at least three beams with independent spatial coordinates which converge at the centre of the location of the test object.

EFFECT: high information content of radiography of fast processes in an inhomogeneous test object.

3 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 processes in optically opaque objects of study, and can be used in radiography of multi-density dynamic objects of large optical thickness in order to increase the information content of radiography.

A known method of obtaining x-ray images of a fast-moving process [1, ZhTF journal, 1957, v. 27, No. 2, p. 43-57]. The method consists in irradiating the object of study with pulsed x-ray radiation of a certain energy range, followed by obtaining a shadow image of the recorded fast-moving process. A device for obtaining x-ray images of a fast process [1] that implements this method. This two-electrode pulsed x-ray tube consists of an anode in the form of a rod of small diameter with an end sharpened under a cone, a cylindrical hollow cathode coaxially located with the anode and removed from it at some distance along the axis. The tube serves as a source of x-ray radiation, providing the formation of a radiation pulse with a duration substantially shorter than the duration of the recorded process. Opposite the X-ray tube, a shadow image registration system is installed behind the object of study.

A consequence of the disadvantages of the method and device is a decrease in the sharpness of x-ray images from the periphery to the center, a decrease in the contrast of the image of objects with low density, which makes it impossible to obtain reliable information about the fast-moving process for objects with different optical thicknesses.

Closest to the claimed invention is a radiographic (in particular, X-ray) installation for acquiring an image of a fast-moving process [2, RF patent for utility model 87810 dated 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 setup contains a main x-ray source that generates a radiation pulse with a duration substantially shorter than the duration of the recorded process, and at least one additional x-ray source with an energy spectral range different 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 object of study, the corresponding registration systems are installed. The radiation sources are spatially spaced 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 of the installation include the low informativeness of x-ray to study the object of study, obtaining an image of the object in no more than three ways.

The creation of the claimed radiographic complex will allow us to start solving the problem of restoring the density distribution of the material in the object of study on the basis of shadow radiograms, without resorting to assumptions about the symmetry of the object.

The technical result when creating the complex is to significantly increase the information content of radiography by illuminating the object at different angles in three coordinate projections and at different points in time.

This technical result is achieved due to the fact that, in contrast to the known method for obtaining a radiographic image of fast processes in an inhomogeneous research object, consisting in providing radiography of areas of the research object with different optical thicknesses in different energy ranges corresponding to them, the spatially temporal tomography of the object is carried out in the proposed method research.

This technical result is achieved due to the fact that, in contrast to the known radiographic complex for obtaining images of fast processes in an inhomogeneous research object, containing time-synchronized radiographic radiation sources that provide radiography of the areas of the research object with different optical thicknesses in different energy ranges corresponding to them, with the corresponding registration systems, in the proposed complex, radiation sources were installed at least in two planes with their location in each of the planes around the projection of the object of research on this plane. A pair of sources in one plane and one source in another plane form a triple of rays with independent spatial coordinates, converging in the center of the object under study.

In addition, the radiographic complex may differ in that the radiation sources are multipulse.

The physical basis of the proposed approach is as follows. In the prototype, each image obtained reflects the two-dimensional nature of the distribution of material in the research object and limits the information picture when registering a fast-moving process, which is due to the peculiarity of the location of the radiation sources relative to the research object. To restore the density distribution of the material in the object of research with a certain degree of certainty, complex mathematical calculations based on assumptions about the symmetry of the object of study are required.

In the proposed technical solution, for the first time when registering fast processes in different-density areas of the object of study, the following was proposed - conditions should be created for obtaining shadow images from different angles in a 3-dimensional dimension in order to provide spatio-temporal tomography. This will significantly increase the information content of the measurements.

In the claimed case, this is ensured by the fact that the spatial arrangement of the radiation sources in at least two planes with their location in each of the planes around the projection of the research object on this plane made it possible to increase, compared with the prototype, at least 6 the number of radiation sources in each from planes and to qualitatively expand the foreshortening range of radiography and, as a result, significantly increase the information content of experimental studies.

The inclusion of radiation sources can be both simultaneous (synchronous) and different at the same time, which will allow you to get an image of the object in different angles and at different points in time, and the multipulse sources will allow you to get an image of the object in each angle at different points in time.

The radiation sources can be either the same or different, providing radiography of different areas of the object of study in their respective different energy ranges, in accordance with the goals and objectives of experimental research.

In FIG. A promising radiographic complex is depicted for obtaining images of fast-moving processes in an explosive x-ray experiment. Here, for clarity, we have taken the option with heterogeneous radiation sources that differ in the energy spectral range of x-ray radiation (according to the prototype, the main sources and additional sources), where 1 are sources of hard X-ray radiation of the BIM type, 2 are sources of soft X-ray radiation, 3 is explosion-proof camera (VZK), 4 - object of study, 5 - registration system, 6 - plane location of sources.

In this radiographic complex, radiation sources are installed in two planes with their location in each of 5 betatrons of the BIM type [3, Pavlovsky AI, Kuleshov GD, Sklizkov GV, Zysin Yu.A., Gerasimov A. AND. High-current iron-free betatrons // DAN SSSR. 1965.V. 160. No. 1. P.68.] And one source of soft x-ray radiation around the projection of the object of study on these planes.

To implement the proposed registration method with reduced sizes of radiation sources, in comparison with the prototype, in the inventive radiographic complex, it is necessary to introduce restrictions on the dimensions of the radiation sources while maintaining their maximum attainable parameters. This is possible in the current case when using small-sized sources of x-ray radiation (1), the creation of which was carried out on the basis of BIM [3]. The use of such a radiation source as a component emitter module will allow for the most efficient placement of, for example, 12 time-synchronized radiation sources in two horizontal planes (6 on each) with their location in 5 types of small-sized BIM [3] and one soft x-ray source radiation (2) in each of the planes around the projection of the object of research on these planes, BIM-type sources are multipulse. With this arrangement, the distance from the small-sized BIM type radiation source to the object (4) will be 3 meters. The assembly is quite compact in the area where the BIM-type radiation sources are located; the diameter with the service area will be about 20 meters. The use of such a number of small-sized betatrons of the BIM type in combination with a single source of soft x-ray radiation will increase by an order of magnitude, in comparison with the prototype, the number of information quanta in the experiment. In FIG. a variant with a horizontal arrangement of the explosion-proof chamber (3) with the object of study (4) is presented, but a variant with a vertical arrangement of the air-borne explosive device is also possible.

In the described experimental design, the inventive method is implemented, consisting in the implementation of spatio-temporal tomography of the object of study. It is implemented as follows.

After the inclusion of 12 radiation sources located at 6 in each plane of time-synchronized sources (1, 2), aimed at the object of study, the object of research (4) is irradiated from different angles. The result of irradiation is obtaining, taking into account the possibility of three-frame registration from one main source, up to 32 radiographic images on the respective registrars of radiation (5), which allow reflecting a 3-dimensional dynamic picture of the fast-moving process occurring in the object of study. Mathematical processing will restore the dynamic picture of the processes occurring in the object of study.

Thus, the radiographic complex, which includes radiation sources that provide radiography of the areas of the object of study with different optical thicknesses in the various energy ranges corresponding to them, for example, a BIM and a source of soft x-ray radiation, which are installed in at least two planes with their location in each of the planes around the projection of the research object on these planes (in particular, 5 BIM and 1 source of soft x-ray radiation on each plane i), where a pair of sources in one plane and one source in another plane form a triple of rays with independent spatial coordinates, converging in the center of the object under study, and taking into account the possibility of three-frame recording from each main radiation source, it will allow up to 32 images of the fast-moving process, which will significantly increase the information content of radiographic (radiographic) studies.

Claims (3)

1. A method of obtaining a radiographic image of fast processes in a heterogeneous object of research, which consists in providing radiography of the areas of the object of study with different optical thicknesses in their respective different energy ranges, characterized in that they perform spatio-temporal tomography of the object of study, provided by at least three rays with independent spatial coordinates converging in the center of the object of study. 2. A radiographic complex for obtaining images of fast-moving processes in an inhomogeneous object of study, containing radiographic radiation sources that provide radiography of the areas of the object of study with different optical thicknesses in their respective different energy ranges, with their corresponding recording systems, characterized in that the radiation sources are installed, according to in at least two planes with their location in each of the planes around the projection of the object of study n and this plane, and the radiation sources used so that a pair of sources in one plane and one source in another plane provided the formation of a triple of rays with independent spatial coordinates, converging in the center of the object under study. 3. The radiographic complex according to claim 2, characterized in that the radiation sources are multipulse.