RU49625U1 - DEVICE FOR RADIOGRAPHY AND TOMOGRAPHY - Google Patents

Abstract

The utility model relates to the study of the internal structure of objects, namely to the analysis of objects by radiation methods, for example using neutron, x-ray or gamma radiation. The technical result of the utility model is to increase spatial resolution, expand functionality, register various types of penetrating radiation: fast neutrons, and / or thermal neutrons, and / or x-rays and gamma rays. The technical result is achieved by the fact that in the device for radiography and tomography, the luminescent screen is made in the form of a plate, on the surface of which there is a three-lens condenser lens. The optical radiation registration system contains a sequentially located input projection lens, an image amplifier, a zoom lens, and a CCD matrix. The means of moving the investigated object is made with the possibility of reciprocating and rotational motion. The source of conical penetrating radiation is made in the form of a neutron generator.

Description

The utility model relates to the study of the internal structure of objects, namely to the analysis of objects by radiation methods, for example using neutron, x-ray or gamma radiation.

Known devices for radiography and tomography of the internal structure of objects in which the studied object is illuminated by a diverging x-ray beam and a shadow image of the internal structure of the object under study is obtained on the corresponding display system.

Klyuev V.V. et al. Industrial radiation introscopy. M. Energoatomizdat, 1985, p. 5-8.

The disadvantage of these devices using a diverging beam is low sensitivity to small-sized details of the internal structure of the object (defects, inclusions).

A well-known technical solution is a device for studying the internal structure of objects, for obtaining shadow projections of the cross sections of the studied object by scanning it with a collimated x-ray beam, recording the radiation transmitted through the object by the detector.

UK patent No. 1283915, IPC: G 01 N 23/08, 1975

In this device, the obtained spatial resolution in shadow projections is determined by the dimensions of the collimated beam and / or detector in the scanning direction, i.e. if there are small details of the structure in the studied object, the latter may not be detected in the resulting shadow projection.

The disadvantages of the known technical solutions are that precisely collimated beams relative to the object are moved to obtain shadow images.

This leads to a complication of the overall design, to increased requirements for radiation protection, to the possibility of gaps in the control of the object due to sudden movements of the emitter, as well as low efficiency of the use of radiation from the source, an increase in the study time, and the need for collimating the beam.

A device for small angle tomography is known, which contains a source of penetrating radiation, a collimator that generates a radiation flux incident on the object in the form of low-diverging beams, means for moving the object relative to the radiation incident on it, a spatial filter, and a detector.

Patent of the Russian Federation No. 2119659, IPC: G 01 N 23/02, 1998. The device has a complex kinematic structure for identifying a diverging beam after the object under study.

A device for radiography and tomography containing a source of penetrating radiation, a means of moving the studied object, an optical radiation registration system containing a scintillation screen, a flat mirror, a lens, a photodetector (TV camera) and a correction lens.

Patent of the Russian Federation No. 2189031, IPC: G 01 N 23/04, 2002. Prototype.

The prototype has a sophisticated optical imaging system, relatively low image clarity and sensitivity.

This utility model eliminates the disadvantages of analogues and prototype.

The utility model is aimed at increasing the efficiency of using fast neutrons, reducing the exposure time, reducing the influence of the background signal, improving the quality of received

images, increasing the productivity of the process, obtaining images not only in the neutron flux, but also in x-ray and gamma radiation.

The technical result of the utility model is to increase spatial resolution, expand functionality, register various types of penetrating radiation: fast neutrons, and / or thermal neutrons, and / or x-rays and gamma rays.

The technical result is achieved by the fact that in a device for radiography and tomography containing a source of penetrating radiation, a means of moving the object under study, an optical radiation recording system with a luminescent screen, a mirror, a lens, a photodetector and a lens, the luminescent screen is made in the form of a plate, on the surface of which is located a lens in the form of a condenser, an optical radiation registration system contains a sequentially located input projection lens, image intensifier, zoom The inhibitory lens, a photodetector constructed as a CCD - array conical penetrating radiation source is located at a point on the normal to the center of the screen of the luminescent converter, and means for moving the object under study is capable of reciprocating and rotary motion.

Luminescent optically transparent screen - the converter is made in the form of a plate of luminescent polystyrene or of a material sensitive to x-ray and gamma radiation, or of luminescent polystyrene with the addition of boron. The capacitor is made three-lens.

The source of conical penetrating radiation is made in the form of a neutron generator.

The essence of the utility model is illustrated in the drawing.

A schematic representation of a device for radiography and tomography with a conical beam, penetrating radiation, where:

1 - source of fast neutrons (neutron generator), 2 - screen converter, 3 - condenser, 4 - deflecting mirror, 5 - input lens, 6 - image intensifier, 7 - scaling lens, 8 - CCD - matrix, 9 - diaphragm, 10 - means of moving the investigated object, made with the possibility of reciprocating and rotational motion.

In the case of a conical beam, the three-lens condenser 3 and the diaphragm 9 allow only light rays that propagate in the transducer screen 2 in the direction of the rays emitted by the source of the conical beam 1 to pass through the optical system.

The capacitor 3 is calculated in the approximation of a point source of ionizing radiation for a given distance between the fast neutron source 1 and the transducer screen 2, as well as between the transducer screen 2 and the input lens 5, taking into account the refractive index of the material of the transformer screen 2 and its radiation spectrum, as well as the coefficient refraction of condenser material 3.

The capacitor 3 is designed to maintain spatial resolution in the case of a conical neutron beam.

When the screen of the transducer 2 is irradiated with a beam of fast neutrons, the neutron radiation is converted into light radiation. In this case, the geometric extensions of all light tracks converge to a point that coincides with the position of the neutron source 1.

The fast neutron source 1 is located at a point lying normal to the center of the luminescent screen of the transducer 2.

The test sample is installed on the vehicle 10, between the source 1 and the screen transducer 2. In the screen transducer, the types of radiation that penetrate the sample are converted into optical radiation.

To obtain a set of projection data for tomography, a radiographic stand was used. The means of movement 10 for the sample provides a set of projection radiographic images at various angular positions relative to the axis of the beam (in the General case, in the range from 0-360 °). Changing the angular position of the sample is carried out using a stepper motor.

The measurement of the angular position and its control is carried out using a sine-cosine rotary transformer (SCWT). When registering fast neutrons, the screen transducer 2 is made of luminescent polystyrene.

When registering thermal neutrons, the screen transducer 2 is made of luminescent polystyrene with boron additives.

When registering x-ray and gamma radiation, it is made of transparent scintillators designed to detect these types of radiation: germanium tungstate, yttrium garnet, etc.

The registration efficiency is provided by the length of the screen transducer 2 along the direction of radiation propagation.

Each radiation beam passing through the sample creates a rectilinear track in the screen transducer 2 during the exposure time, the points of which emit a spherically isotropic light flux.

In this case, the geometric extensions of all light tracks converge to a point that coincides with the position of the neutron source 1.

For a screen converter 2 of finite thickness, projection optics in the absence of a condenser 3 depicts a line in the form of a dash, the length of which is proportional, on the one hand, to the tangent of the off-axis angle, at which the track is visible from the center of the lens, and, on the other hand, to the thickness of the converter screen 2, which leads to a loss of spatial resolution in the peripheral zones of the receiver.

In order to prevent this from happening in the described receiver, after the screen-converter 2 and a lens condenser 3 is installed. Its purpose is to construct in the center of the input aperture (pupil) of the input projection lens 5 an image of the point at which the screen tracks intersect.

The input aperture in this case plays the role of a diaphragm 9, preventing the passage of light rays propagating in directions that do not pass through the fast neutron source 1.

In addition, the input aperture determines the amount of light passing through the input projection lens 5.

In the case of an ideal point source of fast neutrons 1, each track will be displayed on a CCD - matrix 8 in the form of a spot of sufficiently small size and proportional to the aperture ratio of the input projection lens 5.

In the case of a fast neutron source 1, the capacitor 3 is calculated on the basis that the distance from the fluorescent screen - transducer 2 to the neutron source 1 is 500 mm, and the fluorescent screen - transducer 2 with a diameter of 200 mm and a thickness of 100 mm is made of luminescent polystyrene.

The total length of the detector is 1170 mm. The process of data accumulation is automated.

Claims (4)

1. A device for radiography and tomography, containing a source of penetrating radiation, a means of moving the object under study, an optical radiation registration system containing a luminescent converter screen, a flat mirror, a lens, a photodetector and a lens, characterized in that the luminescent converter screen is made in the form of a plate , on the surface of which there is a lens in the form of a condenser, and the optical radiation registration system with a flat mirror contains a projection object in series a telescope, an image intensifier, a zoom lens and a photodetector made in the form of a CCD matrix, a source of penetrating radiation with a conical beam is located at a point lying normal to the center of the luminescent screen-converter, the means for moving the object under study are made with the possibility of reciprocating and rotational motion . 2. The device for radiography and tomography according to claim 1, characterized in that the luminescent screen transformer is made in the form of a plate of luminescent polystyrene or of a material sensitive to x-ray and gamma radiation, or of luminescent polystyrene with the addition of boron. 3. The device for radiography and tomography according to claim 1 or 2, characterized in that the condenser is made of a three-lens. 4. The device for radiography and tomography according to claim 1, characterized in that the source of the conical penetrating radiation is made in the form of a neutron generator.