RU2502986C1 - Neutron radiography method - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: information on the structure and material composition of an illuminated object is obtained by processing primary beam attenuation data, from the ratio and number of neutrons scattered forward and back, as well as the spectrum of gamma radiation arising in the object.

EFFECT: wider field of use of radiographic inspection of the internal structure and identification of material composition of illuminated objects, reduced effect of scattered radiation and high image contrast, simple identification procedure.

1 dwg

Description

The invention relates to neutron radiography and can be used in installations intended for inspection or non-destructive testing of translucent objects with the determination of their internal structure and material composition.

Known x-ray method for determining the mass fractions of substances that make up the body under study. The method includes irradiating the medium at two energy levels, determining the value of the absorption coefficient for each pixel of the body under study and determining the mass fractions of substances entering the body. US patent 2009/0208084, 2009. The disadvantage of this method is the possibility of its use only for ternary media with a predetermined composition.

A known X-ray method for checking an object using multi-energy radiation.

The method includes the interaction of multi-energy radiation with the test object, measuring and recording the measured values after the interaction of multi-energy radiation with the test object, substituting part of the measured values in a predetermined calibration function to obtain information containing the main value of the object’s characteristics, and more accurately determining the characteristics of the material of the object by applying a set of functions suitable for the energy band corresponding to the obtained inf ments Patent of the Russian Federation No. 2351921, 2009. The disadvantage of the proposed method is the lack of a clear criterion that allows you to compare the functional dependence of the measured values of a particular material.

A known method for identifying materials by repeated radiographic irradiation of an object at a given set of energies is set for a variety of substances to be guaranteed identification, a possible error in finding attenuation coefficients is determined, for each energy level, and for each inclusion, using a computer program, a set of substances corresponding to the selected error is determined, after which the materials are identified. Patent of the Russian Federation No. 2426102, IPC: G01N 23/06, 2010

The disadvantage of this method is the ambiguity of identification, associated, in particular, with the fact that substances, especially explosives, may be composite and not contained in the database. In addition, the amount of radiation energy used is limited. So, when controlling aviation baggage, the radiation energy, basically, does not exceed 100 keV. Therefore, many identifiable substances are also limited.

The technical result of the invention is the expansion of the scope of radiographic control of the internal structure and identification of the material composition of translucent objects, reducing the effect of scattered radiation and increasing the contrast of the image, simplifying the identification procedure.

The technical result is achieved by the fact that in a neutron radiography method with a penetrating radiation source in the form of a neutron generator with an integrated position-sensitive alpha particle detector, information on the structure and material composition of the translucent object is obtained by processing data on the attenuation of the primary beam, by the ratio and number of neutrons, scattered back and forth, as well as the spectrum of gamma radiation that arises in the object, and for the separation of images in unscattered and scattered neutrons and use the ratio:

Δt = L / v _n -l / v _α , where:

Δt is the time interval between the moment of registration of an alpha particle and the moment of registration of a neutron flying out of the target in the opposite direction,

L is the distance between the target of the generator and the element of the neutron detector that detected the neutron,

v _n is the neutron velocity of the source,

l is the distance between the target of the generator 1 and the alpha detector element that registered the alpha particle and located on the opposite side with respect to the target of the generator 1 from the corresponding element of the neutron detector, v _α is the speed of the alpha particle.

The invention is illustrated in the drawing, which schematically shows a block diagram of a device for implementation, where: 1 - target neutron generator; 2 - position-sensitive alpha particle detector; 3 and 4 - linear single-axis fast neutron detectors located in the plane perpendicular to the plane of the figure; 5 - illuminated object (the arrow shows the direction of movement of the object), 6 - fan bundles of fast neutrons in a plane perpendicular to the plane of the figure, 7 - gamma spectrometer, 8 - computer unit with software, 9 - screen-collimator for detectors 3 from source neutrons .

Target 1 of the neutron generator is bombarded with a narrow deuteron beam. When a deuteron interacts with a tritium nucleus contained in the target of neutron generator 1, two particles emerge in opposite directions: a fast neutron and an alpha particle.

The moment of registration of an alpha particle by one of the elements of the position-sensitive detector of alpha particles 2 determines the moment and direction of departure of the fast neutron, as well as the elements of the neutron linear detector 4, one of which comes the neutron at a certain subsequent point in time if it passes through the translucent object 5 without interaction. Neutrons arriving at other points in time undergo scattering either in the translucent object 5 or in the elements of the setup.

A linear one-coordinate fast neutron detector 4 serves to simultaneously register neutrons transmitted without scattering, i.e. at certain points in time after registering an alpha particle at the corresponding element of the position-sensitive alpha detector 2, and for detecting neutrons scattered forward, if they arrive at the detector at other times.

Linear single-axis fast neutron detectors 3 mounted in front of the illuminated object 5 from the source side are used to obtain a radiographic image using neutrons scattered in the illuminated object 5 in the opposite direction. For this, the detectors 3 are shielded from the neutrons of the source, going directly using the screen-collimator 9, which also serves to collimate the neutrons emitted by the source. The gamma spectrometer 7 measures the spectrum of radiation resulting from the inelastic scattering of fast neutrons of the source.

When a radiographic image is obtained using unscattered neutrons, only scintillation events are recorded, which are accompanied by the registration of alpha particles arising in the alpha detector elements located on the opposite side with respect to the generator target at the time moments preceding the neutron event. The time difference between the moments of registration of a neutron and an alpha particle Δt is determined based on the alpha particle energy, the source neutron energy, the neutron emission direction and the distances from the generator target to the corresponding elements of the alpha detector and neutron detector:

Δt = L / v _n -l / v _α , where:

L is the distance between the target of the generator and the element of the neutron detector that detected the neutron,

v _n is the neutron velocity of the source,

l is the distance between the target of the generator 1 and the alpha detector element that registered the alpha particle and located on the opposite side with respect to the target of the generator 1 from the corresponding element of the neutron detector,

v _α is the alpha particle velocity.

If the registration of an alpha particle is accompanied by the registration of a neutron at other points in time, then this neutron is scattered. The number and ratio of neutrons scattered back and forth in a certain direction is determined by the material composition of the object in this direction. This is due to the fact that fast neutrons scatter forward on hydrogen, and practically isotropically on heavier elements.

To obtain radiographic data, the translucent object 5 is moved along the plane in which the linear single-axis fast neutron detectors 3 and 4 are located. When scanning, a data set is obtained showing:

spatial distribution of attenuation of the primary neutron beam, spatial distribution of neutrons scattered forward and backward, spatial distribution of chemical elemental composition.

These data are entered as input into a computer program designed to identify the material composition of object 5 in its various sections.

The complex use of 3 types of control increases the information content of the method, the reliability of identification of the material composition of the object, and also simplifies the identification procedure, since it limits the number of substances under consideration.

The position of a particular area within the translucent object 5 and its material composition are visualized on a monitor using stereoscopic images.

The spatial resolution of radiographic images is determined by the cross-section of the elements of linear single-axis fast neutron detectors 3 and 4, the speed of movement of the translucent object 5 and the time of collection of scintillation signals from linear single-coordinate fast neutron detectors 3 and 4.

Each element of the linear single-axis fast neutron detector 3 and 4 consists of a scintillator, a photodetector, electronics for reading and preprocessing the signal, and electronics for transmitting data to the computer unit 8.

Registration of fast neutrons is based on the appearance of recoil protons in the scintillator, which excite scintillation bursts in it. A part of the photons from the scintillation flash arrives at the photodetector, forming electrons in it as a result of the photoelectric effect, which are then detected by the readout electronics.

The side of the rectangular cross section of plastic scintillators used for fast neutrons, in the case of a source in the form of a portable neutron generator, is usually from 1 mm to 20 mm. The length of the scintillator along the beam, necessary for efficient detection of fast 14 MeV neutrons, is about 10 cm. To increase the proportion of scintillation photons arriving at the photodetector, the surface of the scintillator is covered with a reflective layer. As the photodetector, photodiodes are most often used mounted on the end surface of the scintillator from the side opposite to the illuminated object 5.

Claims (1)

A neutron radiography method with a penetrating radiation source in the form of a neutron generator with an integrated position-sensitive alpha particle detector, characterized in that information about the structure and material composition of the translucent object is obtained by processing data on the attenuation of the primary beam, by the ratio and number of neutrons scattered forward and back, as well as the spectrum of gamma radiation arising in the object, and for the separation of images in unscattered and scattered neutrons, use the ratio:
Δt = L / v _n -1 / v _α ,
where Δt is the time interval between the moment of registration of an alpha particle and the moment of registration of a neutron flying out of the target in the opposite direction,
L is the distance between the target of the generator and the element of the neutron detector that detected the neutron,
v _n is the neutron velocity of the source,
l is the distance between the target of the generator 1 and the alpha detector element that registered the alpha particle and located on the opposite side with respect to the target of the generator 1 from the corresponding element of the neutron detector,
v _α is the alpha particle velocity.