RU2476864C1 - Portable detector of hazardous concealed substances - Google Patents

Abstract

FIELD: physics.SUBSTANCE: device has a source of monochromatic neutrons and accompanying monochromatic ?-particles and an ?-particle detector enclosed in a vacuum chamber, a ?-radiation detector and recording electronic circuitry. The device is in form of two portable units - an inspection unit and a control unit - connected to each other, wherein the inspection unit includes a source of labelled monochromatic neutrons and accompanying monochromatic ?-particles, an ?-particle detector, ?-radiation detectors and recording electronic circuitry; the ?-radiation detector is placed at an angle close to 45° from the direction of flux of the labelled monochromatic neutrons, perpendicular to the near plane of the unit, and is provided with protection from the flux of labelled monochromatic neutrons, wherein the device is provided with an additional external ?-radiation detector which is connected to the inspection unit; both ?-radiation detectors are based on BGO crystals; laser line generators are configured to indicate on the inspected object overall dimensions of the region exposed to flux of labelled monochromatic neutrons; spectrometer channels of both ?-radiation detectors are fitted with a thermal correction system consisting of thermal sensors mounted on BGO crystals in thermal contact with said crystals, an amplitude-digital converter and a single-board minicomputer, wherein the thermal sensors are connected by a communication line and a power line to the amplitude-digital converter, which is connected to the single-board minicomputer, which is connected to the power supply system of the device and the control unit.EFFECT: high luminosity, sensitivity of the device, high energy resolution of the spectrometer channel for detecting gamma-radiation and fewer errors associated with thermal correction of gamma-spectra.3 cl, 3 dwg

Description

The invention relates to the field of research or analysis of materials by radiation methods with the measurement of secondary emission of gamma rays using neutrons, in particular, for identification in the field and stationary conditions of explosive, narcotic or potent toxic substances hidden in various types of cars. In addition, in passive mode, with the neutron source turned off, the product can serve as a detector of radioactive substances.

A device for identifying hidden substances (portable detector of dangerous hidden substances) is patented by the Russian Federation No. 2380690, containing a source of monochromatic neutrons and their accompanying monochromatic α-particles, an α-particle detector enclosed in a vacuum chamber, a γ-radiation detector and detecting electronics, including data collection electronics block, control panel, data reception and processing program block, user interface and power sources, the device is made in the form of two portable modules - inspection module Control module connected cables Ethernet-connection and power supply having a length that ensures the safe operation of the operator, the in Inspection module has a source labeled monochromatic neutrons and associated monochromatic α-particles, α-particle detector, the detectors of γ-radiation and recording electronics; the control module contains a control panel, a block of data reception and processing programs, a user interface and a power source; wherein the γ-radiation detector is placed at an angle close to 45 relative to the direction of the flux of labeled monochromatic neutrons, perpendicular to the front plane of the module, and is protected from the flux of labeled monochromatic neutrons; moreover, the inspection module is equipped with a guidance system on the basis of laser line generators, rigidly connected with the source of labeled monochromatic neutrons, for which a translucent window is provided in the case of the inspection module; a multi-element silicon detector is used as an α-particle detector.

All these essential features, except for the performance of the γ-radiation detector based on the LYSO crystal, are in the proposed technical solution.

The disadvantages of this device that impede its implementation in the practice of detection and identification of hidden dangerous substances in cars are the following:

1. The use of a LYSO crystal gamma-ray detector with a sufficiently high level of intrinsic radioactivity does not allow a good energy resolution through the spectrometric channel for registering gamma-quanta and imposes a limitation on the minimum possible intensity of the recorded characteristic gamma radiation. The energy resolution of the spectrometric gamma channel is 20% on the line of gamma radiation with an energy of 0.511 MeV.

2. The dimensions of the device do not allow it to be used when detecting hidden substances in hard-to-reach places or when inspecting objects of inspection that are more than 1.5 meters away from the device.

3. The absence of thermal correction of the gamma-ray spectra obtained using the gamma-detector leads to a shift in the position of the peaks of the characteristic gamma-radiation, which, in turn, leads to errors in the determination of the desired substances and increases the number of false alarms.

4. The system for pointing a tagged neutron beam to an object of inspection based on a laser generator of a vertical line passing through the center of a tagged neutron beam allows it to be combined only with a vertical line passing through the central point of the inspection area of the object of inspection, without taking its real shape into account.

The present invention is intended to solve the following technical problems - increasing the luminosity of the device and its sensitivity with respect to the recorded characteristic nuclear gamma radiation, increasing the energy resolution of the spectrometric channel for registering gamma radiation, providing the ability to detect and identify dangerous hidden substances in hard-to-reach places, reducing errors associated with the lack of thermal correction of gamma spectra required when the temperature changes approx uzhayuschey environment, improving the accuracy of aiming at a neutron flux of labeled suspicious area inspection object. Additionally, the technical problem of reducing the minimum recorded mass of a hidden hazardous substance, as well as the problem of ease of use of the device, is solved.

To solve these technical problems, a portable detector of dangerous hidden substances, containing a source of monochromatic neutrons and their accompanying monochromatic α-particles, an α-particle detector enclosed in a vacuum chamber, a γ-radiation detector and recording electronics, including a data acquisition electronics unit, a control panel, block of programs for receiving and processing data, user interface and power sources, the device is made in the form of two portable modules - an inspection module and a control module connected by cable fuses of an Ethernet connection and power having a length that ensures the safe operation of the operator, while the inspection module contains a source of labeled monochromatic neutrons and their accompanying monochromatic α-particles, an α-particle detector, a γ-radiation detector and recording electronics; the control module contains a control panel, a block of data reception and processing programs, a user interface and a power source; wherein the γ-radiation detector is placed at an angle close to 45 ° relative to the direction of the flux of labeled monochromatic neutrons, perpendicular to the front plane of the module, and is protected from the flux of labeled monochromatic neutrons; moreover, the inspection module is equipped with a guidance system on the basis of laser line generators, rigidly connected with the source of labeled monochromatic neutrons, for which a translucent window is provided in the case of the inspection module; a multi-element silicon detector is used as an α-particle detector, unlike the prototype, it is equipped with an additional external γ-radiation detector connected to the inspection module by a high-voltage power line and a spectrometric channel, both γ-radiation detectors (located inside the inspection module and an external detector) made on the basis of BGO crystals; laser line generators are installed with the possibility of indicating on the object of inspection the overall dimensions of the irradiation region by its flux of labeled monochromatic neutrons; The spectrometric channels of both γ-radiation detectors are equipped with a thermal correction system consisting of temperature sensors mounted on BGO crystals in thermal contact with them, an amplitude-to-digital converter and a single-board minicomputer, while the temperature sensors are connected by a communication line and a power line to the amplitude-to-digital converter connected by a system bus to a single-board minicomputer connected to the device’s power system and to the control module.

Additionally, to increase the sensitivity of the device in terms of detecting the smallest possible mass of a hidden hazardous substance, the signal elements of the multichannel silicon detector of α particles are made in the form of strips (strips) and are located on both sides of the semiconductor crystal perpendicular to the flow of α particles, and the bands on on one side of the crystal are parallel to each other and perpendicular to the direction of the bands on the other side of the crystal, while the intersection of the bands of the signal elements form the α-hour detector pixels IC; laser line generators are installed with the possibility of indicating on the object of inspection the irradiation areas corresponding to the pixels of the α-particle detector. To improve the convenience of working with objects with different distances, the detector contains a module for winding Ethernet connecting cables and power in the form of a coil.

Distinctive features of the proposed technical solution from the well-known adopted for the prototype are the following: the detector is equipped with an additional external γ-radiation detector connected to the inspection module by a high-voltage power line and a spectrometric channel, while both γ-radiation detectors are based on BGO crystals; laser line generators are installed with the possibility of indicating at the object of inspection the overall dimensions of the irradiation region of its flux of labeled monochromatic neutrons; The spectrometric channels of both γ-radiation detectors are equipped with a thermal correction system consisting of temperature sensors mounted on BGO crystals in thermal contact with them, an amplitude-to-digital converter and a single-board minicomputer, while the temperature sensors are connected by a communication line and a power line to the amplitude-to-digital converter connected by a system bus to a single-board minicomputer connected to the device’s power system and to the control module. Additionally, the signal elements of the multi-channel silicon α-particle detector are made in the form of strips (strips) and are located on both sides of the semiconductor crystal perpendicular to the flow of α particles, while the bands on one side of the crystal are parallel to each other and perpendicular to the direction of the bands on the other side of the crystal , while the intersection of the bands of the signal elements form the pixels of the detector of α-particles; laser line generators are installed with the possibility of indicating on the object of inspection the irradiation areas corresponding to the pixels of the α-particle detector. The detector also contains a module for winding Ethernet connecting cables and power in the form of a coil.

Due to the presence of these distinctive features in conjunction with the known from the prototype, the following technical results are achieved:

1. GGO-based gamma-ray detectors based on BGO crystals have an energy resolution on the ¹³⁷ Cs line 2 times better than that of a LYSO-based detector. This circumstance is extremely important for the reliable identification of hidden explosive, narcotic, and potent toxic substances, based on determining the intensities of the peaks of characteristic gamma radiation resulting from the interaction of a fast neutron flux with an energy of 14.1 MeV with carbon, nitrogen, and oxygen nuclei.

2. The presence of an additional external gamma detector based on a BGO crystal, which can be located as close as possible to the area of the object irradiated with a labeled neutron flux, but outside of it, it allows detecting and identifying hidden dangerous substances in hard-to-reach places (for example, a suspicious object inside a parked wall vehicle near the far side), thereby significantly increasing the sensitivity of the portable device.

3. The system of thermal correction of gamma detectors allows automatic calibration of the effect of the temperature shift of the position of the peaks of characteristic gamma radiation in the temperature range - 20 ÷ 50 ° C without carrying out calibration of the gamma channel by standard sources of quanta. The presence of this system ensures the identification of latent hazardous substances at a level of 98% probability, with a probability of false positives of 2%.

4. The use of line laser generators with indication of the overall dimensions of a beam of monochromatic neutrons at the inspection site allows you to reduce and visualize the process of pointing a tagged neutron beam at the inspection site, as well as determining the location of hazardous substances. The use of a multi-element strip silicon alpha detector can significantly reduce the minimum detectable mass of a hazardous substance to 25 g.

6. The presence of a winding module in the form of a coil of Ethernet connecting cables and power between the inspection module and the control module, which is part of the portable detector of hidden dangerous substances, makes it convenient for use in various conditions.

The proposed technical solution can find application in various mobile and stationary systems for checking the presence and identification of hidden dangerous substances in small and medium-sized objects. Portable systems can also be used to search for unidentified objects in the subway, at railway stations, at airports and other public places, as well as for remote inspection of cars.

The proposed technical solution is illustrated in figures 1, 2 and 3.

Figure 1 shows a General diagram of the device.

Figure 2 shows a functional diagram of the thermal correction system.

Figure 3 shows a section of a multi-channel strip detector of α-particles.

The detector shown in Fig. 1 includes an inspection module 12, a control module 14, a winding module - a coil 16 and connecting Ethernet and power cables 13. The inspection module 12 contains a source of monochromatic neutrons - a neutron generator (NG) 10 with a control unit 3, a γ-radiation detector 6 based on a BGO crystal, protection 7 of a BGO crystal of a γ-radiation detector 6, its power supply unit 1, a data acquisition electronics unit 2 with a built-in power supply unit, an Ethernet splitter 4 and a power supply unit 11 of the α-particle detector. The α-particle detector is not indicated in the diagram because it is built into the neutron generator 10. An additional external γ-radiation detector 17 (also based on the BGO crystal) is connected to the inspection module 12 by a high-voltage power line 18 and a spectrometric channel 19. In this case, in the data reception program in the control unit 3 of the device, switching is provided from the detector 6 located inside the inspection module to an external gamma detector 17. The inspection module is made on the basis of a universal container with overall dimensions of 740 × 510 × 410 mm. The total weight of the container with the equipment is 31 kg. Guidance on the object of inspection is carried out using laser line generators 9. Connection to the control module 14 is via connectors 5. The modules are interconnected by two cables 13 through which an Ethernet connection is made and 220 V power is transmitted. The control module 14 contains a laptop with programs receiving and processing data and a user interface and a power supply 15 to 220 V. For pointing at the object of control in the front wall of the container of the inspection module 12 there is a translucent window 8.

Figure 2 shows a functional diagram of a system of thermal correction of the spectra of characteristic γ radiation detected by γ-radiation detectors 6 or 17. The thermal correction system includes a temperature sensor 20, an amplitude-to-digital converter (ADC) 21, a single-board computer 22 connected to the control module 14 with an interface and control unit for data reception and processing programs.

The temperature sensor 20 is installed in the cases of γ-radiation detectors 6 and 17, directly on the BGO crystals in thermal contact with them (γ-radiation detectors 6 and 17 include BGO crystals), a photomultiplier tube (PMT) 23 and a high-voltage divider 24 to it. The high-voltage power supply of the γ-radiation detectors 6 and 17 is carried out using the high-voltage power supply unit 1. A constant voltage +5 V is supplied to the temperature sensor 20 through the ADC board 21. The signal from the temperature sensor 17, which is proportional to the temperature of the BGO crystal, is converted into a digital code. Using a single-board computer 22, on which the ADC board 21 is installed, the digital signal from the temperature sensor 20 is processed and the coefficient of temperature correction of the amplitude of the signal received from the γ-radiation detectors 6 and 17 is currently determined on the control module 14 with a block of data reception and processing programs . The signal from the γ-ray detector 6 or 17 enters the computer of the data acquisition electronics of the control unit 3 and is converted into a digital code. All computers of the thermal correction system and the data acquisition electronics block are connected to a common computer network using an Ethernet splitter 4. Digital information about the thermal correction coefficients and the signal amplitude from the γ-radiation detector 6 is transmitted using an Ethernet network splitter 4 to a control module 14 with an interface and a block of programs for receiving and processing data, with the help of which the analysis and construction of amplitude spectra of signals from a γ-ray detector 6 or 17 are performed, using the found thermal correction coefficients and (corrected spectrum) corresponding to a certain ambient temperature, and without taking them into account (spectrum without correction). A single-board computer is powered by a +5 V DC power supply (internal or common to other elements, for example, 11).

Figure 3 shows a section of a multi-element double-sided strip detector of α particles, which contains signal elements in the form of strips 25 and 26 (p ⁺ and n ⁺ strips, respectively) located on both sides of the semiconductor (Si ) of the crystal 24, while the signal elements 25, 26 are made in the form of parallel strips, the direction of which on one side of the crystal 27 is perpendicular to the direction of the strips on the other side of the silicon crystal 27. Moreover, the intersection of the bands of the signal elements 25 and 26 form ixels of the α-particle detector. The measurement of the coordinates of the α-particle occurs at the moment of coincidence of the signals from any two signal elements 25 and 26 located on opposite sides of the α-particle detector.

Laser line generators 9 are mounted on a neutron generator 10 and are designed to display horizontal and vertical lines on an object that indicate the area of the object being irradiated with a labeled neutron flux corresponding to the pixels of an α-particle detector.

The proposed device operates as follows.

When using the internal γ-ray detector 6, the inspection module 12 is brought to the object of control. The connecting wires 13 are unwound from the coil 16 to the required length for the safe placement of the control module 14. A laser guidance system 9 is turned on, which allows you to correctly set the labeled neutron beams to irradiate the desired area at the control object. Laser generators of lines 9 are rigidly connected to the body of the NG 10, show the direction of the labeled beams. The search module 12 irradiates the control object with several beams of tagged neutrons. The axis of the labeled bundles of NG 10 is directed at an angle to the plane of the front wall of the suitcase. This is because the placement of the equipment in the inspection module 12 was chosen so that the distance between the object and the neutron generator 10 and the distance between the object and the γ-radiation detector 6 were minimal. This condition is necessary to increase the speed of statistics collection. In addition, the γ-radiation detector 6 must be protected from emissions of NG 10. For this, protection 7 of the gamma radiation detector 6 is introduced.

When using an external γ-ray detector 17, the inspection module 12 also approaches the control object. The connecting wires 13 are unwound from the coil 16 to the required length for the safe placement of the control module 14. A laser guidance system 9 is turned on, which allows you to correctly set the labeled neutron beams to irradiate the desired area at the control object. Laser generators of lines 9 are rigidly connected to the body of the NG 10, show the direction of the labeled beams. Unlike the previous version of the operation, the γ-radiation detector 17 is brought directly to the irradiated object, but outside the irradiated zone with labeled neutron beams (respectively, the wires of the high-voltage power line 18 and the spectrometric channel 19 are unwound, which can be connected to the inspection module 12 by a connector). In this case, the protection of the γ-radiation detector 17 from emissions of NG 10 is not required. The search module 12 irradiates the control object with several beams of tagged neutrons.

The measurement cycle includes: starting the neutron generator 10, accumulating and analyzing data coming from the α-particle detector and γ-radiation detector 6 or 17, making decisions in automatic mode, recording measurement results and archiving the data collected during the measurement. In the process of measurement, when the ambient temperature changes, thermal correction of the amplitude distributions of the signals recorded using the γ-radiation detector is automatically performed, which eliminates the need for calibration of the spectrometric channel of the γ-radiation detector.

When the neutron generator 10 is switched off (in passive mode), the product is used as a detector of radioactive substances. To implement this, the proposed device contains a block of programs designed to control the level of radioactivity in the object of inspection. The data analysis program automatically compares the measurement result (the averaged count rate of recorded events in the gamma-ray energy range of 50-3000 keV) with the corresponding value measured previously in the background exposures. In this case, a comparison is made of the numbers of gamma rays recorded by the inspection module in the energy range of 50-3000 keV, in the presence and absence (background measurement) of the control object. If the measured count rate of events recorded by the γ-radiation detector exceeds the level of the natural background, information appears on the monitor screen of the control module 14, indicating that the object of inspection contains a radioactive substance.

Claims (3)

1. A portable detector of dangerous hidden substances containing a source of monochromatic neutrons and their accompanying monochromatic α-particles, an α-particle detector enclosed in a vacuum chamber, a γ-radiation detector and recording electronics, including a data acquisition electronics unit, a control panel, a reception program unit and data processing, the user interface and power sources, the device is made in the form of two portable modules - an inspection module and a control module connected by Ethernet-connection and power cables, having having a length that ensures the safe operation of the operator, while the inspection module contains a source of labeled monochromatic neutrons and their accompanying monochromatic α particles, an α particle detector, γ radiation detectors, and recording electronics; the control module contains a control panel, a block of data reception and processing programs, a user interface and a power source; wherein the γ-radiation detector is placed at an angle close to 45 ° relative to the direction of the flux of labeled monochromatic neutrons, perpendicular to the front plane of the module, and is protected from the flux of labeled monochromatic neutrons; moreover, the inspection module is equipped with a guidance system on the basis of laser line generators, rigidly connected with the source of labeled monochromatic neutrons, for which a translucent window is provided in the case of the inspection module; as an α-particle detector, a multi-element silicon detector is used, characterized in that it is equipped with an additional external γ-radiation detector connected to the inspection module by a high-voltage power line and a spectrometric channel, while both γ-radiation detectors are based on BGO crystals; laser line generators are installed with the possibility of indicating at the object of inspection the overall dimensions of the irradiation region of its flux of labeled monochromatic neutrons; The spectrometric channels of both γ-radiation detectors are equipped with a thermal correction system consisting of temperature sensors mounted on BGO crystals in thermal contact with them, an amplitude-to-digital converter and a single-board minicomputer, while the temperature sensors are connected by a communication line and a power line to the amplitude-to-digital converter, which connected by a system bus to a single-board minicomputer connected to the device’s power system and to the control module. 2. The detector according to claim 1, characterized in that the signal elements of the multichannel silicon detector of α particles are made in the form of strips and are located on both sides of the semiconductor crystal perpendicular to the flow of α particles, while the strips on one side of the crystal are parallel to each other and perpendicular to the direction of the bands on the other side of the crystal, while the intersection of the bands of the signal elements form the pixels of the α-particle detector; laser line generators are installed with the possibility of indicating on the object of inspection the irradiation areas corresponding to the pixels of the α-particle detector. 3. The detector according to any one of claims 1 and 2, characterized in that it comprises a module for winding Ethernet connecting cables and power in the form of a coil.

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