RU2549680C2 - Examination complex for detection of hazardous hidden substances (versions) - Google Patents

Abstract

FIELD: physics, alarm systems.

SUBSTANCE: invention is used for detection of hazardous hidden substances. The essence of the invention consists in that the device for detection of hazardous hidden substances is designed as two modules - examination and control module, connected by Ethernet and power cables, meanwhile the examination module contains several sources of tracer monochromatic neutrons and their respective monochromatic α-particles with detectors of α-particles and several γ-radiation detectors, and designed as a post for examination of vehicles including the site for arrangement of the vehicle and an inspection pit below, where the sources of tracer monochromatic neutrons and their respective monochromatic α-particles are located with α-particle detectors contained in evacuated chambers and designed with a possibility of irradiation of particular field of the vehicle along the whole its width in a single measurement, and also protection of γ-radiation detectors from a flow of monochromatic neutrons; γ-radiation detectors are located from both sides of the site with a possibility of their move both in vertical with reference to the vehicle, and in a horizontal direction, moving to or from the vehicle; the inspection module is fitted with the device of maintaining the certain ranges of air temperature and humidity in the examination pit.

EFFECT: shortening time of examination of vehicles, improvement of reliability of detection of hazardous hidden substances, avoidance of hand operation of operator at examination of the vehicle, and also avoidance of involvement of the driver for moving the vehicle with reference to the sources of monochromatic neutrons, improvement of radiation safety during examination and additional provision of usage of the unit in wide ranges of operating temperatures and humidity.

4 cl, 5 dwg

Description

The invention relates to the field of determining the elemental composition of materials by radiation methods using neutrons, with the measurement of secondary emission of gamma rays, for identification in the field and stationary conditions of explosive, narcotic and 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.

The principle of detection of hazardous substances is based on a comparison of the measured spectra of characteristic radiation arising from the interaction of a fast neutron beam with the nuclei of irradiated substances with reference spectra of known substances.

Known portable detector of dangerous hidden substances - RF patent No. 114368, 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 a recording electronics including a data acquisition electronics unit, a control panel , a block of data reception and processing programs, a 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-c cables connections and supplies 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 α-radiation detector is placed at an angle close to 45 ° relative to the direction of the central flux of labeled monochromatic neutrons, perpendicular to the front plane of the module; moreover, the inspection module is equipped with a rigidly connected with the source of labeled monochromatic neutrons system of pointing them to the inspection object based on laser line generators, for use of which a translucent window is provided in the inspection module case; a multi-element silicon detector is used as an α-particle detector; 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 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.

The common essential features of the prototype, which coincide with the essential features of the proposed technical solution, are as follows: a device for detecting dangerous hidden substances is made in the form of two modules - an inspection module and a control module connected by Ethernet connection cables and power supply, while the inspection module contains a source of labeled monochromatic neutrons and accompanying monochromatic α-particles, α-particle detector enclosed in a vacuum chamber, γ-radiation detector, protection of the γ-radiation detector from otok monochromatic neutrons, recording data acquisition electronics, power source blocks labeled monochromatic neutrons, alpha and gamma detectors; the control module includes a control panel, a block of programs for receiving and processing data, a user interface; a multi-element silicon detector is used as an α-particle detector; The spectrometric channel of the γ-radiation detector is equipped with a thermal correction system.

This known device allows you to conduct a phased inspection of the car for the presence of hazardous substances by moving the device around the perimeter of the car manually, which requires an extremely long search time, and also does not guarantee the absence of untreated areas of the car.

The proposed technical solution is aimed at a significant increase in the efficiency of the vehicle inspection process by expediting the search process. In addition, this decision involves the rejection of the manual movement of the device during the inspection relative to the inspected vehicle and ensuring the absence of untreated inspection zones. An important feature of the solution is the placement in the ground of the neutron source of the screening unit, which leads to a significant increase in radiation safety during the screening.

1. To achieve this technical result, according to embodiment one, in a device for detecting dangerous hidden substances, made in the form of two modules - an inspection module and a control module connected by Ethernet-connection cables and power supply, while the inspection module contains a source of labeled monochromatic neutrons and associated monochromatic α particles, α particle detector enclosed in a vacuum chamber, γ radiation detector, protection of the γ radiation detector from monochromatic neutron flux, recording electronics OF DATA, the power supply blocks labeled monochromatic neutrons, alpha and gamma detectors; the control module includes a control panel, a block of programs for receiving and processing data, a user interface; a multi-element silicon detector is used as an α-particle detector; the spectrometric channel of the γ-radiation detector is equipped with a thermal correction system, unlike the prototype, the inspection module contains several sources of labeled monochromatic neutrons and their accompanying monochromatic α-particles with α-particle detectors and several γ-radiation detectors, and is designed as a vehicle inspection point, including a platform for placing the car and an inspection pit located under it, where the sources of labeled monochromatic neutrons and their accompanying monochromatic α-hours are located egg detectors α-particles enclosed in a vacuum chamber and adapted to detect vehicle irradiation region over its entire width in one dimension, as well as protecting the detectors from the γ-radiation flow monochromatic neutrons; γ-radiation detectors are located on both sides of the site with the possibility of their movement both vertically relative to the car and in the horizontal direction, bringing them closer or closer to the car; the inspection module is equipped with a device for maintaining certain temperature and humidity ranges in the inspection pit.

2. To achieve this technical result, according to option two, in the device for detecting dangerous hidden substances, made in the form of two modules - an inspection module and a control module connected by Ethernet-connection cables and power supply, while the inspection module contains a source of labeled monochromatic neutrons and their accompanying monochromatic α-particles, α-particle detector, enclosed in a vacuum chamber, γ-radiation detector, protection of the γ-radiation detector from the flow of monochromatic neutrons, recording electronics for collecting nnyh, the power supply blocks labeled monochromatic neutrons, alpha and gamma detectors; the control module includes a control panel, a block of programs for receiving and processing data, a user interface; a multi-element silicon detector is used as an α-particle detector; the spectrometric channel of the γ-radiation detector is equipped with a thermal correction system, unlike the prototype, the inspection module contains several sources of labeled monochromatic neutrons and their accompanying monochromatic α-particles with α-particle detectors and several γ-radiation detectors, and is designed as a vehicle inspection point , including a platform for placing the car and an inspection pit located under it, where the sources of labeled monochromatic neutrons and their accompanying monochromatic are placed in the form of a matrix cally α-particle detectors α-particles enclosed in a vacuum chamber and capable of irradiating the whole or part of the vehicle across its width in one dimension, as well as protecting the detectors from the γ-radiation flow monochromatic neutrons; γ-radiation detectors are located on both sides of the site along the entire length of the matrix of monochromatic neutron sources with the possibility of moving γ-radiation detectors both vertically relative to the car and in the horizontal direction, bringing them closer or closer to the car; the inspection module is equipped with a device for maintaining certain temperature and humidity ranges in the inspection pit.

3. To achieve this technical result, according to option three, in the device for detecting dangerous hidden substances, made in the form of two modules - an inspection module and a control module connected by Ethernet-connection cables and power supply, while the inspection module contains a source of labeled monochromatic neutrons and their accompanying monochromatic α-particles, α-particle detector, enclosed in a vacuum chamber, γ-radiation detector, protection of the γ-radiation detector from the flow of monochromatic neutrons, recording electronics for collecting nnyh, the power supply blocks labeled monochromatic neutrons, alpha and gamma detectors; the control module includes a control panel, a block of programs for receiving and processing data, a user interface; a multi-element silicon detector is used as an α-particle detector; the spectrometric channel of the γ-radiation detector is equipped with a thermal correction system, unlike the prototype, the inspection module contains several sources of labeled monochromatic neutrons and their accompanying monochromatic α-particles with α-particle detectors and several γ-radiation detectors and is designed as a vehicle inspection point, including a platform for placing a car and an inspection pit located under it, where sources of labeled monochromatic neutrons and associated m onochromatic α-particles with α-particle detectors, enclosed in vacuum chambers and configured to irradiate the entire vehicle by stepwise moving the platform along the vehicle in a plane parallel to the plane of its bottom, as well as protecting γ-radiation detectors from the flow of monochromatic neutrons; γ-radiation detectors are located on both sides of the site with the possibility of their synchronous movement with the platform along the entire length of the car, as well as with the possibility of their movement both vertically relative to the car and in the horizontal direction, bringing them closer or closer to the car; the inspection module is equipped with a device for maintaining certain temperature and humidity ranges in the inspection pit.

4. To achieve this technical result, according to option four, in the device for detecting dangerous hidden substances, made in the form of two modules - an inspection module and a control module connected by Ethernet-connection cables and power supply, while the inspection module contains a source of labeled monochromatic neutrons and their associated monochromatic α-particles, α-particle detector, enclosed in a vacuum chamber, γ-radiation detector, protection of the γ-radiation detector from the flow of monochromatic neutrons, electronics collecting and data, power supplies of the source of labeled monochromatic neutrons, alpha and gamma detectors; the control module includes a control panel, a block of programs for receiving and processing data, a user interface; a multi-element silicon detector is used as an α-particle detector; the spectrometric channel of the γ-radiation detector is equipped with a thermal correction system, unlike the prototype, the inspection module contains several sources of labeled monochromatic neutrons and their accompanying monochromatic α-particles with α-particle detectors and several γ-radiation detectors and is designed as a vehicle inspection point, including a platform for placing the car and an inspection pit located under it, where the sources of labeled monochromatic neutrons and their accompanying monochromatic α-hours are located egg detectors α-particles enclosed in a vacuum chamber and adapted to detect vehicle irradiation region over its entire width in one dimension, as well as protecting the detectors from the γ-radiation flow monochromatic neutrons; γ-radiation detectors are located on both sides of the site with the possibility of their movement both vertically relative to the car and in the horizontal direction, bringing them closer or closer to the car; the inspection platform is equipped with a movable platform for stepwise longitudinal movement of the vehicle placed on it; the inspection module is equipped with a device for maintaining certain temperature and humidity ranges in the inspection pit.

Distinctive features of the proposed solution from the well-known adopted as a prototype, according to option one, are as follows: the inspection module contains several sources of labeled monochromatic neutrons and their accompanying monochromatic α-particles with α-particle detectors and several γ-radiation detectors and is designed as an inspection point cars, including a platform for placing the car and an inspection pit located under it, where the sources of labeled monochromatic neutrons and related mono Panchromatic α-particle detectors α-particles enclosed in a vacuum chamber and adapted to detect vehicle irradiation region over its entire width in one dimension, as well as protecting the detectors from the γ-radiation flow monochromatic neutrons; γ-radiation detectors are located on both sides of the site with the possibility of their movement both vertically relative to the car and in the horizontal direction, bringing them closer or closer to the car; the inspection module is equipped with a device for maintaining certain temperature and humidity ranges in the inspection pit.

The distinguishing features of the proposed solution from the well-known adopted for the prototype, according to option two, are as follows: the inspection module contains several sources of labeled monochromatic neutrons and their accompanying monochromatic α-particles with α-particle detectors and several γ-radiation detectors and is designed as an inspection point cars, including a platform for placing the car and an inspection pit located under it, where sources of labeled monochromatic neutrons and related monochromatic α-particles with α-particle detectors, enclosed in vacuum chambers and configured to irradiate all or part of the vehicle across its entire width in one measurement, as well as protect γ-radiation detectors from the flow of monochromatic neutrons; γ-radiation detectors are located on both sides of the site along the entire length of the matrix of monochromatic neutron sources with the possibility of moving γ-radiation detectors both vertically relative to the car and in the horizontal direction, bringing them closer or closer to the car; the inspection module is equipped with a device for maintaining certain temperature and humidity ranges in the inspection pit.

The distinguishing features of the proposed solution from the well-known adopted as a prototype, according to option three, are as follows: the inspection module contains several sources of labeled monochromatic neutrons and their accompanying monochromatic α-particles with α-particle detectors and several γ-radiation detectors and is designed as an inspection point cars, including a platform for placing a car and an inspection pit located under it, where sources of labeled monochromatic neutrons are located on a moving platform and the accompanying monochromatic α-particles with α-particle detectors, enclosed in vacuum chambers and configured to irradiate the entire vehicle by stepwise moving the platform along the vehicle in a plane parallel to the plane of its underbody, as well as protecting γ-radiation detectors from the flow of monochromatic neutrons; γ-radiation detectors are located on both sides of the site with the possibility of their synchronous movement with the platform along the entire length of the car, as well as with the possibility of their movement both vertically relative to the car and in the horizontal direction, bringing them closer or closer to the car; the inspection module is equipped with a device for maintaining certain temperature and humidity ranges in the inspection pit.

The distinguishing features of the proposed solution from the well-known adopted for the prototype, according to option four, are as follows - the inspection module contains several sources of labeled monochromatic neutrons and their accompanying monochromatic α-particles with α-particle detectors and several γ-radiation detectors, and is made as an item for inspection of vehicles, including a platform for placing a car and an inspection pit located under it, where sources of labeled monochromatic neutrons and their accompanying sources are located nochromatic α-particles with α-particle detectors, enclosed in vacuum chambers and configured to irradiate a specific area of the vehicle across its entire width in one measurement, as well as protect γ-radiation detectors from the flow of monochromatic neutrons; γ-radiation detectors are located on both sides of the site with the possibility of their movement both vertically relative to the car and in the horizontal direction, bringing them closer or closer to the car; the inspection platform is equipped with a movable platform for stepwise longitudinal movement of the vehicle placed on it; the inspection module is equipped with a device for maintaining certain temperature and humidity ranges in the inspection pit.

Due to the presence of these distinctive features, a significant reduction in the time of inspection of cars is achieved, as well as an increase in its efficiency, i.e. ensuring the identification of hazardous hidden substances. It is also ensured that the vehicle is inspected without manual operation by the operator, and, according to options 2-4, and without the participation of the driver, to move the car relative to sources of monochromatic neutrons. Thanks to the placement of neutron sources in the earth, radiation safety during the search is significantly increased. Additionally, the installation is used in a wide range of operating temperatures and humidity.

This device - an inspection complex - can be used as stationary posts for identifying explosive, narcotic and potent toxic substances hidden in cars of various types. In addition, in passive mode, with the neutron source turned off, the device can serve as a detector of radioactive substances.

The proposed technical solutions are illustrated by figures 1-5.

In FIG. 1 shows a cross section of the device, essentially common to all variants of its implementation (without the depicted moving platforms).

Figure 2 shows the device according to the first variant of the solution - the sources of monochromatic neutrons with detectors of α particles built into them are stationary in a line perpendicular to the direction of movement of the car along the inspection pit, and the car moves with its own motion (or manually) step by step relative to them.

Figure 3 shows the device according to the second variant of the solution - the sources of monochromatic neutrons with detectors of α particles embedded in them are stationary in the form of a matrix (in several rows), providing simultaneous inspection of the entire car or part of it, for example, the luggage or engine compartments, while the car moves on its own (or manually) step by step relative to them.

Figure 4 shows the device according to the third solution - the sources of monochromatic neutrons with integrated detectors of α particles are placed on a moving platform with the possibility of irradiating the entire car with stepwise movement of the platform along the car in a plane parallel to the plane of its bottom, γ radiation detectors are located on both sides of the platform with the possibility of their simultaneous movement with the platform along the entire length of the car, the car is stationary, and the driver is outside the inspection platform.

Figure 5 shows the device according to the fourth embodiment — the sources of monochromatic neutrons with α-particle detectors built into them are stationary in a line, and the car is placed on a movable platform for its stepwise longitudinal movement.

Shown in figures 1-5, the device for detecting dangerous hidden substances in the car is made in the form of two modules - inspection and control module. The inspection module includes a platform 1 with guides 2 for placing the vehicle 3 and an inspection pit 4 located underneath it, usually lined with concrete 5 and closed with a neutron-passing cover 6, where the sources of labeled monochromatic neutrons and their accompanying monochromatic α- are located particles with α-particle detectors enclosed in a vacuum chamber - hereinafter neutron generators 7 with their control units 12, and the protection of γ-radiation detectors 7 from the flow of monochromatic neutrons 8. On both sides of the pl gadgets 1 are located γ-radiation detectors 9, made with the possibility of their movement both vertically relative to the car 3, and in the horizontal direction, approaching or removing them from the car 3, for example on racks 10 (in this case, as an example, on racks two gamma-ray detectors are located 9). Also, the registration module contains recording electronics and power supplies 11. The control module 13 is separated from the inspection module by a safe distance (in terms of radiation and explosion safety) and is connected to the inspection module by Ethernet-connection cables and power 14. The control module 13 includes a personal computer with a block of programs for receiving and processing data and a user interface.

In figure 2, the neutron generators 7 are stationary with the possibility of irradiating a specific area of the car 3 over its entire width in one measurement, γ-radiation detectors 9 are located on both sides of the site 1 with the possibility of their movement both vertically relative to car 3, and in horizontal direction, bringing them closer to or moving away from the car 3. At the same time, the car 3 should move relative to the neutron generators 7 step by step, for which a special marking can be applied on the site. The movement is carried out either by the driver with the engine turned on, or manually by the coast.

In figure 3, the neutron generators 7 are stationary in the form of a matrix (in several rows), providing inspection of either the entire car 3 at the same time, or a significant part of it, for example, the luggage or engine compartments. If the matrix of neutron generators 7 is located underneath the entire car 3, then it drives in once for inspection, but if not, then the car 3 moves in its own right (or manually) step by step relative to the matrix of generators 7.

In Fig. 4, neutron generators 7 are placed on a movable platform 15 (with electric drive) mounted on rails 16 with the possibility of irradiating a specific area of the car 3 over its entire width in one movement. The γ-radiation detectors 9 are additionally made with the possibility of their movement along the car 3, for which they are placed on the carts 17 mounted on the rails 16. The car 3 is stationary.

5, the neutron generators 7 are stationary with the possibility of irradiating a specific area of the car 3 over its entire width in one measurement. Γ-radiation detectors 9 are located on both sides of the platform 1 with the possibility of their movement both vertically relative to the car 3, and in the horizontal direction, bringing them closer or closer to the car 3. The car 3 is placed on a movable platform 18 mounted on the rails 16 for step-by-step longitudinal displacement. The platform 18 with the car 3 is moved by a drive (electric, manual, etc.).

The above device operates as follows.

Option 1 (figure 2)

The car 3 enters the inspection platform 1 along the guides 2 laid on it, located on both sides of the inspection pit 4. On the guide rails 2 there are stops that limit the movement of the car along the inspection pit 4 by distances exceeding the dimensions of the inspection pit 4. The driver stops the car 3 above a source of labeled neutrons 7 so that it is possible to irradiate a specific area of the vehicle 3 along its entire width with a beam of labeled neutrons. The position of the car 3 is fixed on the guides 2. The complex operator includes neutron generators 7, and a certain area of the car 3 is irradiated with a labeled neutron flux. It should be noted that prior to irradiating a vehicle 3 with a tagged neutron beam, the operator includes power to neutron generators 7 and α-particle detectors built into them, as well as power to γ-radiation detectors 9 installed on special racks 10 on both sides of car 3, with the possibility of displacements both vertically relative to vehicle 3, and in the horizontal direction, moving them closer or farther away from vehicle 3. To prevent the ingress of atmospheric precipitation and dust, a protective cover 6 of the inspection pit 4 is provided. As f concrete 5, polyethylene and iron 8 are used to protect γ-radiation detectors 9 from direct neutron hit in them. In the process of irradiating a vehicle 3 with a labeled neutron flux, information from α-particle detectors and γ-radiation detectors 9 is sent to the control unit 13 of the installation. Power and information transfer from detectors of α-particles and detectors of γ-radiation 9 is carried out using cables 14. After the end of irradiation of the car 3 and the decision by the operator, the driver either leaves the inspection platform 1 or moves the car to another position along the inspection pit 4 s the purpose of the search of his other area. If explosives are found in car 3, the operator reports this information to the special services and car 3 remains in the same position above the inspection pit 4 until the arrival of the special services.

Option 2 (figure 3)

Car 3 enters the inspection platform 1 and stops above the inspection pit 4 in a position where it is possible to inspect the entire vehicle in one measurement. After that, the operator turns on the neutron generators 7 and the entire volume of the vehicle 3 is irradiated with a labeled neutron flux. At the end of the inspection process, based on the operator’s opinion, the car moves out of the inspection pit 4 (there is no explosive) or remains in the same position until the arrival of the security services.

Option 3 (figure 4)

The car 3 enters the inspection platform 1 and stops above the inspection pit 4 in a position where it is possible to inspect any part of it by moving the neutron generators installed on the platform 18 along the guide rails 16, while synchronously with the movement of the neutron generators 7 and their control units 12 γ-radiation detectors 9 located on the bogies 17 are moved along the guide rails 16. Using the control module 13, a step-by-step synchronous movement of neutron generators 7 and a gamma-detector 3 along a vehicle according to the needs of a particular inspection vehicle region 3. Moving neutron generators 7 and γ-radiation detectors 9 takes place automatically via the control unit 13.

Option 4 (figure 5)

The car 3 enters a movable platform 18 located on the guide rails 16 above the inspection pit 4. Neutron generators 7 and their control units 12 are stationary in the inspection pit 4. The γ-radiation detectors 9 are also stationary on the racks 10. Irradiation of a certain area of the car 3 carried out by moving the platform 18 along the guide rails 16.

Claims (4)

1. A device for detecting dangerous hidden substances, made in the form of two modules - an inspection module and a control module connected by Ethernet connection cables and power supply, while the inspection module contains a source of labeled monochromatic neutrons and their accompanying monochromatic α-particles, an α-particle detector enclosed in a vacuum chamber, γ-radiation detector, protection of the γ-radiation detector from the monochromatic neutron flux, recording data acquisition electronics, power supplies of the source of labeled monochromatic neutrons rons, alpha and gamma detectors; the control module includes a control panel, a block of programs for receiving and processing data, a user interface; a multi-element silicon detector is used as an α-particle detector; The spectrometric channel of the γ-radiation detector is equipped with a thermal correction system, characterized in that the inspection module contains several sources of labeled monochromatic neutrons and their accompanying monochromatic α-particles with α-particle detectors and several γ-radiation detectors and is designed as a vehicle inspection point, including a platform for placing the car and an inspection pit located under it, where the sources of labeled monochromatic neutrons and the accompanying monochromatic α-parts are located c with α-particle detectors, enclosed in vacuum chambers and made with the possibility of irradiating a certain area of the car over its entire width in one measurement, as well as protecting γ-radiation detectors from the flow of monochromatic neutrons; γ radiation detectors are located on both sides of the site with the possibility of their movement both vertically relative to the car and in the horizontal direction, bringing them closer or closer to the car; the inspection module is equipped with a device for maintaining certain temperature and humidity ranges in the inspection pit. 2. A device for detecting dangerous hidden substances, made in the form of two modules - an inspection module and a control module connected by Ethernet-connection cables and power supply, while the inspection module contains a source of labeled monochromatic neutrons and their accompanying monochromatic α-particles, an α-particle detector enclosed in a vacuum chamber, γ-radiation detector, protection of the γ-radiation detector from the monochromatic neutron flux, recording data acquisition electronics, power supplies of the source of labeled monochromatic neutrons rons, alpha and gamma detectors; the control module includes a control panel, a block of programs for receiving and processing data, a user interface; a multi-element silicon detector is used as an α-particle detector; The spectrometric channel of the γ-radiation detector is equipped with a thermal correction system, characterized in that the inspection module contains several sources of labeled monochromatic neutrons and their accompanying monochromatic α-particles with α-particle detectors and several γ-radiation detectors and is designed as a vehicle inspection point, including a platform for placing a car and an inspection pit located under it, where sources of labeled monochromatic neutrons and their accompanying monochromat are placed in the form of a matrix iCal α-particle detectors α-particles enclosed in a vacuum chamber and capable of irradiating the whole or part of the vehicle across its width in one dimension, as well as protecting the detectors from the γ-radiation flow monochromatic neutrons; γ-radiation detectors are located on both sides of the site along the entire length of the matrix of monochromatic neutron sources with the possibility of moving γ-radiation detectors both vertically relative to the car and in the horizontal direction, bringing them closer or closer to the car; the inspection module is equipped with a device for maintaining certain temperature and humidity ranges in the inspection pit. 3. A device for detecting dangerous hidden substances, made in the form of two modules - an inspection module and a control module connected by Ethernet-connection cables and power supply, while the inspection module contains a source of labeled monochromatic neutrons and their accompanying monochromatic α-particles, an α-particle detector enclosed in a vacuum chamber, γ-radiation detector, protection of the γ-radiation detector from the monochromatic neutron flux, recording data acquisition electronics, power supplies of the source of labeled monochromatic neutrons rons, alpha and gamma detectors; the control module includes a control panel, a block of programs for receiving and processing data, a user interface; a multi-element silicon detector is used as an α-particle detector; The spectrometric channel of the γ-radiation detector is equipped with a thermal correction system, characterized in that the inspection module contains several sources of labeled monochromatic neutrons and their accompanying monochromatic α-particles with α-particle detectors and several γ-radiation detectors and is designed as a vehicle inspection point, including a platform for placing a car and an inspection pit located under it, where sources of labeled monochromatic neutrons and their accompanying sources are located on a moving platform ohromaticheskih α-particle detectors α-particles enclosed in a vacuum chamber and configured to irradiate the entire vehicle when indexing movement of the platform along the vehicle in a plane parallel to the plane of the bottom, as well as protecting the detectors from the γ-radiation flow monochromatic neutrons; γ-radiation detectors are located on both sides of the site with the possibility of their synchronous movement with the platform along the entire length of the car, as well as with the possibility of their movement both vertically relative to the car and in the horizontal direction, bringing them closer or closer to the car; the inspection module is equipped with a device for maintaining certain temperature and humidity ranges in the inspection pit. 4. A device for detecting dangerous hidden substances, made in the form of two modules - an inspection module and a control module connected by Ethernet-connection and power cables, while the inspection module contains a source of labeled monochromatic neutrons and their accompanying monochromatic α-particles, an α-particle detector enclosed in a vacuum chamber, γ-radiation detector, protection of the γ-radiation detector from the monochromatic neutron flux, recording data acquisition electronics, power supplies of the source of labeled monochromatic neutrons rons, alpha and gamma detectors; the control module includes a control panel, a block of programs for receiving and processing data, a user interface; a multi-element silicon detector is used as an α-particle detector; The spectrometric channel of the γ-radiation detector is equipped with a thermal correction system, characterized in that the inspection module contains several sources of labeled monochromatic neutrons and their accompanying monochromatic α-particles with α-particle detectors and several γ-radiation detectors and is designed as a vehicle inspection point, including a platform for placing the car and an inspection pit located under it, where the sources of labeled monochromatic neutrons and the accompanying monochromatic α-parts are located c with α-particle detectors, enclosed in vacuum chambers and made with the possibility of irradiating a certain area of the car over its entire width in one measurement, as well as protecting γ-radiation detectors from the flow of monochromatic neutrons; γ-radiation detectors are located on both sides of the site with the possibility of their movement both vertically relative to the car and in the horizontal direction, bringing them closer or closer to the car; the inspection platform is equipped with a movable platform for stepwise longitudinal movement of the vehicle placed on it; the inspection module is equipped with a device for maintaining certain temperature and humidity ranges in the inspection pit.

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