RU66822U1 - PEDESTAL RADIATION MONITOR - Google Patents

Abstract

Pedestrian radiation monitor refers to the field of detection and control of the level of ionizing radiation and is designed to detect unauthorized movement of nuclear materials and radioactive substances during their production, storage, processing or transportation. The monitor contains object presence sensors, unauthorized access sensors, gamma and neutron detection units, a detection system control unit, a light and sound alarm system, consisting of a light and sound alarm unit and a CAN remote indicator. The gamma radiation detection units consist of a polystyrene-based scintillator in the form of a parallelepiped surrounded by reflective coatings, one of which has a volume of at least 10,000 cm ³ and a length of at least 100 cm, the other at least 5,000 cm ³ and a length of at least 50 cm, two photoelectronic multipliers, a high-voltage power supply, a signal conditioning amplifier, an amplitude-time signal sampling device, a protective casing with a connector. The neutron detection unit includes a He-3 proportional counter with a volume of at least 0.8 liters, a length of at least 100 cm and placed in a polyethylene moderator, a high-voltage power supply, a signal preamp, discriminators of the upper and lower levels, and a protective casing with a connector. The control unit for the detection system includes a microprocessor, a processing and control board, and a power supply. The monitor detects gamma radiation and neutrons with high sensitivity and uniformity at any point along the height of the controlled space, while ensuring the stability of the main characteristics and the reliability of the monitor in a wide temperature range, manufacturability in the manufacture, assembly and adjustment, simplicity and ease of use. 1 s.p. f-ly and 4 z.p. f-ly, 2 ill.

Description

The utility model relates to the field of means of detecting and controlling the level of ionizing radiation and can be most effectively used to detect unauthorized movement of nuclear materials (NM) and radioactive substances (RS) by personnel of enterprises of the nuclear power, nuclear weapons complex and other institutions involved in the processes production, storage, processing or transportation of nuclear materials and radioactive substances.

A radiation portal monitor is known (RF Certificate No. 9318, IPC G 01 T 1/167, application filing date 1998.06.23, publication date 1999.02.16) containing two measuring columns with gamma radiation detection units and neutron detection units and connected to the columns electronics unit. Three gamma-ray detection units are located in each measuring column, one detection unit is located in the upper part of the column in the middle of its length, and the other two in the lower part along the edges of the column length. The neutron detection units are arranged in alternation with the gamma radiation detection units. The disadvantages of the known radiation portal monitor are:

- the electronics unit is not part of the measuring columns, made in the form of a remote unit, connected to the columns with cables and should be located indoors, for example, in the guardhouse of a checkpoint, which complicates the installation of a radiation monitor at the place of operation and requires the installation of additional cable tracks;

- individual coordination of the output signals of each detection unit with the input devices of the electronics unit is required, which eliminates the interchangeability of the detection units without additional adjustment, limits the distance between the measuring columns and the electronics unit, and also complicates the process of setting up the monitor;

- a larger number of gamma radiation detection units in the lower part of the column compared to the upper one creates an inhomogeneity of sensitivity to gamma radiation, determined along the vertical axis of symmetry of the monitor.

The closest in technical essence to the claimed is a device for the detection of radioactive materials (RF Patent No. 2129289, IPC G 01 T 1/167, filing date 1998.01.20, publication date 1999.04.20), which includes a detection unit

gamma radiation, neutron detection unit, object presence sensors, unauthorized access sensor, controller, light and sound alarm system, power supply and control panel. The controller is a microprocessor device connected to units for detecting gamma radiation and neutrons, sensors for the presence of an object, an unauthorized access sensor, a light and sound alarm system, and a control panel. The power supply provides the device with the necessary electrical energy. The gamma radiation detection unit consists of a scintillator, in which the energy of gamma rays is converted into a light flash; a fiber through which a light flash is transported to a photomultiplier tube; a photomultiplier tube in which a light flash transforms into an electrical signal; amplifier-driver of these signals; amplitude discriminator of signal level. The neutron detection unit consists of a polyethylene neutron moderator filled with helium (He-3) counter of slow neutrons, an amplifier-driver of signals from the counter and an amplitude discriminator of signal level.

The disadvantages of the known device for the detection of radioactive materials are:

- the use of a single photoelectron multiplier in the gamma radiation detection unit does not allow reducing the influence of its noise on the detection threshold by electronic methods (especially at high ambient temperatures) and, accordingly, ensuring the stability of the detection threshold over a wide temperature range;

- the presence in the detection unit of gamma radiation of the fiber makes them not technological, difficult to manufacture, reduces resistance to external factors and limits the scintillator in changing its size (length, width, height);

- the presence in the device for the detection of radioactive materials of only one type of gamma radiation detection unit does not optimally ensure uniformity of sensitivity to gamma radiation for a given height of the controlled space defined along the vertical axis of symmetry of the device;

- the lack of communication with an external computer does not allow you to quickly check the operation of the device for the detection of radioactive materials in various modes, test the operation of gamma and neutron detection channels and set parameters that determine the operation of the device;

- non-automated operation of the device for detecting radioactive materials, due to the fact that the device operates under external control (as evidenced by the presence of an external control panel in its composition).

The inventive pedestrian radiation monitor eliminates these disadvantages of the prototype and solves the following problems:

- registers gamma radiation and neutrons, with high sensitivity and uniformity at any point along the height of the controlled space;

- provides stability of the main characteristics and reliability of the monitor in a wide temperature range;

- provides communication with an external computer for operational verification of the monitor.

It has the following advantages:

- manufacturability of manufacturing, assembly and tuning;

- simplicity and ease of use;

- the ability to create various modifications of pedestrian radiation monitors, differing both in the composition of the detection units and in the width of the controlled space.

The tasks are solved as follows. A gamma-ray detection unit and an external CAN indicator are introduced into the pedestrian radiation monitor, which includes object presence sensors, unauthorized access sensors, a gamma radiation detection unit, a neutron detection unit, a detection system control unit and a light and sound alarm system, while the system control unit the detection unit is connected to gamma and neutron detection units, object presence sensors, a light and sound alarm system, and non-sun sensors access authorization.

The pedestrian radiation monitor consists of two measuring columns, which include: gamma-ray detection units, neutron detection units, unauthorized access sensor, light and sound signaling unit and, in one of the columns, a detection system control unit.

The gamma radiation detection units are structurally made in the form of a “monoblock” and consist of a polystyrene based scintillator representing a parallelepiped, one of which has a volume of at least 10,000 cm ³ and a length of at least 100 cm, another with a volume of at least 5000 cm ³ and a length of at least 50 cm, and surrounded by reflective coatings, two photomultiplier tubes (PMTs) mounted on an unprotected reflective material end of a plastic scintillator, a high-voltage power supply for a PMT, a signal conditioning amplifier with

PMTs, devices for amplitude-time sampling of signals from PMTs, a protective casing with a connector for powering the detection unit and removing logical signals from it that are sent to the control unit of the detection system. The presence of an amplitude-time sampling device reduces the effect of PMT noise at high ambient temperatures (up to + 50 ° C) and, accordingly, reduces the detection threshold of NM and PB.

The neutron detection unit is also a “monoblock” and includes: an He-3 proportional counter with a volume of at least 0.8 liters, a length of at least 100 cm and placed in a polyethylene moderator, a high-voltage power supply of a proportional counter, a signal preamp-shaper from the counter , discriminators of the upper and lower levels, a protective casing with a connector for powering the detection unit and removing from it logical signals arriving at the control unit of the detection system. Discriminators of the upper and lower levels provide the selection of signals from a proportional counter corresponding to the registration of neutrons.

The "monoblock" structure of building blocks for detecting gamma radiation and neutrons ensures the interchangeability of blocks without reconfiguration, increases resistance to external factors.

The location of the two modifications of the gamma-ray detection units in the measuring column is made in such a way as to ensure that the sensitivity along the given height of the pedestrian radiation monitor to gamma-radiation is no more than ± 15%, defined along the vertical axis of symmetry of the monitor.

The control unit for the detection system includes a microprocessor, a processing and control board, and a power supply. The control unit for the detection system is connected to the detection units, a light and sound alarm system, object presence sensors and unauthorized access sensors.

The sound and light alarm system consists of two blocks: a light and sound alarm block and an external indicator - CAN (VI-CAN). The light and sound alarm unit is installed in the measuring column. VI-CAN is located in the guardhouse of the checkpoint. In addition to the sound emitter and LED emitters, the VI-CAN contains a relay output for notifying the external security loop about the detection of NM and PB in the monitored space of the monitor, a “Reset” button and a PC-4 connector for connecting an external computer. Using an external computer and a service program, the operation of the pedestrian radiation monitor in various modes is checked, the operation of gamma and neutron

detection channels and set parameters that determine the operation of the monitor. In case of detection of NM or PB, the Reset button restores the monitor to its original state.

When the doors of the measuring columns are opened during operation of the monitor, unauthorized access sensors are triggered and a signal is sent to the control unit of the detection system.

The inventive device is illustrated by the drawings presented in figures 1-2, where figure 1 shows the appearance of a pedestrian radiation monitor, where indicated:

1 - measuring columns;

2 - sensors of the presence of the object;

3 - block light and sound alarm;

4 - remote indicator - CAN.

Figure 2 presents the structural diagram of a pedestrian radiation monitor, where indicated:

2 - sensors of the presence of the object;

3 - block light and sound alarm;

4 - remote indicator - CAN;

5 - blocks detecting gamma radiation;

6 - neutron detection blocks;

7 - unauthorized access sensors;

8 - control unit of the detection system.

A pedestrian radiation monitor, contains two measuring columns 1 with the sensors for the presence of the object 2 located in them, a light and sound alarm unit 3, gamma radiation detection units 5, neutron detection units 6, unauthorized access sensors 7, and a detection system control unit 8, which connected to the gamma radiation detection units 5 and neutrons 6, the sensors of the presence of the object 2, the sensors and unauthorized access 7 and the light and sound alarm system, consisting of light and sound signaling unit 3 and remote CAN indicator (VI-CAN) 4, having a relay output for notifying the external security loop about the detection of nuclear materials or radioactive substances in the controlled space, the “Reset” button to reset the monitor to its initial state, a connector for connecting to an external computer and a checkpoint installed in the guardhouse. The gamma radiation detection units 5 consist of a plastic scintillator in the shape of a parallelepiped with reflective coatings, one of

a skeleton with reflective coatings, one of which has a volume of at least 10,000 cm ³ and a length of at least 100 cm, another with a volume of at least 5,000 cm ³ and a length of at least 50 cm, two photoelectronic multipliers mounted on the end face of a plastic scintillator, a high-voltage source power supply for photomultiplier tubes, an amplifier-driver of signals from photomultiplier tubes, devices for amplitude-time sampling of signals from photomultiplier tubes, a protective casing with a connector for a pit The unit for detecting gamma radiation and removing logic signals from it, which are sent to the control unit for the detection system 8. The neutron detection units 6 consist of a He-3 proportional counter with a volume of at least 0.8 liters and a length of at least 100 cm and placed in a polyethylene moderator , a high-voltage power supply of a proportional counter, a preamplifier-driver of signals from the counter, discriminators of the upper and lower levels, a protective casing with a connector for powering the neutron detection unit 6 and removal logical signals coming from it to the control unit of the detection system 8. The control unit of the detection system 8 contains a microprocessor, a processing and control board and a power supply.

The operation of the pedestrian radiation monitor (MP) is controlled by the control unit for the detection system 8, which processes the information received from the gamma radiation detection units 5, neutron detection units 6, the presence sensors of the object 2, unauthorized access sensors 7, and generates control signals to the sound system and light alarm 3, 4.

MP has four main operating modes: “Warm-up”, “Background Set”, “Standby” and “Measurement”.

The MP is turned on by supplying voltage to it from an external network. After power is supplied to the MP, it automatically switches to the "Warm-up" mode. At the start of the mode, a short beep sounds. The “Warm-up” mode is designed to suspend the MP for the duration of the output of analog devices to operating mode. In this mode, alternating with an interval of 1 second, the red and yellow indicators on the light and sound block 3 and VI-CAN 4 blink.

Upon completion of heating, the MP switches to the “Background Set” mode. In the background dialing mode, the detection blocks 5 and 6 are tested and the counting values of the background gamma and neutron radiation are set. At the start and at the end of the mode, a short sound signal is emitted, on the light and sound signaling unit 3 and VI-CAN 4, the yellow indicator flashes with an interval of 1 second. Values dialed

counting rates will subsequently be basic when deciding on the presence of NM or RS in the measurement object. During background dialing, access to the controlled MP space (the space limited by the distance between the measuring columns 1 and their height) is prohibited. When the presence sensors 2 are triggered, a continuous beep sounds and the background dialing stops. After removing the object that caused the presence sensors 2 to be activated from the controlled space, the background continues.

After completing the background dialing, the MP goes into the “Standby” mode and the green indicator lights up on the light and sound block 3 and VI-CAN 4. In the absence of the measurement object, the MP automatically monitors the change in the background and periodically monitors the state of the detection units 5 and 6. When the radiation situation changes at the location of the MP above the specified one, a short sound signal is given, at the light and sound signaling unit 3 and VI-CAN 4 with an interval the yellow indicator flashes for 1 second. After 5 seconds or when you press the "Reset" button on the VI-CAN 4, the monitor returns to the "Standby" mode. On the light and sound signaling unit 3 and VI-CAN 4, the green indicator lights up.

In the event of failure of one of the detection units 5 and 6, the faulty detection unit is automatically turned off and the message is transmitted to an external computer. MP continues to be in the "Standby" mode, while the detection threshold of the monitor is deteriorating.

After the appearance of the object in the controlled space, the presence sensors 2 generate the corresponding signal, the MP stops tracking the background and switches to the "Measurement" mode. On the light and sound signaling unit 3 and VI-CAN 4, the green indicator goes out and the yellow indicator lights up.

In the “Measurement” mode, the content of the counting channels collected for a given period of time from the operation of the presence sensors 2 is analyzed. If the intensity of gamma or neutron radiation exceeds the detection threshold set with respect to the background level, a long sound signal is given, at the light and sound block alarm 3 and VI-CAN 4 the red indicator lights up, followed by a flashing yellow or green indicator. The combination of a burning red and a flashing green indicator corresponds to the detection of gamma radiation through the registration channel, a burning red and a blinking yellow means detection by the neutron registration channel, and a burning red with flashing yellow and green means the detection of both the gamma radiation registration channel and the neutron registration channel .

Upon detection of NM or RS, the MP stops. After removing the control object from the controlled space of the MP, by pressing the "Reset" button on the VI-CAN 4 or automatically after 20 seconds, the monitor is put into "Standby" mode.

In the absence of NM or RW at the facility, at the end of the monitoring procedure, the yellow and audible signaling unit 3 and VI-CAN 4 turn off the yellow indicator and the green one lights up, after which the MP is ready to continue operation.

When the doors of the measuring columns 1 are opened, unauthorized access sensors 7 are activated and a continuous sound signal is given.

The use of a pedestrian radiation monitor at various enterprises increases the reliability of measurement results and the effectiveness of counteracting illicit trafficking in nuclear materials and radioactive substances.

Claims (1)

A pedestrian radiation monitor containing two measuring columns with gamma-ray detection units, neutron detection units, object presence sensors, unauthorized access sensors, a detection system control unit, a light and sound alarm system and an external CAN indicator, while the detection system control unit is connected to gamma and neutron detection units, object presence sensors, light and sound alarm systems and unauthorized sensors access, characterized in that the gamma radiation detection units consist of a plastic scintillator in the form of a parallelepiped with reflective coatings, one of which has a volume of at least 10,000 cm ³ and a length of at least 100 cm, another with a volume of at least 5,000 cm ³ and a length of at least 50 cm, two photoelectronic multipliers mounted on the end face of a plastic scintillator, a high-voltage power source for photoelectronic multipliers, an amplifier-driver of signals from photoelectronic multipliers devices, devices for amplitude-time sampling of signals from photoelectronic multipliers, a protective casing with sockets for supplying the detection unit and removing from it logical signals arriving at the control unit of the detection system, and neutron detection units consist of an He-3 proportional counter with a volume of at least 0, 7 l and a length of at least 100 cm and placed in a polyethylene moderator, a high-voltage power supply of a proportional counter, a preamplifier-driver of signals from the counter, discriminators bottom and bottom level, a protective casing with connectors for powering the neutron detecting unit and removing logical signals from it, which are fed to the control unit of the detection system, while the sound and light alarm system consists of a sound and light alarm unit and a CAN remote indicator with relay output to notify the external security circuit of the detection of nuclear materials or radioactive substances in the controlled space, the "Reset" button to reset the monitor to its original state, a connector for connecting to an external computer and a checkpoint installed in the guardhouse.