RU2819699C1 - Modular design of gamma radiation detection unit - Google Patents

Abstract

FIELD: measurement.

SUBSTANCE: invention relates to a modular design of a gamma-radiation detection unit. Gamma-radiation detection unit consists of two separate modules: an electronics unit and a replaceable cartridge containing an identifier card and two Geiger-Muller gas-discharge counters. Electronics unit has a power supply, a shaping amplifier, an information processing and storage device and an identification device. Communication of modules and power supply of replaceable cartridge is carried out by means of sealed high-voltage connectors. Correction coefficients are transmitted by reading information from an identifier card attached to each replaceable cartridge. In order to determine compliance of the identifier card with a certain replaceable cartridge, numbers are applied on them. Identification device is installed in the electronics unit, which reads values of correction coefficients and enters them into the information processing and storage device.

EFFECT: possibility of rapid replacement of a replaceable cartridge containing detecting elements with a new one while reducing the time for stopping measurements for replacing the replaceable cartridge and setting the detection unit to no more than 10 minutes.

3 cl, 2 dwg

Description

The invention relates to the field of nuclear instrumentation, namely to dosimetric radiation monitoring equipment. It is a gamma radiation detection unit in a modular design, designed for continuous monitoring of the radiation situation and measuring the dose rate of ionizing radiation, consisting of an electronics unit and a replaceable cartridge containing detecting elements - Geiger-Muller counters.

During monitoring of the radiation situation, in order to check the accuracy of measurements, detection units are subjected to a verification procedure at least once every three years. To carry out the verification procedure, it is necessary to stop the measurement process, dismantle the system and transport the detection units to the place of verification work. In the case of operating a deployed system for continuous monitoring of the radiation situation (for example, at a nuclear power plant), which includes a large number of detection units reduced to a single information output device, it is necessary to dismantle the entire system or several detection units. This process is very expensive, labor-intensive and, most importantly, associated with the need to stop the radiation monitoring process for the period of verification. Detection units can also fail, which is most often caused by a malfunction of the actual detecting elements - Geiger-Muller counters. To repair the detection unit, it is necessary to disassemble the entire device and replace Geiger-Muller counters, which takes considerable time and requires the presence of highly qualified specialists at the installation site of the system.

In addition, repair is not limited to simply replacing the detecting element with a new one, since each Geiger-Muller counter has its own correction factors that characterize the efficiency of the detector to a certain type of radiation, the degree of attenuation of radiation on the way to the working volume of the detector, etc. To configure the detection units, namely, enter the values of correction factors, taking into account which ensures the reliability of the information coming from Geiger-Muller counters, it is necessary to connect each detection unit to a computer with special software installed. The process of setting up detection units in large distributed systems containing many detection units requires stopping the measurement process, is labor-intensive and takes considerable time.

Thus, the urgent task is to ensure that verification or repair work is carried out without a long shutdown of the radiation monitoring process.

To solve the problem, it is proposed to use a modular design of the detection unit with separation of the detecting elements from the electronics unit by placing the Geiger-Muller counters in a replaceable cartridge (module), which must be replaced during the verification procedure or repair work. The modular principle of constructing the detection unit will significantly reduce the interruption time of the radiation monitoring process due to the prompt replacement of a replaceable cartridge. The automation of the process of introducing correction factors will further speed up the process of setting up the detection unit when replacing a replaceable cartridge.

A dosimeter-radiometer of ionizing radiation of a compact built-in (modular) design is known (utility model patent RU 145480 U1), containing a radiation detector, namely a p-i-n diode, in which highly doped p- and n-regions are created in a lightly doped silicon semiconductor, as well as an interface control and data transmission, calibrator, voltage converter, integrated circuit and microprocessor. The microprocessor is connected to a control and data transmission interface, which is designed to connect to the information and power buses of a mobile device. A miniature dosimeter-radiometer-spectrometer belongs to devices for monitoring the radiation situation and is designed to detect, measure and process the results of gamma radiation dose rate measurements. The dosimeter-radiometer is placed in a compact case and is designed to be quickly installed in a mobile communicator device from the group: smartphone, tablet computer, laptop and is equipped with autonomous power supplies.

The disadvantages of the analog include the lack of technical ability to quickly replace the detecting element for carrying out repairs or mandatory verification activities due to the placement of the recording part of the device in a closed housing. Another disadvantage is the lengthy and complex process of setting up detection units due to the need to connect each detection unit to a computer containing special software for making settings and correction factors.

The closest technical solution adopted for the prototype is the DBG-S11D gamma radiation dosimeter, designed for continuous monitoring of the radiation situation, namely for carrying out continuous measurements of the dose equivalent rate and the absorbed dose rate of gamma radiation (Manufacturer: NPP Doza LLC, . Moscow, state register number: 42783 - 11 https://www.doza.ru/catalog/continuous_monitoring/DBG-S11D/).

DBG-S11D consists of a detection unit and a data processing and transmission unit, which are connected to each other via cables using terminal boxes. The detection unit consists of two monoblocks, a control board and an interface board. The radiation recording monoblock is housed in a plastic case and consists of a Geiger-Muller gas-discharge counter, a high-voltage power supply board and a signal conditioner. All components of the DBG-S11D are housed in a single housing.

The main disadvantage of the prototype is the lack of automated entry of correction factor values when setting up the device. It is necessary to connect each detection unit to a computer with installed special software “Configurator” FVKM.001005-07 34 01. The procedure for setting up units that are used as part of large distributed continuous radiation monitoring systems requires stopping the measurement process, is labor-intensive and takes considerable time.

In addition, if the prototype malfunctions, it becomes necessary to replace the entire detection unit, since its design does not allow replacing only the detecting elements.

Essential common features of the prototype and the claimed invention are the purpose associated with continuous monitoring of the radiation situation, namely measuring the dose rate of gamma radiation and the use of gas-discharge Geiger-Muller counters as detecting elements.

The purpose of the present invention is to create a gamma radiation detection unit, the design of which allows for rapid replacement of detecting elements and adjustment of the unit for testing and repair work.

To achieve this goal, it is necessary to solve two problems, the solution of which is not provided by the prototype, namely, to develop a modular design of the detection unit and automate the process of its adjustment and configuration when replacing detecting elements.

The first problem is solved by implementing a modular approach to the design of the detection unit, as a result of which the device consists of two easily separated modules: a replaceable cartridge containing only detecting elements - gas-discharge Geiger-Muller counters, and an electronics unit that provides power to all elements of the detection unit, preliminary processing signals coming from meters, as well as setting up the unit and storing the received information.

The second problem is solved by introducing an automatic system for transmitting correction factors based on an identification device. The transfer of correction factors is carried out by reading information from the identification card attached to each replacement cartridge. To determine whether the ID card matches a specific replacement cartridge, identification numbers are applied to them. An identification device is additionally installed in the electronics unit, which reads the values of correction factors and enters them into the information processing and storage device.

The technical result is the ability to quickly carry out the procedure for replacing a replaceable cartridge containing detecting elements with a new one: the time to stop measurements to replace a replaceable cartridge and configure the detection unit is no more than 10 minutes.

A gamma radiation detection unit is proposed in a modular design with a replaceable cartridge containing detecting elements, designed for constant monitoring of the radiation situation and measuring the dose rate of ionizing radiation, which provides the ability to quickly replace the replaceable cartridge and automatically configure the detection unit if it is necessary to carry out verification or repair work without long-term shutdown of radiation monitoring.

In fig. Figure 1 shows a block diagram of a gamma radiation detection unit.

The gamma radiation detection unit consists of two separate modules: an electronics unit 1 and a replaceable cartridge 2. The electronics unit contains a power source 3, a shaper amplifier 4, an information processing and storage device 5 and an identification device 6. The replaceable cartridge contains an identification card 7 and two Geiger-Muller counters 8 (not shown in Fig. 1).

In fig. Figure 2 shows a diagram of a replaceable cartridge based on gas-discharge Geiger-Muller counters.

The replaceable cartridge includes two gas-discharge Geiger-Muller counters 8, two high-voltage connectors 9, four technological holes for bolts 10, which are used to connect the modules of the detection unit, and a protrusion for convenient removal of the replaceable cartridge 11.

The detection unit operates as follows.

Power source 3 generates and supplies power voltages to all elements of the detection unit. Gas-discharge counters 8 detect gamma rays. Signals from the output of each counter are supplied to the corresponding input of the amplifier-former 4. The generated pulses are supplied to the corresponding inputs of the information processing and storage device 5.

The input of correction factors corresponding to a specific replaceable cartridge with meters is carried out automatically by transmitting information from the identifier card 7 to the identification device 6. The information processing and storage device 5, based on information from the meters, calculates the dose rate values taking into account the entered correction factors. The information transmission system, its indication and further use can be implemented in various known ways and are not discussed here.

In a specific implementation of the gamma radiation detection unit, data exchange and power supply to the counters is carried out using high-voltage HSB-40 connectors or similar connections. Automatic identification uses an RFID tag attached to an ID card and an RFID reader as an identification device. Mechanical fastening of the replacement cartridge to the electronics unit is ensured by a bolted connection; The tight fit of the replaceable cartridge to the electronics unit is ensured by a rubber band laid along the body of the replaceable cartridge.

Replacing a faulty or subject to verification replacement cartridge with a new one is carried out as follows:

- Turn off the power to the detection unit.

- Unscrew the bolts one by one and remove them from the counter holes.

- Using the protrusion for convenient removal of the replaceable cartridge, the modules of the detection unit are separated.

- Attach a new replacement cartridge with an RFID tag, aligning the high-voltage connectors with the holes in the electronics unit.

- Screw the bolts into the mating holes.

- Turn on the power of the detection unit.

- Reading of correction factors occurs automatically, after which the detection unit is ready for operation.

Claims (3)

1. Modular design of a gamma radiation detection unit for continuous monitoring of the radiation situation and measuring the dose rate of ionizing radiation, containing gas-discharge Geiger-Muller counters, a power source and a shaper amplifier, characterized in that the detection unit is structurally composed of two mechanically connected modules: a replaceable cartridge containing Geiger-Muller counters and an identification card, and an electronics unit, which additionally includes an identification device and a device for processing and storing information, while the electrical connection of the modules and data exchange is carried out using sealed high-voltage connectors. 2. The modular design of the detection unit according to claim 1, characterized in that an RFID tag attached to an identification card is used for automatic identification, and an RFID reader is used as an identification device. 3. The modular design of the detection unit according to claim 1, characterized in that a smart card is used for automatic identification, and a smart card reader is used as an identification device.