RU129268U1 - FIELD SPECTROMETER GAMMA RADIATION - Google Patents

Abstract

A gamma-ray field spectrometer, characterized in that it has a detection unit and a registration unit, the detection unit includes a scintillation crystal connected in series with its inputs and outputs, a photovoltaic multiplier, a preamplifier, a controlled inverter amplifier, a peak detector, and an analog-to-digital converter, output which is connected to the first input of the microprocessor system of the detection unit, and the control input of which is connected to the first output of the microprocessor system of the unit detection unit, the detection unit also has a stabilization system, including a pulsed current generator, the input of which is connected to the second output of the microprocessor system of the detection unit, and the output is with an LED configured to provide signals to the photocathode of the photomultiplier tube, and including a thermal sensor, the output of which is connected to the second input of the microprocessor system of the detection unit, the third output of which is connected to the input of a controlled high-voltage power supply connected to its m output with a power input of the photoelectronic multiplier, the fourth output of the microprocessor system of the detection unit is connected to the control input of a controlled amplifier-inverter, the second output of which through a discriminator controlled through the control input from the fifth output of the microprocessor system is connected to the third input of the microprocessor system of the detection unit, which the sixth output is connected to the control input of the peak detector, and the bidirectional input-output is connected to the wireless module of the unit d

Description

The utility model relates to the field of detection and identification of radionuclides of various origin (natural, industrial, including medical) and can be used in laboratory and field conditions.

From the level of technological development known spectrometer MKS-AT6101 [Spectrometers MKS-AT6101. Type description. Appendix to the Certificate of type approval of measuring instruments. Entered in the State Register of Measuring Instruments. Registration No. 32791-09, the information can be found on the Internet], intended for gamma and neutron spectral scanning of the environment with reference to the terrain (GPS), control over the movement of radioactive sources and nuclear materials, and radiation mapping. The spectrometer consists of an external spectrometer unit for detecting gamma radiation and an information processing unit interconnected. The external spectrometric unit includes a NaI (Tl) scintillation detector, a photomultiplier (PMT), an analog-to-digital converter, an LED stabilization device, a digital thermal compensation of the spectrometric path from the built-in temperature sensor, and a microprocessor system. The information processing unit includes an audible alarm device, a liquid crystal screen for displaying information, a keyboard and a microprocessor system. The disadvantage of this device is the lack of means of recording explanatory information about the conditions for measuring the spectrum, that in the conditions of field pedestrian measurements, the operator is forced to manually perform a large number of actions, namely, to enter the results of measurements and a description of the conditions for their performance in the work log, which leads to a significant decrease in labor productivity operator. Another disadvantage is the presence of a cable between the two blocks of the spectrometer, which makes it difficult to manipulate the spectrometer in the field. The gamma radiation spectrometer MKSP-01 "RADEK" was selected as a prototype [The gamma radiation spectrometers MKSP-01 "RADEK". Description of the type of measuring instrument. Appendix to the Certificate of type approval of measuring instruments. Included in the State Register of Measuring Instruments. Registration No. 46000-10 with information can be found] made in the form of a monoblock consisting of a detection unit, a photovoltaic multiplier, an analog-to-digital converter and a microprocessor system. The spectrometer also contains a GPS receiver and a BlueTooth radio transmitting module for transmitting measured data to a computer. The spectrometer is used to determine the activities and specific activities of radionuclides in the samples and under conditions of natural occurrence. The spectrometer can be used for work in both laboratory and field conditions.

The disadvantage of this device is that the spectrometer is implemented as a monoblock. Given that in the field measurements are made in hard-to-reach places and in adverse conditions, this design complicates the operator’s control of the spectrometer and may not provide constant monitoring of the spectrometer’s functioning. Another disadvantage is the lack of automated means for recording explanatory information. In conditions of field measurements, the operator is forced to manually fix the coordinates of the measurement location, enter the measurement results and a description of the conditions for their measurements in the work log, which leads to a significant decrease in the operator's labor productivity.

The task that the utility model is aimed at is expanding the arsenal of tools and creating a new spectrometer that is convenient to use.

The technical result of the proposed spectrometer is:

- the ability to automate the recording of information about the conditions and place of measurement of the spectrum,

- the possibility of operational monitoring of the measurement

The problem is solved by changing the scheme of the proposed spectrometer.

The gamma radiation field spectrometer has a detection unit and a recording unit. The detection unit includes a scintillation crystal connected in series with its inputs and outputs, a photoelectric multiplier, a preamplifier, a controlled amplifier-inverter, a peak detector, and an analog-to-digital converter. The output of the analog-to-digital converter (ADC) is connected to the first input of the microprocessor system of the detection unit, and the control input of the ADC is connected to the first output of the microprocessor system of the detection unit. The detection unit also has a stabilization system, including a pulsed current generator, the input of which is connected to the second output of the microprocessor system of the detection unit, and the output is connected to an LED made with the possibility of supplying signals to the photocathode of the photoelectronic multiplier. The stabilization system also includes a temperature sensor, the output of which is connected to the second input of the microprocessor system of the detection unit. Its third output is connected to the input of a controlled high-voltage power supply connected to its output with the power input of the photoelectronic multiplier. The fourth output of the microprocessor system of the detection unit is connected to the control input of a controlled amplifier-inverter. Its second output through the discriminator, controlled through the control input from the fifth output of the microprocessor system, is connected to the third input of the microprocessor system of the detection unit. The microprocessor system of the detection unit with its sixth output is connected to the control input of the peak detector, and the bi-directional input-output is connected to the wireless interface module of the detection unit. The registration unit incorporates a microprocessor system of the registration unit, to which a display, keyboard, memory card, positioning system receiver, USB interface, Ethernet interface, registration module wireless interface module, which has two-way communication with the detection unit's wireless interface module, are connected. The registration unit also includes, connected to the microprocessor system of the registration unit, an audio amplifier, to which a microphone and speaker are connected.

The Figure shows, as an example of implementation, a functional diagram of a gamma radiation field spectrometer.

The Figure indicates: 1 - detection unit, 2 - registration unit, 3 - scintillation crystal, 4 - photomultiplier tube, 5 - preamplifier, 6 - controlled inverter amplifier, 7 - peak detector, 8 - analog-to-digital converter, 9 - controlled high-voltage power supply, 10 - LED, 11 - pulse current generator, 12 - discriminator, 13 - microprocessor system of the detection unit, 14 - module of the wireless interface of the detection unit, 15 - temperature sensor, 16 - microphone, 17 - speaker, 18 - audio amplifier, 19 - display, 20 - keyboard, 21 - cards and memory, 22 - positioning system receiver, 23 - USB interface, 24 - Ethernet interface, 25 - microprocessor system of the registration unit, 26 - module of the wireless interface of the registration unit,

The gamma-ray field spectrometer consists of two units - detection unit 1 and registration unit 2.

Detection unit 1 has a measuring circuit, which contains a scintillation crystal 3, coupled to a photoelectric multiplier 4, a preamplifier 5, the output of which through a controlled amplifier-inverter 6 and peak detector 7 is connected to an analog-to-digital converter 8. The output of the analog-to-digital converter 8 is connected to the first input of the microprocessor system 13 of the detection unit, and its control input is connected to the first output of the microprocessor system 13 of the detection unit. The detection unit 1 also has a stabilization system, including a pulsed current generator 11, the input of which is connected to the second output of the microprocessor system 13 of the detection unit, and the output is connected to the LED 10, the signals (flashes) of which are fed to the photocathode of the photomultiplier tube 4. The stabilization system includes also a temperature sensor 15, the output of which is connected to the second input of the microprocessor system 13 of the detection unit. The third output of the microprocessor system 13 is connected via a controlled high-voltage power supply 9 to the power input of the photoelectronic multiplier 4, the fourth output of the microprocessor system 13 is connected to the control input of a controlled amplifier-inverter 6, the second output of which is through a discriminator 12, controlled through the control input from the fifth output of the microprocessor system 13, connected to the third input of the microprocessor system 13. The microprocessor system 13 is connected with its sixth output to the control input of the peak detector 7, and d bidirectional input-output - with module 14 of the wireless interface of the detection unit

The registration unit 2 incorporates a microprocessor system 25 of the registration unit to which a display 19, a keyboard 20, a memory card 21, a positioning system receiver 22 are connected, for example, a GPS / GLONASS receiver, a USB interface 23, an Ethernet interface 24 and a wireless module 26 the registration unit interface having two-way communication with the module 14 of the wireless interface of the detection unit. The registration unit 2 further comprises, connected to the microprocessor system 25 of the registration unit, an audio amplifier 18 to which a microphone 16 and a speaker 17 are connected. A field gamma-ray spectrometer operates as follows.

Light flashes generated in scintillation crystal 3, when gamma radiation is transmitted, are detected by a photoelectronic multiplier, the output signals of which are amplified by a preamplifier 5 and a controlled amplifier-inverter 6 and are fed to the input of peak detector 7 and the input of discriminator 12. The peak detector receives a signal at its input , produces at its output a signal equal to the maximum input signal. The signal from the output of the peak detector 7 is fed to an analog-to-digital converter 8. If the input signal of the discriminator 12 of the pulse registration level, which is set by the microprocessor system 13 through its fifth output to the control input of the discriminator 12, the discriminator generates a signal that the microprocessor system 13 of the detection unit receives . According to this signal, the microprocessor system 13, using its first output, controls the ADC 8, which makes a measurement, the result of which the microprocessor system 13 receives through its first input, and stores it in the buffer memory, after which the microprocessor system 13 sends a control pulse from its fifth output to discriminator 12, which provides the zeroing of the signal generated by the peak detector 7.

The measurement circuit is stabilized by the reference peak formed in the gamma spectrum upon receipt of light pulses from a special LED 10 at the input of the photoelectronic multiplier 4. The LED 10 is powered by a pulse current generator 11 controlled by a microprocessor system 13. The microprocessor system 13 determines the position of the reference peak on the spectrum and then maintains its position within specified limits by controlling according to a special program that takes into account the data of temperature sensor 16, the coefficient is amplified a controlled amplifier-inverter 6 and the voltage generated by the controlled high-voltage power supply 9.

The detecting unit 1 through an additionally introduced module 14 of the wireless interface of the detection unit establishes a connection for two-way communication with the module 26 of the wireless interface of the registration unit, through which it receives commands from the registration unit and sends processing results to it.

In the process, the microprocessor system 25 displays the current results on the display 19 and plays through the audio amplifier 18 and the speaker 17 sound signals informing about the measurement process. To measure the gamma radiation spectrum, the operator on the keyboard 22 dials the “Start measurement” command, for which the microprocessor system 25 of the registration unit via the wireless interface module 26 of the registration unit, the wireless connection and the wireless interface module 14 of the detection unit sends the “Start measurement” command to the microprocessor system 13 a detection unit that measures the spectrum and then through the wireless interface module 14 of the detection unit, wireless connection and mod ul of the wireless interface 26 of the registration unit sends the results back to the microprocessor system 25. After receiving the measurement result, the microprocessor system 25 fixes the coordinates of the measurement location using the receiver of the positioning system 22, using a microphone 16 and audio amplifier 18, the microprocessor system 25 records the operator’s comments on the spectrum measurement, combines spectrum measurement results, measurement coordinates and time, and operator comments in a single file and saves it on memory card 21 as a separate on the file.

At the end of operation, the microprocessor system 25 of the registration unit via the USB interface 23 or Ethernet interface 24 can be connected to a personal computer for further processing of the measurement results.

The use of the proposed spectrometer makes it possible to automate the collection and recording of information about the conditions and place of spectrum measurements together with the measurement results, which frees the operator from the need to make handwritten entries in the log in any weather conditions characteristic of field measurements, thereby increasing operator productivity and convenience.

Also, the operator has the ability, regardless of the registration unit, which is constantly located with the operator, to move the detection unit, which allows measurements to be made in hard-to-reach places and difficult conditions for measurements, constantly monitoring the progress of measurements.

Claims (1)

A gamma-ray field spectrometer, characterized in that it has a detection unit and a registration unit, the detection unit includes a scintillation crystal connected in series with its inputs and outputs, a photovoltaic multiplier, a preamplifier, a controlled inverter amplifier, a peak detector, and an analog-to-digital converter, output which is connected to the first input of the microprocessor system of the detection unit, and the control input of which is connected to the first output of the microprocessor system of the unit detection unit, the detection unit also has a stabilization system, including a pulsed current generator, the input of which is connected to the second output of the microprocessor system of the detection unit, and the output is with an LED configured to provide signals to the photocathode of the photomultiplier tube, and including a thermal sensor, the output of which is connected to the second input of the microprocessor system of the detection unit, the third output of which is connected to the input of a controlled high-voltage power supply connected to its m output with a photoelectron multiplier power input, the fourth output of the microprocessor system of the detection unit is connected to the control input of a controlled amplifier-inverter, the second output of which is connected through a discriminator controlled through the control input from the fifth output of the microprocessor system to the third input of the microprocessor system of the detection unit, which the sixth output is connected to the control input of the peak detector, and the bidirectional input-output is connected to the wireless module of the unit d detection unit, while the registration unit incorporates a microprocessor system of the registration unit, to which a display, keyboard, memory card, positioning system receiver, USB interface, Ethernet interface, wireless interface module of the registration unit are connected, having two-way communication with the wireless interface module of the detection unit , and also includes an audio amplifier connected to a microprocessor system of the registration unit, to which a microphone and speaker are connected.

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