RU2029316C1 - Spectrometer-dosimeter - Google Patents

Abstract

FIELD: nuclear technology. SUBSTANCE: measuring unit has three semiconductor detectors with different thickness and made of different materials; the detectors are located one under another. Each detector is connected in series with charge-sensitive amplifier and analog-to-digital converter, comparator, stretcher-amplifier, analog-to-digital converter. Outputs of above mentioned units are connected with data bus of single-crystal microcomputer. On-line memory, interface circuit, indication unit, control circuit, control board are connected with the microcomputer. The first control bus of single-crystal microcomputer is connected with on-line memory, interface circuit, indication unit, control board, control circuit and blocking inputs of charge-sensitive amplifiers of the first to the third channels correspondingly. The second control bus is connected with control circuit, data bus of single-crystal microcomputer, plate of the comparator and stretchers-amplifiers, analog-to-digital converters of the first to the third channels correspondingly. EFFECT: complete automation of measurement and data processing. 2 dwg

Description

 The invention relates to nuclear physics, dosimetry, nuclear instrument engineering, radiation medicine and biology.

 There are various methods for determining the radioactivity of substances, biological products, soil samples, food products, etc. Their application is usually based on the use of various techniques and instruments of nuclear physics. These are methods for measuring the radioactivity of substances using ionization, gas-discharge, scintillation, semiconductor and other counters [1,2], which are part of dosimeters. However, in practice it is often necessary to measure separately all three types of radioactivity simultaneously and using the same method (for example, in the case of studying the consequences of accidents in Chernobyl, Chelyabinsk-70, etc.).

 The use of semiconductor detectors [2] and systems of them makes it possible to create more informative and at the same time simpler, more durable and mobile devices for measuring radioactivity, which is difficult in the case of bulky scintillation and ionization detectors and low-informative gas-discharge detectors, which usually do not measure alpha radioactivity. However, the use of one semiconductor detector in a dosimeter [3] does not allow recording the dose from all types of radiation, since it is insensitive to all types of radiation at the same time.

 Known semiconductor device [4], which records charged radiation. However, it does not detect neutral gamma radiation and does not use the spectrometric and identification properties of a system of semiconductor detectors. The disadvantage is the use of analog signal processing from detectors, rather than digital, which has much greater speed and accuracy.

 A device for measuring spectra and identification of charged radioactive radiation based on the use of the ΔE-E technique on two semiconductor detectors [2,5] is known. The closest in essence to the invention should be considered an identifying spectrometer [5]. However, it does not register neutral gamma radiation and the memory unit used in it does not allow determining the radiation dose, which does not realize all the possibilities of the method.

 The invention overcomes this disadvantage, to register gamma radiation, a third semiconductor detector is introduced, which is structurally located behind the second. The third detector is selected from such a semiconductor material and such a thickness (several millimeters) to ensure the registration of gamma rays in a large energy range. It is used from a semiconductor material that is more effective for detecting gamma radiation with an energy of 0.1-10 MeV, for example, from germanium, cadmium telluride or mercury iodide, substances that are more effective for gamma radiation than a silicon detector because that the atomic number Z of germanium (Z = 32) and especially mercury iodide (Z = 80) exceeds the atomic number of silicon (Z = 14).

 Figure 1 shows a device for determining alpha, beta and gamma radioactivity of substances, biological products, soil samples, etc.

 The measurement of radioactivity is as follows. The test sample 3 is placed on the shelf of tripod 1. A telescope of 2 semiconductor detectors, consisting of three semiconductor detectors (alpha, beta and gamma) and placed in a tube, is brought close to the substance being studied for radioactivity using a tripod screw so that it can be detected alpha particles (≅ 2 cm from the substance). In the tube in the compartment behind the detectors, recording electronics and a communication device with a personal computer 4 are located. Determination of the radioactivity of substances is reduced to placing them at a distance of ≅ 2 cm to the proposed device, which consists of three semiconductor detectors of different thicknesses and of a certain material, which achieves simultaneous registration of flows energy and doses of alpha, beta and gamma radioactivity.

 The purpose of the invention is a device for the simultaneous measurement of flows, spectra and doses of alpha, beta and gamma radiation of substances, increasing information content, increasing the dynamic range of the recorded energies and doses, reducing time and increasing measurement accuracy at high speed, which is achieved by determining radioactivity using three semiconductor alpha, beta and gamma radiation semiconductor detectors of different thicknesses and from a certain material, including the use of a special (third) a gamma radiation detector with a thickness of several millimeters, which allows to significantly expand the dynamic range of the recorded gamma radiation energies by more accurate determination of the total dose and to fully automate measurements.

 The purpose of the invention is achieved in that the measurement device employs three semiconductor detectors of different thicknesses and from a certain material located one below the other, each of which is connected in series with a charge-sensitive amplifier, a comparator, a streamer-amplifier and an amplitude-to-digital converter, the outputs of which are connected to the bus data of a single-chip computer with which a random access memory, an interface board, an indication device, a control circuit, a control panel, a control bus are connected A single-chip computer is connected to random access memory, an interface board, an indication device, a control panel, a control circuit, and blocking inputs of charge-sensitive amplifiers of the first, second, and third channels, respectively, and a control bus is connected to a control circuit, a single-chip computer data bus, a comparator board, and stretcher cards -amplifiers, amplitude-to-digital converters of the first, second and third channels, respectively, thereby achieving full automation of measurements and processing Data heel.

 A significant difference of the proposed device is the possibility of separate and simultaneous registration of flows and doses of alpha, beta and gamma radiation in a large energy range, determined by the thickness of each of the three detectors, as well as the choice of semiconductor material of the detectors. This allows you to increase the accuracy of dose measurement several times in comparison with the prototype due to a more accurate determination of the energy spectrum of the recorded radiation (alpha, beta and gamma).

 The proposed distinguishing features in the aggregate are not known, therefore, the proposed solution meets the criterion of "Significant differences".

 The functional diagram of the spectrometer dosimeter is shown in figure 2.

 The spectrometer-dosimeter includes a block of 5 detectors, consisting of three semiconductor detectors (with a collimator), three identical channels, each consisting of a block of 6 analog measurements and an analog-to-digital converter (ADC) 7, control unit 8, single-chip computer 9, operational memory device (RAM) 10, indicator 11, keyboard block 12, interface block 13. The first and third outputs of a system block 5 of three semiconductor detectors 1 are connected to the first inputs of the first or third blocks of 6 analog measurements, respectively the outputs of which are connected to the first inputs of the first to third ADCs 7. The second outputs of the first to third analog measurement units 6 and the first outputs of the first to third ADCs 7 are connected to the first inputs of the control unit 8 through the control bus, and the first outputs of the control unit are connected via the control bus with the second inputs of the first to third ADC 7, respectively. The second outputs of the first to third ADCs 7 are connected to a common bus of a single-chip computer 9, to which are connected the second outputs of the control unit 8, the combined inputs and outputs of RAM 10, the first inputs of the indicator 11, the first outputs of the keyboard unit 12, the combined inputs and outputs of the interface unit 13. The first outputs of a single-chip computer 9 are connected to the first inputs of RAM 10. The second outputs of a single-chip computer 9 are connected via a control bus to the second inputs of RAM 10, the second inputs of the indicator 11, the inputs of the keyboard unit 12, the second inputs of the interface unit 13, and the second inputs the odes of the control unit 8, the second inputs of the first to third units 6 of analog measurements, respectively, and the inputs of the single-chip computer 9 are connected via the control bus to the second outputs of the keyboard unit 12, the second outputs of the interface unit 13, and the third outputs of the control unit. The first inputs and outputs of the interface unit 13 are displayed on a separate connector and are used to connect the device to a computer.

 The spectrometer dosimeter operates as follows.

 When registering alpha, beta or gamma radiation, an electric pulse from the corresponding semiconductor detector is fed to block 6, in which the signal is amplified and formed for subsequent conversion to ADC 7, as well as the formation of a trigger and identification pulse for control block 8. After conversion, the amplitude code is fixed in the ADC 7 internal register and is written to RAM 10 in the corresponding program cycle. The identification code of the detector in which the radiation is detected is generated by block 8 and the computer 9 is read out simultaneously with the amplitude code. The transformations in the three channels occur independently with a breakdown of the recorded energy range into 63 levels, which allows the analysis of the recorded alpha, beta and gamma radiation by their spectral, energy and isotopic composition for alpha radiation, using the software-implemented ΔЕ- method E, the logic of coincidences - anti-coincidences, and also determine the dose both total and for each type of radiation.

 The operation of the spectrometer-dosimeter is controlled by a computer 9 in accordance with a given mode. The mode is set by the operator in interactive mode using blocks 12 and 13. Control signals from the computer 9 to the peripheral devices are transmitted via the control bus. The system performance is achieved due to the hardware and software implementation of the data recording cycle set by the ADC 7 in RAM 10. The writing cycle is supported by the control unit 8 using the first and second control buses. The interface unit 13 provides a byte parallel or serial exchange between a spectrometer-dosimeter and a computer of any type (DVK, IBM, etc.) as well as writing and reading from any type of tape recorder.

 In accordance with a given measurement program, the computer 9 controls the operation of the spectrometer-dosimeter and accumulates information in RAM 10. Upon completion of the accumulation and processing, the data is displayed on the indicator 11 or recorded on a tape recorder, or the computer is read for more detailed analysis. The use of a computer 9 with a set of routines stored in a resident read-only memory allows you to quickly control the device, change the data processing algorithm, and use a spectrometer-identifier-dosimeter in conjunction with computers of any type (DVK, IBM, etc.).

The proposed spectrometer dosimeter allows the registration of fluxes and doses of alpha radiation with an energy of 1-25 MeV / nucleon and an activity of 0.5 becquerels / l and an efficiency close to 100%, beta radiation with an energy of 0.1-3 MeV s with an efficiency of 80%, beta radiation with an energy of 3-5.5 MeV with an efficiency of 50% and an activity of 1-2 becquerel / l, gamma radiation with an energy of 0.05-2 MeV with an efficiency of ≈20% and an energy of 2- 10 MeV with an efficiency of no worse than 10%, starting from the background values of the equivalent dose rate of 0.15 μ˙3V / h (15 μR / h). The range of recorded radiation fluxes is from the initial (background values) to 10 ⁶ particles / cm ² ˙ s. The total equivalent dose rate is also determined. A spectrometer dosimeter can be used for a wide range of tasks: from high-precision household dosimetry to special scientific research. So, for example, it allows you to measure the content of strontium-90 in food and natural objects with an accuracy of 0.1 becquerel per sample with a mass of 30 g, to determine the content of radon-222, simultaneously with its isotopes-219 and 220.

Claims (1)

 SPECTROMETER-DOSIMETER containing a block of detectors consisting of two semiconductor detectors, the first and second outputs of which are connected respectively to the first inputs of the first and second blocks of analog measurements, the first outputs of which are connected to the first inputs of the first and second analog-to-digital converters, the control unit and a single-chip electronic computer associated with the first input and output with a common bus, to which the combined inputs and outputs of the random access memory are connected VA, the first inputs of the indicator and the first outputs of the keyboard block, characterized in that a third block of analog measurements, a third analog-to-digital converter are introduced into it, and a third semiconductor detector is introduced into the block of detectors, the output of which is the third output of the block of detectors and connected to the first input the third block of analog measurements, the first output of which is connected to the first input of the third analog-to-digital converter, second inputs and first outputs of all analog-to-digital converters, the first input and output block and the controls and the second outputs of all analog measurement units are connected to the first control bus, the second outputs of all analog-to-digital converters and the control unit are connected to the common bus of a single-chip electronic computer and the combined inputs and outputs of the interface unit, the second inputs of all analog measurement units are connected to a second control bus to which a third output and a second input of a control unit are connected, a second input and an output of a single-chip electronic computer, second inputs of an operational storage and display, the second input and output interface, as well as input and output a second keyboard unit.

Images