RU2645770C1 - Method for determining distance to gamma-radiation source - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: method for determining distance to gamma-ray source includes measurement of energy spectrum in areas of its characteristic peak of total absorption and compton scattering, performing gamma-physical calculations, determining distance from the derived dependencies. Gamma-physical calculations involve determination of number of pulses in the peak of the total absorption and the selected region of the compton scattering, correction of measurements taking into account function of detector response, algorithm of transition to the distance value.

EFFECT: increased accuracy and simplified determination of distance to gamma-radiation sources.

2 dwg

Description

The invention relates to the field of environmental protection, search and detection of radioactive sources, in particular sources of gamma radiation, as well as monitoring the radiation state of objects.

It can be used for remote detection in the field of sources emitting gamma radiation, determining the distance from sources to the place of registration, as well as improving the level of safety of work.

Known technical solution:

Application: 2001113992/282001113992/28, 05.22.2001. The method of remote detection of radioactive objects. The method consists in determining the distance to the ionizing radiation source, from the measured values of atmospheric nitrogen fluorescence intensities in the UV spectrum at wavelengths of 315.9 nm, 337.1 nm and 357.7 nm, and by determining the difference in attenuation of radiation by the atmosphere at these wavelengths to the source of radioactive contamination.

The disadvantages of the known solutions are the inability to obtain information about the form of ionizing radiation, as well as a large error in determining the distance.

The technical solution is also known:

Patent RU 2072531 C1 of 01/27/1997, a device for determining the location of point radiation sources. The inventive device contains three identical one-dimensional coding masks located in the same plane on the sides of an equilateral or rectangular isosceles triangle with m elements in each mask. At a distance from the respective masks are three identical one-dimensional position sensitive detector with m sensor elements in each detector. Each element of the detector is equipped with a detector fiber, the output of which is installed a recovery mask, consisting of m elements, which are color filters spaced across the transmission spectrum.

However, the device is difficult to manufacture, coding masks cannot provide the necessary energy range, which significantly reduces the scope

The technical solution is also known:

Patent RU 2011100561 dated 11/01/2011. A method for searching and determining the coordinates of a gamma radiation source. The method consists in detecting radiation by several detectors located on the platform of a mobile robot. Using a gamma visor, a combined picture of the video and gamma images of the studied area containing the radiation sources is obtained.

However, the implementation of the method requires a bulky collimated detection system, measurements at several points. The position of the AI is determined geometrically, and the combination of gamma and video images requires the development and manufacture of additional expensive non-standard equipment. The measurement time is very significant.

The specified solution can be considered as a prototype of the claimed.

The technical problem solved by the invention is to create technical means by which it is possible to determine the distance to gamma radiation sources in the absence of preliminary information about their activity, shape, visualization; and from one location.

The technical result provided by the invention consists in the versatility and simplicity of determining the distance to gamma radiation sources, the reliability of the information obtained regardless of the spectral composition and activity of the sources, the use of standard spectrometric equipment, and the absence of the need to measure at multiple points and collimate the detector.

The solution to this technical problem is provided by the set of essential features set forth below.

The measured spectral values of the intensity of gamma radiation are not used as absolute values, but relative (from certain ranges of the spectrum).

The spectrum of the investigated source of gamma radiation is measured at two energy sites:

- in the region of its characteristic peak of total absorption (SPP),

- in the energy region of its Compton scattering (Raman scattering).

Gamma-physical calculations, with the developed algorithm for switching from the number of detected pulses in selected parts of the spectrum, to the distance between the gamma radiation source and the place of measurement, while the dependence is derived that relates the number of recorded pulses in the indicated energy ranges to the desired distance:

Where

L [m] is the distance between the detector and the source of gamma radiation,

A _L is the ratio of the number of recorded pulses dN _cr / dN _nnn in the studied place,

And ₀ is the ratio of the recorded pulses dN _0кp / dN _0nnn on the detector surface (L = 0),

Ф _∂ - coefficient depending on the instrument line of the spectrometer,

dN _nnn , dN _cr , dN _0nnn , dN _{0 cr} - the number of recorded pulses in the areas of the peak of total absorption and Compton scattering of the gamma radiation source.

Description of the invention

When a beam of gamma radiation passes through a substance, its intensity decreases due to interaction with atoms. In the energy range 0.05 ... 3 MeV, the three processes of the interaction of gamma rays with matter are most significant: Compton scattering, photoelectric effect, and electron and positron pair formation [1].

In the photoelectric effect (photoelectric absorption), all the energy of the gamma-ray is absorbed by atoms, and the beam intensity can be determined by the ratio:

Where

μ is the linear attenuation coefficient in the substance, m ^-1 .

As a result of the Compton effect, absorption and scattering processes occur.

The intensity of scattered radiation can be determined from the relation: [2, 4]

For air in the energy range up to 3 MeV, the process of pair formation can be completely neglected [1, 4].

Thus, when gamma radiation passes through a layer of matter from certain isotopic radiation sources (III), one can distinguish 2 energy regions from their spectra:

- the region of the peak of total absorption, characterized only by absorption processes;

is the region of Compton scattering, characterized by scattering and absorption processes.

Consider the ratio of the number of γ-quanta in the Raman region to their number in the _SPP (dN _kp / dN _nnn ), (Fig. 1).

This ratio depends on:

a) the energy of the monoline (SPP) of the selected isotope,

b) - characteristics (chemical composition, shape and size) of the spectrometer detector (Ф _∂ ),

c) - characteristics of the substance between the source and the detector,

g) - the thickness of the layer of substance between the source and the detector.

Items

a), b), c) are almost always known and constant;

d) - the ratio dN _cr / dN _nnn is dependent on the thickness of the layer, and for the Earth’s atmosphere, the distance from the source of gamma radiation to the point of detection:

where from

Where

L is the distance between the radiation source and the detector of the spectrometer,

Ф _∂ is the function of the instrument line of the detector.

Therefore, knowing the energy of the SPT isotope, the instrument line of the spectrometer, μ of air, and determining the number of pulses dN _nnn and dN _cr in selected sections of the spectrogram (Fig. 1), we can determine the distance between the IRS and the detector.

To determine the desired dependence, the following gamma-physical calculations were performed:

- modeling the type and configuration of the gamma radiation detector;

- modeling of energy spectra of gamma radiation when passing through a detector and an air layer.

The program LCRM LLC EffVarke [3], the Monte Carlo method, was used.

On the spectrograms, 2 sections were identified in the above energy regions (SPP, Raman spectroscopy) and the ratios of the numbers of recorded pulses were determined (Fig. 1).

This dependence, approximated by the exponential function, has the form:

Where

L [m] is the distance between the detector and the source of gamma radiation,

A _L is the ratio of the number of recorded pulses dN _kp / dN _nnn in the studied place,

And ₀ is the ratio of the recorded pulses dN _0кp / dN _0nnn on the detector surface (L = 0),

Ф _∂ - coefficient depending on the instrument line of the spectrometer.

dN _nnn , dN _kp , dN _0nnn , dN _0кp - the number of recorded pulses in the areas of the SPP and Raman source.

To confirm the operability of the proposed method and the adequacy of the gamma-physical calculations, an experimental check was carried out using a Gelinyuk gamma-ray spectrometer (Exploranium GR-820) and an ¹³⁷ Cs isotope source with an activity of 1.1 * 10 ⁸ Bq.

The source was installed at distances of 0, 10, 40, 80, 100 meters from the detector. Energy ranges were selected:

- 630 ... 690 keV IFR - 300 ... 360 keV KP.

Spectrum acquisition time was determined by the necessary statistics.

And ° (at L = 0) amounted to ... 0.37.

Ф _∂ (in the energy range 0.3 ... 1 MeV) - 1.2.

The results are presented in FIG. 2.

The discrepancy with the calculated data did not exceed 20% with a probability of P = 0.95.

In the implementation process, the proposed method is that:

1. preliminary, for the used gamma-ray spectrometer and certain isotopic sources, it is calculated or experimentally determined

And ₀ = dN _0cr / dN _0nnn , (L = 0) on the parts of the SPP and Raman spectrum;

2. install gamma-spectrometric equipment in the studied area and conduct a set of spectrum;

3. determine the number of recorded pulses in the selected ranges dN _nnn , dN _kp and calculate their ratio

A _L = dN _kp / dN _nnn ;

4. according to the ratio proposed in the "method ..." and the obtained values of A _L and A ₀ determine the distance between the source of gamma radiation and the place of measurement:

Where

L [m] is the distance between the detector and the source of gamma radiation,

A _L is the ratio of the number of recorded pulses dN _kp / dN _nnn in the studied place,

And ₀ is the ratio of the recorded pulses dN _0кp / dN _0nnn on the detector surface (L = 0),

Ф _∂ - coefficient depending on the instrument line of the spectrometer,

dN _nnn , dN _kp , dN _0nnn , dN _0кp - the number of recorded pulses in the areas of the SPP and Raman source.

Thus, the application of this method allows you to determine the distance to the sources of gamma radiation in the absence of preliminary information about their activity, shape, visualization and from one location. The necessary data are taken entirely from the obtained spectrogram of standard spectrometric equipment, in the absence of the need for measurements at several points and collimation of the detector.

Literature

1. Workshop on nuclear physics / I.A. Antonov, A.N. Boyarkin and others. M .: Publishing house of Moscow University, 1988.

2. Israel Yu.A., Stukin E.D. Gamma radiation from radioactive fallout. Atomizdat, M., 1967.

3. Program LLC “LCRM” EffVarke, Monte Carlo method. URL: http: //www.lcm.ru

4. Mashkovich V.P., Kudryavtseva A.V. Protection against ionizing radiation.

Claims (8)

A method for determining the distance to a gamma radiation source, including measuring the energy spectrum in the regions of its peak of total absorption and Compton scattering, characterized in that the number of pulses in the peak of total absorption and the selected region of Compton scattering is determined, then their ratio is calculated, and the required distance is determined by dependencies connecting the distance with the calculated ratio:

Where L [m] is the distance between the detector and the source of gamma radiation, A _L - the ratio of the number of recorded pulses dN _nnn / dN _cr in the studied place, A ₀ - the ratio of the number of recorded pulses dN _0nnn / dN _0кр on the surface of the detector (L = 0), F _d - coefficient depending on the instrument line of the spectrometer, dN _nnn , dN _cr , dN _0nnn , dN _{0 cr} - the number of recorded pulses in the areas of the peak of total absorption and Compton scattering of the gamma radiation source.

Images