RU2578047C1 - Method of density determining - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: invention can be used for determination of density by irradiating the controlled substance by quanta flow from source of electromagnetic radiation. Invention consists in measurement of density by irradiating the controlled substance by quanta flow from source of electromagnetic radiation, registration of back-scattered radiation, use of intensity of radiation detector count and a calibration curve, the radiation detector count intensity is measured as well as count intensity of detector at different depth of immersion of protective shield, determining rated intensity of radiation detector count and spatial distribution of density of controlled substance by comparing the dependence of standard intensity of radiation detector counting from the depth of immersion of protective shield with calibration graphs of the standard count intensity of radiation detector from the depth of immersion of protective shield for controlled substance with various density distributions over depth.

EFFECT: technical result consists in upgraded accuracy of measurement of substances with density variable by depth.

1 cl, 3 dwg

Description

The invention relates to radiation methods for non-contact measurement of the density of a substance using electromagnetic (x-ray or gamma) radiation and can be used to increase the depth of these measurement methods, as well as in installations designed to measure density, analyze and sort substances and materials, measure density and phase composition of fluids; determining the spatial distribution of the concentration of heavy elements.

The density of the material can be determined by analyzing the attenuation of x-ray or gamma radiation passing through the substance. The desired result of the initial measurement is not the mass density, ρ, which will be the final product, but the electron density index, ρ _e , of the substance. The electron density index is related to the mass density according to the formula (1):

where Z is the atomic number of the substance, A is its atomic weight.

The attenuation of a radiation beam with an energy E, intensity I ₀ (E) passing through a material with a thickness l and density ρ _e can be written in the form (2):

where µ _m (E) is the mass attenuation coefficient of the substance, I (E) is the flux of radiation quanta to the detector.

To determine the density, I (E) and I ₀ (E) are measured, ρ _{e is} found using expression (2), then ρ is found using expression (1). The resulting density ρ is the weighted average of the densities at different depths with the weights distributed exponentially (the greater the depth, the lower the weight coefficient).

The mass attenuation coefficient µ _m (E) depends on the substance. In order to measure the density of a substance in the considered way, calibration tests are often carried out with known substances or their combinations. Thus, densitometers based on the use of x-ray or gamma radiation allow contactless control of density. They are used, in particular, when measuring density:

- aggressive, highly viscous, hot and under high pressure liquids;

- rocks in the wells;

- multiphase media flowing through pipelines;

- bulk materials and sometimes gases.

In many cases, the density of the material changes spatially. This applies in particular to bulk materials and timber. In the case of bulk material, the density near its surface may differ from the bulk due to, for example, other humidity, weight compaction or different particle size distribution. The change in density along the depth in the case of timber is related to the ring structure of the log and the presence of various defects. Knowing the change in density of a log in depth or density at a certain depth allows you to reject damaged logs or logs that show too many knots or are resinous, and also allows you to determine the price of wood. The density of oil products in pipelines can also be spatially dependent due to fractionation. Moreover, the degree of separation depends on the flow regime and can vary with time.

Radiation methods and devices used for non-contact measurement of the density of a substance are characterized by depth, which is determined by the thickness of the investigated substance, which creates 90% of the recorded signal.

Known "Measurement of density using back scattering of gamma radiation." The method includes: placing a gamma radiation detector near the tank; detection of gamma radiation from a gamma radiation source scattered in the opposite direction by a fluid medium by a gamma radiation detector; determination of the density of the fluid based on the intensity of gamma radiation scattered in the opposite direction and perceived by the gamma radiation detector. RF patent No. 2386946, IPC: G01N 9/00, 2010. Analog.

A disadvantage of the analogue is the uncontrolled effect on the results of measuring the density of deposits located on the wall. This is due to the fact that the contribution to the detector signal from various regions of the medium to be measured decreases with distance from the plane in which the source and detector of gamma radiation are located. Therefore, deposits on the wall make the most significant contribution to the value of the detector signal.

The well-known "Method of non-contact density measurement of waste rock in the composition of the rock mass on a conveyor belt." The essence of the method lies in the fact that the studied rock mass is irradiated with a gamma-ray flux of a radiation source, gamma-ray fluxes are recorded and the bulk density is determined taking into account the intensities of gamma-ray fluxes, while the bulk density of the rock placed on a moving conveyor in the rock mass, consisting of mineral and rock, is determined by the difference in DC voltage signals proportional to the intensity of direct gamma radiation passing through the furnace mass, and the intensities of scattered gamma radiation after interaction with minerals, while the flow of gamma rays of the radiation source is directed vertically up the longitudinal axis of the conveyor. RF patent No. 2492454, IPC: G01N 23/00, 2013. Analog.

The disadvantages of the analogue are:

- the dependence of the measurement results on the degree of separation of rock and mineral along the conveyor cross-section, and in the case of a sufficiently complete separation thereof also on the spatial arrangement of the focus of the scattered radiation, i.e. both the amount of rock mass and the volumetric ratio of mineral and rock in a given section;

- the need for the implementation of the method of preliminary separation of rock and minerals on the conveyor;

- the need for the location of the source and detector of radiation on different sides of the investigated object.

The well-known "Method and device for radiation measurement of the density of solids" by irradiating a controlled object with a gamma radiation flux, registering backscattered radiation and determining the density from the obtained data, in which backscattered radiation is recorded simultaneously in each of the two detector channels, approximates the distribution density function the radii of the emission of photons by an exponential dependence, in relation to the counting intensity in two detector channels, receive the integral characteristics the attenuation of the scattered radiation along the radius, on the basis of which, according to the calibration curve, the dependence of the integral characteristic on the density at a given radiation energy sets the density of the control object. RF patent No. 2345353, IPC: G01N 23/06, G01N 9/24. 2009 Prototype.

The disadvantages of the prototype are: the inability to control the depth of the method and, as a result, the low accuracy of the measurement in the case of a substance with a density variable in depth, which leads to a limited scope of the method for substances whose density is constant throughout the volume.

The low measurement accuracy in the case of a substance with a density variable with depth in depth is due to the fact that the density of the radiation entering the detector almost exponentially depends on the path traveled by the radiation from the source to the detector in the controlled substance. Therefore, the main contribution to the detector signal is made by the areas adjacent to the surface of the controlled substance between the source and the radiation detector and often differ in density from the rest of the controlled substance.

The technical result of the invention is the ability to control the depth of the method and, as a result, increase the accuracy of the measurement in the case of substances with a density variable with depth and expand the scope.

The technical result is achieved by the fact that in the method of determining the density by irradiating the controlled substance with a quantum stream of an electromagnetic radiation source, registering the backscattered radiation, using the count rate of the radiation detector and the calibration graph, the count rate of the radiation detector and the count rate of the monitor detector are measured at various immersion depths of the protective screen, determine the normalized count rate of the radiation detector, find the spatial p spredelenie density controlled substance by comparing the dependence of the normalized intensity of the radiation detector count on the depth of immersion of the protective screen with calibration graphs of the normalized intensity of the radiation detector count on the depth of immersion of the protective screen obtained for controlled substances for different distributions of the density of its depth.

The invention is illustrated in FIG. 1-3.

In FIG. 1 shows an example of one of the devices providing the implementation of the method, where: 1 - radiation source, 2 - radiation detector, 3 - protective shield, 4 - controlled substance, 5 - radiation quanta, 6 - monitor detector.

In FIG. 2 and FIG. Figure 3 shows the dependences of the relative contribution to the flux of radiation quanta 5 to the detector 2 layers of the controlled substance 4 of different thicknesses, calculated under the condition that: the distance L between the generator 1 and detector 2 is 20 cm, and the density of the controlled substance 4 is 2.7 g / cm ³ . The calculations were performed for various sources of electromagnetic radiation: X-ray generators with a voltage on the X-ray tube of 250 kV and 400 kV, respectively, as well as an ¹³⁷ Cs isotope source with 662 keV gamma-ray energy.

The dependencies shown in FIG. 2 and 3 are obtained respectively in the absence and in the presence of a protective shield 3 made in the form of a 1 cm thick tungsten plate and introduced into the controlled substance 4 to a depth of 2 cm.

The device comprises: a radiation source 1 with a monitor detector 6; a radiation detector 2 located at a distance L from the generator; a protective screen 3 and a device for immersing it inside the controlled substance 4 (not shown in Fig. 1) located between the source 1 and the detector 2. When measuring, the source 1 and the detector 2 are located near or on the surface of the controlled substance.

Scintillation detectors, for example, based on a scintillator in the form of a sodium iodide crystal (NaI: Tl) optically coupled to a photomultiplier, can be used as detector 2 and monitor detector 6. The monitor detector 6 may not be used, in particular, in the case of a sufficiently high stability of the output of the x-ray generator.

The protective screen 3 is made of a material that effectively attenuates x-rays. Such materials, in particular, are lead and tungsten. The dimensions of the protective screen 3 should be sufficient to prevent quanta 5 from directly from the source 1 to the detector 2, bypassing the controlled substance 4, at any depth of immersion of the protective screen. The thickness of the protective screen d is determined from the ratio:

L> d >> 1 / µ,

where: µ is the coefficient of linear attenuation of radiation in the material of the protective shield, L is the distance between the radiation source and the X-ray detector.

The quanta 5 leaving the source 1 towards the controlled substance 4 partially enter into it. As you move away from source 1, the flux of quanta 5 decreases due to photoabsorption and Compton scattering by the atoms of the controlled substance 4. The quanta 5 that fall on the protective screen 3 are absorbed in it. The fraction of quanta 5 that reached detector 2 depends on the density ρ of the controlled substance 4, distance L, and also on the immersion depth of the protective shield 3 in the controlled substance 4. The quanta 5 that reach detector 2 cause the formation of electric pulses in it, the number of which is proportional to the flux quanta. A change in the immersion depth of the protective shield 3 in the controlled substance 4 leads to a change in the thickness of the layer of the controlled substance 4, from which the quanta 5 can enter the detector 2, and, consequently, to a change in the intensity of the electrical impulses arising in the detector 2.

If the depth of the method for measuring density is determined as a layer of a controlled substance with a thickness that determines 90% of the total quantum flux 5 to detector 2, then, as can be seen from FIG. 2 and FIG. 3, when using x-ray generators with a voltage of 250 kV and 400 kV on the x-ray tube, the introduction of a protective shield 3 inside the controlled substance 4 by 2 cm leads to an increase in the depth of the method from ≈7.5 cm to ≈9 cm and from ≈8.5 cm, respectively up to ≈10 cm. In the case of an ¹³⁷ Cs isotope source, the introduction of a protective shield 3 does not increase the depth of the method, but, like in the case of X-ray generators, it provides a density measurement in regions of the substance under control 4 more remote from the surface. From FIG. 3 it can be seen that the layer of the controlled substance 4 with a thickness of 2 cm (the depth at which the protective shield 3 is inserted) does not contribute to the flux of quanta 5 to the detector 2. Thus, by changing the immersion depth of the protective shield 3, it is possible to change the thickness of the layer of the controlled substance 4, for which density measurement is performed.

The method is implemented as follows.

Place the device and the protective screen 3 on the surface of the controlled substance 4.

They turn on the power of electronic devices: source 1 (when using an X-ray generator), detector 2 and monitor detector 6.

The controlled substance 4 is irradiated with a stream of electromagnetic radiation. The radiation of the source 1 partially enters the controlled substance 4, passes through it and goes to the detector 2. The protective screen 3 prevents quanta 5 from directly from the source 1 to the detector 2, bypassing the controlled substance 4.

Measure the intensity of the count of electrical pulses obtained using the detector 2 and the monitor detector 6.

Find the ratio of the count rate of the detector 2 to the count rate of the monitor detector 6, obtaining a normalized count rate of the detector 2.

Re-find the normalized count rate of the detector 2 at different immersion depths of the protective screen 3 inside the controlled substance 4.

The dependence of the normalized count rate of the detector 2 on the immersion depth of the protective screen 3 is built.

Get a set of calibration graphs for a given substance with various depth density distributions according to the results of numerical modeling (Patent RU No. 2386946, IPC G01N 9/00, 2010) and / or by measuring test samples (GOST 23061-90. Soil. Methods of radioisotope density measurements. OKSTU 2009 and patent RU No. 2249836, IPC: G01V 5/12, 2005).

The obtained dependence of the normalized count rate is compared with calibration graphs from the set.

The spatial distribution of the density of the controlled substance 4 is determined from the calibration graph that is most consistent with the experimentally obtained dependence of the normalized counting intensity of detector 2, using one of the criteria of probability theory.

Claims (1)

A method for determining the density by irradiating a controlled substance with a quantum flux of an electromagnetic radiation source, registering back-scattered radiation, using the count rate of the radiation detector and the calibration graph, characterized in that the count rate of the radiation detector and the count rate of the monitor detector at different immersion depths of the protective screen are measured, and the normalized counting intensity of the radiation detector, find the spatial distribution of density ontroliruemogo substance by comparing the dependence of the normalized intensity of the radiation detector count on the depth of immersion of the protective screen with calibration graphs of the normalized intensity of the radiation detector count on the depth of immersion of the protective screen obtained for controlled substances for different distributions of the density of its depth.

Images