RU2614318C1 - X-ray analyzer of gold and heavy elements - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: usage: for X-ray spectral analysis of gold and heavy elements. Technical character of the invention lies in the fact that the X-ray analyzer of gold and heavy elements comprises X-ray tube with a side window as a radiation source, a sample holder, the detection device with detectors disposed in line, the recording apparatus, the inputs of recording apparatus are connected to the outputs of the detector, collimators and filters of primary and secondary beams, wherein the secondary beam collimator is designed with a plurality of holes or channels, thereby the sample holder is designed to install the sample with a flat or concave working surface of a cylinder, the X-ray tube axis is positioned in the plane perpendicular to cylinder, its focus is positioned at the generating line passing through the diametrically opposite cylinder point, wherein the secondary beam collimator is designed with beam dividers in the plane axial to theelectron beam.

EFFECT: invention provides uniformity and strength of the sample, improves efficiency and expand contrast of the spectra.

4 dwg, 1 tbl

Description

The invention relates to spectrometers and analyzers for x-ray fluorescence analysis (XRF) of the composition of substances.

Known x-ray analyzers containing a radiation source, a sample holder and a detection device with energy or wave dispersion (Anisovich K.V. Fluorescence X-ray spectral analysis // Devices for non-destructive testing of materials and products. Handbook edited by V. Klyuev, book 2 , M., 1986, p. 121-183).

By energy resolution, energy dispersive spectrometers with semiconductor detectors (PDDs) are superior to those used in X-ray diffraction spectrometers with wave dispersion in the energy region above 20 keV.

The disadvantage of PDM spectrometers is that the radiation scattered from the sample overloads the detector and limits the count rate.

The prototype is an AZTEC Gold Analyzer X-ray analyzer of gold and heavy elements, containing an X-ray tube with a side window, a sample holder, a detection device with detectors arranged in a row, recording equipment, the inputs of which are connected to the outputs of the detectors, collimators and filters of primary and secondary beams, and the secondary beam collimator is made with many holes and channels (MEA Robertson. British patent No. 2196113, 1988; M.E. Robertson, C. Feather. Determination of gold, platinum and uranium in South African ores by high- ener gy XRF spectrometry. X-Ray Spectrometry, 2004, 33, p. 164-173).

To analyze the elements of the K-series radiation in the prototype, up to 12 detectors of high-purity germanium (OCH) and a 160 kV x-ray tube with a power of 3 kW are used. The sample is poured into a plastic container with a length of 30 cm and a diameter of up to 2 cm. Gold at the level of 1 g / t is analyzed in 100 g of ore in 100 seconds with a confidence level of 95%.

The disadvantage of the prototype is the differentiation of heavy particles when filling the sample into a narrow long container and the accumulation of gold at its bottom. The container complicates the compaction of the sample. Part of the irradiated zone is obscured by the sample itself, due to which the contrast worsens.

The technical result of the invention is to ensure uniformity and strength of the sample, increasing the efficiency and contrast of the spectra.

To achieve the specified technical result in an X-ray analyzer of gold and heavy elements, containing an X-ray tube with a side window as a radiation source, a holder of a cell with a sample, a detection device with detectors arranged in a row, recording equipment, the inputs of which are connected to the outputs of the detectors, collimators and filters primary and secondary beams, moreover, the collimator of the secondary beam is made with many holes and channels, according to the invention, the sample holder is made with the ability to install a sample with a working surface, flat or concave along the cylinder, on the cylinder, the axis of the x-ray tube is located perpendicular to the cylinder of the plane, and its focus is on the generatrix of the cylinder, the detectors or output holes of the collimator of the secondary beam are located on the generatrix passing through the point of the cylinder diametrically opposite to the source, moreover, the secondary beam collimator is made with dividing plates in planes axial to the electron beam.

The drawings show:

FIG. 1 - the proposed x-ray analyzer;

FIG. 2 is a view A of FIG. one;

FIG. 3 is a diagram of experiments to evaluate polarization;

FIG. 4 - experimental spectra of the radiation of a sample at different positions of the x-ray tube relative to the plane of the beams.

As the radiation source using an x-ray tube 1 with a side window (Fig. 1). The detection device 2 comprises detectors 3 arranged in a row with separate electronic paths. The inputs of the recording equipment 4 are connected to the outputs of the detectors 3.

A sample cell 6 with sample 7 is installed in the sample holder 5.

The sample holder 5 is configured to mount the sample with a flat or concave cylinder working surface on the cylinder. The axis FF _{1 of the} X-ray tube 1 is located in a plane perpendicular to the cylinder, and its focus is located on the generatrix of the cylinder at the point F ₁ .

The analyzer is equipped with a collimator 8 and a primary beam filter 9 and a collimator 10 and a secondary beam filter 11.

The detectors 3 or the outlet 12 of the collimator 10 of the secondary beam are located on the generatrix passing through the point F _{2 of the} cylinder diametrically opposite to the source.

The secondary beam collimator 10 is made with dividing plates 13 in axial (intersecting on the axis FF ₁ ) planes (Fig. 2).

The analyzer circuit as a whole can be turned upside down.

In this case, the upper surface of the sample is formed with a punch and a cell with the sample is placed on the cylinder in its lower part.

The center F _{3 of the} sample is located on the circumference of the cylinder. Non-flowing samples can be installed in holder 5 without the use of ditches.

X-ray tube 1 can be deployed back along the beam F ₁ F.

Filter 9 can be made of tin 3-5 mm thick. The secondary beam filter 11 is made of elements with an absorption edge above the energy of the analytical line of one of the elements being determined, for example, gold.

The diagrams do not show the nodes of the change of samples, filters and other details.

X-ray analyzer of gold and heavy elements works as follows.

Sample 7 with a mass of 50-100 g and a thickness of up to 2-3 cm is poured into a cuvette 6 or molded by a press. A concave-bottom cuvette 6 is filled, starting from the marginal recessed zones. Samples are irradiated and the content of the elements is judged by spectrum. The calculation of the concentrations produced by known methods.

Analyzes are carried out automatically.

When performing the analyzer, you can use a 150 kV X-ray tube and 8-12 OCHG or other detectors up to 5 mm thick arranged in 1-2 rows with loads of more than 10 ⁵ imp./s.

Matrices with many detectors are made.

You can select a radius R _{1 of the} cylinder 3-10 cm. The radius R _{2 of the} surface of the sample can be selected 1.5-2 times larger than the radius R ₁ . The size of the sample 7 along the axis of the cylinder can be chosen 2-3 times larger than the radius R ₁ .

In the table. Figure 1 shows the lines of elements determined simultaneously with gold or used as secondary beam filters. Preliminary determine the coefficients of overlap to eliminate interference.

Lead radiation can overload the detector. To suppress the emission of lead and the Compton peak in the analysis of gold, filters from element layers from tungsten to platinum up to 150 microns thick are suitable. With a large number of detectors, the thickness of this filter will be less.

On the model of the analyzer (Fig. 3) with a Si (Li) detector, experiments were performed to evaluate the polarization of the bremsstrahlung of electrons with an energy of 40-60 keV. An x-ray tube with a tungsten anode was used. The factor or coefficient of suppression of scattered radiation with energy E is estimated by the expression

where N _II and N _⊥ are the intensities of the scattered radiation or the number of pulses in the spectra when the axis of the electron beam is parallel or perpendicular to the scattering plane.

Degree of polarization

In FIG. Figure 4 shows the spectra normalized by barium peaks measured at the X-ray tube positions along the Z and Y axis. The solid line is the spectrum of the Sgd2 sample in the plane of the electron beam, the dotted line is the spectrum in the perpendicular plane. The spectra confirm a decrease in scattering in the plane of polarization. At high energies, the effect will be greater.

The experiments confirmed that:

- the bremsstrahlung of the x-ray tube is partially polarized;

- in the plane of polarization, the scattering of radiation with an energy above 44 keV decreases by 1.26 times, and at the edge of the spectrum - by 2 times (Fig. 4);

- the degree of polarization of the beam increases to 0.3 at the edge of the spectrum;

- the polarization decreases to zero in the middle part of the spectrum (by the end of the path in the anode, the electrons lose their original direction).

The projections of the primary and secondary photons onto the plane of the circuits form inscribed angles based on the diameter of the circle, and the scattering angles are equal to or close to 90 °. The electric vectors of the main radiation component in the proposed scheme converge to the generatrix passing through the point F ₂ . Photons practically do not scatter along these vectors.

With N detectors, pulse overlays are reduced by N ² times, the analysis time by N times, for example, 10 times.

The proposed analyzer is simpler and more efficient than the known wave spectrometers and spectrometers with a Barkle polarizer.

The analyzer circuitry provides separation of the secondary radiation flux and high contrast due to filters, registration of radiation at the minimum of the scattering cross section by many detectors, and the use of polarization.

X-ray analysis of K-series radiation with high penetrating power increases the representativeness of the sample, reduces matrix effects and line overlays.

The analyzer is applicable on a conveyor for analyzing crushed ore with a surface rolled on a cylinder or pulp through breakthrough-resistant concave windows made of plastic or aluminum with a thickness of 0.2-0.5 mm.

Ditches with a flat or slightly concave bottom are convenient for filling and compacting the sample and ensure uniformity, i.e. the prototype disadvantage is eliminated - the accumulation of heavy particles at the bottom of an elongated container when filling the sample. The concavity of the sample and the bottom of the cuvette provides an increase in the strength, efficiency and contrast of the spectra due to the large solid angle and a decrease in the spread of scattering angles.

Under optimal conditions and when using modern detectors with high loads, the thresholds for the detection of heavy elements in rocks reach a fraction of g / t per minute.

The proposed X-ray analyzer can in some cases replace the laborious methods of analysis with the melting and decomposition of samples, with hazardous waste and evaporation of acids, arsenic and lead, etc.

The inventive analyzer can be in demand in geology, ecology, mining and other branches of science and industry.

Claims (1)

An X-ray analyzer of gold and heavy elements, containing an X-ray tube with a side window as a radiation source, a sample holder, a detection device with detectors arranged in a row, recording equipment, the inputs of which are connected to the outputs of the detectors, collimators and filters of the primary and secondary beams, the secondary collimator the beam is made with many holes or channels, characterized in that the sample holder is made with the possibility of installing the sample with a flat or concave cylinder near the working surface on the cylinder, the axis of the x-ray tube is located in the plane perpendicular to the cylinder, and its focus is on the generatrix of the cylinder, the detectors or the output openings of the collimator of the secondary beam are located on the generatrix passing through the point of the cylinder diametrically opposite to the source, and the collimator of the secondary beam is made with dividing plates in planes axial to the electron beam.

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