RU2235599C1 - Method for separation of diamond-containing materials - Google Patents

Abstract

FIELD: concentration of minerals comprising minerals luminescent upon radiation.

SUBSTANCE: method involves exciting luminescence by pulsed roentgen radiation of duration sufficient for flaming up of prolonged luminescence component; measuring total intensity of short and prolonged luminescence components at the moment of action of roentgen radiation pulse; measuring intensity of prolonged delayed luminescence component after termination of roentgen radiation pulse; determining separation criterion by ratio of total short and prolonged luminescence component intensity level and prolonged luminescence component intensity level; separating useful mineral.

EFFECT: increased selectivity of separation process owing to the use of differences in kinetics of roentgen luminescence of minerals under separation process.

3 cl, 1 dwg

Description

The invention relates to the field of mineral processing containing luminescent minerals under the influence of radiation.

Known methods of separation based on the pulsed mode of x-ray irradiation of the flow of material entering the irradiation zone, as a rule, on an inclined tray. The grains of the enriched material passing through the irradiation zone at the moments of action of X-ray pulses are irradiated, under the influence of which a number of minerals, including diamonds, luminesce. From materials on the study of the nature of diamond luminescence, it is known that the processes of luminescence ignition and decay are characterized by at least two luminescence components that differ in the luminescence decay time constant. The decay time constant of the short luminescence component does not exceed 10 ^-7 s, the decay time constant of the long component reaches (l-10) · 10 ^-3 s. The evaluation of the X-ray luminescence intensity of minerals is carried out not at the moments of excitation of the X-ray pulses, but with some delay after the end of the X-ray pulse. Thus, the measurement of the afterglow of minerals, i.e. the intensity level of the long-term decay component of their luminescence. Moreover, the registration of these signals can be carried out both from the side of x-ray irradiation, and from the opposite side (the so-called X-ray absorption mode) (see Operating Instructions for the Luminescent Separator LS-D-4-03, St. Petersburg, 1997, p. 7-8; p.10; p.13-15; p.17-21).

A disadvantage of the known separation methods is the low selectivity in the processing of diamond-containing ores, especially when the content of such accompanying minerals as zircon, feldspar, plagioclase and the like is increased in deposits. The fact is that in diamonds the range of luminescence intensity, including its long-term damping component, is very wide and depends on many factors: the size and color of the crystals, the purity of their surface, the presence of cracks and chips on their faces, the spatial orientation of the diamond at the moment the intersection of the x-ray irradiation zone, the content of impurities in the diamond crystal lattice, etc. Moreover, in weakly luminescent diamonds, the signals of the long-term component are commensurate with the level of “noise” of the optical and electronic recording paths. Reliable extraction of such diamonds requires a large amplification of electrical signals, and the level of the separation threshold with which the signal from diamond is compared has to be brought close to the level of "noise". At the same time, most of the accompanying minerals, especially zircons with bright luminescence, have a significant value of the signals of the long-term afterglow component that exceeds the separation threshold. As a result, such associated minerals are perceived by the separator as diamonds and are extracted into the concentrate. An increase in the separation threshold level in order to prevent the registration of associated minerals leads to the loss of weakly luminescent diamonds, i.e. to reduce extraction.

There is also a known method of mineral separation, which consists in pulsed excitation of luminescence, measuring the intensity of the afterglow of luminescence, bringing the amplitude of the signals of the afterglow of luminescence to one level, determining the rate of change in the intensity of afterglow in a given time interval and then comparing the measured speed with pre-selected boundary values of the speed range corresponding to the lowest and the longest afterglow of a useful mineral (see a.s. 14549014, 03 B 13/06, 1995 , bull. No. 25, prototype).

The disadvantage of this method is the low selectivity of the separation process. There are several reasons for this. Both diamonds and related minerals are characterized by a variety of shapes of the luminescence decay curves described by complex mathematical expressions, i.e. for most samples of luminescent minerals, the decay curves of the long-term component of luminescence differ from the exponential function. Because of this, the rate of change in afterglow intensities even among the same type of minerals (for example, feldspars) will have a very wide spread in a given fixed time interval. The same conclusion is valid for other types of minerals, and for diamonds. Thus, the predetermined boundary values of the velocity spread, which must be satisfied by the decay rates of the long-term component of the useful mineral, should have a fairly wide range. In this case, it is inevitable that the values of the luminescence decay rates measured by this method for a significant part of the accompanying minerals will be within the boundaries of the speed range selected for the useful mineral. As a result, such minerals will be recorded as diamonds. Narrowing the range of boundary velocity values in order to increase selectivity inevitably leads to a decrease in the extraction of a useful mineral. In addition, the need to bring the amplitude of the signals to one level introduces additional distortions in the process of calculating the decay rate of a long-term component.

The technical result of the invention is to increase the selectivity of the separation process through the use of differences in the kinetics of X-ray luminescence of the separated minerals and, as a result, an increase in the percentage of useful mineral in the concentrate (improvement of condition).

The achievement of the technical result provides a separation method, including excitation of luminescence with pulsed X-ray radiation of sufficient duration to ignite the long-term luminescence component, measuring the intensity of the long-term luminescence component after the end of the x-ray pulse, determining the value of the separation criterion, comparing it with a threshold value and separating the useful mineral from the result comparison, in which the total intensity of the short and long Yelnia luminescence component at the time of X-ray radiation pulse, measure the intensity of the long component of luminescence with a delay after the pulse X-rays, determine a criterion of separation from the ratio of the total intensity level of short and long luminescence component to the level of intensity of delayed luminescence components on which produce separation of useful mineral.

In addition, the duration of the exciting x-ray pulse when measuring the total intensity of the short and long luminescence components from the side of the incident x-ray is chosen 0.4-0.6 ms, the intensity level of the long-term luminescence component is measured with a delay relative to the end of the exciting x-ray pulse 0.5- 3 ms, and the separation of the useful mineral is carried out when the ratio

(J ₁ + J ₂ ) / J ₂ <28,

where J ₁ - the intensity of the short component of the luminescence,

J ₂ is the intensity of the long-term component of luminescence.

In addition, the duration of the exciting x-ray pulse when measuring the total intensity of the short and long luminescence components from the side opposite to the incident x-ray is chosen to be 0.4-0.6 ms, the intensity level of the long-term luminescence component is measured with a delay relative to the end of the exciting x-ray pulse 0 , 5-3 ms, and the separation of the useful mineral is carried out when the ratio

(J ₁ + J ₂ ) / J ₂ <34,

where J ₁ - the intensity of the short component of the luminescence,

J ₂ is the intensity of the long-term component of luminescence.

The method is based on the experimentally established difference in the kinetics of x-ray luminescence of diamonds and related minerals. At the moment of exposure to an x-ray pulse, the level of luminescence intensity of many minerals, including diamond, is determined by the sum of the short J ₁ and long J ₂ components of the X-ray luminescence, the contribution of which depends on the physical properties of the mineral, as well as on the time of the flare-up (decay) of the long luminescence component. A duration of 0.5 ms radiation pulses is quite sufficient to flare up the long-term luminescence component of J ₂ minerals to the level of its reliable detection. At the end of the x-ray pulse, taking into account the tightening of its trailing edge, the short component of the luminescence of minerals J _i decays in a time not exceeding 150 μs.

In the proposed method, at the time of exposure to an x-ray pulse, the total intensity of the short and long luminescence components J ₁ + J _{2 is} measured, and then, with a delay selected in the interval 0.5-3.0 ms after the end of the x-ray pulse, the intensity is measured for a long luminescence components J ₂ . The decision “diamond - associated mineral” is carried out after calculating the ratio

(J ₁ + J ₂ ) / J ₂ = K, (1)

where (J ₁ + J ₂ ) is the signal amplitude of the total intensity of the short and long components of the luminescence at the time of the action of the x-ray pulse;

J ₂ is the amplitude of the intensity signal of the long-term luminescence component.

For typical separation modes, when the duration of X-ray pulses is 0.5 ms, and the pulse repetition period is 4.0 ms, numerous experimental studies have established the following:

I. In the variant of measuring the luminescence intensities (J ₁ + J ₂ ) and J ₂ from the irradiation side of the material, the ratios

K <28 - for 99.83% of the investigated diamonds;

K> 26 - for luminescent minerals represented by the highest percentage in associated ores (zircon, feldspar, picroilmenite, plagioclase, etc.).

II. In the variant of measuring the luminescence intensities (J ₁ + J ₂ ) and J ₂ from the side opposite to the direction of irradiation of the material, the relations

K <34 - for diamonds;

K> 32 for associated minerals.

However, the determination of the value of K for each luminescent mineral with existing circuit solutions used in separators with a pulsed regime of x-ray radiation, in some cases is impossible. This is explained by the very large dynamic range of luminescence intensities (J ₁ + J ₂ ) and J ₂ , the values of which have a difference reaching three orders of magnitude and depend on the physical properties of the luminescent minerals, their size, spatial orientation at the time of irradiation, cleaved faces, etc. P. In order to prevent the loss of weakly luminescent diamonds when measuring the long-term component J ₂ in the electron path of the separator with a linear gain characteristic, significant gain factors are required. In this case, bright signals when measuring the total intensity (J ₁ + J ₂ ) cause saturation of the amplifier stages, the signals are limited in amplitude, as a result, the magnitude of the electric signal does not correspond to the true intensity and, as a result, distortions are inevitable in determining K.

The method is implemented by a device whose structural diagram is shown in the drawing.

The device comprises a hopper 1, a feeder 2, a transport mechanism 3, a pulse excitation source 4, a photodetector 5 (6) mounted either on the side of the incident radiation or on the side opposite to the incident radiation, the processing unit 7 of the luminescence intensity signals, made in the form of a logarithmic amplifier the first input of which is connected to the photodetector 5 (6), the calculation unit 8 of the ratio of the luminescence components made on the basis of operational amplifiers, the first input of which is connected to the pulse source 4 excitation, and the output with block 9 of the development of commands with an actuator.

The device operates as follows.

Material from the hopper 1 is fed to the feeder 2, and from it to the transporting mechanism 3 (as an option - an inclined tray), which feeds the material into the excitation zone. The pulse source 4 generates pulses of x-ray radiation. Light signals of the luminescence of minerals at the moments of the action of x-ray pulses and after their completion are converted either by a photodetector 5 (in the variant of measuring the luminescence intensity from the side of the incident X-ray) or by a photodetector 6 (in the variant of measuring the luminescence intensity from the side opposite to the incident X-ray) signals. The signals from the photodetector 5 (6) are fed to the processing unit 7 of the luminescence intensity signals, which is made in the form of a logarithmic amplifier, which allows you to compress the dynamic range of electrical signals recorded from the photodetector 5 (6) by at least three orders of magnitude, provides sufficient amplification of weak signals and prevents the amplitude limitation of bright luminescence signals. In this case, relation (1) takes the form

ln (J ₁ + J ₂ ) / lnJ ₂ = lnK.

From the property of logarithms we get

ln (J ₁ + J ₂ ) / lnJ ₂ = ln (J ₁ + J ₂ ) -lnJ ₂ = lnK.

Thus, the estimation of the ratio of the luminescence components (J ₁ + J ₂ ) / J ₂ results in calculating the difference in the electrical signals received at the output of block 7 (logarithmic amplifier). The signals from the output of block 7 are fed to block 8, which calculates the ratio of the signals of the luminescence components, determines the criteria for sorting the minerals, and decides on the separation of the useful mineral. The algorithm for calculating the ratio of the luminescence components is as follows: the signal U ₁ is measured, which is proportional to the total luminescence intensity of the mineral (J ₁ + J ₂ ), at the time of the x-ray pulse, its value is stored for a time longer than the delay time of the x-ray pulse before measuring the intensity of the long-term luminescence component J ₂ , (for example, before the start of the next x-ray pulse); the signal U ₂ proportional to the intensity J ₂ is measured, after which the difference signal U _p = U ₁ -U _{2 is} calculated. To make the decision “diamond is an accompanying mineral”, the difference signal value U _{p is} compared with the threshold value U _threshold = lnК. The criterion U _p <U _threshold means that the diamond has been registered, in this case, a command is given to separate the useful mineral into the concentrate. The option, when U _p > U _threshold , means that the accompanying mineral passed through the registration zone, the separation command is not issued. By the beginning of the next X-ray pulse, the measured signals are zeroed, thereby preparing the electronic recording path for subsequent measurements. The commands for separation of minerals generated by block 8 are sent to the command generation block with an actuator 9, which directs the useful mineral to the concentrate receiver 10. The remaining material, together with the accompanying minerals, enters the tail receiver 11.

The application of the proposed separation method in comparison with known methods can reduce the total number of cut-offs by 4-6 times, increase the condition of the concentrate by 3-5 times, reduce the number of cut-offs per diamond by 4-5 times and bring it to a value of 1.23 cut-off by diamond, and thereby increase the selectivity of the process.

Claims (3)

1. The method of separation of diamond-containing materials, including the excitation of luminescence by pulsed X-ray radiation of sufficient duration to ignite the long-term luminescence component, measuring the intensity of the long-term luminescence component after the end of the x-ray pulse, determining the value of the separation criterion, comparing it with a threshold value and separating the useful mineral from the result comparison, characterized in that measure the total intensity of short and long luminescence component at the time of the x-ray pulse, measure the intensity of the long-term luminescence component with a delay after the end of the x-ray pulse, determine the separation criterion by the ratio of the total intensity level of the short and long-term luminescence component to the intensity level of the long-term luminescence component by which the useful mineral is separated. 2. The separation method according to claim 1, characterized in that the duration of the exciting x-ray pulse when measuring the total intensity of the short and long components of the luminescence from the side of the incident x-ray radiation is selected from 0.4 to 0.6 ms, and the intensity level of the long-term luminescence component is measured with a delay relative to the end of the exciting x-ray pulse 0.5-3 ms, and the separation of the useful mineral is carried out when the ratio

where J ₁ is the intensity of the short component of the luminescence; J ₂ is the intensity of the long-term component of luminescence. 3. The separation method according to claim 1, characterized in that the duration of the exciting x-ray pulse when measuring the total intensity of the short and long luminescence components from the side opposite to the incident x-ray, select 0.4-0.6 ms, measure the intensity level of the long-term component luminescence with a delay relative to the end of the exciting pulse of x-ray radiation of 0.5-3 ms, and the separation of the useful mineral is carried out when the relation

where J ₁ is the intensity of the short component of the luminescence; J ₂ is the intensity of the long-term component of luminescence.