RU2670677C2 - Diamond separation method and device for its implementation - Google Patents

Abstract

FIELD: technological processes.SUBSTANCE: method of separation of diamonds includes the transportation of the rock in the form of a stream of individual particles, irradiation of the rock with X-rays with a wide energy spectrum, registration of the intensity distribution of radiation passing through the section of the rock stream at different energies, determination of the presence of diamond rocks in individual particles according to the characteristic deviations of the two-dimensional distribution of the optical density of the rock particle from the individual model of the optical density of a single-component substance and the separation of such particles. Individual model of optical density is constructed for the main substance by the robust regression method as a polynomial model of two-dimensional density. Device implementing the method consists of a transporting mechanism, an X-ray source, detector device based on linear X-ray detectors (one with the possibility of recording high energy, another with the possibility of recording low energy), a filter means disposed therebetween, computer judgment means, and a reset actuator. Vertical axes of the X-ray source, filter and detector means are combined.EFFECT: accuracy of determining the diamond hidden inside the rock is increased, which increases the efficiency of the separation process.1 cl, 2 dwg

Description

The invention relates to the field of mining, namely, x-ray methods of enrichment of various rocks of minerals, and can be used in the separation of diamond-bearing rocks.

There is a method of separation of particles of useful material and a device for its implementation [patent RU for the invention No. 2517148, IPC W03B 13/00 (2006.01), priority 28.12.2012, publ. 05.27.2014, patent holders Lukyanchenko Evgeny Matveyevich, Zakharov Vladimir Gavrilovich (both - RU)]. The method of separation of particles of useful material includes irradiating the material being analyzed with a beam of primary x-ray radiation, registering penetrating x-ray radiation, comparing the signal with a threshold value and isolating the particle of useful material by comparison. The analyzed material is irradiated on a belt of a moving conveyor with a plane-parallel beam of primary x-ray radiation with a divergence of not more than 0.1 °, the cross section of which is smaller than the particle size of the useful material. After that, the intensity of the penetrating penetrating X-ray radiation is recorded by a position-sensitive detector. In this case, the X position of the particle on the conveyor belt is determined by the position-sensitive detector, and the Y coordinate is determined based on the speed of the conveyor belt. The method is carried out using a device containing x-ray-optically coupled source of primary radiation, a collimator of primary radiation and a detector. The source of primary radiation is a source of non-diverging X-ray beam with a divergence of not more than 0.1 °. The primary collimator is made in the form of a comb of a material that strongly absorbs the primary x-rays. The detector is a position-sensitive detector. The device further comprises a conveyor belt with a layer of material being analyzed, moving at a constant speed, a transmitted radiation collimator and a transmitted radiation filter installed between the transmitted radiation collimator and the position-sensitive detector. However, the selectivity and reliability of separation for rough diamonds is insufficient, since diamonds can be in the flow of material sent for separation in an undisclosed form, while there is no reliable way to distinguish the included diamond from the build-up or notch on the particle of waste rock, because for any x-ray spectrum radiation, there is the thickness of the waste rock, such that the absorption coefficient will exactly match this diamond.

There is a method of separation of diamonds [patent RU No. 2470714, IPC W03B 13/00 (2006.01), priority 07/21/2011, publ. December 27, 2012, patent holder Limited Liability Company “Laboratory of X-ray Diagnostic Systems” (RU)], including transportation of diamond-bearing rock in the form of a monolayer stream of individual particles, irradiation of the rock by X-rays, registration of the distribution of the intensity of radiation transmitted through the section of the rock stream, diamond characterization and diamond separation by magnitude characteristics. The rock is irradiated by two narrow sequentially located monoenergetic beams of radiation, the energies of which are not equal to each other. The distribution of the radiation intensity of each beam that has passed through the same section of the rock flow is recorded with the aid of two successive linear x-ray-sensitive detectors. Each of the detectors registers radiation only from the corresponding radiation beam, and the maximum spectral sensitivity of each of their detectors is equal to the energy of the corresponding radiation beam. The characteristic of a diamond is the quotient from dividing the natural logarithm of the ratio of the intensity of radiation transmitted through a diamond to the intensity of radiation passing through a diamond and any other particle of the rock, a single radiation beam, to the natural logarithm of the ratio of the intensity of radiation passing through the same diamond to the intensity radiation passing by diamond and any other particle of rock, another beam of radiation. This method is implemented by a device. The proposed method is implemented using a device consisting of: a bunker for diamond-bearing rock, a transporting mechanism (conveyor), two x-ray sources, two X-ray-sensitive detectors, an information processing unit, a reset mechanism and a drive.

This method has several disadvantages, namely:

1. A significant amount of diamonds are hidden inside the rock. As a result of the calculation of the characteristic used in this method, the section of the rock for which it was calculated falls into one of two classes: diamond or hollow rock. The method is not intended to identify diamond, hidden inside the rock.

2. The required accuracy of the calculation used in the method of the characteristic requires a high accuracy of comparison of the measurements of two consecutively located linear detectors. Such a comparison is significantly hampered by the inability to accurately control the speed of the transport mechanism and the possible displacement of rock particles during transportation from one detector to another.

3. The composition of different particles of waste rock varies due to the presence of various impurities. Therefore, the characteristic proposed in this method has a large dispersion in areas of waste rock from different particles, which does not allow it to be used to identify diamonds hidden inside the rock.

Closest to the claimed technical solution are a method and a device for the separation of bulk materials using a blowing device equipped with blowing nozzles located in the fall area, which is located after the conveyor belt [patent RU No. 2344885, IPC W07C 5/34 (2006.01), priority 25.11. 2004, publ. 01/27/2009, patent holder KommoDas GmvH (DE)]. Blowing nozzles are controlled by computer-based assessment tools, depending on the signals of radiation detectors penetrating through the bulk material flow onto a conveyor belt, which is emitted by an x-ray source and detected by detector means. X-rays that pass through the particles of the bulk material are filtered to separate at least two spectra with different energy ranges before the position-sensitive detection of this radiation, which is integrated over the energy range, using at least one detector tool. The device contains an x-ray source, computer assessment tools and detector means, at least two filtering devices are installed to at least one of the detector means, which allow the passage of x-ray radiation of mutually different energy spectra, and detector lines consisting of many individual elements located across the conveyor belt, with a line of detectors provided with each filter. The line of detectors corresponding to the width of the conveyor belt is formed by linear photodiode arrays whose active surface is covered with fluorescent paper. The filters are metal foils through which X-rays pass with mutually different energy levels and are located up to the detectors under the conveyor belt, and the X-ray tube that produces the bremsstrahlung radiation is located above the conveyor belt. The device is equipped with a shielding box located essentially above the conveyor belt and surrounding the latter and the blowing section as a casing covering the conveyor belt at the site before the x-ray source, and at the beginning of the tape the inclined tray covers the inlet flap. The device includes more than two filters to use more than two levels of energy. However, if there are diamonds hidden inside the rock, the reliability of the selection of the valuable component from the flow of the sorted material is not ensured.

The technical result of the claimed invention is to improve the accuracy of determining the diamond, hidden inside the rock, which increases the efficiency of the separation process.

The specified technical result in relation to the method, including the transportation of rock in the form of a stream of individual particles, irradiation of the rock with X-rays with a wide energy spectrum, registration of the distribution of the intensity of radiation transmitted through a section of the rock stream at different energies, determination of the presence of diamond in individual particles of the rock particles, is achieved by the fact that the presence of diamond is determined by the characteristic deviations of the two-dimensional distribution of the optical density of the rock particle from the structure Noah individual model-density single-component substances.

Regarding the device, the achievement of the specified technical result is due to the fact that in the device, including the transporting mechanism, the x-ray source, the detector means based on linear X-ray sensitive detectors, the filtering means, the computer-based assessment tools and the reset actuator, the filtering means the vertical axes of the x-ray source, filter and detector means are combined. One linear X-ray-sensitive detector is used with the possibility of registering high energy, the other with the possibility of registering low energy.

This set of features of both the method and the device was not revealed from the patent documentation and scientific and technical information, which allows to make a conclusion about the novelty of these technical solutions.

The alleged invention is illustrated graphic materials. FIG. 1 shows the sequence of operations included in the inventive method. FIG. 2 is a diagram of the device for implementing the method.

The method using the specified device is implemented as follows.

A two-channel two-dimensional image is formed from successively obtained one-dimensional tuples of measurements at different points in time, the channels of which correspond to low and high radiation energy. On the image threshold individualization of the binarization are highlighted, which are then independently analyzed. Assuming that the object consists of a single-component substance with inclusions of another substance, a polynomial model of a two-dimensional optical density is constructed for the main substance of the object using the robust regression method. The constructed model is compared with the initial two-dimensional optical density distribution, and if deviations from the model are characteristic of the presence of inclusions of diamonds in the initial substance, this object is marked as recoverable.

The proposed method is implemented using a device consisting of: a bunker 1 for diamond-bearing rock, a transporting mechanism 2, an x-ray source 3 located above the transporting mechanism, two X-ray linear detectors 4, 6 separated by a filter 5 and connected to an information processing unit 7, the output of which is connected to the reset mechanism 8, as well as the accumulator 9. Positional number 10 denotes a detachable object (a particle of rock with a diamond inside it).

The device works as follows. From the bunker 1 by the transporting mechanism 2, diamond-bearing rock is successively fed to the irradiation zone. A portion of the rock over the entire width of the tape is irradiated with an x-ray source 3 with a wide energy spectrum. The intensity distribution of the radiation transmitted through the particles is recorded at different energies with the help of two linear X-ray sensitive detectors 4 and 6, separated by filter 5 and located in the same plane with the source. The vertical axes of the x-ray source, filter and detector means are combined. Measurements from the detectors enter the information processing unit 7, which determines the presence of diamond inclusions in the rock particles and transmits the control signal to the reset mechanism 8. Thus, objects 10 with inclusions of diamonds are sent by the reset mechanism to the drive 9.

Implementation of the invention will increase the separation efficiency, increasing the extraction of diamonds due to the reliable determination of the presence of undisclosed diamonds in the rock particles.

Claims (2)

1. A device for the separation of diamonds, including a transporting mechanism, an x-ray source, detector tools based on linear X-ray detectors, filtering means, computer assessment tools and an actuator reset, characterized in that the filtering means is located between the detector means, with the vertical axis of the source X-ray, filter and detector means are combined. 2. The device according to claim 1, characterized in that, as linear X-ray-sensitive detectors, one is used with the possibility of recording high energy, the other with the possibility of recording low energy.