RU2538571C1 - Analysis of solid mineral samples for efficiency of lumpy luminescent sorting and device to this end - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: proposed method comprises consecutive feed of lumps in control zone for irradiation and registration of wanted signal. Said lumps are fed in said zone in fixe path with lump sides' fixation relative to wanted signal registration radiation directions with setting of unlimited control zones passages with variable irradiation and registration parameters. Proposed method is realized with the help of the device including the case, lumps feeder, irradiator and radiation receiver as well as control device. Irradiator and receiver incorporate their drives. Lumps feeder is composed of multisection trick displacing on guide shaft and provided with specimen fastener and driven by step motor with the help of drive belt. Microprocessor-based control device controls the speed of passing by of control zone, operation of irradiator, receiver and their drives as well as a series of logically related experiments with specimens runs through control zone.

EFFECT: perfected process.

2 cl, 2 dwg

Description

The invention relates to the mining industry and can be used to work out rational parameters of lumpy luminescent sorting for various types of ores (for example, scheelite-containing).

Widely known and described by a number of authors are methods of static research of sample samples for the possibility of using the technology of lumpy luminescent sorting. So, for example, the technique of lump studies of scheelite-containing ores using a fluorescent lamp (RF patent 2465459). In the process of technological mapping, lump studies of a preliminary assessment of the distribution of a useful mineral (scheelite) over the surface of lumps (particle size) are additionally carried out using a fluorescent lamp. In this case, the pieces are divided into four groups. Pieces of rock in each group differ in luminescence level:

1. Weak luminescence of individual grains.

2. Intense luminescence on one side of the piece (dispersed distribution of the useful mineral over the surface).

3. Uniform, weak luminescence over the entire surface of the pieces.

4. Uniform, intense luminescence over the entire surface of the pieces.

As a result of the studies, the WO ₃ content in the pieces of each group is determined and the feasibility (inappropriateness) of isolating the pieces of the group during separation into the enriched product is justified. To solve the problem of selective separation during separation of pieces of individual groups into an enriched product, the modes of irradiation and registration of useful signals, as well as the algorithm for processing luminescence signals, are substantiated. These studies are very important for developing the final result on the structure of enriched and tailing separation products, i.e. a very important task of justification is being solved, which quality pieces should fall into the enriched and tail products. At the same time, these studies do not give an answer on the rational parameters of radiation and registration devices, as well as on rational algorithms for processing luminescence signals to achieve the task of selecting pieces of a certain quality in an enriched product. This is a separate task that requires additional dynamic research, in fact, with great approximation simulating real processes that ensure the effectiveness of luminescent lump sorting of ores.

The closest solution is the well-known method for the dynamic study of samples of solid minerals in conditions as close as possible to industrial lump sorting. For example, using a laboratory separator type LSL-20 LLC Egont (Equipment. Separators. Luminescent separator laboratory LSL - 20 http://WWW.egont.ru). In the separator, pieces with a particle size of 20 to 3 mm are loaded into the hopper, uniformly fed by a vibratory feeder to a second vibratory feeder, on which the pieces are lined up and sequentially fed (in free fall) to the control zone. In the control zone, the pieces are irradiated with X-ray or ultraviolet rays and viewed by photodetectors. Pieces whose luminescence corresponds to the level set by the operator are separated by an electro-pneumatic valve into a concentrate collector. The separator allows you to sort the pieces according to the intensity of the glow, the time of excitation or quenching of the luminescence, as well as the spectral composition of the X-ray luminescence of minerals. Separation of pieces during registration of photoluminescence is carried out according to the intensity of the glow. The separator operates in automatic mode on the instructions of the technologist, who sets the separation border for the content of the separated metals.

This technical solution has several disadvantages associated with the method of supplying pieces to the control zone (registration zone), which does not provide for strict fixation of the piece in relation to the direction of action of the radiation and registration devices. The position of the piece passing the control zone with respect to the direction of action of the radiation and registration devices is not fixed and is random in nature. Therefore, it is not possible to compare the received luminescence signals (when passing through the control zone) with the parameters of the luminescent minerals located on the surface of the piece facing the radiation and recording devices at a given time. In addition, the trajectory of the pieces in free fall is not stable. When the pieces pass through the control zone, the distance from their surface to the radiation sources and registration of luminescence signals constantly changes. It should be noted that the magnitude of the luminescence signal varies in proportion to the ratio of varying distances from the surface of the pieces to the sources of radiation and registration raised a cubic degree. Thus, even a small spread in the motion path causes a significant change in the luminescence signals, in which a piece with a low content of the useful component and passing closer to the radiation and registration devices can form a more powerful luminescence signal and be perceived by the registration system as ore. At the same time, a piece richer with a useful component, passing at a certain distance, can form a much less powerful luminescence signal and can be perceived as pedigree. Moreover, this method of studying luminescent types of ores does not allow to repeat the experiment with the same position of the piece in the control zone (registration zone) with other radiation or registration parameters. At the same time, this research method does not exclude a hard physical effect on the pieces of rock during feeding to the control zone and at the time of selection by an electro-pneumatic valve or a slide device. As a result of physical impact on a piece of interspersed softer than the host rock of a useful mineral (for example, scheelite) are painted from the surface of the pieces. Subsequent studies of the sample using other parameters of radiation and registration of luminescence produce incompatible results with the actual content of the useful component in the pieces.

The objective of the invention is to increase the efficiency of substantiation of rational technological parameters of lumpy luminescent sorting of the studied types of ores.

The problem is solved in that the pieces are fed into the registration zone (control zone) along a rigidly fixed path and with fixing the sides of the piece relative to the radiation directions of the registration of the useful signal, providing an unlimited number of passes of the control zone with different parameters of irradiation and registration. For this, the emitter and the receiver are equipped with moving devices, and the device for feeding the pieces into the control zone is made in the form of a multi-section carriage moving along the guide shaft with a sample mounting mechanism driven by a stepper motor using a drive belt, and the control device based on the microcontroller has functions for controlling the high-speed mode of passage of samples in the control zone, functions for controlling the emitter, receiver, and devices for their movement, as well as a series of logically related experiments running samples through the control zone.

Figure 1 shows the appearance of the laboratory bench for research of technological types of ores.

1 - Moving carriage with test samples

2 - The mechanism of fixation of samples in sections of a moving carriage

3 - Stepper motor

4 - Drive belt

5 - Shaft for moving the carriage with samples

6 - Housing with radiation and registration devices

7 - Stand bed

8 - Lightproof external stand housing

Figure 2 presents a structural diagram of a laboratory bench for research of technological types of ores.

1 - Moving carriage with test samples

3 - Stepper motor

9, 10, 11, 12 - Sensors for fixing the position of the drive belt

13 - Test sample

14 - Emitter

15 - Detector

16 - Logic analyzer

17 - Gear device moving emitters and detectors

18 - Stepper motor device for moving emitters and detectors

19 - Microcontroller control functional parts of the stand

20 - Personal computer.

Case Studies

The appearance of the laboratory bench for research of technological types of ores is presented in figure 1. The bench for laboratory research of technological types of ores includes a device for feeding pieces to the registration zone - 1, which is made in the form of a movable container with a mechanism for attaching the test samples - 2. Moving the carriage with samples - 1, is carried out using a stepper motor drive - 3 and a drive belt - 4 along the guide shaft - 5. The design is assembled on a fixed bed - 6. The microcontroller - 19 solves the problem of controlling the functional parts of the stand. In particular, the microcontroller performs the functions of controlling the speed of passage of samples in the control zone, the functions of controlling the emitter, receiver, and devices for their movement, as well as a series of logically related experiments running samples through the control zone. The emitter and receiver are mounted above the trajectory of the container with the samples in the casing - 6 (on guides with the possibility of translational motion of the emitter and detector - 18 moving devices set by the stepper motor with a worm gear). This design of the mounting of the emitters and the receiver provides the ability to programmatically change (in a series of logically related experiments) the distance from the emitter and receiver to the test sample with the sample being unchanged with respect to the emitter and receiver.

The design of the stand described above provides an experiment with a series of runs of one sample, in which the position of the sample is strictly fixed, only the distance from the sample to the emitter, receiver and / or radiation parameters (spectrum, time of exposure), and the algorithm for processing luminescence signals change. Based on the results of a run using a logical analyzer - 16, a luminescence signal template is generated, the parameters of which are stored in a database on the hard drive of a personal computer - 20, and according to the results of a series of runs, a set of luminescence signal templates with parameters of the motion path.

It is necessary to highlight the most important design parameters of the stand that determine its research functionality:

1. The stroke parameters of the carriage with the test samples are established from the condition that the experiment is possible as close as possible to the real conditions of the movement of the pieces in an industrial separation unit, where the sorted pieces of rock mass are accelerated in free fall when passing from the vanishing point from a feeding-folding mechanism (vibrating feeder or stabilizing element) ) to the control zone (the area of the emitter and the registration device). In known separation devices, this distance ranges from 100 to 500 mm. The stand design includes a carriage stroke length with samples up to 500 mm.

2. The movement speed of the studied samples is an important parameter that determines the efficiency of sorting ores containing luminescent minerals (especially when it is necessary to separate luminescent useful minerals and luminescent minerals of the host rocks). Using a rational choice of this parameter (together with the parameters of the radiation device), it is possible to achieve the maximum luminescent contrast of useful luminescent minerals (which should be selected in the enriched product) and luminescent minerals of empty rocks (which should accumulate in the tail product). To solve this problem, the speed of the sorted pieces in the control zone and the width of the control zone are chosen so that the radiation exposure time on the sample is sufficient to excite the luminescence of the useful mineral, but not enough to excite the luminescence of the minerals contained in the host rocks. For example, scheelite excitation time is 2-5 μs, and calcite excitation time is 40-50 μs. In the framework of this task, to ensure maximum luminescent contrast of the separated minerals through the choice of the irradiation mode, the speed of the sample should be more than 0.5 m / s and the width of the control zone about 2 mm. In addition, to ensure the study of the modes that are most suitable for processes in industrial plants, the automated carriage control system with the samples under study has a mode in which the acceleration of the carriage corresponds to the acceleration of free fall of pieces in the registration chamber.

3. The location of the radiation and registration devices relative to the trajectory of the studied samples. In order to provide modeling and study with maximum accuracy the processes in industrial separators on the stand, it is possible to change the distances from a moving sample in the control zone to radiation and recording devices in the range from 10 to 90 mm.

4. Design parameters of the carriage with the studied samples. The design of the carriage determines the functionality of the study of the limiting distances between ore pieces, at which the registration system and the selection system (actuator) work efficiently. These features determine the following parameters for the moving carriage:

- The number of sections in the carriage determines the number of simultaneously studied samples (allows you to study the effectiveness of the registration system with different sequences of movement of ore and non-metallic samples). The construction of the stand uses a three-section moving carriage, which allows you to explore various options for the movement of ore and rock pieces;

- The dimensions of the sections determine the size of the samples and the possibility of establishing and researching, substantiating the minimum intervals of movement of the pieces in an industrial separator. In the proposed stand design, the dimensions of the section in the carriage are 100 × 41 mm. This allows you to explore the particle size classes + 1-20 mm and + 20-50 mm in a wide range of motion intervals between pieces. The minimum interval of movement between pieces is limited only by the size of the partition between sections and is 2 mm.

The claimed technical solution increases the reliability of dynamic ore research methods on the effectiveness of luminescent lump separation. The problem of factor analysis of the operation of the system for registering useful pieces during separation is being solved. This reduces the complexity of research and improves the accuracy of the rationale for rational technological parameters of lumpy luminescent sorting and the studied types of ores.

Information sources

1. RF patent No. 2465459. A method of stabilizing the quality of ores / Khakulov V.A., Novikov V.V., Kononov O.V., Sytsevich N.F., Khakulov V.V. // Bull. I. - 2012. - No. 30.

2. Equipment. Separators Laboratory luminescent separator LSL - 20 http://WWW.egont.ru

3. P.V. Naleikin, E.G. Litvintsev, B.S. Gorodets, V.A. Rasulov, V.I. Mikheikin, V.V. Zverev. Assessment of the concentrability of celestine ores by radiometric methods

4. M.L. Gaft, V.A. Rasulov, E.G. Litvintsev, E.L. Evdokimenko, V.V. Moroshkin, A.I. Chernyak, T.Yu. Hut. The use of luminescence of minerals when excited by a laser for lump separation of ores. In: Advanced scientific and production experience recommended for implementation in the exploration industry. VIEMS - M., 1989.

Claims (2)

1. A method for studying samples of solid minerals on the effectiveness of lumpy luminescent sorting, which includes sequentially supplying pieces to a control zone for irradiating and registering a useful signal, characterized in that pieces are fed into a registration zone (control zone) along a rigidly fixed path and fixing the sides of the piece relative to the directions of radiation of the registration of the useful signal with the installation of an unlimited number of passes of the control zone with varying parameters of exposure and registration. 2. A device for studying samples of solid minerals on the effectiveness of lumpy luminescent sorting according to the method described in claim 1, comprising a housing, a device for supplying pieces to the control zone, an emitter and a radiation receiver, a control device, characterized in that the emitter and receiver have moving devices and the device for supplying pieces to the control zone is made in the form of a multi-section carriage moving along the guide shaft with a mechanism for fastening samples, driven by a stepper motor with the help of Strongly drive belt, and a control device configured based microcontroller has function control high-speed mode control passage area samples, control functions emitter and receiver devices moving them, as well as a series of control functions are logically related experiments samples run through the reference zone.

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