RU2662828C1 - Radiometric separator - Google Patents

Abstract

FIELD: mining; technological processes.SUBSTANCE: invention relates to mineral beneficiation technology and can be used to pre-enrich the minerals after large or medium crushing as well as for batch sorting of the material after fine crushing. Radiometric separator contains a vibrating feeder for piecewise feeding pieces of ore for separation, a drum setter with cells corresponding to the size of the separated pieces and arranged evenly around the circumference of the drum, a source of penetrating (primary) radiation, located above the drum set and creating an irradiation strip across the motion of the pieces, a receiver of secondary radiation from the pieces, an electronic unit for the analysis of secondary radiation signals, which commands the actuator to extract useful pieces into the concentrate, electromagnet controlling the actuator, a concentrating hopper for receiving useful pieces and a tail bunker for receiving pieces of gangue. At each cell of the drum-type spreader, the bottom is made in the form of a tilting plate with two fixed positions, closed – in the irradiation zone and open – in the zone of allocation of useful pieces into the concentrate. Each cell executive mechanism is made in the form of a movable retainer holding the flip plate in the closed position in the irradiation zone and releasing it from fixation in the zone of allocation of useful pieces to the concentrate. Hopper of reception of useful pieces is located under a cell of a drum-type distributor in a zone of allocation of useful pieces and the roller located from the internal side of the panel, establishing folding plates in a starting position.EFFECT: increase the efficiency of separation.1 cl, 4 dwg, 1 tbl

Description

The invention relates to the field of mineral processing, containing minerals that respond to primary radiation, such as x-ray, and emit secondary radiation, such as luminescence, under its influence, and can be used for preliminary enrichment of mineral raw materials after large or medium crushing, and for batch sorting of material after fine crushing.

Known radiometric ore separator developed by the company EGONT LLC (St. Petersburg), designed for the separation of lumpy products with a particle size of 10 to 50 millimeters (Tereshchenko S.V. Theory and practice of radiometric methods for testing, sorting and separation of ores: Textbook / S.V. Tereshchenko, G.A. Denisov. - Apatity: Publishing House of Federal University PetrSU, 2007. UDC 622.725, 248 p., P. 161). Its design includes an ore supply unit, consisting of two vibratory feeders: the first with a flat tray for unloading the separator hopper, the second with a profile tray that divides the ore material into four streams, in which the pieces move one after another and are fed into the free fall path, dividing partitions, an x-ray block of primary radiation, providing in pieces with a conditional content of a useful component (hereinafter referred to as useful pieces) excitation of secondary radiation, a block for recording secondary signals radiation from useful pieces, including four photodetectors, one for each ore stream, an electro-pneumatic valve block (EPC) for deviating the useful pieces from compressed air path by compressed air, a receiver, to reduce the effect of a drop in compressed air pressure when the EPC is triggered, two gutters for removing separation products. It should be noted that the dividing partitions are designed to shield photodetectors from the secondary radiation of useful pieces moving in adjacent streams.

The disadvantage of the separator is the low separation efficiency due to inaccurate air jet penetration into useful pieces during their separation, which negatively affects the technological indicators of separation - skipping pieces with a high content of useful component (PC) in the tail product, as well as clogging of the separation concentrate by rock pieces . This is because the signal to isolate (hereinafter the cutoff) a useful piece from the free fall trajectory is generated by the secondary radiation signal recording unit when the pieces pass through the excitation zone, and the signal to turn on the EPA comes with a fixed delay, taking into account the passage of pieces from the registration zone to the cutoff zone . However, the speed of the pieces on the free fall trajectory has some scatter. Therefore, the air stream of the EPA does not always hit exactly the target, as a result of which part of the useful pieces are missed and enter the tail chute instead of the concentrate, and some of the breed pieces can fall into the separation concentrate. There are several reasons for the instability of the speed of movement of the pieces when moving them from the measurement zone to the cutoff zone in the specified separator:

1. When cutting off one or more useful pieces, one or more portions of air are blown into the separator separation chamber for 10-20 milliseconds in a volume of 3 to 6 liters under a pressure of six atmospheres. Spreading in all directions, part of the air flow is directed upward, against the movement of the pieces, not predictably reducing their speed. This is especially noticeable on flat pieces having a small mass, but having a large area. This factor causes a slight increase in the flight time of the pieces from the measurement zone to the cut-off zone and, as a result, a decrease in the efficiency of the pneumatic jet getting into the useful piece, while the likelihood of it getting into the rock piece increases;

2. In the separator between the transport channels on the trajectory of free fall of the pieces there are dividing partitions, which eliminate the influence of secondary radiation from useful pieces following through adjacent channels. Some pieces of ore, the size of which does not differ significantly from the width of the transport corridor - between dividing partitions, when moving, touch the surface of the partitions, reducing their own speed. This factor also reduces the likelihood of efficiently cutting off useful pieces into the concentrate trough.

Another disadvantage of the separator under consideration is the instability of pressure in the compressed air system, especially with frequent and (or) simultaneous operation of EPA in each transport channel. Despite the presence of a receiver in the separator, the air pressure on the EPA decreases with each cut-off, which reduces the energy of the impact of a stream of compressed air on a useful piece moving in free fall, increasing the likelihood of it falling into the tail channel.

In addition, since the specified separator requires the use of a compressed air system, it is therefore mandatory to maintain its quality, i.e. low humidity and exclude the ingress of foreign impurities into it, for example, technical oil used in compressor devices. A decrease in these indicators adversely affects the performance of high-speed EPCs, the separation efficiency of which depends on the quality of their work.

All of these reasons adversely affect the technological indicators of separation.

Also known, adopted as a prototype and the closest in technical essence, a separator for ore dressing, including a hopper, a vibratory feeder, a transporting mechanism in the form of a drum feeder with recesses on its surface in the form of a trapezoid for holding grains of material, an actuator in the form of a gate, a source and a penetrating radiation detector (USSR Author's Certificate N 1489041, class B03B 13/06, 1987).

The disadvantage of this separator is its use as an actuator that releases useful pieces into a concentrate trough, a gate, the use of which, due to its inertia, inhibits the performance of the separator. Upon receipt of a command by the actuator, the electromagnet is forced to overcome the resistance of the moment of inertia of the entire mobile system, including the resistance of the spring, which, after the end of the activation command, returns the entire movable system of the actuator, together with the electromagnet armature to its original state, which forces the electromagnet to increase its power, and this entails a decrease in the speed of the actuator, which leads to an increase in the distance between moving one after another kami ore mass, to exclude the allocation together with a useful piece of another, following him piece. These reasons limit the performance of the separator (Tereshchenko SV Theory and practice of radiometric methods for testing, sorting and separation of ores: a Training manual. / SV Tereshchenko, GA Denisov. - Apatity: Publishing House of Federal University PetrSU, 2007. UDC 622.725, 248 p., P. 158).

The purpose of the invention is to increase the efficiency of separation, by reducing the loss of useful pieces with the tail of the separation product, and increasing the performance of the separator, by increasing the speed of the actuator.

The present invention is aimed at achieving a technical result, which consists in increasing the efficiency of the radiometric separator, producing the separation of bulk material into products - ore containing useful pieces with a higher content of PC compared to the original ore mass, and rock containing containing pieces of empty or slightly mineralized rock (with PC content below the onboard content adopted during mining) through the use of a drum feeder with cells located and uniformly on the circumference of the drum. The bottom of each cell is made in the form of a folding plate with two fixed positions. The actuator of each cell provides the maximum accuracy of the selection of useful pieces in the concentrate, reducing the loss of useful pieces with a tail separation product, improving the technological parameters of separation.

The technical result is achieved by the fact that the proposed radiometric separator contains a vibratory feeder for piece feeding of pieces of ore for separation; a reamer with cells corresponding to the size of the separated pieces and arranged uniformly around the circumference of the drum, with the bottom of each cell of the reamer being made in the form of a folding plate with two fixed positions, closed in the area of primary radiation exposure and registration of secondary radiation, and open in the area the allocation of useful pieces in the separation concentrate (cut-off zone), and the actuator of each cell is made in the form of a movable retainer holding the reclining pl astin in a closed position in the irradiation zone and releasing it from fixation in the cutoff zone; a primary radiation source located above the drum pickup, creating an irradiation band of pieces across their movement; secondary radiation receiver from useful pieces with a PC content higher than the onboard; an electronic unit for analyzing the signals of the secondary radiation, which generates a command to the actuator to isolate useful pieces into the separation concentrate; an electromagnet controlling the actuator; a concentrate hopper for receiving useful pieces and a tail hopper for receiving pieces of waste rock; a roller located on the inside of the drum pickup, which sets the hinged plates to their original position.

The proposed radiometric separator makes it possible to reliably separate useful pieces into a concentrate due to the fact that the rotational speed of the drum pickup and, accordingly, the linear speed of the pieces moving from the registration zone to the cut-off zone is stable, which eliminates the error with a hard-set delay for actuator operation.

The increase in the speed of the actuator in the specified separator is due to the exclusion from the structure of the actuator of a massive gate with drive levers, a decrease in the mass of the armature of the electromagnet and its power, because to actuate the actuator requires only a change in the position of the movable rod, interacting with the latch only at the time of cutoff.

The invention is illustrated by the following drawings:

in FIG. 1 is a schematic illustration of a separator;

in FIG. 2 shows the cells of a drum-type distributor with an actuator and an electromagnet;

in FIG. 3 shows the dynamics of the operation of the separating device;

in FIG. 4 schematically shows an embodiment of a multi-channel separator.

The separator works as follows. The pieces of separated ore 1 and 2 (Fig. 1) from the tray of the vibratory feeder 3 are sequentially fed to a rotating drum stacker 4, cells 5, 6 of which move with a linear speed V equal to the linear speed of the pieces 1, 2 moving along the tray of the vibratory feeder 3. The bottom of each cell 7 (Fig. 2) in the initial state is held by the latch 8 in the closed position. Thus, each piece 1 and 2 (Fig. 1), falling off the vibrator feeder tray 3, is in the cell of the pickup 4, which moves them into the primary radiation zone 9, which is generated, for example, by the X-ray tube 10. When crossing the X-ray strip 9 in useful piece 1 (black), as a result of the interaction of the primary radiation 9 with the substance of the useful piece, secondary radiation 11 occurs, for example, the luminous flux of luminescence. The photodetector 12 registers the luminescence of the piece, converts this light radiation into an electrical pulse and transmits it to an electronic unit (not specified) for analysis and generation of a cutoff signal. This signal is supplied to the electromagnet 13 with a fixed delay due to the time the piece moves from the irradiation zone 9 to the cutoff zone 14. Since the speed of the pieces 1, 2 is set by the drum pickup and it is constant, the delay in the operation of the electromagnet 13 is also always constant. Upon receipt of the signal in the coil of the electromagnet 13, its anchor is attracted to the core, moving the movable rod 15 (Fig. 2) to a distance sufficient so that its edge can interact with the actuator 8, when it reaches the cutoff zone 14 (Fig. 1 ) The electromagnet 13 in the first phase of operation does not interact with the actuator 8 (Fig. 3a), because turns on before the movable latch 8 reaches the misfire zone 14 (Fig. 1). Therefore, the anchor, without significant weight, is attracted to the core of the electromagnet in a short time (1-2 milliseconds) and moves the rod 15 (Fig. 3a) to the position corresponding to the cutoff. The actuator in the form of a movable latch 8 when moving the drum-type pickup 4 runs over the extended rod 15, changes its position relative to the axis of attachment 20 and releases from fixing the bottom 17 of the cell of the drum-pickup 4 (Fig. 3b), the plate of which is folded down ( Fig. 3c). The useful piece 1 (Fig. 1) falls through and enters the concentrate groove 16. The pieces of waste rock 2 remaining in the cells of the drum-laying machine 4, when they move further, independently fall out of the cells in the lower part of the laying-out device and enter the tail channel 19. The bottom plates 17 the cells released from the latches 8 in the cut-off zone are returned to their original position by means of the roller 18 and when the drum-laying device 4 is rotated, they are set to their original closed position.

The proposed radiometric separator, in order to further increase its performance, can be performed in a multi-channel version (Fig. 4). To do this, the vibrator feeder is made multi-grooved, the drum pickup is multi-grooved, while the source of primary radiation must cover all the channels of the drum pickup, and each channel must be equipped with a secondary radiation receiver and an actuator.

The efficiency of the proposed radiometric separator is confirmed by the example of X-ray luminescent separation of a sample of apatite-containing ores (Table 1) using the EGONT X-ray luminescent separator (experiment 1) and the proposed radiometric separator (experiment 2).

It was found that the extraction of P ₂ O ₅ in the concentrate when using the proposed radiometric separator increased by 1.4 times from 53.4 to 75.8%. This was achieved by eliminating by 12% unjustified losses of pieces with a conditional content of P ₂ O ₅ in the separation tails and reducing the dilution of the separation concentrate by 3% by 3%.

Claims (1)

A radiometric separator containing a vibratory feeder for piece feeding ore pieces for separation, a drum pickup with cells corresponding to the size of the separated pieces and arranged uniformly around the drum circumference, a source of penetrating (primary) radiation located above the drum pickup and creating an irradiation band across the pieces, a secondary receiver radiation from pieces, an electronic unit for the analysis of secondary radiation signals, giving a command to the actuator to isolate useful pieces into the concentrate, an electromagnet controlling the actuator, a concentrate hopper for receiving useful pieces and a tail hopper for receiving pieces of waste rock, characterized in that in order to increase the separation efficiency, by reducing the loss of useful pieces with a tail separation product, and increase productivity separator, by increasing the speed of the actuator, the bottom of each cell of the drum distributor is made in the form of a reclining plate with two fixed positions open, in the irradiation zone and open in the zone of extracting useful pieces into a concentrate, the actuator of each cell is made in the form of a movable latch that holds the reclining plate in a closed position in the irradiation zone and freeing it from fixing in the zone of extracting useful pieces into a concentrate, the hopper for receiving useful pieces is located under the cell of the drum pickup in the area of selection of useful pieces and a roller located on the inside of the pickup, which sets the folding plates in the end new position.

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