RU2273523C1 - Device for extraction of valuable components by density - Google Patents

Abstract

FIELD: mining industry; extraction of valuable components by density, for example, extraction of noble metals and rare minerals, metals and tin.

SUBSTANCE: proposed device includes supporting frame, deck plate with riffles used for discharge of light fraction of mixture, drive, deck plate position control system, water supply and distributing system and loading bin. Device is provided with partition-splitter mounted on deck plate for forming gap between deck plate and/or riffles over part of its length; loading bin consists of at least two sections; deck plate is provided with additional riffles whose direction differs from that of riffles used for discharge of light fraction of mixture. Depth of riffles used for discharge of light fraction and additional riffles is no less than 2 mm; deck plate is made in form of parallelogram at acute angle of 75-82°; additional riffles are located at angle of 5-15° relative to one sides of deck plate.

EFFECT: enhanced efficiency of separation of minerals by density; increased productivity of equipment.

9 cl, 2 dwg

Description

The invention relates to the mining industry and can be used to extract valuable components by density, for example, to extract precious metals, as well as minerals of rare metals and tin.

Known devices made in the form of concentration tables of the SKO-7.5 type, which are used mainly in the finishing cycle of rough concentrates (catalog "Supporting concentration tables" SKB GOM, Novosibirsk, 1978 - analogue).

The disadvantages of these devices are: high weight (~ 1.5 t), large overall dimensions, low specific productivity (t / (m ² · h)), lack of operational adjustment of the longitudinal inclination of the deck.

The main disadvantages can also be attributed to the fact that they provide low density separation of minerals, especially in the case of complex material composition of the mineral mixture.

Known devices for the extraction of valuable components, made in the form of concentration tables with a rhomboidal deck firm Jemeni (prospectus from Mineral Deposits Ltd "Gemeni Table", US patent No. 4758334, CL 03 03 5/04, 1985), and SKO - 3 , 5 (RF patent No. 2100085, 03 B 5/04, 09/06/95, bull. No. 36, 12/27/97).

The concentration table SKO-3,5 has a large mass (2.9 t) and significant dimensions. Concentration tables SKO-3,5 do not allow deep finishing of rough concentrates, and the narrowing trough installed on the deck does not give the desired effect of preliminary concentration.

The concentration tables of the company "Jemeni" are applicable for the extraction of particles of valuable components with only fineness of less than 0.1 mm due to the small depth of the grooves. The disadvantages of these tables include the impossibility of setting the optimal tilt angles of the deck in the longitudinal and transverse directions, and the manufacture of a deck with a rhomboid shape is difficult.

The known concentration table with a deck in the form of a parallelogram with an acute angle of 70 ° (diagonal) SKO-2, manufactured by Trud OJSC, Novosibirsk, which has been widely used in the domestic practice of mineral processing (Donchenko A.S., Donchenko V.A. . Handbook of the mechanics of the ore dressing factory. M: Nedra, 1975, pp. 171-178; Handbook of ore dressing, in 3 volumes, vol. 2 "Basic processes", edited by OS Bogdanov. M. : Nedra, 1974, pp. 83-103 - prototype).

The curving of the deck of the SKO-2 table is located at an angle equal to ~ 20 ° relative to the bottom edge of the deck, which negatively affects the movement of valuable minerals through the inter-groove channels due to excessive lifting. At the same time, the coupling of the drive head and the deck is not located in the center of the aft part (side of the deck to which the drive head is connected), which causes vertical vibrations at the corners of the deck during table operation. To eliminate them, the deck frame must be strengthened, which causes an increase in its mass. To maintain the asymmetric motion of the deck, the head of the drive table must also be strengthened and, therefore, also have a large mass.

The depth of the corrugations in the region of the formation of the “head” of the table (edge) is 1 mm, which is insufficient for the concentration of noble metal particles with complex morphology due to their drift with wash water. On concentration tables of this type, when the angle of the transverse inclination of the deck to the horizon in the range of 5-10 ° is observed, a violation of the process is observed due to deviation of the line of movement of the deck from the axial direction. This is due to the fact that the lower rubber shock absorbers are located at the same level and the height of the support posts is not the same. The irrigation system for deck tables with flush water is imperfect. During the process of selective separation of minerals in the case of setting the angle of the longitudinal inclination of the deck in the range of 1.5-2 °, dehydration of the deck is observed in the area of unloading of the concentrate.

Due to the above disadvantages, this device is ineffective, and sometimes unacceptable, for example, for processing material with a complex material composition.

As a rule, the general requirement for the enrichment process on the tables is the need for size classification with the removal of particle size classes of more than 3 mm.

The problem to which the present invention is directed, is to increase the efficiency of separation of minerals by density on concentration tables during processing of materials with different material composition fineness (-30 + 0,01) mm with a variety of morphology of valuable components, while reducing the mass-dimensional characteristics of the device .

This problem is solved by the fact that in the inventive device for extracting valuable components by density from an initial mixture containing a support frame, a deck with riffles serving to remove a light fraction of the mixture, a drive head, a deck position control system, a water supply and distribution system and a loading hopper additionally installed a partition-cutter placed on the deck and made with the possibility of a gap with the deck and / or corrugations on part of its length, the loading hopper is made up of at least sections, on the deck, at least under the loading hopper, additional riffles are made, the direction of which differs from the direction of the riffles designed to divert the light fraction of the mixture, and the riffle depth is at least 2 mm, and the deck is made in the form of a parallelogram with an acute angle of 75 -82 °.

In the device, additional riffles can be located at an angle of 5-15 ° to one of the sides of the deck (to the upper side).

In the device, the flutes for the removal of light fractions and / or additional flutes may have a constant or variable depth along the length.

In the device, the partition-cutter placed on the deck is configured to form a gap in its upper zone with the deck and / or riffles, at least a part of its length.

In the device, the deck position control system may include racks connecting the deck to the support frame.

In the device, the pitch angle of the deck can be no more than 3 °, and the transverse angle of the deck can be no more than 10 °.

In the device, the water supply and distribution system may include a water distributor and a spray.

In the device, the corrugations for the removal of light fractions are located at an angle of 8-15 ° to the bottom edge of the deck.

The long-term practice of using concentration tables in the enrichment of ores and sands of precious metals, rare metals and tin in processing plants, mines and in painstaking artels shows that all existing domestic and foreign devices have common disadvantages:

a) low specific productivity (t / (m ² · h));

b) high mass and significant overall dimensions;

c) low efficiency in the enrichment of a material with a complex material composition;

d) unacceptability in the allocation of precious metals with complex morphology.

This is because the design of the concentration tables is based on the method for separating minerals by density in a thin layer in an aqueous medium, mainly due to asymmetric reciprocating movements caused by the drive head. This does not take into account the material composition of the mineral mixture, the shape of the particles of valuable components, and often their size. On the deck of the concentration table, there are phenomena that explain the low efficiency of the allocation of valuable components:

a) compaction of a layer of heavy minerals in the inter-groove space, which reduces its segregation;

b) the displacement of particles of noble metals with complex morphology from the interfacial space with heavy minerals;

c) the almost complete absence of advancement on the inter-groove space of particles of valuable components having a rounded shape; especially with insufficient effectiveness of the drive mechanism (tables type SKO);

d) the separation of minerals by density occurs mainly at the moment of moving the mineral layer across the grooves, which is often ineffective.

The inventive device is illustrated by the drawings shown in figures 1 and 2.

Figure 1 presents a longitudinal section of a device for extracting valuable components; figure 2 - a view of figure 1.

A device for extracting valuable components by density from the initial mixture contains a support frame 1, deck 2 with grooves 3, used to divert the light fraction of the mixture, a deck control system 2. The deck control system 2 contains a drive - an electric motor 4, racks 5 and 7 with rubber shock absorbers , deck 2 is installed on the uprights 5 and 7. The device also contains a drive head 6 mounted on the support frame 1, elements, for example, support racks 7, for adjusting the angles of the longitudinal and transverse tilts of deck 2. The device is equipped with a stop 10 nnym to enhance asymmetric deck movement. The device also contains a water supply and distribution system, consisting of a water distributor 8, drain troughs 9 and spray 11, as well as a loading hopper 12 and a partition-cutter 13 mounted on deck 2 and configured to form a gap with deck 2 and / or riffles 3 and / or flutes 16 on part of its length. The loading hopper 12 can be made up of three parts 14, 15 and 17, and on deck 2, at least under the loading hopper 12, additional riffles 16 are made, and their direction B differs from the direction B of the riffles 3 intended for the removal of light fraction mixtures. Flutes 3 and 16 are performed with a depth of at least 2 mm, and deck 2 in the form of a parallelogram with an acute angle α = 75-82 °, for example, α = 80 °.

Additional flutes 16 can be located to one of the sides 2 (upper side) at an angle β = 5-15 °, the device contains racks 7 connecting deck 2 with the supporting frame 1.

The loading hopper 12 consists of several sections and allows you to feed material to various points of the upper zone of the table deck, depending on the morphology of the particles of valuable components and their content. Material with a simple material composition is fed into section 17 of the loading hopper 12 (slurry receiver) located in the upper corner of deck 2. As the material composition of the material becomes more complicated and the content of valuable components increases, it is fed to the next sections of the loading hopper 12 up to the last section 14.

On deck 2, under the loading hopper 12, additional riffles 16 are made, the direction of which B differs from correction B in riffles 3 for the removal of a light fraction. The corrugations 3 are located to the lower edge of deck 2 at an angle of 8-15 °, with this design of the deck, a more efficient separation of minerals by density is provided with increased selection when isolating difficult to recycle particles and valuable components. The depth of the additional corrugations 16 is variable, but not less than 2 mm. Additional corrugations 16 are located, for example, at an angle β = 10 ° to one of the sides of the deck (upper side). These corrugations provide effective capture of valuable components at the moment of the greatest loosening of the mineral mixture, which is observed at the point of contact with the deck 2 of the table. In this case, the flutes 16 provide accelerated advancement of the bottom layer by creating a direction to the flow of pulp along the slope of the deck 2.

Deck 2 is performed in the form of a parallelogram with an acute angle α = 75-82 °. If the angle α <75 °, then the docking of the drive head and deck is rather significantly offset relative to the center of the aft deck, which leads to the formation of significant vertical vibrations of the deck and, in addition, the asymmetric movement of the deck is distorted during operation of the deck, and its ellipsoidal and circular movements occur which leads to a sharp decrease in the efficiency of separation of minerals.

If the angle α> 82 °, then during operation of the device there is no effect of flushing waste rock with oncoming streams of water and, therefore, the device does not provide effective separation of minerals.

The inventive shape of the deck 2 provides docking with the drive head 6 in the center of the stern of the deck 2, which eliminates its vibration in the corners, and also reduces the slope of the lifting of the material in the diagonal direction. In this case, the mass of deck 2 is reduced four times, which increases the efficiency of the drive head 6.

The device is equipped with a baffle-cutter 13 mounted on deck 2 with the possibility of forming a gap with deck 2 and / or riffles 3, and / or riffles 16 for parts of its length. The partition-cutter 13 is made in the form of a plate mounted behind the loading hopper over the entire width of deck 2. The gap is formed above deck 2 and additional grooves 16 and partially above the nearby grooves 3 and can have a variable length and height due to the movement of the partition-cutter 13 along the grooves (not shown in the drawing).

Thanks to the baffle-cutter 13, the enriched product with a particle size of (-5 + 0.01) mm is separated from the bulk of the waste rock and sent through the gap to the edge region of the grooves 3. The waste rock is transported along the slope of deck 2 without falling into the concentrate formation area, since the bottom part of the partition-cutter 13 does not have a gap with the surface of the deck 2.

Additional flutes 16 and flutes 3 for the removal of light fractions can have both constant and variable depth along the length, but not less than 2 mm, and their depth in each case can be the same.

If the depth of the grooves is less than 2 mm, then valuable components are not retained in the inter-groove channels of the deck and are washed off with water into the dump products.

Based on theoretical and experimental studies, the applicant found that when the depth of the grooves is more than 80 mm, no light fraction is separated from the mixture, i.e. there will be no separation of the components of the mixture, the device will be inoperative.

The depth of the grooves 3 at the ends is at least 2 mm, which optimizes the operation of the device and ensures the advancement of the “head” in the form of a continuous strip without loss. In addition, the high ends of the corrugations 3 contribute to the creation of a water barrier (hill), which, as a result of a water hammer (from the drive head 6), holds valuable components, dilutes the “head” and promotes its advancement. At the same time, gangue minerals present in the pre-enriched product, under the influence of incoming flushing water, are directed along the inter-groove channels in the opposite direction downhill.

The docking unit of the drive head 6 (crank) and table deck 2 consists of a support with rubber shock absorbers 5, a hinge 18 and a conical connection 19 and a rod of the drive head 21, which allows you to adjust the angles of the longitudinal and transverse tilts of the deck relative to the horizon. The pitch angle of the deck is not more than 3 °. The transverse tilt angle of the deck is not more than 10 °.

To maintain the same dimensions in height of the support racks 7, which simultaneously serve as adjusters of the angles of the longitudinal and transverse tilts of the table deck, the support racks 7 are equipped with a device consisting of compensator corners 20 with grooves for setting their optimal position. Compensation corners 20 are installed and bolted before the installation starts, with the same height of the support posts 7 and with a longitudinal tilt angle of the deck + 1.5-2 ° and a transverse tilt angle of the deck 5-6 ° More precise adjustment of the tilt angles of the deck 2 with the help of rotary mechanisms does not distort the trajectory of the deck.

The deck irrigation system has been improved with flushing water. Spray 11 can consist of either one or several autonomous sections, mounted on the sides of the deck 2, connected to the water distributor 8 by means of flexible hoses (not shown in the drawing).

One of the sprinklers 11 is installed along the front edge of the table deck 2, made in the form of a tube with holes and is designed to irrigate the deck 2 with flush water in case of setting its longitudinal angle of more than 1.5 °.

The device is equipped with a stop 10, which increases the efficiency in the separation of minerals fineness less than 0,044 mm

For effective shut-off and withdrawal of the concentrate of valuable components, a cutter 22 is installed, the position of the knife of which is fixed in the desired position.

The proposed device, made in the form of a concentration table, operates as follows. The source material in the form of pulp with a liquid to solid ratio of 4-10: 1 with a grain size of up to 30 mm is fed through a loading hopper (slurry receiver) 12 to deck 2 of the table. Depending on the content of valuable components and material composition, the material is fed into different sections of the slurry receiver 12.

The separation of valuable components from gangue minerals takes place on the flutes 16 located under the feed hopper 12. The operator sets the required gap between the partition-cutter 13 and deck 2 and / or flutes 3, 16 depending on the size and quantity of valuable components. Further, the pre-enriched product, passing through the gap, is transported along the edges of the reflexes 3. To clean the concentrate from mineral impurities, the operator adjusts the optimal longitudinal and transverse angles of the deck using the rotary mechanisms of the support posts 7. At the same time, the concentrate strip 60-70 mm wide should move towards the unloading direction, and the impurity minerals are washed off with water throughout the entire path to the depth of deck 2 along the flutes 3. The amount of flush water is visually determined using all sprays 11 installed along the sides of the deck 2. The resulting concentrate, as necessary, is subjected to one or more purification operations in the same manner as the original product.

The performance of the device will depend on the material composition of the starting material, as well as the content of valuable components in it.

Claims (9)

1. A device for extracting valuable components by density from the initial mixture, containing a support frame, a deck with flutes serving to remove a light fraction of the mixture, a drive, a deck position control system, a water supply and distribution system and a loading hopper, characterized in that the device is additionally equipped with a shutoff partition mounted on the deck and configured to form a gap with the deck and / or flutes on a part of its length, the loading hopper is made up of at least two sections, on the deck, To a lesser extent, additional riffles are made under the loading hopper, the direction of which is different from the direction of the riffles for the removal of the light fraction of the mixture, and the depth of the riffles for the removal of the light fraction of the mixture and additional riffles is at least 2 mm, and the deck is made in the form of a parallelogram with an acute angle of 75 82 °, while additional riffles are located at an angle of 5-15 ° to one of the sides of the deck - the upper side. 2. The device according to claim 1, characterized in that the flutes for removal of the light fraction and / or additional flutes have a constant depth. 3. The device according to claim 1, characterized in that the riffles for removal of the light fraction and / or additional riffles have a depth that is variable in length. 4. The device according to claim 1, characterized in that the deck position control system comprises racks connecting the deck to the support frame. 5. The device according to claim 4, characterized in that the racks are equipped with corners-compensators. 6. The device according to claim 1, characterized in that the longitudinal angle of the deck is not more than 3 °. 7. The device according to claim 1, characterized in that the angle of the transverse inclination of the deck is not more than 10 °. 8. The device according to claim 1, characterized in that the water supply and distribution system contains a water distributor and sprayed. 9. The device according to claim 1, characterized in that the flutes for removal of the light fraction are located at an angle of 8-15 ° relative to the bottom edge of the deck.

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