RU2354456C1 - Vibratory concentrator - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention refers to concentration of minerals, particularly to facilities for gravitation concentration and can be implemented for extraction of useful component out of various grain materials. The vibratory concentrator consists of a case, of a vibratory exciter, and of a concentrating element in form of symmetrically arranged transverse ribs with incline to the side of vertical walls and an incline to a charging side of the concentrator. Variation in their number, height and angle of incline is acceptable. A corrugated coating of the concentrating element is made wear resistant. The case and the concentrating element are designed to vary frequency and amplitude of vibration. The concentration element is made in form of a plate, the transverse ribs on which are made as a whole with the plate; the plate is equipped with lengthwise vertical directed walls. A receiving box is assembled at the charging end of the vibratory concentrator on the plate; the box is screened from the external side with a transverse vertical wall exceeding the height of the transverse ribs. The concentration element is equipped with a large-meshed removable grate made with vertically directed plates; the grate is installed above the transverse ribs and is secured to the lengthwise walls. Variation in height of the plates of the removable grate and in sizes of its meshes is acceptable.

EFFECT: increased extraction of heavy mineral grains and also increased efficiency of gravitational concentration of minerals and specific output of process.

3 cl, 3 dwg

Description

The invention relates to the field of mineral processing, and in particular to apparatus for gravity processing, and can be used to extract the useful component from various granular materials.

A known screening hub, including a box, a vibration exciter, a concentration element in the form of symmetrically arranged transverse ribs, the ribbed coating of the concentration element is made wear-resistant, the box and the concentration element have the ability to change the frequency and amplitude of vibration, the concentration element is made in the form of a thin layer non-perforated plate, transverse ribs on which are made integral with the plate, the plate is provided with longitudinal, vertically arranged walls, the transverse ribs having t bias towards the vertical wall and inclined in the feed-end hub screen, and can change their number, height and angle / 1 /.

The disadvantage of the screening concentrator / 1 / is the lack of necessary structural elements in it, which make it possible to increase the specific productivity of the process and at the same time continuously concentrate and output high-density fractions and light fractions of a wide range of fineness into separate products.

The closest in technical essence and the achieved result is a vibration concentrator, including a box, vibration exciter, a concentration element in the form of symmetrically arranged transverse ribs, the ribbed coating of the concentration element is made wear-resistant, the box and the concentration element have the ability to change the frequency and amplitude of vibration, the concentration element is made in the form of a plate , the transverse ribs on which are made integral with the plate, the plate is provided with longitudinal, vertically arranged E-walled cross ribs are bias toward vertical walls and tilting to the loading side vibrokontsentratora, it being possible to change their number, height and angle / 2 /.

The disadvantage of this device / 2 / is the lack of the necessary structural elements in it, which allow to increase the specific productivity of the process and at the same time continuously concentrate and output fractions of high density and light fractions of a wide range of fineness into separate products.

The aim of the invention is to increase the efficiency of gravitational mineral processing and specific productivity of the process by improving the conditions for the separation of mineral mixtures and continuous vibrodynamic removal of fractions of high density and light fractions of a wide range of particle sizes in individual products with the possibility of their controlled output.

This goal is achieved by the fact that in a vibration concentrator including a box, a vibration exciter, a concentration element in the form of symmetrically arranged transverse ribs, the ribbed coating of the concentration element is made wear-resistant, the box and the concentration element have the ability to change the frequency and amplitude of vibration, the concentration element is made in the form of a plate, transverse ribs on which are made integral with the plate, the plate is provided with longitudinal, vertically arranged walls, the transverse ribs have a bias towards the vertical walls and a bias towards the loading side of the vibroconcentrator, and it is possible to change their quantity, height and angle of inclination; at the loading end of the vibrocentrator, a receiving box is placed on the plate, shielded from the outside by a transverse vertical wall with a height exceeding the height of the transverse ribs, a concentration element equipped with a coarse removable grate made of vertically arranged plates mounted on top of the transverse ribs and fixed to the longitudinal walls, in this case, it is possible to change the height of the plates of the removable grating and the size of its cells, the concentration element with symmetrically arranged transverse ribs is divided into separate sectors by means of separating transverse ribs similar to symmetrically located transverse ribs, but with a mirror-inclined slope, while the separating transverse ribs are tightly connected by their external end ends with longitudinal walls, and between their inner end ends, along the axial line of the concentration element, are made passageways from sector to sector, a similar passage is also made from a receiving box shielded on the working side by dividing transverse ribs of an adjacent first sector, transverse ribs located inside each sector are tightly interconnected and with dividing transverse ribs by their inner end ends and have the gap between its external end ends and longitudinal walls, immediately behind each of the dividing transverse ribs on the reverse loading side, is made in the plate openings shielded along their opposite longitudinal edges by transverse ribs similar to dividing transverse ribs, and from the inner end ends by inclined walls with a height equal to the height of the transverse ribs, a slot-shaped hole is made in the plate for the output of tails exiting through the edges of the latter from the loading of the dividing transverse ribs, shielded from the outside by a transverse vertical wall with a height exceeding the height of the transverse ribs, at the outer ends of the last dividing ribs of the vibroconcentrator, concentrate receivers are installed symmetrically with respect to the longitudinal axial line of the concentrating element, shielded from the working side by side inclined walls with a height exceeding the height of the transverse ribs, and having an adjustable clearance in the lower part near the plate surface, the upper edges of the transverse dividing ribs and inclined walls, shielding slit-like openings, are provided along the entire perimeter of the slit-like openings deflecting their visors with the ability to change their height and angle.

When creating the invention, the authors proceeded from the following.

With vibrations of the layer of enriched material, minerals with a higher density in relation to the minerals of waste rock tend to occupy the lowest level in this layer. Such conditions of vibration of the material layer are created in working vibratory feeders and in the process of screening. Therefore, in vibratory feeders or on the working surface of a vibrating screen, it is advisable to additionally create conditions for the concentration and withdrawal of such minerals in one product, and light fractions in another. This can be achieved if structural elements are introduced on the bottom of the vibratory feeder or on the working surface of the screening hub or vibroconcentrator that will provide such conditions. In particular, it is rational to concentrate the element in the form of a plate on which the transverse ribs are made integral with the plate. Make them rationally wear-resistant (for example, from titanium, polyurethane, rubber, fluoroplastic, plastic, etc.) in the form of a ribbed coating with symmetrically arranged transverse ribs over the entire area of the plate, and on the sides of the plate with vertically arranged longitudinal walls. The height of these walls should exceed the height of the layer of the processed material, so that the material does not leave the working area through the side walls of the concentration element. For reliability, the selection of mineral grains of increased density from the material, the ribs should have a slope in the direction of the vertical walls and a slope in the loading direction.

The above concentration conditions are acceptable for many types of mineral raw materials. In this case, the enrichment efficiency increases especially when the grain density of the useful component is much higher than the density of the grains of waste rock, for example, in the enrichment of gold-bearing ores and sands, in the enrichment of rare-metal raw materials, tin ores, and many other types of raw materials similar and similar in terms of separation.

The invention is illustrated by drawings, where in Fig.1 shows a General view of the vibroconcentrator, Fig.2 is a top view of the vibroconcentrator with its working ribbed coating, Fig.3 is a view along section AA.

The vibroconcentrator includes a box 1, mounted by means of shock absorbers 2 on the support frame 3, and a vibration exciter 4, designed to create the necessary vibrations of the working bodies of the vibrocentrator. On the box 1, a concentration element 5 is placed, made in the form of a plate 6 with a ribbed wear-resistant coating of symmetrically arranged transverse ribs 7. On the sides of the plate 6, longitudinal, vertically located walls 8 are tightly fixed. Depending on the width of the box 1, the number of concentration elements 5 can be more.

To improve the selection and transportation of high-density mineral grains along the transverse ribs 7, they have a slope in the direction of the vertical walls 8, and for better retention of these mineral grains on the plate 6 in the intercostal cavities 9, the transverse ribs 7 are inclined to the loading side of the vibro-concentrator.

At the loading end of the vibroconcentrator, a receiving box 10 is placed on the plate 6, shielded from the outside by a transverse vertical wall 11 with a height exceeding the height of the transverse ribs 7.

The concentration element 5 with symmetrically arranged transverse ribs 7 is divided into individual sectors 12 by means of transverse ribs 13, similar to symmetrically located transverse ribs 7, but with a mirror-inclined slope. The dividing transverse ribs 13 are tightly connected by their external end ends to the longitudinal walls 8.

Along the axial line of the concentration element 5 between the inner end ends of the dividing transverse ribs 13, passages 14 are made from one sector 12 to another, followed by sector 12. A similar passage 14 is also made from a receiving box 10, shielded from the working side by dividing transverse ribs 13 adjacent to her first sector 12.

The transverse ribs 7 located inside each sector 12 are tightly connected to each other and to the dividing transverse ribs 13 with their inner end ends and have a gap between their outer end ends and longitudinal walls 8.

Immediately behind each of the dividing transverse ribs 13 on the reverse loading side, slotted holes 16 are made in the plate 6, shielded along their opposite longitudinal edge by ribs 17, similar to the dividing transverse ribs 13. From the inner end ends, the slotted holes 16 are shielded by inclined walls 18 with a height equal to the height of the transverse ribs 7.

At the end of the reciprocating concentrator, a slit-like hole 19 is made in the plate 6 for outputting tails exiting the apparatus through the edges of the latter from the loading of the dividing transverse ribs 7. The slit-like opening 19 is shielded from the outside by the transverse wall 20 with a height exceeding the height of the transverse ribs 7.

At the outer ends of the last dividing ribs 7 of the vibroconcentrator, concentrate receivers 21 are mounted symmetrically with respect to the longitudinal axial line of the concentrating element 5, in communication with the pocket 22 for withdrawing the concentrate from the apparatus.

Concentrate receivers 21 are shielded from the working side by side inclined walls 23 with a height exceeding the height of the transverse ribs 7 and having adjustable gaps 24 in the lower part near the surface of the plate 6.

The upper edges of the transverse dividing ribs 13, the ribs 17 and the inclined walls 18, the shielding slotted holes 16, are provided around the perimeter of the slotted holes 16 with deflecting visors 25 with the possibility of changing their height and angle.

To increase the layer of enriched material and its better separation, the concentration element 5 is equipped with a coarse removable grate 26 made of vertically arranged plates 27. A removable grate 26 is mounted on top of the transverse ribs 7 and fixed to the longitudinal walls 8. To control the process of vibration concentration, it is possible to change the height of the plates 27 of the removable lattice 26 and its cell size 28.

The vibroconcentrator works as follows.

Material containing solid particles of various sizes and densities is fed to a receiving box 10, from which it enters the concentration element 5 over the edges of the coarse removable grating 26 and the transverse dividing ribs 13 and through the passages 14 first into the first sector 12 of the concentration element 5, and then to subsequent sectors. On the concentration element 5, the material is separated by the density of its particles. Heavier mineral grains occupy the lowest position in the vibrating layer of material and along the intercostal cavities 9, sliding along the ribs 7, move in the direction of the vertical walls 8. The movement of the heavy mineral grains along the intercostal cavities is facilitated by the slope of the transverse ribs 7 in the direction of the vertical walls 8, and their retention in the intercostal cavities 9 contributes to the inclination of the ribs 7 in the loading side of the vibroconcentrator. Having reached the vertical walls 8, heavy mineral grains move first along these walls along the gaps 15, and then along the transverse dividing ribs 13 to the passage 14 through which they pass from one sector 12 to another. From the last sector 12, heavy mineral grains through an adjustable gap 24 enter the concentrate collectors 21 and then through the pocket 22 are removed from the apparatus. Made in the form of a plate 6, the concentration element 5 ensures that all the finest and slimiest particles of the useful component enter the concentrate. This is largely facilitated by the fact that the transverse ribs 7 are made integral with the plate.

The tail particles of material move over the edges of the coarse removable grating 26 and the transverse ribs 7 and the dividing transverse ribs 13 and are continuously discharged from the apparatus through the slotted holes 16 and the slotted holes 19, shielded by the ribs 17, the inclined walls 18 and the vertical wall 20, respectively. Deflecting visors 25 prevent the entry of heavier mineral grains into the light tail fractions.

The continuous output of the tailings through the slit openings 16 and the slit-like openings 19 from the entire area of the concentration element 5 provides a high specific productivity of the apparatus, and the labyrinth output of heavy mineral grains ensures their high extraction into the concentrate and high efficiency of the vibroconcentration process.

An increase in the layer of enrichable material, and therefore, an increase in the extraction of heavy mineral grains, is ensured by the fact that the concentration element 5 is equipped with a coarse removable grating 26 made of vertically arranged plates 27 and fixed over the transverse ribs 7.

Adjustment and regulation of the concentration process is carried out by changing the frequency and amplitude of vibration of the duct 1 and the concentration element 5, as well as changing the angle of inclination of the duct 1, changing the size, quantity, height and inclination angles of the transverse ribs 7 and the dividing transverse ribs 13, the depth of the intercostal cavities 9, the width of the slit holes 16, the number of concentration elements 5, the height of the plates 27 of the removable grating 26 and the size of its cells 28, the technological load of the enriched material.

Thus, the proposed technical solution in comparison with the prototype will allow, by improving the conditions for the separation of mineral mixtures and continuous vibrodynamic removal of fractions of high density and light fractions of a wide range of fineness in individual products with the possibility of their controlled output, increase the efficiency of gravitational enrichment of minerals of a wide range of fineness and process performance.

Information sources

1. Patent of the Russian Federation No. 2284865 "Roar-concentrator" / M.N. Zlobin, E.M. Zlobin, A.M. Zlobin. No. 2005113214/03 dated 03.05.2005, Bull. 2006, No. 28.

2. Patent of the Russian Federation No. 2284864 "Vibroconcentrator" / M.N. Zlobin, E.M. Zlobin, A.M. Zlobin. No. 2005114815/03 dated 05.16.2005, Bull. 2006, No. 28 (prototype).

Claims (3)

1. A vibroconcentrator including a box, a vibration exciter, a concentration element in the form of symmetrically arranged transverse ribs, the ribbed coating of the concentration element is made wear-resistant, the box and the concentration element have the ability to change the frequency and amplitude of vibration, the concentration element is made in the form of a plate, the transverse ribs of which are made at the same time with a plate, the plate is provided with longitudinal, vertically arranged walls, the transverse ribs have a slope towards the vertical walls and a clone to the loading side of the vibroconcentrator, and it is possible to change their number, height and angle of inclination, at the loading end of the vibroconcentrator a receiving box is placed on the plate, shielded from the outside by a transverse vertical wall with a height exceeding the height of the transverse ribs, characterized in that the concentration element is equipped with a coarse mesh a removable grill made of vertically arranged plates mounted on top of the transverse ribs and fixed to the longitudinal walls, while it is possible Changing the height of the removable plates and the lattice size of its cells. 2. The vibroconcentrator according to claim 1, characterized in that the concentration element with symmetrically arranged transverse ribs is divided into separate sectors by means of separating transverse ribs, similar to symmetrically located transverse ribs, but with a mirror-inclined slope, while the separating transverse ribs are tightly connected by their external end ends with longitudinal walls, and between their inner end ends, along the axial line of the concentration element, passages are made from sector to sector, The illogical passage is also made from the receiving box, shielded from the working side by the dividing transverse ribs of the adjacent first sector, the transverse ribs located inside each sector are tightly connected to each other and to the dividing transverse ribs by their inner end ends and have a gap between their outer end ends and longitudinal walls, immediately behind each of the dividing transverse ribs on the reverse loading side, slotted holes are made in the plate, shielded along their opposite longitudinal edge with ribs similar to dividing transverse ribs, and from the inner end ends of inclined walls with a height equal to the height of the transverse ribs, a slot-like hole is made in the plate for outputting tails exiting through the edges of the latter from the loading transverse ribs, shielded from the outside by a transverse vertical wall with a height exceeding the height of the transverse ribs at the outer ends of the last dividing the vibroconcentrator ribs are equipped with concentric receivers symmetrically located with respect to the longitudinal axial line of the concentrating element, shielded from the working side by side inclined walls with a height exceeding the height of the transverse ribs, and having an adjustable clearance in the lower part near the plate surface. 3. The vibroconcentrator according to claim 1, characterized in that, in order to prevent the ingress of heavier mineral grains into the light fractions of the enriched material, the upper edges of the dividing transverse ribs and inclined walls, screening slit-like openings, are provided with deflecting visors around the entire perimeter of the slit-like openings with the possibility of changes in their height and angle.

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