EA014397B1 - Tray magnetic separator - Google Patents

Abstract

Provided is a tray magnetic separator for magnetic concentration of weak-magnetic ore and separating magnetic impurities from mineral raw materials. The separator comprises an operating element in the form of a pair of inclined trays, each having thereunder a magnetic system, a feeder, a loading bin and a flushing unit for flushing magnetic and non-magnetic fractions. The magnetic system of each tray comprises magnetic blocks, the blocks including permanent magnets and being magnetized along the longitudinal direction of the tray. One ferromagnetic concentrator is situated between each pair of sequential blocks, each ferromagnetic concentrator forming one of the poles of the magnetic system, the polarity of which poles alternating along the longitudinal direction of the tray. The separator further comprises a magnetically conductive screen adapted to locate alternately over the trays of the pair to form an operating gap such that the magnetic flux produced by the magnetic system closes via the concentrators and the screen and forms local magnetic traps within said gap next to the concentrators for catching magnetic particles of input material.

Description

Technical field

The invention relates to magnetic separators, in particular to high-gradient magnetic separators, which can be used for magnetic enrichment of weakly magnetic ores and purification of mineral materials from magnetic impurities.

State of the art

Magnetic separators are widely known in the art which are used to separate the starting material into magnetic and non-magnetic fractions. One of the types of magnetic separators are polygradient, or high-gradient, separators in which the separation of magnetic and non-magnetic fractions occurs due to the creation in the working area of the areas of action of high-gradient magnetic forces. In these areas, the extraction and retention of magnetic particles occurs, while non-magnetic particles freely pass through these areas.

In tray magnetic separators, these areas of action of high-gradient magnetic forces are created when the initial product moves along the tray or trough. It is also known that in the process of polygradient separation to extract small particles with low magnetic susceptibility from the starting material, it is necessary to ensure high values of the power parameter in the separator working zone

В‘§га <1В, where В is the magnetic induction vector, which is achieved by simultaneously ensuring high values of the magnetic field induction and its gradient.

In particular, from the USSR copyright certificate 1681961, a polygradient magnetic separator is known that contains an endless chain with rods and ferromagnetic concentrators in the form of springs passing through the slit gap of the inclined trough formed by magnetic circuits, pole tips of the electromagnetic system and non-magnetic inserts. Magnetic flux is created by coils mounted on magnetic cores. When the separator is operating, the chain with concentrators is moved along an inclined trough towards the material to be separated in the form of a suspension fed into the slotted gap. Concentrators with particles of the magnetic fraction drawn to them in a magnetic field are washed with water jets after exiting the trough. The purified suspension (non-magnetic fraction) flows by gravity through the gutter, after which it is drained from the lower end of the gutter.

The disadvantage of this separator is its low operational reliability. Circuit elements moved in an inclined trough, as well as rods and concentrators, are subject to significant alternating mechanical loads at the entrance and exit of the magnetic field. This circumstance, as well as the intensive abrasive wear of the chain joints, will cause its frequent failure and, accordingly, the need for replacement or restoration. In addition, the design of the magnetic system of the separator causes significant idle magnetic flux scattering fluxes. At the same time, the use of an electromagnetic system increases the separator's energy requirements.

The closest analogue of the present invention is a magnetic separator according to the application for the invention of the Russian Federation 94038142. This separator contains a feeder, an inclined tray with a magnetic system located below it, a receiving hopper and a flushing device for flushing magnetic and non-magnetic fractions. The magnetic system contains horseshoe-shaped permanent magnets connected in pairs and forming W-shaped magnetic circuits with coils installed on the poles of the same name. The poles of the magnetic circuits are directed toward the bottom of the tray. The separated material in the form of a suspension is moved along the channels of the inclined tray, while the magnetic particles are attracted to its bottom at the points of contact of the poles. The purified material (non-magnetic fraction), passing by gravity through the gutter, flows freely from it. After stopping the supply of initial power and removing the voltage from the coils, the magnetic fraction is periodically unloaded by flushing, since the magnitude of the magnetic field created by permanent magnets is not enough to hold the particles of the magnetic fraction. Such a configuration of the magnetic system makes it possible to increase the quality of separation compared to the separator according to the USSR author's certificate 1681961, and the absence of movable parts in the separator used to move the concentrators makes it possible to simplify the design of the separator and reduce the wear of its elements.

However, the design of the magnetic system of this separator does not allow creating zones with a high value of the power parameter on the surface of the bottom of the tray

В-§гас1 В, which leads to low efficiency of this separator when working with small weakly magnetic material. In addition, the use of magnetizing coils in a magnetic system tightens energy requirements.

Thus, there is a need to improve the tray magnetic separators to increase the efficiency of magnetic separation with a decrease in the loss of magnetic product in the enrichment process and a decrease in the content of magnetic impurities in the process of purification of mineral raw materials.

- 1 014397

SUMMARY OF THE INVENTION

The present invention is the creation of a high-gradient magnetic tray separator with increased magnetic separation efficiency by creating zones with a high value of the power parameter

This problem is solved due to the fact that the working element in the form of at least one pair of inclined trays is additionally included in the tray magnetic separator for separating the source material into magnetic and non-magnetic fractions, including a feeder, a receiving hopper and a flushing device for washing off the magnetic and non-magnetic fractions under each of which is a magnetic system containing magnetic blocks, including permanent magnets and magnetized along the longitudinal direction of the tray, and between each pair of consecutive b the shackles are located on one ferromagnetic concentrator, each of which forms one of the poles of the magnetic system, the polarity of which alternates along the longitudinal direction of the tray, and the separator further comprises at least one magnetically conductive screen associated, respectively, with at least one pair of trays and made with the possibility of alternating arrangement of pairs above the trays with the formation of a working gap, so that the magnetic flux generated by the magnetic system is closed through concentrators and wounds, forms in this gap near the concentrators local magnetic traps for capturing magnetic particles of the source material.

This configuration of the magnetic system of each of the trays ensures the creation of zones with a high value of the power parameter at the bottom of the tray

V 'dhab with increasing separation efficiency. The configuration of these zones in the form of narrow strips perpendicular to the direction of movement of the source material along the tray ensures the passage of material in the immediate vicinity of these zones with the effective extraction of magnetic particles. The use of a permanent magnet system reduces the energy requirements of the separator, while the magnetically conducting screen introduced into the separator contributes to the concentration of magnetic flux in the working gap, and when it is removed from the position above the corresponding tray, the magnetic flux is weakened in the working gap and the magnetic fraction is unloaded. In this case, the use of paired trays with a common screen, alternately placed above them, provides an effective redistribution of magnetic flux between the trays of a pair that are in working and non-working state, respectively.

In one of the preferred embodiments of the invention, the magnetic blocks comprise high energy rare earth magnets.

In yet another preferred embodiment of the invention, each hub comprises at least one protrusion directed toward a respective tray.

In yet another preferred embodiment of the invention, the hopper comprises a separation gate.

In yet another preferred embodiment of the invention, magnetic contact is provided between the hubs of the magnetic systems of each pair of trays.

In yet another preferred embodiment of the invention, magnetic blocks adjacent to one hub from different sides are magnetized in opposite directions.

Brief Description of the Drawings

The following is a detailed description of a preferred embodiment of the present invention with reference to the accompanying drawings, the description of which is presented below.

In FIG. 1 is a longitudinal sectional view of a tray of a magnetic separator with a magnetic system and a magnetically conducting screen disposed above the tray in accordance with the present invention and callout A illustrating the closure of magnetic flux lines through a magnetically conducting screen;

in FIG. 2 shows two trays with magnetic systems, combined in a working pair and having a common screen, in accordance with the present invention.

The implementation of the invention

The magnetic high-gradient tray separator of the present invention contains a working body in the form of a system of paired inclined trays. The separator may contain at least one such pair. In FIG. 1 is a longitudinal section through one separator tray 6 with a magnetic system located beneath it. Each tray has its own magnetic system, which contains magnetic blocks 1 in the form of rectangular parallelepipeds, including high-energy rare-earth magnets and mounted on the base 2 of non-magnetic material. The magnets of the blocks 1 are enclosed in casings designed to protect the magnets and their fastening on the base 2. The blocks 1 are magnetized along the longitudinal direction of the tray 6. Between each pair of consecutive blocks 1 there is one ferromagnetic concentrator 3 having at least one pointed protrusion 8, directed towards the tray. The hubs 3 form the poles of the magnetic system, and their polarity alternates along the longitudinal direction of the tray 1, with the blocks 1 adjacent to one

- 2 014397 to hub 3 from different sides, magnetized in opposite directions. Between the concentrators of the magnetic systems of each pair of trays, a magnetic contact is provided. The space between the protrusions 8, protruding above the blocks 1, is filled with a substrate 5 of non-magnetic material. Above the tray 6 with the formation of a slit working gap is a magnetically conductive screen 4.

The blocks 1 form the magnetic flux collected by the concentrators 3 and closed through the protrusions 8 and the shield 4. The magnetic flux closure lines are illustrated on callout A in FIG. one.

In FIG. 1, the screen 4 is located above one tray 6, however, it can be alternately placed over both trays of the pair.

The separator trays are connected in pairs with the channels of the feeder 9, located on the side of the raised ends of the trays, and a receiving hopper (not shown), located on the side of the lowered ends of the trays and containing the separation gate. The separator also includes a flushing device for flushing magnetic and non-magnetic fractions (not shown).

Due to the concentration of magnetic flux on the working protrusions of the concentrators, high-gradient sections are formed at the bottom of the tray, having the form of narrow strips oriented perpendicular to the longitudinal direction of the tray 1, that is, the direction of movement of the material during operation of the separator. These highly gradient regions act as local magnetic traps for magnetic particles.

The calculations showed that the values of the force parameter

B * £ gas1B in the zone of action of the traps can reach values up to 2500 T ² / m. The fact that high-gradient sections are located perpendicular to the direction of movement of the enriched or cleaned material ensures the passage of the entire volume of the specified material in the immediate vicinity of such sections, which minimizes the probability of accidental magnetic particles entering the non-magnetic product.

The operation of the magnetic separator of the present invention in a wet magnetic enrichment process is described with reference to FIG. 2, which shows two trays 6 and 7 with magnetic systems, combined in a working pair and having a common screen 4, in accordance with the present invention. The work of the tray separator with connected in pairs trays takes place cyclically, and the screen 4 occupies an operating position above each of the trays in turn. When using the separator in the wet magnetic enrichment process, the duty cycle consists of three stages. In the first stage, with the working position of the screen 4 above the first tray 6, as shown in FIG. 2, through one of the feeder channels (not shown in FIG. 2), the first tray 6 is loaded with an enriched initial product that has previously been processed on a standard separator with a weak magnetic field and freed from strong magnetic fractions. The inclined arrangement of the tray ensures the movement of the source material along the tray in the direction from the feeder to the receiving hopper (not shown in Fig. 2) along the slotted working gap. When the source material moves along the slotted working gap of the tray 6, magnetic traps of this tray capture and hold weakly magnetic particles contained in this material. In this case, the non-magnetic fraction freely passes through the tray to the receiving hopper, where it is sent to the receiving hopper for the non-magnetic fraction using a dividing gate.

In the second stage, while maintaining the position of the screen above the tray 6 using a flushing device, water washing of the magnetic fraction trapped by the traps is carried out and it is released from particles of a non-magnetic fraction that can become stuck between magnetic particles. The position of the separation gate still ensures the direction of the particles of the non-magnetic fraction into the corresponding section of the receiving hopper.

In the third stage, the screen 4 is moved to the working position above the second tray 7. At the same time, the separation gate is moved to the position for directing the product being washed off from the first tray 6 to the section of the receiving hopper for the magnetic fraction. In the absence of a screen 4 above the magnetic system of the tray 6, the magnetic flux passing through the working protrusions of the concentrators is significantly weakened, and the magnetic force becomes insufficient to hold weakly magnetic particles, which are washed away with water into the receiving hopper by means of a flushing device. The difference in the magnitudes of the forces holding the magnetic particles in the magnetic traps of the separator with the working and non-working position of the magnetic screen relative to each tray is increased due to the magnetic contact between the concentrators of the magnetic systems of the paired trays. The magnetic flux generated by the magnetic blocks of the tray above which there is no screen is closed in this case through the magnetic contact area of the concentrators and the magnetically conducting screen above the second tray of the pair. This increases the difference in the magnitude of the magnetic flux passing through the working protrusions of the hubs of the paired trays and, accordingly, by the magnetic forces acting in their magnetic traps, with the working and non-working position of the magnetically conductive screen.

In the implementation of the third stage of the separation process in the first tray 6 in the second tray 7, the first stage of the separation process is performed.

The cyclical operation of the separator during the wet magnetic enrichment process is illustrated in

- 3 014397 table, which shows the correspondence between the stages of operation of the paired trays.

Separation stage First tray I II III second tray III % T

The proposed separator can also be used in the dry cleaning process of a material containing low concentrations of weakly magnetic impurities, for example, in dry sand enrichment for the needs of the glass industry. In this case, the unloading of one tray of the pair is carried out by moving the magnetically conductive screen to a position above the second tray of the pair, and the duty cycle consists of two stages, since there is no stage of washing the magnetic particles trapped by magnetic traps. The absence of this stage does not affect the efficiency of the separator, since the cleaning does not pose the problem of obtaining a concentrate with a minimum content of a non-magnetic fraction and non-magnetic particles entering the magnetic product during unloading of the separator is not a disadvantage in its operation.

Although the invention is described by way of example of a preferred embodiment, it is obvious to a person skilled in the art that changes and modifications can be made to him without deviating from its essence and scope, which are determined by the attached claims.

Magnetic traps are in the form of narrow strips directed perpendicular to the direction of motion of the separated material, and are characterized by a high value of the force parameter

В · §ГабВ, which significantly increases the separation efficiency.

Claims (6)

CLAIM 1. Tray magnetic separator for separating the source material into magnetic and non-magnetic fractions, including a feeder, a receiving hopper, a flushing device for flushing the magnetic and non-magnetic fractions and a working body in the form of at least one pair of inclined trays, under each of which there is a magnetic system, containing magnetic blocks, including permanent magnets and magnetized along the longitudinal direction of the tray, and between each pair of consecutive blocks there is one ferromagnetic concentrator, each of which it forms one of the poles of the magnetic system, the polarity of which alternates along the longitudinal direction of the tray, and the separator further comprises at least one magnetically conductive screen connected respectively to the specified at least one pair of trays and configured to alternately arrange the pair above the trays to form a working gap, so that the magnetic flux generated by the magnetic system, closing through the concentrators and the screen, forms a local magnet in this gap near the concentrators traps for capturing magnetic particles of the source material. 2. The separator according to claim 1, characterized in that the magnetic blocks contain high-energy rare earth magnets. 3. The separator according to claim 1, characterized in that each concentrator contains at least one protrusion directed to the corresponding tray. 4. The separator according to claim 1, characterized in that the hopper contains a separation gate. 5. The separator according to claim 1, characterized in that a magnetic contact is provided between the concentrators of the magnetic systems of each pair of trays. 6. The separator according to claim 1, characterized in that the magnetic blocks adjacent to one hub from different sides are magnetized in opposite directions.