SU1710133A1 - Magnetic separator - Google Patents

Abstract

The invention relates to magnetic enrichment. The purpose of the invention is to improve the quality of the regenerated magnetic fluid. The separator has a working chamber (IQ 2, located under the loading nozzle 7 in the interpolar gap, the side surfaces of which are made along the profile of pole pieces 1. At the same time, vertical plates (P) 3 of ferromagnetic material are fixed to the K 1 end face, and P 3 are connected additional plates forming channel 11 for the passage of purified water to additional K 4. Between P 3 there is a grating of ferromagnetic grates 9 of a triangular profile with the top facing up. The upper cut of P 3 is located below cut K2, and the lower cut is below channel 11. The output end of the pipe 7 is located between P 3 below their upper edge, but above the lattice. The liquid enters K 2 through pipe 7 under the action of a magnetic field and its relaxation and regeneration takes place (2 (S1-10) Sl) • ^ 1 / e. /

Description

The invention is related to magnetic enrichment and can be used in the regeneration of magnetic fluid from a single emulsion.

Known magnetic separator for the regeneration of magnetic fluid, comprising a cylindrical body, a magnetic system in the form of blocks of magnets with a magnetic circuit, made in the form of a closed Archiemed pyramid, located in the body coaxially with it, loading, drain and sand pipe.

The disadvantage of this separator is the low efficiency of extraction of the magnetic fluid (MF) from the aqueous emulsion due to the insufficient magnetic force due to the design of the magnetic circuit.

A magnetohydrostatic separator is also known, which includes an electromagnetic system with pole tips of a hyperbolic profile, a chamber placed in an interpolar gap, a limiter of the lower liquid level, a flow conditioner, a flow divider, a loading and unloading nozzle.

The disadvantage of this separator is the low efficiency of the regeneration process, which is associated with the loss of the MF and is due to the design of the working chamber.

The closest to the invention is a magnetic separator containing a magnetic system, a working chamber located in an interpolar gap, the side surfaces of which are made along the profile of pole pieces, plates of ferromagnetic material rigidly fixed to the ends of the chamber, additional chambers connected by a bridge formed by the ends of the working chamber, its side surfaces and plates, repeating the profile of the side surface of the working chamber with the formation of a channel for the passage of water, loading and unloading full-time fittings ,.

A disadvantage of the known separator is that it does not provide for the removal of sludge, which reduces the quality of the regenerated liquid and increases its consumption for 3S magnetohydrostatic separation by using fresh magnetic fluid.

The purpose of the invention is to reduce the consumption of magnetic fluid in the process of magnetohydrostatic separation by increasing the quality of the regenerated magnetic fluid due to the removal of sludge-forming particles from it.

The goal is achieved by the fact that in a magnetic separator containing a magnetic system, a working chamber located in the interpolar gap, side

the surfaces of which are made along the profile of pole pieces, plates of ferromagnetic material, rigidly fixed to the ends of the chamber, additional chambers connected by a bridge.

0 formed by the ends of the working chamber, its side surfaces and plates that repeat the profile of the side surface of the working chamber with the formation of a channel for the passage of water, loading and unloading

5 nozzles ;, plates made of ferromagnetic material are installed in such a way that their upper section is located below the upper section of the working chamber, and the lower section is below the channel for the passage of water; between the lower section of the ferromagnetic plates and the side surfaces of the working chamber there is an image. van clearance for water passage; between the ferromagnetic plates there is a grate with a grate made of ferromagnetic material with

5 section of the profile of the triangle, set the top up; the grate bars are located along the working chamber and rigidly fixed on its ends; the boot nozzle is installed at the top of the working

0 camera between the ferromagnetic plates so that its lower cut is located below the upper cut of the plates; A discharge port for sludge-forming particles is installed above the grate.

5 In FIG. 1 shows a separator, a cross-section; in fig. 2 shows section A-A in FIG. 2. The separator consists of pole pieces 1, working chamber 2, ferromagnetic plates 3, additional chambers 4, G1 plate 5, jumper 6, loading nozzle 7, nozzle for discharge of magnetic fluid 8, grate 9, nozzle for unloading slime IQ, channel passageway

5 water 11, jumpers 12, the drain pipe 13. The pipe 10 is installed above the grill 9, In the gap between the hyperbolic pole pieces 1 there is a working chamber 2. Side surfaces

0 working chamber 2 is made according to the profile of pole pieces 1. Inside the working chamber 2 along its vertical axis are ferromagnetic plates 3 with a gap between them, which are rigidly

5 are fixed to the ends of the working chamber 2. The upper cut of the plates 3 is located below the upper cut of the working chamber 2, and the lower cut is below the channel for passing cleaned

water 11. Between the lower section of the ferromagnetic plates 3 and the side surfaces of the working chamber 2 there is a gap for the passage of water. Additional chambers A are formed by the ends of the working chamber 2, its side surfaces and plates 5, which repeat the profile of the side surfaces of the working chamber 2. Additional chambers 4 are connected by a jumper 6. Plates 5 form with the side surfaces of the working chamber 2 a channel 11 for the passage of purified water. The boot nozzle 7 is located between the ferromagnetic plates 3 in the upper part of the working chamber 2 in such a way that its lower cut is located below the upper cut of the ferromagnetic plates 3.

A nozzle for draining the magnetic fluid is installed in the bottom of the working chamber 2. The grate 9 is installed with interferromagnetic plates 3 butt against them along the entire length of the working chamber 2 and is rigidly fixed to its ends. The grates of the grate are made of ferromagnetic material, have a cross section of the shape of the tpey of the top-up bar, and are located along the working chamber 2 with a gap of 2-3 mm between them. The discharge pipe 10 is made in the form of a pipe and installed above the grate 9.

The separator works as follows.

The separator is installed in the ferromagnetic fluid regeneration cycle — in the process of magnetohydrostatic separation of non-magnetic materials. Include magnetic separator system. A magnetic fluid is poured through the loading nozzle 7 until it is drained through the nozzle 8 to drain the FMF. Then through the pipe 7 serves the original emulsion, formed in the process of washing the products of the MHS-separation from the fluid with water and containing 0.5-0.8%. When pouring the FMF on the grate 9, an additional layer of the FMF is formed due to the magnetic field induced by the magnetic system of separators between the grate 9 of the grate.

The original emulsion enters the space between the plates 3. Since the FMG enveloping grate 9 forms a kind of liquid gate, then the emulsion will overflow through the top of the plates 3 and enter the space bounded by the plates 3 and 5 and pass between them through the channel 11 into additional cameras 4.

When passing through channel 11 from the emulsion, the magnetic field of the separator extracts the remaining FMF in it and settles in the FMJ layer held in the interpolar gap between the pole tips 1. Purified water is discharged through the nozzle 13. When the emulsion is in the space between the plates 3, it is extracted magnetic field and settles on the grate weakly magnetic sludge containing sludge-forming particles, impregnated with FMF and part of the free FMJ on the grating 9, its excess volume, which is not kept induced on the grates The magnetic field is poured into the FMF layer held in the interpolar gap between the pole pieces 1. The sludge deposited on the grate 9 floats onto the surface of the FMF layer enveloping it due to the release of the FMF in a magnetic field and as it accumulates it discharges through the nozzle 10.

Due to the removal of sludge-forming particles isolated from MFs, the quality of the FMF-magnetization increases and its consumption is reduced. For example, in case of MHS separation of crushed scrap of leaded cable with copper residential, the consumption of MFs is reduced by 22.5 kg per ton of the mixture to be separated.

Formula of the invention Magnetic separator comprising a working chamber located under the loading pipe in the interpolar gap of the electromagnetic system, the side surfaces of which are made along the profile of pole pieces having a hyperbolic profile, vertical G1 plates made of ferromagnetic material, attached to the end of the working chamber with the formation of additional cameras and connected to vertical plates additional plates that repeat the profile of the side surface of the working chamber, located with a channel for the passage of purified water into additional chambers, a jumper connecting additional chambers and nozzles for output of regeneration products, characterized in that, in order to improve the quality of the regenerated magnetic fluid, the separator is equipped with a grate in the form of grates of ferromagnetic material, having a cross section a triangular profile with the top facing upwards, which is installed between the plates along the longitudinal axis of the working chamber and is associated with them, while the upper cut of the plates is located below the The upper section of the working chamber is lower, and the lower section is below the channel for the passage of purified water, with the outlet end of the loading pipe located between the plates below their upper edge but above the grate.

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Claims (1)

Claim A magnetic separator comprising a working chamber located under the loading nozzle in the interpolar gap of the electromagnetic system, the lateral surfaces of which are made along the profile of pole tips having a hyperbolic profile, vertical plates of ferromagnetic material, 35 fixed to the end of the working chamber with the formation of additional chambers and connected to vertical additional plates repeating the profile of the side surface of the working chamber, located with the formation of a channel for the passage of purified water into additional chambers, a jumper connecting additional chambers and nozzles for outputting regeneration products, characterized in that, in order to improve the quality of the regenerated magnetic fluid, the separator is equipped with a grate in the form of grid-irons made of ferromagnetic material having a triangular cross-section50 a profile with an apex facing up, which is installed between the plates along the longitudinal axis of the working chamber and connected with them, while the upper section of the plates is located below the upper section 55 eyes of the chamber, and the lower slice is below the channel for the passage of purified water, and the output end of the loading pipe is located between the plates below their upper edge, but above the grill. D'd FIG. 2