RU2036015C1 - Magnetic separator - Google Patents

Abstract

FIELD: chemical industry. SUBSTANCE: magnetic separator has a feeder, a magnetic system in the form of part of a ring and a set of plate-like magnets disposed immovably, with the magnetic system being enclosed in the drum. The separator also has a drum drive, collectors of ferromagnetic and non-magnetic particles mounted under the drive and pole tips placed between the plate-like magnets and lying outside the plate-like magnets towards the drum. The drum has V-shaped ribs sloped towards the drum rotation. Their vertexes are mounted along middle line of the drum surface in the direction opposite to the drum rotation. A spring-loaded comb is mounted between the feeder and the drum. The collectors of ferromagnetic particles are placed outside and inside the drum facing each other. A magnetic circuit roller reiterating the contour of the outer sectional surface of the drum and a magnet are placed correspondingly. The collector of ferromagnetic particles has magnet members under it. The drum surface can be made flexible. There are grooves on the surface of the pole tips. A magnetic roller is mounted under the feeder with the abutment to the drum. EFFECT: facilitated manufacture. 3 cl, 6 dwg

Description

 The invention relates to techniques for cleaning bulk material from ferromagnetic inclusions in the chemical, mining, agricultural, pharmacological industries, for example, for products such as titanium dioxide powder, grain processing products, fine ores, alloying additives in metallurgy.

 Known separator [1] containing a feeder with a wedge divider, a tray, a scraper mounted for rotation around its vertical axis, with movable and fixed parts of the magnetic system, made in the form of sections of a ring shape mounted inside the shell, a housing with a mechanical drive and a vibrator.

 The disadvantages of this separator are its complexity, unreliability, which consists in the need for a narrow gap between the housing and the cone to create a sufficiently powerful magnetic field, where scrapers are also located. For soft powders, such as titanium dioxide powder, flour, and the like, coalescing fine-grained products passed into slits of the order of a few millimeters (otherwise small fractions of a ferromagnet are not removed even by a very strong magnetic field), the device’s operation is not only ineffective, but also impossible, how the product immediately clogs the slotted ducts and it takes a minute to disassemble the device. The use of scrapers with their circular rotation around the cone of the shell causes abrasion of both the scrapers and the inner surface of the shell and the housing, as a result of which the gap increases and the material from abrasion contaminates the product. Frequent change of scrapers is also required, which complicates maintenance, reduces the time of productive operation.

 It is also known a device of an electromagnetic separator [2] including a feeder, a fixed magnetic system in the form of a part of a ring from a set of plate magnets, enclosed in a drum, a drum drive, collections of ferromagnetic and non-magnetic particles mounted under the drum.

 The disadvantage of this device is the large loss of power of the magnetic system due to the scattering flux between the magnetic circuits having a radial arrangement. The implementation of the entire segmented product of the drum with magnetic elements with a massive magnetic rotor is unreasonably high material consumption, and hence the strengthening of the entire design of the device. A bunch of magnetic core rods, filling the entire working area, increases the friction area, contributes to clogging of the working area with the product, being an additional source of product pollution from particles formed during friction. Unacceptable and the use of spray for powders that have passed the drying or calcination. As a result, the device’s low efficiency, and for soft powders, prone to sticking together, inoperability is due to clogging of the volume zone of the working gap by the product.

 The purpose of the invention is improving the efficiency of the operation.

 The goal is achieved in that the magnetic separator, comprising a feeder, a fixed magnetic system in the form of a ring part from a set of plate magnets enclosed in a drum, a drum drive, collectors of ferromagnetic and non-magnetic particles mounted under the drum, is characterized in that pole tips are placed between the plate magnets protruding beyond the plate magnets towards the drum, the drum is made with U-shaped ribs placed with an inclination in the direction of rotation of the drum and mounted peaks along the middle line of the drum surface, in the direction of rotation of the drum, a spring-loaded comb is installed between the feeder and the drum, above the collector of ferromagnetic particles, opposite and inside the drum, respectively, a magnetically conducting roller and magnet repeating the relief of the outer ribbed surface of the drum, and a collection of ferromagnetic particles made with magnetic elements underneath.

 To increase the effectiveness of the magnetic system by reducing and (or) eliminating the gap between the inner surface of the drum and the outer surface of the magnetic system, as well as to reduce the stickiness of the product on the surface of the drum, its cylindrical part and (or) surface, including U-shaped ribs, are made elastic, mainly from rubber, lactase or based on fibrous texture and resins.

 Increasing the efficiency of the magnetic system contributes to the execution of grooves on the surface of the pole pieces (notches).

 A magnetic roller is mounted under the feeder to collect random ferromagnetic particles under the feeder.

 In FIG. 1 shows a magnetic separator device; figure 2 section aa in figure 1; Fig.3,4 magnetic elements; figure 5 is the same with a drum with an elastic surface; in Fig.6 view B in Fig.1.

 The magnetic separator contains a feeder (not shown), a fixed magnetic system 1 in the form of a ring part from a set of plate magnets enclosed in a drum 2, between which are placed pole pieces protruding beyond the plate magnets towards the drum 2 connected to the drive (not shown) . The drum 2 is made with U-shaped ribs 3 placed with an inclination in the direction of rotation of the drum and mounted peaks along the midline of the surface of the drum back to the direction of rotation of the drum. At the ends, the drum 2 is equipped with flanges 4, inclined from the drum 2. Between the feeder and the drum, a spring-loaded comb 6 is installed above the tray 5. The spring 7 is cylindrical. Outside the magnetic system 1, but also inside the drum, a semi-closed magnet 8 is mounted stationary above the collector 11 of ferromagnetic particles, and opposite it, on the other side of the drum 2 there is a repeating relief of the outer ribbed surface of the drum, a magnetic roller 9 with a flat spring pressing 10. Under the foam collector of ferromagnetic particles magnetic elements 12 are fixed. The end surfaces of the pole pieces 13 are made from the surface to the drum with grooves of risks commensurate with the domain associations and plate magnets of the system 1. The entire device is mounted in a box heat 14.

 Magnetic separator operates as follows.

 The powder intended for processing enters the tray 5 from the feeder, interacts with the scattering comb 6, causing it to oscillate on the spring 7, which creates a predominantly horizontal component of movement along the surface of the tray 5 and drum 2, which disperses the powder in an even layer on the surface of the drum 2 rotating from the drive away from the flow of powder.

 A thin uniform layer of powder enters the intermittent bipolar magnetic field of the magnetic system 1, where the ferromagnetic inclusions of the powder, guided by a changing magnetic field, perform complex mechanical movements, which contributes to their exit from the powder mass to the surface of the drum and its retention. When particles with magnetic properties approach the non-magnetic part of drum 2, they are pulled together in chains and concentrated on the ribs 3, approaching the vertices where the ribs 3 meet on the middle line of the drum 2. The ribs 4 exclude premature exit of the powder from the magnetic zone. Magnetic chains of particles deposited on the drum 2 lose their adhesion with the magnetic system 1 and crumble into a pencil box 11, where they are attracted and held by the magnetic elements 12.

 Individual particles with magnetic properties can be retained due to molecular adhesion with the surface of the drum 2 or with ribs 3 and do not come off in the collector 11, fall on the surface of the magnetic roller 9, which is magnetized from the magnetic field of magnet 8, holds ferromagnetic particles until it rotates with ribs 3 from the surface of the drum 2, where particles are crumbled into the collector 11, which is facilitated by the oscillations of the roller 9 under the action of the spring 10 and its demagnetization in the opposite side from the surface of the drum. The collected ferromagnetic particles are periodically unloaded by the operator from the foam container 11.

 The device does not interrupt the process flow, cannot clog, since the working area is open, the magnetic system is more efficient.

Claims (4)

 1. MAGNETIC SEPARATOR, comprising a feeder, a stationary magnetic system in the form of a part of a ring from a set of plate magnets, enclosed in a drum, a drum drive, collectors of ferromagnetic and non-magnetic particles mounted under the drum, characterized in that, in order to increase the separation efficiency, between plate magnets placed pole pieces protruding beyond the plate magnets towards the drum, the drum is made with V-shaped ribs placed with an inclination in the direction of rotation of the drum and installed vertices along the middle line of the drum surface in the direction of rotation of the drum, a spring-loaded comb is installed between the feeder and the drum, above the collector of ferromagnetic particles, a magnetically conducting roller and magnet repeating the relief of the outer ribbed surface of the drum are respectively placed opposite the each other, and the collection of ferromagnetic particles is made with magnetic elements over them.  2. The separator according to claim 1, characterized in that the surface of the drum is made elastic, for example, from rubber or based on a fibrous texture and resins.  3. The separator according to claim 1, characterized in that the grooves are made on the surface of the pole pieces.  4. The separator according to claim 1, characterized in that a magnetic roller is installed under the feeder with an adherence to the drum.

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