RU2125489C1 - Gravitational magnetic separator - Google Patents

Abstract

FIELD: mining industry; wet magnetic concentration of finely disseminated iron ores. SUBSTANCE: separator has housing in form of inclined trough and feeding and discharge devices. Bottom of housing is lined with magnetized plates with like poles pointed outside. EFFECT: enhanced cleaning of separated products at concentration of finely divided suspensions. 3 cl, 1 dwg

Description

 The invention relates to devices for the separation of finely divided suspensions of heavy and magnetic particles. It can be used to isolate metal particles from similar suspensions.

 There are various devices for magnetic cleaning of suspensions, including bathtubs (housings) and magnetic systems placed in them (see, for example, ed. St. USSR N 302136; BI N 15, 1971, MKI B 03 C 1/04).

 Also known is a magnetic-hydraulic separator (prototype), including a housing made in the form of an inclined trough, in which slotted magnetic systems of permanent magnets are installed, a loading and unloading device (ed. St. USSR N 1049104, class B 03 C 1/04 , BI N 39, 10.23.83). The disadvantage of all known devices, including the prototype, for the isolation of finely divided suspensions of heavy and magnetic particles is the low degree of purification of the separation products, i.e. large clogging of the non-magnetic fraction with magnetic particles and of the magnetic fraction with non-magnetic particles.

 The aim of the invention is to provide a device that provides a high degree of purification of the separation products during the enrichment of finely divided suspensions.

 This goal is achieved by the fact that the bottom of the inclined gutter is covered with magnetized tiles with the same poles, which eliminates the closure of magnetic lines of force at the adjacent poles of the magnets and thereby ensures that the magnetic field is filled with the entire volume of the gutter with the direction of the magnetic field gradient in the direction of gravity.

 This goal is also achieved by the fact that inside the case one or several, at intervals from each other, solid partitions with holes in the area of their abutment to the bottom and with drain channels installed on top of their rear sides are installed. Each of these partitions compacts the bottom heavy magnetic fraction, and the water displaced during this creates an upward flow of water along it, which carries off non-magnetic light particles fixed to the back of the partition to the drain chute.

 Due to the action of the volume magnetic field, the gradient of which is parallel to the force of gravity, heavy magnetic particles do not fall into the drain, which significantly increases the separation efficiency of a mixture of light non-magnetic and heavy magnetic particles.

 One or more holes in the lower part of the partition, in the area of its adjacency to the bottom, release a heavy magnetic fraction into the next compartment of the trench for cleaning it, which contributes to its complete release from impurities of light non-magnetic particles. This is also facilitated by the fact that in each compartment of the casing enclosed by solid partitions, according to the invention, spatter is installed. Water coming from them into a stream moving along the magnetic bottom leaches light non-magnetic particles to the top of the stream, which then rise higher.

 The drawing shows a gravitational magnetic separator, where: 1 - feed pipe; 2 - power distributor; 3 - housing in the form of an inclined trough; 4 - magnetized tiles; 5 - water sprayed; 6 - a solid partition with holes in the area adjacent to the bottom; 7 - drain trough; 8 - a slot in the side wall of the housing; 9 - receiver for heavy magnetic fraction; 10 - receiver for a light non-magnetic fraction.

The housing (3) is a trough inclined at an angle of 30 - 45 ^o with a bottom width of about 1000 - 1500 mm and a side height of about 600 mm. Magnetic ferrite-barium tiles 65 x 85 x 14 mm in size and a magnetic field strength of 300 - 400 Oe are laid at a distance of 10 - 12 mm from each other along its entire bottom. Moreover, all their outer poles have the same polarity. In the upper part of the housing (3), a power distributor (2) is installed, which is a box with a slot in the bottom of a width of 40 mm and a length of the entire width of the bottom. In the housing (3), at intervals of approximately 1,500 mm from each other and from the distributor (2), one or more solid partitions (6) are installed with a height of approximately 300 mm with square holes in the area of their abutment to the bottom of the housing (3). The number of holes 3 pcs., Their size is 60 x 60 mm. On the back of each partition (6), an inclined drain chute (7) is installed, which leads through a slot (8) in the side of the housing (3) to a light non-magnetic fraction in the receiver (9). At the end of the housing (3), a receiver (10) for a heavy magnetic fraction is installed.

 The feed is a mixture of small (less than 0.1 mm) non-magnetic and magnetic particles, in the form of a suspension, with a density of about 1200 g / l through the feed pipe (1) enters the power distributor (2), from which a layer with a thickness of about 40 mm flows down along the inclined magnetic bottom of the housing (3) in a volume magnetic field formed by the magnetic poles of the same name of the magnetic tiles (4) with a magnetic field strength on their surfaces of 300 - 400 E.

 Water from the spray (5) mixes a layer of magnetic particles moving along an inclined magnetic surface and flushes non-magnetic particles from it, which float up in the area of the partition (6), go into the drain trough (7) and are removed from the separator.

 Due to the action of magnetic and gravitational forces, magnetic particles do not float in the area of the partition (6), but go through the openings in it into the next part of the body for similar enrichment (cleaning), and then are removed from the separator in the form of a concentrate of magnetic particles.

 Tests of the gravitational magnetic separator on the enrichment of the rough concentrate of magnetic separation of finely disseminated magnetite ores (quartzites) showed that a concentrate with an iron content of 70% is obtained on a separator with three purification capabilities, which is achieved in foreign factories only through the use of cationic reverse flotation. Its exclusion in the operations of finishing iron ore concentrate due to the use of the developed gravitational magnetic separator provides a large economic effect.

Claims (3)

 1. Gravity-magnetic separator, comprising a housing in the form of an inclined trough with magnets installed in it, a feeding and unloading device, characterized in that the bottom of the housing is covered with magnetized tiles with the same poles out.  2. The separator according to claim 1, characterized in that one or more solid partitions with holes in the area of their abutment to the bottom and with drain channels are installed inside the housing one or more at intervals from each other, mounted on top of their rear sides.  3. The separator according to claim 2, characterized in that in each compartment of the housing, limited by solid partitions, water sprays are installed.