RU2129471C1 - Magnetic hydraulic separator - Google Patents

Abstract

FIELD: washing magnetic concentration of natural deposits, preferably fine-grained ore. SUBSTANCE: main magnetic system is designed as permanent magnets which opposite poles provide slots in bottom of feeding tank. Slots in their beginnings are parallel to linear rotation velocity vector of suspension in tank. In addition each magnetic plate of additional system is glued with magnets on its both sides. External poles of said magnets have same sign on its surface but are opposite on both sides of plate. EFFECT: increased output of concentrated ore, decreased content of iron (ore particles) in waste. 2 cl, 1 dwg

Description

 The invention relates to equipment for wet magnetic mineral processing, mainly finely disseminated iron ores (ferruginous quartzites).

 Various magnetic hydroseparators are also known, also called magnetic deslamers, including tanks, supply tanks with magnets integrated in the loading nozzles (the so-called main magnetic system), loading and unloading devices, drain troughs and rakes). (see, for example, "Guide to ore dressing," t. 1, edited by O.S. Bogdanov and others, M., 1972).

 Also known is a magnetic hydroseparator, including an additional slotted magnetic system, a shell for supplying power to it, and a tray for changing the direction of flow of the suspension from vertical to horizontal (prototype RF patent N 2106203, see Bull. Inventory N 7, 1998).

 The disadvantage of all known magnetic hydroseparators, including the prototype, is that in the discharge product (waste) there is an increased content of magnetic ore particles.

 The objective of the invention is to improve the magnetic hydroseparator for waste (discharge) free from ore particles.

 The problem is solved in that the main magnetic system is made of permanent magnets, the poles of opposite sign form slots in the bottom of the supply tank, parallel to the vector of the linear speed of rotation of the suspension in it, as well as the fact that each magnetic plate of the additional magnetic system is glued on both sides by magnets, the outer poles of which are unique for each of its surfaces, but opposite in sign for both sides of the plate.

 With this arrangement of the main magnetic system, the flow of the suspension, rotating in the supply tank, repeatedly (until the suspension exits from it) crosses the magnetic lines of force of the poles of the magnets installed above the outlet openings of the tank in its bottom.

 At the same time, according to the studies performed, ferromagnetic sections arise on the surface of ore weakly magnetic particles, which facilitate the transition of these particles into sediment (ore fraction), whereas in known magnetic hydroseparators, these weakly magnetic ore particles go into the discharge (waste).

 The creation of ferromagnetic sections on the surface of weakly magnetic ore is also facilitated by the fact that each magnetic plate of the additional magnetic system is glued on both sides with magnetized tiles of permanent magnets, the outer poles of which are unambiguous on each side of the plate, but opposite in sign for each side of the same plate.

 Moreover, in the gaps between two adjacent plates, the field is created by permanent magnets whose outer poles are opposite in sign. Therefore, each ore particle crosses the magnetic lines of force and therefore is additionally magnetized. Additional bias reduces the loss of ore mass with waste magnetic separator.

 The indicated arrangement of magnetic plates (for example, tiles) on the surface of each plate of the additional magnetic system leads to the fact that one of its surfaces has, for example, a southern polarity, and the second - a northern one. This approximately doubles the magnetic field strength in the gap between adjacent plates, which enhances the magnetization of ore particles and thereby helps to solve the problem.

 The developed magnetic hydroseparator is shown in FIG. 1, where, 1 - a chan, 2 - an additional magnetic system, 3 - a shell of an additional magnetic system, 4 - a feeding device, 5 - a rake drive, 6 - a supply tank with a main magnetic system installed on its bottom, 7 - a pallet, 8 - drain chute, 9 - rake, 10 - outlet.

 Several quadrangular openings 150 mm wide and 200 mm long are cut in the bottom of the supply tank 6; moreover, the long side of each hole is parallel at their beginning to the vector of the linear speed of rotation of the suspension in it. Along the edges of the long sides of each of these holes, magnets with opposite poles are installed towards each other. They form magnetic gaps.

 Each magnetic plate of the additional magnetic system consists of a steel plate with a length of 1400 mm for hydroseparators with a tub diameter of 5000 mm. The thickness of the steel plate is 8 mm. On one side, the plate is glued over with magnets with southern outer poles, and on the other side with north.

 One end of the pasted plate is installed in the slot of the shell of the pan 7, and the other is attached to the shell 3.

 The initial power is supplied through the pipe 4 tangentially to the supply tank 6 and is brought into rotation in it (due to the tangential feed). At the same time, ore particles repeatedly cross magnetic lines of force, are magnetized and slotted magnetic gaps pass along with non-metallic particles vertically downward.

 The pallet 7 directs the flow of the suspension between the magnetic plates of the additional magnetic system 2. In their gaps due to the specified location of the outer poles of the magnets, the magnetic field is much higher than in the known technical solutions of magnetic hydroseparators. This ensures that the upstream suspension is removed from ore particles, which is more effective due to pre-magnetization.

 Industrial testing of the developed magnetic hydroseparator confirmed that the new technical solution provides waste with a low iron content. This allows you to increase the yield of concentrate, which gives a great economic effect.

Claims (2)

 1. Magnetic hydroseparator, comprising a tub, a supply tank with a main magnetic system, an additional magnetic system made of vertical radially diverging magnetic plates, a supply and discharge device, characterized in that the main magnetic system is made of permanent magnets, the poles of which are opposite in sign slots in the bottom of the supply tank, parallel at their beginning to the vector of the linear speed of rotation of the suspension in it.  2. The hydraulic separator according to claim 1, characterized in that each magnetic plate is additionally magnetically glued on both sides with magnets, the outer poles of which are unique for each of its surfaces, but opposite in sign for both sides of the plate.