SU1102630A1 - Magnetic separator - Google Patents

Abstract

MAGNETIC SEPARATOR, INCLUDING a magnetic system consisting of a magnetic conductor, windings: No and pole lugs, rotor. Power N5 O with. interpolar gap, characterized in that, in order to increase the separation efficiency by optimizing the gaps between ferromagnetic bodies in the separation and regeneration areas, it is equipped with guide osobleni E input cassettes zyzor in the pole, and the width of the working organ cassette exceeds the interpolar gap. SmyV ffttmoHt / e smy§

Description

The invention relates to the enrichment of minerals, in particular to the separation of finely divided iron ore and manganese pshamov on magnetic separators, and can be used in the metallurgical industry. A magnetic separator is known, whose working organ is a cassette with ferromagnetic bodies pivotally connected to the cassette walls. The swivel provides the ability to change the distance between the ferromagnetic bodies 1J. The disadvantages of the separator are the need to use an additional mechanism to change the distance between the ferromagnetic heat when they are regenerated and the need to cut off the power supply at the time of regeneration. The closest to the proposed technical essence and the achieved result is a magnetic separator, including a magnetic system consisting of a magnetic conductor, excitation windings and pole however nechnik, a rotary working body with peripheral cash dispensers of ferromagnetic bodies distance between each other, feeder installed over the interpolar gap C2. In a known separator, when the cassette passes through the gap between the pole pieces, due to the influence of the magnetic field, the ferromagnetic bodies are attracted to each other, compressing the spring elements. With this, the gaps between the ferromagnetic bodies are reduced. But the reduction of gaps in the separation zone is limited by the presence of spring elements between the ferromagnetic bodies. The location of the latter at the axis of the connection of ferromagnetic bodies within the dimensions of the pole pieces leads to clogging of the cassette by a non-removable magnetic product during the registration. Due to the fact that the width of the cassette is smaller than the gap between the pole pieces, the gaps between the extreme ferromagnetic bodies and pole tips increase as the gap between the ferromagnetic bodies decreases, which leads to an increase in the likelihood of magnetic particles in the nonmagnetic product, i.e. to reduce separation efficiency. In addition, when installing small initial gaps, ferromagnetic bodies are poorly regenerated, and as initial gaps increase, the total gap between ferromagnetic bodies increases, t decreases the number of the latter, and a higher magnetic field strength is needed to bring the ferromagnetic bodies closer in the separation zone. The purpose of the invention is to increase the separation efficiency by optimizing the gaps between ferromagnetic bodies in the separation and regeneration areas. This goal is achieved by the fact that a magnetic separator comprising a magnetic system consisting of a magnetic conductor, excitation windings and pole pieces, a rotary working body with peripheral cassettes of ferromagnetic bodies. installed with the possibility of changing the distance between them, the feeder mounted above the interpolar gap is provided with guides for inserting the cassettes into the interpolar gap, the working device cassettes being wider than the interpolar gap. The operation of the separator is illustrated in the drawing, in which: In FIG. 1 shows a magnetic separator, a plan view; in fig. 2 the same general view section; on . FIG. 3 - cassette with ferromagnetic bodies, general view; in fig. 4 is a view A of FIG. 3, in FIG. 5 is a view of the cassette at the separation site; in fig. 6 and 7 - the same at the regeneration site. The magnetic separator includes a magnetic system consisting of excitation windings 1 and i ar pipes 2, 3 rotor 4, on the peripheral part of which ferromagnetic bodies 5 are located, connected in cassettes with the possibility of changing the distance between them in the horizontal plane, in the direction perpendicular to the direction movement of the cassette when moving it between the pole tips of the magnetic system. Ferromagnetic bodies 5 are vertically mounted springs, rods, plates, and the like, connected in cassettes using flexible connections, such as, for example, strip rubber, springs, etc. The fastening of ferromagnetic bodies in the cassette is located outside the pole pieces, i.e. above and below them. It is possible to use balls as a ferromagnetic body, steel wool, etc., fixed, for example, on rubber bands, the ends of which are also connected outside the pole pieces. The connection of ferromagnetic heat 5 is made with the help of plates 6 and rods 7, to which each ferromagnetic body is fixed with the possibility of movement in the indicated direction. The width of the cassette thus formed is greater than the width of the gap between the pole pieces of the magnetic system. In this case, the ferromagnetic bodies are located at a distance from each other, which ensures their effective regenerant. walkie-talkie. The cassette is limited in length by the walls 8 rigidly connected to the base of the cassette 9. To improve the conditions for inserting the cassette into the gap between the pole tips of the magnetic system, the separator is equipped with guides 10 and 11, and the pole tips of the magnet system can be performed with a corresponding curvilinear surface. Platform 12 of the loading device 13 is mounted on the elastic element 14. The separator operates as follows. Electric power is supplied to the magnetic system, consisting of excitation winding 1 and magnetic circuit 2, 3 Rotor A, rotating in a horizontal plane, inserts the cassettes with ferromagnetic bodies 5 into an interpolar gap. The ferromagnetic bodies 5 are fastened in the cassette with fastener assemblies consisting of plates 6 and rods 7, the ferromagnetic bodies being located at a distance that ensures efficient regeneration, and along the length of the cassette is limited by walls 8 connected to the base 9. When approaching the interpolar gap, the guides 10 and 11 compress and form the position of the ferromagnetic ones 5. At the same time, initial power is supplied through the device 13 and the source material is separated according to the magnetic properties. Upon leaving the zone of operation, the magnetic field of the cassette enters the regeneration section, where the vibrator, acting on the pad 12 of the loading device 13 mounted on the elastic element 14, under the action of elastic forces increases the distance between the bodies 5 to the original ones. Moreover, the dynamic effect on the ferromagnetic body 5 of the vibrator (by pulsating supply of flush water, etc.) will increase the efficiency of regeneration. In high-intensity magnetic separators with contact ferromagnetic; Such a medium, such as balls, rods, metallic wool, etc., has a higher separation efficiency, and the regeneration conditions of ferromagnetic bodies are worse than in separators with a non-contact ferromagnetic medium, such as plates, which are set apart from each other. Due to their contact, the likelihood of trapping fine magnetic particles is increased. Due to the fact that the connection of ferromagnetic bodies is located outside the dimensions of the pole pieces, when the contact of ferromagnetic bodies increases, the distance between them from the contact point to the connection increases, which leads to a decrease in the intensity towards the connection. In this way, in the separation zone, highly-magnetic particles are first separated, and as they approach the point of contact, weakly magnetic ones. In the separator, ferromagnetic bodies are spaced apart from each other, ensuring their effective regeneration, but since the width of the cassette exceeds the width of the gap between the pole pieces, and the connection of the ferromagnetic bodies is located outside the dimensions of the pole pieces, when entering the separation zone, the ferromagnetic bodies approach each other to contact. with the other in a direction perpendicular to the direction of movement of the cassette.

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Claims (1)

MAGNETIC SEPARATOR, including a magnetic system consisting of a magnetic circuit, field windings and pole pieces, rotor A Fie ?! Nutrition ------------ 7 At a working body with cassettes of ferromagnetic bodies located on the periphery, installed with the possibility of changing the distance between them, a feeder mounted above the interpolar gap, characterized in that, in order to increase the separation efficiency by optimizing the gaps between the ferromagnetic bodies in the separation and regeneration, it is equipped with guiding devices for inserting the cassettes into the ^v pole-gap zyzor, and the width of the cassettes of the working body exceeds the size of the pole-gap. '