SU1715425A1 - Magnetic drum separator - Google Patents

Abstract

The invention relates to magnetic separation and is intended for use in foundries for the cleaning and regeneration of steel and cast iron shot. The purpose of the invention is to simplify the design, reduce metal consumption and increase the separation efficiency. The separator contains a drum (B) with a magnetic system of permanent magnets (PM) in the form of rectangular prisms installed on a rome made of a ferromagnetic equilateral angle. The same poles of the PM face the surface B. The intermediate pole is located between the PM. At the same time, ferromagnetic plates are installed at the intermediate pole with the possibility of moving the latter radially to surface B. Ferromagnetic stepped pole tips attached to the curvilinear surface B are attached to the working facets PM facing the surface B in increments of 90 & circumferentially B. The source material enters B, where under the action of a magnetic field, the fractional particles are attracted to B. The nonmagnetic bulk material is removed by gravity from B. 1 Cp. f-ly, 2 ill.

Description

The invention relates to magnetic separation and is intended for use in foundries for the cleaning and regeneration of steel and cast iron shot by magnetic separation of shot-sand mixtures formed in the working process of shot-blasting plants widely used in foundries.

Drum magnetic separators for cleaning shot are known, consisting of a working body in the form of a non-magnetic drum with a magnet system located inside the drum in the form of blocks of permanent magnets, with a certain pitch installed along the curvilinear surface of the drum, while the angle between the radial axes of adjacent blocks practically 2-15 °. The advantage of these structures is the repeated measurement of the polarity of the magnetic field around the circumference of the drum, which contributes to the improvement of the quality of the concentrate during ore dressing.

The disadvantages of these structures are: the need to use a relatively large number of blocks of permanent magnets, which leads to an increase in size, metal intensity and cost.

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imosti separators; relatively large fluxes in the magnetic system due to the relatively small pitch of the placement of blocks of permanent magnets, which leads to an additional increase in metal intensity and a decrease in the separating capacity of the separator; the degree of heterogeneity of the magnetic field is relatively low (i.e., the magnitude of the geometric gradient of the magnetic field strength) on the drum surface, which significantly reduces the separating ability of the separator; the inability to control the intensity of the magnetic field on the surface of the drum, which reduces the separation efficiency.

Similar separator structures are also known, which differ from the described structures in that devices are placed inside the drum which allow the magnetic system as a whole to be moved relative to the drum surface and thereby regulate the magnetic field strength on the drum surface, which is an advantage of these structures.

The disadvantage here is the relatively large complexity of the separator designs due to the need to use rather complex and cumbersome lifting and turning devices embedded inside the drum. In addition, these deficiencies also remain in these structures.

A drum magnetic separator is known, consisting of a working body in the form of a nonmagnetic drum, inside of which there is a magnetic system made of permanent rectangular magnets mounted on p, e, the poles of the same name facing the surface of the drum, additional permanent magnets, and ferromagnetic plates mounted on the rotor radially to the surface of the drum. In the operating mode, ferromagnetic plates serve here as intermediate poles of the magnetic system, which increases the separation efficiency and is an advantage of the design.

The disadvantages of the known separator are as follows: the need to use a relatively large number of blocks of permanent magnets, which leads to an increase in size, metal consumption and cost of the separator; a relatively low degree of heterogeneity of the magnetic field on the surface of the drum (in the areas where the main and additional permanent magnets are located), which reduces

the separating ability of the separator; large scattered fluxes between additional permanent magnetic and ferromagnetic plates (due to

relatively small pitch of magnets around the circumference of the drum), which further increases the intensity of the metal and reduces the separating ability of the separator; the inability to control the intensity of the magnetic field on the surface of the drum, which reduces the separation efficiency.

The purpose of the invention is to simplify the design, reduce the metal consumption and increase the efficiency of the separator.

This goal is achieved by fixing the ferromagnetic intermediate pole between the permanent magnets and the intermediate ferromagnetic pole.

plates can be moved radially to the drum surface, and to the working edges of the permanent magnets facing the drum surface are attached ferromagnetic pole tips of a stepped shape, facing with their stepped profile to the curvilinear surface of the drum, while as a magnetic magnetic frame the system uses an equilateral angle of ferromagnetic material, to which the intermediate pole and magnets are attached with a step of 90 ° around the circumference of the drum, and in the plates attached to the intermediate pole, made grooves.

This technical solution allows to simplify the design and reduce the metal consumption and cost of the separator by reducing the required number of permanent magnets (by more than 15 times compared to the prototype), while maintaining a sufficient length of the working sector of the magnetic field around the circumference of the drum. In this case, the use of installed on

the intermediate pole of ferromagnetic plates with the ability to move the latter in the radial direction to the surface of the drum allows you to adjust the magnitude of the magnetic field strength

on the surface of the drum, which contributes to increased separation efficiency. The use of ferromagnetic stepped pole tips increases the degree of heterogeneity of the magnetic field (i.e. the magnitude of the magnetic field strength gradient) on the drum surface, which contributes to an increase in the separating ability of the separator. In addition, the use of stepped pole tips mounted on the working faces of permanent magnets allows increasing the intensity of the magnetic field on the curvilinear surface of the drum with the simplest - flat form of the working faces of the permanent magnets, since for a sufficiently large number of steps the profile is steep. lugs closely enough repeats the curved shape of the drum surface.

The use of a frame in the form of a ferromagnetic equilateral angle in combination with stepped ferromagnetic pole lugs makes it possible to use the simplest and most technologically advanced blocks of permanent magnets, made in the form of rectangular prisms, and to simplify the design and complexity of manufacturing a separator. whole

FIG. 1 shows the proposed separator, a general view; in fig. 2 is a view along arrow A in FIG. one.

The separator consists of a working body in the form of a non-magnetic drum 1 with strips 2 fixed to it, mounted for rotation around fixed semi-axes 3. Inside the drum there is a magnetic system consisting of permanent magnets in the form of rectangular prisms 4 fixed to the frame in the form of a ferromagnetic angle 5, to which an intermediate pole in the form of a ferromagnetic plate 6, mounted between blocks of permanent magnets, is also attached. The permanent magnets are magnetized in the radial direction to the surface of the drum and installed in 90 ° increments around the circumference of the drum with the same poles facing the surface of the drum. Ferromagnetic (steel) 7-pole pole tips are attached to the working flat faces of permanent magnets, the stepped profile of which faces the curved surface of the drum. Ferromagnetic plates 8 are attached to the intermediate pole with the possibility of moving these plates in the radial direction to the drum surface, for which the corresponding grooves 9 are made in the plates 8. The magnetic system as a whole is rigidly attached to the stationary semi-axis m 3 using cheeks 10 attached to the rm and semi axis m. -. , .. ;. :.

The separator is also equipped with a 10 ish scrammer, made in the form of a concave plate of non-magnetic material and installed next to the drum on the side of the permanent magnet blocks, receivers 1T and 12, mounted under the drum, a reflective wall 13 made of non-magnetic material and mounted on opposite (with respect to permanent magnet blocks) drum side).

The separator works as follows.

In the operating mode, the drum 1 is rotated along arrow B, and into the working area between the surface of the drum 1 and sklyom 10 a loose crumb mixture is fed along arrow B. In this case, under the action of a magnetic field of permanent magnets, ferromagnetic steel or cast iron is attracted to the drum surface, and the non-magnetic fraction (sand) spills naturally through the slide 10 into the receiver 11. The shot extracted from the loose shot-sand mixture with the help of the rotating drum 1 is carried to the unloading zone bounded by the non-magnetic When the fraction is transported (on the surface of the drum) from the extraction zone to the discharge zone, the shot undergoes periodic magnetization reversal, which provides a fairly low contamination of the extracted sand. fractions. In this case, by moving the plates 8 in the radial direction, the magnitude of the magnetic conductivity of the working interpolar gaps between the permanent magnets can be changed, which makes it possible to control the intensity of the magnetic field on the drum surface to a certain degree (almost within t40%). The latter circumstance, in turn, allows to realize the maximum possible separation efficiency (in this case, the minimum sand infiltration of recoverable shot) depending on the specific initial conditions of operation of the separator (moisture content and particle size of the sand mixture, etc. ).

The presence of permanent magnets of ferromagnetic stepped pole pieces on the working faces allows increasing the intensity and heterogeneity of the magnetic field on the drum surface, which provides an increase in the separating ability of the separator and, accordingly, sufficiently complete extraction of the fraction from the shot-sand mixture (almost no less than 95%).

Making the frame in the form of an equilateral ferromagnetic angle in combination with a stepped ferromagnetic pole tips allows the use of the most simple in shape and technologically advanced.

blocks of permanent magnets, made in the form of rectangular prisms, and to simplify the design and complexity of manufacturing the separator as a whole.

Thus, the described distinctive features make it possible to simplify the design, reduce the metal consumption, increase the efficiency and the extracting ability of the separator.

At present, the studies have been completed and the drawings (at the level of the draft design) of a small-sized experimental sample of a drum magnetic separator with a drum diameter of 408 mm and a working length of 750 mm are completed. The mass of the separator (without drive, feeder and receivers) is 148 kg, the productivity of shot sand mixture is not less than 40 t / h. Compared with the known separator ПБ Э - 90/250, the specific productivity (per unit mass) of the proposed separator is more than 3 times higher, while the total mass of the same type of permanent magnets used in the compared separator designs is reduced with 1600 to 75 kg.

Claims (2)

1. Drum magnetic separator, which includes a working body in the form of a non-magnetic drum, inside which there is a magnetic system, consisting of permanent magnets installed in the frame in the form of rectangular prisms, whose poles of the same name are facing the surface of the drum, and an intermediate pole in the form of a ferromagnetic plate attached to the chamber and installed between the permanent magnets, it is necessary that, in order to simplify the design, reduce the metal consumption and increase the separation efficiency, it is equipped with rotary plates / mounted on the intermediate pole with the possibility of their movement in the radial direction to the drum surface and ferromagnetic pole tips located on the working faces of the permanent magnets facing the drum surface and having a stepped profile, while the rom magnetic system is made of equal a corner of a ferromagnetic material on which permanent magnets are installed in 90 ° increments around the drum circumference. 2. The separator according to claim 1, characterized in that the slots installed on the intermediate pole of the ferromagnetic plates are made. ff Phage. one eight FIG. one