RU2678008C1 - Vibration centrifuge - Google Patents

Abstract

FIELD: technological processes.SUBSTANCE: invention relates to devices for separating suspensions into liquid and solid phases using centrifugal forces, namely, filtering centrifuges with vibratory discharge of sediment, and can be used in chemical, food and other industries. Vibrating centrifuge consists of body (1), working body (3), inside which magnets are installed parallel to its generator, drive rotational movement of the working body from motor of rotation (8) and the vibratory drive of the working body in a vertical plane from a flat linear induction motor. Inductors (11) of a linear asynchronous motor are rigidly fixed to base (2), and the rotor is ring (12), movable and spring-loaded in a vertical plane. Ring (12) is made of metal with high electrical conductivity, is rigidly connected to working body (3) and has symmetric through holes (13) not smaller than the size of the working surface of one inductor (11).EFFECT: reduced material consumption and increased centrifuge reliability.1 cl, 4 dwg

Description

The invention relates to a device for separating suspensions into liquid and solid phases using centrifugal forces, and in particular to filter centrifuges with vibrational discharge of sediment, and can be used in chemical, food and other industries.

Known filtration vertical vibrating centrifuge, consisting of a housing, a working body, inside of which are installed magnets parallel to its generators, drives for vibration and rotational movements of the working body [1].

The disadvantage of the technical solution is the low reliability of the vibratory drive of the centrifuge working body due to the transfer of significant dynamic forces to the bearing assemblies, the presence of a large number of rubbing and wearing parts.

Closest to the proposed technical solution is a vertical filtration vibrating centrifuge, consisting of a housing, a working body, inside of which magnets are installed parallel to its generatrix, a rotational drive of the working body from the rotation motor and a vibrating drive of the working body in the vertical plane from a linear linear asynchronous electric motor, inductors which is rigidly fixed to the base, and the rotor is a ring, movable and spring-loaded in a vertical plane ty made of metal with high electrical conductivity and rigidly connected to the working body [2].

The disadvantage of the technical solution is the presence of a complex and expensive control unit that periodically connects and disconnects the inductors of the linear asynchronous electric motor from the network during the operation of the centrifuge, which is accompanied by high inrush currents in the windings of the inductor, which in turn reduces the reliability of the vibration drive.

In all constructions known to the authors, the vibrational movement of the working body along the axis of rotation, realized from a linear asynchronous electric motor (LAD), is provided by periodically connecting and disconnecting the latter through the control unit.

The aim of the invention is to reduce the cost, material consumption and increase the reliability of the vibration centrifuge.

This is achieved by the fact that symmetrical through holes are made on the ring, and the size of one hole is not less than the size of the working surface of one inductor.

The proposed technical solution has a significant difference from the known ones, namely that the vibrational movement of the working body from the LAD is realized without a unit for turning on and off the motor inductors from the power supply during operation. This is achieved through through holes made symmetrically on the ring, which is also the rotor of the LAD. LAD inductors are constantly connected to the network during the operation of the centrifuge. The ring through a spline connection is informed of the rotational movement from the rotation motor. At the moment of rotation, when a part of the ring without holes is located opposite the LAD inductors, an electromagnetic force arises under the action of which the ring comes in translational motion, for example, down in a vertical plane. In this case, the elastic elements located under the ring are compressed. As the ring rotates, there comes a moment at which the symmetrically located holes of the ring are opposite the LAD inductors, while the electromagnetic field disappears, and due to the energy accumulated in the elastic elements, the ring returns to its original state, while continuing to rotate. Further, at the moment when parts of the ring without holes will pass opposite the inductors, the ring will again come into translational motion and then the described process will be repeated.

The oscillation frequency of the working body will be determined by the number of holes on the ring and its frequency of rotation.

Thus, the proposed technical solution will allow for the vibrational movement of the working body of the centrifuge from the LAD without the block of its periodic connection and disconnection from the network, which will reduce the cost, material consumption and increase the reliability of the centrifuge.

In FIG. 1 shows a General view of the proposed centrifuge. In FIG. 2 shows the position of the working body (its part) at the moment when opposite the inductors are parts of the ring without holes; in FIG. 3 provisions of the working body (its part) at the moment when opposite the inductors are parts of the ring with holes; in FIG. 4 is a section AA in FIG. one.

The centrifuge has a housing 1, which rests on the base 2. Inside the housing there is a working body 3 connected through a disk 4 with a horizontally located pulley 5. The pulley 5 with the help of V-belts receives rotation from the pulley 7, mounted on the shaft of the electric motor 8. When the pulley 5 is rotated, the working 5 the centrifuge is rotated around its vertical axis through a spline connection 6.

Inside the housing there is a linear electric drive of the vibrating movement of the working body in a vertical plane, which is a flat LAD, consisting of several inductors 11, rigidly fixed to the base, and the rotor is a ring 12, on which symmetrical through holes 13 are made. Ring 12 is rigidly fixed to the disk 4 , movably and spring-loaded in a vertical plane by means of rollers 9 and elastic elements 10. Ring 12 is made of metal with high electrical conductivity (for example, aluminum or copper) and can be made manufactured from aluminum or copper tube or a cylindrical shape rolled aluminum or copper plate, which is formed from a tubular cylinder, which operate through openings symmetrical, the magnitude of the holes should be at least the size of the working surface of one inductor [3].

Magnets 18, a receiving funnel 14, a cutting cone 15 and a guiding cone 16, forming cavities for collecting the concentrate and the liquid fraction, are installed inside the centrifuge’s body parallel to the generatrix of the working body. In the lower part of the housing is an assembly funnel 17 of the concentrate, from which the latter can be fed to the conveyor or to the storage hopper.

When voltage is applied to the electric motor 8, the centrifuge working member 3 and the ring 12 will rotate around its axis, transmitted through the spline connection 6 from the pulley 5, while the LAD inductors are constantly connected to the network. At the time of rotation, when a part of the ring without holes is opposite the LAD inductors, an electromagnetic force arises, under the influence of which the ring 12 comes into translational motion, for example, down. When the ring 12 moves, the elastic elements 10 are compressed (Fig. 2). As the ring 12 rotates, there comes a moment at which the holes 13 in the ring are located symmetrically with respect to the LAD inductors 11, while the electromagnetic force disappears and under the action of the potential energy accumulated in the elastic elements 10, the ring 12 returns to its original state (Fig. 3) while continuing to rotate. Then the part of the ring without holes is again opposite the inductors 11 and the process described below is repeated. In this case, the working body 3 performs a vibrational-rotational movement. The size of one hole 13 on the ring 12 should be not less than the size of the working surface of one inductor, which will ensure the return of the working body to its original position at the moment when the symmetric holes 13 are located opposite the inductors 11 LAD, due to the elastic elements 10.

In this design, the frequency and amplitude of the oscillations of the working body depends on its speed, respectively, by adjusting the speed of the working body, you can change the parameters of its vibrations. The frequency of rotation of the working body can be changed using a voltage frequency converter or thyristor voltage regulators [4].

Also, the frequency and amplitude of the oscillations of the working body also depends on the number of symmetrical holes 13 made on the ring 12. The more such holes, the greater the frequency of vibrations of the working body at its same rotation frequency.

During the operation of the centrifuge, the dehydrated material in the form of pulp enters the receiving funnel, and getting on the working body, spreads evenly. Moving along the annular gap, the pulp is sent to zone A (Fig. 1), in which an electromagnetic field begins to act on it. Particles of the concentrate under the influence of a magnetic field are lowered onto the outer surface of the working body, forming a sediment held by the magnetic field.

Subsequently, the concentrate particles settled on the working body move down the outer surface of the working body and fall into zone B. In the upper initial part of zone B, the particles of the concentrate are still influenced by the electromagnetic field (Fig. 1). As you move down zone B, the influence of the electromagnetic field on the particles of the concentrate weakens. Under the action of a centrifugal field, the particles of the concentrate break away from the working body and enter the annular cavity a, and under the influence of their own weight fall into the assembly funnel and then onto the conveyor receiving tape or storage hopper.

The liquid phase of the pulp, leaving zone A, is discarded by centrifugal forces in the radial direction from the rotor and enters the annular cavity b, from which it is removed to the outside.

Information sources

1. USSR patent 312625, MCP B04b 3/06. Vertical vibration centrifuge for dehydration of minerals / Poturaev V.N. 1971, Bulletin No. 26.

2. Patent 2624702, Russian Federation, IPC B04b 3/06. Vibration centrifuge / Linenko A.V., Linenko Yu.A., Khalilov B.R., Tuktarov M.F .; Applicant and patent holder Bashkir State Agrarian University, 09.03.2016

3. Nasar SA, Boldea I. Linear traction electric machines: Per. from English / Ed. Dr. tech. sciences A.S. Kurbasova. M .: Transport, 1981. 176 p.

4. Ilyinsky N.F., Moskalenko V.V. Electric drive: energy and resource saving: textbook. allowance for students. higher textbook. institutions - M .: Publishing center "Academy", 2008. - 208 p.

Claims (1)

A vibration centrifuge, consisting of a housing, a working body, inside which magnets are installed parallel to its generatrix, a rotational drive of the working body from the rotation motor and a vibrating drive of the working body in a vertical plane from a flat linear asynchronous electric motor, the inductors of which are rigidly fixed to the base, and the rotor is a ring, movable and spring-loaded in a vertical plane, made of metal with high electrical conductivity and rigidly connected to the working body ohm, characterized in that the ring is made of symmetrical through holes, and the size of one hole is not less than the size of the working surface of one inductor.

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