SU1378931A1 - Vibration screen - Google Patents

Abstract

The invention relates to a vibration technique and m. used by for sifting various materials in the mining, metallurgical, construction industry, production of powder materials. The purpose of the invention is to increase reliability in operation. The screen consists of a case 1 with electromagnetic exciters 2 mounted on it, connected with a sieve (C) 3 by means of drive elements (E) 4, loading 5 and unloading 6 leakages (T). On the opposite side of the E 4 installation, the C 3 side of the housing 1 has retaining E 7 in the form of elastic bonds, interacting through C 3 with the drive E 4. Different variants of E 4 and 7 are possible. Pathogens 2 report E 4 reverse-rotational vibrations. The latter are transmitted through the contact points E 4 and C 3 to the entire sieve surface. The material entering through T 5, the passage through C 3 is sifted out and output through T 6. In this case, the E 7 provide the contact C 3 and the driven E 4, reduce the displacement of the C 3 and stabilize the oscillation process of the sieve surface. 4 hp f-ly, 5 nl, s cl

Description

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The invention relates to vibration technology and can be used for sifting various materials in the mining, metallurgical, and construction industries, as well as in the manufacture of powder materials.

The purpose of the invention is improving the reliability of the screen.

Fig, 1 shows the roar, longitudinal section; in fig. 2 and 3 — embodiments of retaining elements; in fig. 4 and 5 - variants of the nodes of the interaction of the drive and retaining elements.

The vibrating screen consists of a housing 1 with electromagnetic exciters 2 mounted on it, connected to sieve 3 by means of driving elements 4, loading 5 and unloading 6 currents. On the opposite side from the installation of the drive elements 4 of the screen 3, retaining elements 7 are installed, which are connected to the housing 1. Retaining elements 7 can be made in the form of elastic connections. In another embodiment, the driving 4 and retaining elements 7 can be made fixed to axis x 8 and 9 bangs, the central point of their contact with the sieve is on a plane passing through the axes of rotation of these levers.

The surfaces of the drive and supporting elements that are in contact with the sieve can have two variants. For thin screens, it is rational to perform them, respectively, in the form of protrusions 10 and depressions 11, and the radius of the depressions is greater than the radius of the projections. The sieve 3 located between the interacting parts is deformed in the shape of these parts and securely clamped. Another type of this unit is two platforms interacting with each other, between which there is a sieve 3, One site is provided with needles 12, respectively, and with holes 13, into which needles 12 pass through the sieve surface cells. Pressing these pads to each other provides a secure fixing of the sieve 3. Such a design is applicable when using sieves with a large sieve mesh size when its deformation is difficult and the mesh size of the sieve 3 is sufficient to allow the needle 12 to pass through it without disrupting the sieve fabric.

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The roar works as follows.

The causative agents 2 communicate to the drive elements 4, mounted on the shaft, reciprocating rotational oscillations, which, through the contact points of the drive elements 4 and the sieve 3, are transmitted to the entire sieve surface. The material enters the loading chute 5, and the passage through the sieve 3 is sieved. Separated material is removed from the screen through discharge discharge 6. Retaining elements 7 ensure reliable contact of the sieve 3 and the drive elements 4 during the operation of the screen, excluding slamming of the sieve on them, which reduces the amount of screen movement, and therefore stabilizes oscillation sieve surface.

The necessary force of pressing the support elements 7 is ensured by the trx deformation or the weight of the counterweight. When the lever design drive 4 and retaining 7 elements interact as follows. The drive element 4 performs reciprocating movements around the axis 8. Point A of the drive element 4, in contact with the screen, moves around a circle of radius Rp. However, the movement of the contacting point B of the retaining element occurs along a circle of radius Gr, i.e. on a different trajectory. The distance between these points varies from 0 to A, B in one half period of oscillation.

A variant of the arrangement of the lever drive and retaining elements, when the relative movements of points A and B are minimal, is the placement of the axes of rotation of the driving and retaining elements and their points of contact with the sieve on the same line.

Claims (3)

1. Vibrating screen, including a body with vibration exciters mounted on it and a sieve connected with them by means of drive elements, characterized in that, in order to increase the reliability of the screen, the screen is provided with retaining elements which are mounted on the body reverse side of the drive elements sieve with the ability to interact through a sieve with drive elements. 2, the vibrating screen according to claim 1, characterized in that the retaining elements are made in the form of elastic bonds, 3. Vibrating screen according to claim 1, characterized in that the drive and retaining elements are made in the form of levers fixed on the axes, and their central point of contact with the sieve is on a plane passing through the axes of rotation of the respective drive and retaining levers, 4, the vibrating screen according to claim 1, characterized in that the surfaces of the driving and supporting elements in contact with the sieve are made respectively in the form of spherical protrusions and depressions, the radius of the depressions being larger than the radius of the projections, 5, The vibrating screen according to claim 1, characterized in that the surfaces of the drive and supporting elements in contact with the screen are respectively in the form of needle pads and hole pads. Fi.g Fig.Z FIG. f5 FIG. five