RU2014159C1 - Screen - Google Patents

Abstract

FIELD: ferrous metallurgy. SUBSTANCE: screen has box 1 with a vibrator, undersieve 2 fastened to the box, sieve 3 is freely laid on the undersieve. Flexible strike members 9, 12 are fastened to the working surface of the sieve by posts 10. The loading part of sieve 3 is connected to the box by a flexible link. Box 1 is made with limiting thrusts 8, 11 mounted coaxially with posts 10 in a spaced relation to strike members 9, 12 and for axial displacement and fixing. Strike members 12 and limiting thrusts 11 located around the periphery of the box are made with projections and hollows respectively, for example, V-shaped. EFFECT: improved structure. 3 cl, 2 dwg

Description

 The invention relates to ferrous metallurgy and the mining industry, in particular for sieving difficult-to-screen fractions of various materials.

A known screen includes an oscillating box with a support rigidly attached to it, a sieve freely placed on the support and an impact element that is integral with the sieve, the mass of the sieve being selected from the ratio m _c / m _k = 1.75 ... 2.0 where m _c - sieve mass, kg; m _to - the mass of the box, kg [1].

A disadvantage of the known screen is that with an increase in the intensity of vibrations when screening wet and sticky materials, when it is necessary to fulfill the condition Г = (АВ˙ω ² ) / g> 3.3, the number of collisions of the sieve with the box (working frequency of the sieve) becomes two times lower than the frequency of the box, i.e., the interaction of the sieve with the box is carried out not in each period of oscillation of the latter, but through the period, which leads to a decrease in the performance of the screen and the efficiency of screening.

 The purpose of the invention is to increase the screening efficiency of wet and sticky materials by increasing the operating frequency of the sieve.

 This is achieved by the fact that the screen is equipped with shock elastic elements fixed by means of racks on the working surface of the sieve, and the box is made with restrictive stops mounted coaxially with the stands with a gap relative to the shock elastic elements with the possibility of interaction with the latter, while elastic shock elements and limit stops located on the periphery of the box, made with protrusions and recesses, respectively.

 This goal is also achieved by the fact that the protrusions of the elastic shock elements and the notches of the limit stops located on the periphery of the box are V-shaped, while all the limit stops are made with the possibility of axial displacement and rigid fixation.

 In FIG. 1 shows a rumble, a general view; in FIG. 2 is a section along AA in FIG. 1.

The screen consists of an oscillating box 1, a support plate 2 rigidly attached to it, on which a sieve 3, which is a shock element, is freely laid. Shock absorbers 4 are installed in the loading part of the screen, preventing the sieve 3 from moving along the box 1. The last 1 is supported by the frame 5 through the shock absorbers 6, and it receives vibrational excitation from the vibrator 7. The mass of the box with the sieve is selected from the ratio m _c / m _k = 1, 75 ... 2.0. The box 1 is made with limit stops 8, and shock elastic elements 9 are fixed on the working surface of the sieve 3, by means of racks 10 interacting with limit stops 8, while the elastic shock elements and limit stops located on the periphery of the box are made with protrusions and recesses, respectively.

 The stops 11 located on the periphery can be made in the form of V-shaped sockets, and the profile of the elastic elements 12 located on the periphery, repeats the profile of the cavity of the V-shaped sockets. All restrictive stops 8 and 11 are made with the possibility of axial displacement in the bushings 13 and rigid fastening with the help of clamps 14.

 The roar works as follows.

 The material is fed to a sieve 3, where it is divided into under-sieve and over-sieve products. Under the influence of the vibrations of the box 1, excited by the vibrator 7, the material moves towards the discharge part of the sieve 3. The latter is freely placed on the box 1 through the sieve 2 and also perceives vibration from the vibrator 7, but since box 1 and sieve 3 are not rigidly connected and have different masses, then they oscillate with different amplitudes and collide with each other, imposing additional impact effects on the material layer. The restrictive stops 8, 11 and shock elastic elements 9, 12, installed with a gap, ensure the constancy of the working frequency of the box 1 and sieve 3. The magnitude of the shock impulse is carried out by adjusting the gap by moving the limit stops 8 and 11 in the bushings 13 and their fastening the help of the clamps 14. Limit stops 11 located on the periphery and made in the form of V-shaped sockets, as well as elastic elements 12, located also on the periphery and repeating the cavity profile of the V-shaped sockets, preventing The lateral displacement of the sieve 3 relative to the box 1 is fixed. The longitudinal displacement of the sieve 3 relative to the box 1 is limited by shock absorbers 4.

 Thus, the use of screening makes it possible to increase the screening efficiency of particularly wet and sticky materials.

Claims (3)

 SCREEN, including box with a vibrator attached to the box box, loosely laid on the box and connected to the box loading end through an elastic connection sieve, the mass ratio of which to the mass of the box is 1.75 - 2.0, characterized in that, in order to increase the efficiency of the screening process of wet and sticky materials by increasing the working frequency of the sieve oscillations, the screen is equipped with shock elastic elements fixed by racks on the working surface of the sieve, and the box is made with restrictive stops E mounted coaxially with struts with a clearance relative to the drum elastic elements capable of cooperating with the latter, wherein the shock elements and limiting abutments disposed along the periphery of the box are formed with projections and recesses, respectively.  2. The screen according to claim 1, characterized in that the protrusions of the elastic impact elements and the notches of the limit stops located on the periphery of the box are made V-shaped.  3. The screen according to claim 1, characterized in that all the limit stops are mounted with the possibility of axial displacement and rigid fixation.

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