SU1077659A1 - Vibrosieve of hydraulic screen - Google Patents

Abstract

1. VIBROSITO HYDRO-GROUNDING, including working and supporting wire grids laid one on another, whose cell size is at least twice as large as the diameter of their wire, and the size of the grid of the supporting grid exceeds the size of the working grid cell, and the transverse wires of the grids are offset in relation to one the other, with the formation of a bulk screening cell, characterized in that, in order to improve the quality of screening cleaning of the surface and the screening capacity by reducing the hydraulic matching The screening screen is additionally equipped with at least one mesh that is placed between the working and supporting Grids, and its cell size is equal to the size of the cells of the working grid, and the size of the grid of the supporting grid is at least twice as large as the cell of the working grid. , while the bulk cell of the screening is represented by a parallelepiped, whose faces are inclined in the direction of material unloading at an angle of 6 dr 45 2. The vibrating screen, according to claim 1, characterized in that the angle of inclination of the parallels the lepiped is calculated according to the formula a, b, g de2 is the angle of the parallelepiped faces; Iw - is normal to the grid; it is a reptile of the speed of vibration; 1L- - the rate of movement of the solution on the grid in the direction of discharge.

Description

The invention relates to the mining industry, in particular, to devices for classifying rewatered material, cleaning mud. A hydroshort vibrating screen is known, which includes a screening surface with square cells 1. The disadvantage of such a vibrating screen is its relatively low productivity during the procuring of the overmoistened material of small classes. The closest to the invention to the technical essence and the achieved result is a vibrating screen. a hydroharmonic screen, including working and supporting wire grids laid one on another, in which the cell size is at least twice as large as the diameter of their wire, and the size of the mesh of the supporting grid exceeds the size of the working grid cell, and the transverse wires of the grids are offset one relative to another with the formation of a bulk cell of screening 2. The disadvantage of this vibration screening gyrocircuit is that the cross wires of the supporting grid, cross the cell, decrease the duty ratio, resulting in OIS walks increase hydraulic resistance of the sieve surface and therefore decrease productivity of the shaker. In addition, when classifying small classes, the probability of clogging the sieve surface is relatively high. The aim of the invention is to improve the quality of cleaning of the screening surface and screening performance by reducing the hydraulic resistance of the screen surface. This goal is achieved by the fact that the vibrating screen of the hydrocircuit includes overlaid working and supporting wire grids, in which the cell size is at least twice as large as the diameter of their wire, and the size of the cell of the supporting grid exceeds the size of the cell of the working grid, and the transverse wires of the grids in the plane the siftings are displaced one with another to form a bulk screening cell, additionally equipped with at least one grid that is placed between the working and supporting grids, and its cell size is equal to measure the cells of the working grid, and the cell size of the reference grid is at least twice as large as the size of the working grid cell, while the bulk screen cell is represented by a parallelepiped whose faces are inclined in the direction of material unloading at an angle of 6-45 Moreover, the angle of inclination parallelepiped faces are calculated using the formula where b is the angle of inclination of parallelepiped faces; - normal to the grid component of the speed of vibration; VT is the rate of movement of the solution along the grid in the direction of discharge. FIG. 1 shows a schematic diagram of a hydro-screen with a proposed 1 "lm vibrating screen; in fig. 2 — vibrating screen grids, view in the screening plane (node G in FIG. 1); in fig. 3 is a view A of FIG. 2; in fig. 4 is a diagram of a change in the size of the passage particles as a function of the angle of inclination of the faces of the bulk cell. Vibrating screen consists of a cassette in the form of several grids 1-3, superimposed and pressed against one another. The upper grid 1 is working, the lower 2 is supporting, and all the other grids (for example, one) are intermediate 3. The transverse wires 4-6 of all grids. 1-3 are modeled one relative to another In such a way that they form a volumetric cell in the form of a parallelepiped 7 the base of which is, for example, the cell of the working grid 1, and the top is the cell of the reference grid 2. The edges B of parallelepiped 7 are inclined in the direction of transporting the material, and the angle of inclination is chosen from 6 to 45 ° depending on the flow rate of the material on the working grid 1. The number of prom weft grids 3 are chosen so that the height of the parallelepiped 7 is not less than the size of the cell of working grid 1 and depends on the thickness of the wire of working grid 1. For ease of transport and storage of cassettes of grid 1 - 3 in places of contact with the supports, they are glued together with rubber or epoxy resin . . .. The sieve works as follows. The drilling fluid from the channel system (not shown) enters the receiving tank 9, fills it and pours onto the sieve surface 10 of the vibroray 11, which performs harmonic circular vibrations. The solution enters the grid at a certain speed, caused by a height difference, and therefore flows over the surface 10 at a rate H, which can gradually increase by jjipH tilting the surface 10 in a direction

Claims (2)

1. Vibrating screen, comprising working and supporting wire meshes stacked on top of one another, the mesh size of which is at least twice the diameter of their wire, and the mesh size of the support mesh exceeds the mesh size of the working mesh, and the transverse wires of the meshes are shifted one relative to the screening plane another with the formation of a volumetric screening cell, characterized in that, in order to improve the quality of cleaning the screening surface and screening performance by reducing the hydraulic resistance of the sieve surface, the vibrating sieve is additionally equipped with at least one mesh, which is placed between the working and supporting grids, and its cell size is equal to the size of the mesh of the mesh, and the mesh size of the supporting mesh is at least twice as large as the mesh size of the mesh in this case, the volumetric screening cell is represented by a parallelepiped whose faces are inclined in the direction of unloading the material at an angle of 6 to 45? 2. Vibrating screen, according to π. 1, characterized in that the angle of inclination of the faces of the box is calculated by the formula S = arc sin where is the angle of the faces of the box; 1l - normal to the grid component of the vibration velocity; | A- is the velocity of the solution along the grid in the direction of discharge. FIG. 1 1077659 A .1077659