SU1729616A1 - Sizing screen sieve - Google Patents

Abstract

The invention relates to cellular grids for screening, for dividing bulk material into size classes in the mining, construction and other industries. The screen of the screen includes a working surface with slit-shaped holes and longitudinal ribs located between them. The holes are arranged in a checkerboard pattern, are 2-2.5 times longer than their width, are oriented with the long side parallel to the longitudinal ribs, which smoothly mate with the edges of the holes, are curved with a curvature increasing from the loading end of the sieve to the discharge end and with maximum height of not more than 0.5 of the width of the hole. 2 Il.

Description

The invention relates to cellular grids designed for p) and bulk materials, and can be used in the mining, construction, metallurgical and other industries.

Known flat cellular sieves with various openings are known, including alkaline with a staggered arrangement on the surface of the sieve. The arrangement of the holes in the chess pieces allows one to increase the living cross section of the sieve and to increase the efficiency of screening of the cubic material.

The disadvantage of this screen is the low efficiency of the screening of the flat and narrow class of material related by weight to the undersize product. Such pieces of material, having their long side across the slotted hole and moving along a flat sieve, are not sifted and, having blocked several screens in the transverse direction of the sieve, block the screening of cubic pieces of material.

A sieve is known that contains openings and holes on a working surface made in the form of inclined ribs periodically positioned between the openings along the width of the screen and which are directed along the working surface and limited in length by the dimensions of the openings. The presence of fins on the sieve surface will increase the wear resistance of the sieve and slightly increase the efficiency of screening the material due to the reorientation of the pieces facing the fins.

The disadvantage of such a sieve is the low efficiency due to the uneven positioning of the ribs on the sieve surface, as well as the fact that these ribs create a retarding effect, reducing the performance of the screen. In addition, when a material encounters ribs, it may accumulate near the ribs and overlap the holes with larger chunks, which leads to a decrease in the efficiency of screening the material.

The purpose of the invention is to increase the efficiency of sifting.

The goal is achieved by the fact that the holes on the screening surface of the sieve are arranged in a staggered order with a length of 2-2.5 times their width, oriented with the long side parallel to the longitudinal ribs, which smoothly match. with the edges of the holes, a curvilinear shape with a curvature increasing from the loading end of the sieve to the discharge opening, and with a maximum height of not more than 0.5 of the opening width.

FIG. 1 shows a sieve, top view: FIG. 2 shows section A-A in FIG. one.

On the working surface 1 of the sieve there are slit-shaped holes 2, arranged in a checkerboard pattern. In addition, on the working surface 1, there are made longitudinal curvilinear ribs 3. opposite each aperture and smoothly mating with the end edges A and 5

0 number of home openings. The curvature of the surface of the rib 3 at section K is made with radius RI, and at section I with radius R2. while RI R2. The maximum height H of the rib 3 is no more than half the width.

5 slots open, i. H 0.5 t, and the length of the slit nh 2-2.5 times its width, i.e. n (.5) m.

The device works as follows.

0 When moving along the working surface of 1 sieve of lumpy material, the cubic-shaped pieces are smaller or close to the size of the slit width of the hole .2 is easily sifted into the undersize product. So-called

5, the hard class of material, having one of the dimensions of the piece, is somewhat larger than the width of the slit of opening 2, crawls on edge 3 in section K, turns directly into the adjacent hole 2 with other faces smaller than the width of the slit, and also sifts. When a material moves in a dense layer, some pieces of it can go along edge 3 to section I, which has a large curvature, which allows

5, increase the speed of movement of the piece and return to it around the transverse axis, falling directly into the next hole 2 with the other edges, and also sift. Those. screening efficiency will increase due to repeated reorientation of the sides of the piece with respect to the screening surface.

In addition, when a piece of material moves, the curved surfaces K and I

5. The surface of contact of the piece, with the edge 3, decreases, therefore, the resistance force of the material on the sieve will decrease. When in the bulk bulk material of the elongated pieces,

0 in terms of mass and size to the undersize class, the proposed sieve design will allow these pieces to be sifted into the undersize product. Finding long edges on the previous edges 3 while moving forward, a long piece falls on the next edge 3 by the middle part. Moving further along the sloping section K of the edge 3 to its upper point, the piece will begin to tip over to the right or left side, falling into hole 2. As a result of this

the likelihood of narrow and long pieces entering hole 2 increases, which increases the efficiency of screening material.

The maximum height of the rib 3 is taken to be equal to no more than 0.5 of the slot width of the hole 2 for structural considerations and the need to orient the required class of material into the hole 2.

When the piece moves along the edge 3 to a height equal to 0.5 of the slit width or 0.5 of the thickness of the piece, its center of gravity will be at a height equal to the size of the piece being shaken off, and the line connecting the center of gravity to the counterweight face of the hole, the PSD will be inclined by an angle of 45 ° to the working surface of 1 sieve. Such an inclination is enough for the piece, having turned around with a different face, to see through the hole. As the height of the rib 3 increases, the elevation angle of section K will change, which will impede the movement of the material along the sieve and will contribute to its accumulation in the rib zone, blocking the hole. With a smaller height of the rib 3, the piece will not turn over both in the longitudinal and in the transverse plane, since the center of gravity of the piece will not be able to cross the critical point necessary for the reversal.

In order to better sift the elongated pieces of material that are located when moving the long side along the sieve, the length of the slit of the hole is 2-2.5 times longer than its width.

It is known that the elongated pieces have a thickness smaller than the material class to be cut, i.e. short pieces will have a mass less than the mass of the cubic material, and long pieces with a length 2-2.5 times greater than its thickness by weight will equalize. Such pieces are suitable for the undersize product, which, after turning off, enter the ball mill, where they are regrinding according to the principle of impacting small masses of pieces of material with large masses of balls. With an increase in the length of the hole 2 by more than 2.5 times, the mass of pieces of cutting material, which is undesirable for the undersize product, will increase, as this will affect the energy intensity of the mill when grinding pieces of increased mass.

In addition, in a large gap there are pieces of wood, the average size of which will be higher than the required dropout class, which will reduce the quality of the product (for example, rubble)

Consequently, the proposed sieve design makes it possible to increase the efficiency of screening a material of both cubic and narrow elongated shape by turning them relative to the longitudinal and transverse axes as the material moves along inclined ribs located on the working surface of the sieve, increasing the likelihood of the undersize product entering the sieve hole.

And the elongated shape of the hole 2-2.5 times longer than its width also improves the screening efficiency and separates into the undersize product a material that is mass suitable for grinding it in a ball mill without increasing its energy intensity, which leads to an increase in the productivity of technological lines for the preparation of ore continents and for improving the quality of the screened material.

Ф орм ул а и з о бртете и.

The sieve of the screen, including the working surface with the opening of the microfluid farm and the longitudinal ribs located between them, is characterized in that, in order to increase the efficiency of the screening, the holes are arranged in a checkerboard pattern, made 2,0-2,5 times longer the widths are oriented with the long side parallel to the longitudinal ribs, which are smoothly matched with the edges of the holes, are made with a curvilinear shape with a curvature increasing from the loading end of the sieve to the discharge one, and with a maximum height of not more than 0.5 width s hole.

Editor M.Kelemes

Tehred M. Morgenthal

Proofreader A.Osaulenko

Order 1462 Circulation: Subscription

VNIIPI State Committee for Inventions and Discoveries at the State Committee on Science and Technology of the USSR 113035, Moscow, Zh-35. Raushska nab „4/5

-: -: &

Production and publishing combine T1tenti, g. Uzhgorod, 101 Gagarin St.

Claims (2)

Claim . Screen sieve, including a working surface with slit-shaped openings and longitudinal ribs located between them, characterized in that, in order to increase the screening efficiency, the openings are staggered, made 2.0-2.5 times longer than their width, oriented with the long side parallel to the longitudinal ribs, which are smoothly mated with the edges of the holes, made of curved shape with a curvature increasing from the loading end of the sieve to the unloading, and with a maximum height of not more than 0.5 width tverstiya. Fig .. 2 ζ, υ