SU1627279A1 - Screening web of a vibratory screen for classifying sinter - Google Patents

Abstract

The invention relates to ferrous metallurgy and can be used in the production of sinter (A). The goal is to increase the efficiency of sieving A with a grain size of up to 100 mm by improving the uniformity of distribution of A across the width of the screening web (PP) and additionally eliminating the key holes from A. Dg of this PC contains loading 1 and unloading 5 plates and screening cards (PC) 2 and 3 with holes 9. In this case, the PC is overlapped with each other with the formation of longitudinal projections-locks 4 at the points of their connection. At half of the PP with its boot side, the longitudinal protrusions-locks 4 are made of separate sections 6. located at a distance from each other equal to 3-10 heights of the protrusion-lock 4. Between the sections 6 protrusions-locks 4 ends of adjacent PCs 2 and 3 are made oblique. PC 2 and 3 are installed with a gap of 8 relative to each other, having a trapezoid shape in cross section. The larger base of the trapezoid is facing the working surface of the PP, and the smaller one is made no more than the minimum linear size of the screening hole 9 PC 2 and 3. Under the action of vibration, A moves along PCs 2 and 3 and, due to gaps 7 between sections 6 in the projections-locks 4, across PCs 2 and 3. This provides a more uniform distribution of A across the width of the PCB. Fine grains A through holes 9 wake up on the PP, and suitable A, pass through PCs 2 and 3 and plate 5, is poured into the receiving funnel. Gaps 8 exclude waking up suitable And in the sifting trifle-return. 4 il. fe with yu XI yu 4J Yu Rig

Description

The invention relates to ferrous metallurgy and can be used in the production of sinter.

The aim of the invention is to increase the efficiency of sieving agglomerate with a particle size of up to 100 mm due to its more uniform distribution across the width of the screening web and additional screening of fines from the sinter.

Figure 1 shows a vibrating screen for sintering sinter, general view; figure 2 - section aa in figure 1; on fig.Z - canvas, top view; figure 4 - section bb in fig.Z.

The device contains loading plates 1, side 2 and central 3 screening cards, mounted overlapping with each other to form longitudinal locks-locks 4 at the junction points of the cards, discharge plates 5, locks-loops 4 along the length of the web are made of separate sections 6 installed on distance from each other (gaps 7), equal to 3-10 height of the ledge-lock. In the places of breaks of 7 protrusions-locks, the ends of interchangeable screening cards are made inclined, and adjacent cards are installed with a gap of 8 relative to each other, having a trapezoid shape in cross section, the larger base of which is facing the working surface of the screening web, and the smaller one is not more than the minimum linear size, for a slit-hole - the width of the screening hole 9 cards 2,3.

The device works as follows.

Rough agglomerate is fed to the loading plate 1 of the screening web, with which it moves to the screening cards 2 and 3, where in the projections-locks 4 between sections 6 along the length of the web there are distances-breaks 7. Under the influence of vibration, the agglomerate moves along the cards 2 and 3 and due to the presence of gaps 7 — across these maps (from areas of large agglomerate aggregation to less loaded sections), which ensures its more uniform distribution over the width of the screening web. Small grains of agglomerate (return) through the screening slots 9 (the width of which is usually within 5-C mm) are spilled under the screening sheet, and the suitable agglomerate, having passed the screening cards and discharge plates, is poured into the receiving funnel. The trapezoidal gaps 8 between the screening cards 2 and 3 between sections 6 are filled with pieces of agglomerate and this is also the fact that the minimum width

Gaps 8 do not exceed the width of the slits of the sifting cards; it excludes spillage of suitable agglomerate into the screened fines-return.

On the first stage, the screening blade has ledges-locks made of sections or with gaps 7, so that at the initial stage of screening trivia from sinter

0 to achieve a more uniform distribution across the width of the web. The length of the breaks of the protrusions-locks selected, based on the actual size of the protrusions-locks and pieces of agglomerate. The thickness of the protrusions-locks (a)

5 is a constant value (for a particular screen) in the range of 10 to 50 mm; on the sifting screen of the vibrating screen, the agglomerate of various characteristics is always represented mainly

0 pieces of size 0-100 mm. Therefore, if the length of the gap is less than 3 values of the protrusion-lock thickness, the movement of pieces of agglomerate across the width of the web through these gaps will be limited. When the length

5 breaks are 3-10 times the thickness of the projection-lock, 10 relative free movement of the agglomerate under the action of vibration (even with a size up to 100 mm) through these gaps along the

0 the width of the web from the areas of its larger aggregation to the areas less loaded. A further increase in the length of the breaks is of little effect, since this to a lesser extent contributes to the uniform distribution of the agglomerate across the width of the web.

Thus, in the first half of the screening sheet, two to five breaks of the longitudinal projections-locks can be made, depending on the thickness

0 ledge-lock (a), screen length and other design features,

In addition, the execution on the cone ends of the abutting cards made by casting, facilitates their fitting during installation, since

5 in this case it is necessary to process the end of a carbide card not along the entire height, but only along the lower edge, i.e. on a small thickness.

Claims (1)

Invention Formula Vibrating screen sifting cloth for sintering, including loading and unloading plates, sifting cards with holes, mounted overlap with each other to form prodal lobes-locks in the places of their connection, characterized in that, in order to increase the efficiency of sintering sintering size 100 mm by improving the uniformity of the distribution of the agglomerate across the width of the screening web and additionally screening trivia from the agglomerate, half of the screening web from its loading side The protrusion-locks are made of separate sections located at a distance from each other equal to 3-10 of the height of the lock-projection, while between the sections of the protrusion-locks the ends of the adjacent the sifting cards are inclined, and the cards are installed with a gap relative to each other, which has a trapezium shape in the transverse seed, the larger base of which faces the working surface of the sifting web, and the smaller one is not larger than the minimum linear size of the sifter hole of the card. Aa flKltXlMKIK re Figg 4 in 6 Z.55 I /