RU18503U1 - GARBRING SCREEN SECTION - Google Patents

Description

Grate section

Useful fashion1 | l refers to the technique of separating bulk bulk materials by size, mainly of medium and small classes, and can find application in the mining, metallurgical and other industries.

Known grate section of the screen, containing two support beams and fixed on both ends of the grate (see AS USSR No. 882648 of 03/07/80, MKI V07V 1/00). Grid-irons are made in the form of rectangular load-bearing beams with protective elements and are installed using elastic elements. Support beams are made rectangular.

The elastic fastening elements of the grid-irons do not allow to strictly maintain the specified optimal ratio of the sizes of the grid-iron section during operation.

In addition, the free vibrations and bends of the grates, their large frontal resistance to the movement of the material, due to the rectangular shape and placement above the support beams, leads to crushing and sticking of the material, and as a result - to a violation of the aspect ratio of the grate section.

grates on both ends made in the form of rods of circular cross section (see Olevsky V.A. Designs and calculations of screens, M. 1955, p. 11, Fig. 4). Honor beams are made rectangular and equipped with a perforated rubber coating, into the recesses of which the ends of the grates are inserted.

The fastening of grates in the rubber coating of the support beams and the use in the known construction of support beams of a rectangular shape with a rough rubber coating, contributing to the adhesion of the material and clogging of the screening surface on the fastening areas of the grates, do not allow to establish and maintain with a sufficient degree of accuracy the necessary ratio of the geometric dimensions of the grate section.

The mentioned disadvantages of the known designs do not provide the specified optimal live section of the grate section and are the reason for the low efficiency of screening and the quality of the output product.

The creation of a utility model is based on the task of improving the grate section of the screen, @ which, due to new construction and fastening of structural elements, provides a constant predetermined optimal live section of the grate section and, as a result, increasing the screening efficiency and the quality of the resulting product by reducing the fine fraction in it .

To solve the problem in the well-known grate section of the screen, containing two support beams and grate fixed to them by both ends, made in the form of rods of circular cross-section, according to the utility model, the grate is fixed, the geometric dimensions of the section are determined from the relations:

2 h d + 3.4d + 0.331 + 100;

D 20 + 0.67d;

2 S -0.034K + 1.28K- OD5,

where d is the diameter of the grate, mm;

S- width of the inter-spike w; spruce, mm; D - thickness; ina of the support beam, mm;

1 and h are the length and width of the screening surface of the section, respectively, mm;

K is the size of the output product, mm

In addition, in the grate section of the screen, according to a utility model, the ends of the grate are fixed in holes whose axes are not lower than the axes of the support beams.

The support beams, according to the utility model, are made of a calibrated rod of circular cross section.

The indicated ratios of the geometric dimensions of the grate section of the screen are established on the basis of experiments.

NIKOV in calibrated round support beams, creates an optimal living cross-section of the screening surface of the grate section, which ensures the effective separation of small fractions into the under-product.

In FIG. 1 shows the construction of the grate section of the screen, a top view; in FIG. 2 is a longitudinal section through fragment I of the grate section in FIG. 1; in FIG. 3 is an example of a support beam structure; in FIG. 4 - sectional options aa in FIG. 3; in FIG. 5 is an example of one tier of the screening surface of the GIL-52 screen, consisting of eight grate sections in FIG. 1.

The grate section of the screen (figure 1) contains two support beams 1 and grates 2 fixed to them by both ends, made in the form of rods of circular cross section. The ends of the grates 2 are fixed motionless in the holes 3 (Fig. 3 and 4), the axes of which are not lower than the axes of the support beams 1 of circular cross section.

Grates 2 and support beams 1 can be made of high manganese spring-spring steel ST-65G, characterized by high strength and reliability under alternating loads.

The holes 3 in the support beams 1 can be made by drilling both through and in the form of nests (Fig. 2).

The ends of the grid-irons 2 are fixed in the holes 3 of the support beams 1 by means of a welded joint, for example, copper solder in an argon medium that does not violate the structure of steel.

Installation of the inventive grate section of the screen is as follows.

In the holes 3 drilled in the first support beam 1, the first ends of all the grid-irons 2 are sequentially inserted and then welded. The second ends of the grid-irons 2 are successively inserted one by one and welded in the holes 3 of the second support beam 1.

The extreme openings 3 in the support beams 1 can be made through and, accordingly, the length of the extreme grates 2 is increased. In this particular embodiment, the support beams 1 and the extreme grates 2 form a frame that additionally provides rigidity to the grate section.

The proposed grate section can work as a screening surface in both stationary and moving screens. The most effective application of the inventive design in vibration inertial screens with a screening surface in the form of one or more separate sections, installed, for example, in a cascade.

Experiments confirming the efficiency of screening and the high quality of the obtained product using the grate sections of the claimed design were carried out at the Stakhanov Ferroalloy Plant on a vibrating screen GIL-52 with two tiers of sieving surfaces. Each tier consists of several, for example, eight grate sections (Fig. 5).

Dry coke and coke with a moisture content of 15–20% were classified.

The inter-jaw slots of the upper and lower tiers of the screening surface of the screen were calculated according to the upper and lower limits of the specified size class of the output product.

Both tiers are installed at an angle to the horizon that exceeds the angle of repose of the dispersed material, in a specific example for GIL-52 it is 10 °. Initial material is fed to the upper tier from above, while the small fraction falls into the inter-grate slots, and the large fraction, moving along the screening surfaces of the screen, enters the bunkers (not shown in the drawing). At the same time, pieces of coke with a fineness exceeding the upper limit of the required size class are removed from the upper tier, and the oversize product of the lower tier is the output product of the screen.

The table shows the data of the sieving of dry and wet coke on a typical screen GIL-52 with two tiers of sieving surfaces from the inventive grate sections.

These tables confirm the efficiency of screening and the high quality of the output product obtained on a screen with the claimed grate sections.

In the course of the experiments, it was found that the application of the inventive grate section is most effective when screening dry bulk materials and materials with high adhesive ability in small, thin and very thin classes, i.e., with sieving classes of 10 mm and below.

Claims (3)

1. The grate section of the screen, containing two support beams and fixed on both ends of the grate, made in the form of rods of circular cross section, characterized in that the grate is fixed motionless, the geometric dimensions of the section are determined from the relations:
h = d ² + 3.4d + 0.331 + 100;
D = 20 + 0.67d;
S = -0.034K ² + 1.28K-0.15,
where d is the diameter of the grate, mm;
S is the width of the inter-grid gap, mm;
D is the thickness of the support beam, mm;
l and h are the length and width of the screening surface of the section, respectively, mm;
K is the size of the output product, mm  2. The grate section of the screen according to claim 1, characterized in that the ends of the grate are fixed in holes whose axes are not lower than the axes of the support beams. 3. The grate section of the screen according to claim 1, characterized in that the support beams are made of a calibrated round rod.