RU2456094C1 - Pass screen - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to screening rocks and construction materials, crushing and sorting jobs, and screen sizing of construction materials. Pass screen comprises sieving surface, drive, loading and unloading devices. Sieving surface is composed of sections made from eight, ten, twelve, etc number of equilateral triangles interconnected by their lateral sides. Note here said sections are interconnected by free third sides to make screw drum. Four, five, six and more zigzag right and left screw lines are arranged along perimeter of said drum. Four, five, six and more equal-pitch screw grooves facing each other are made on said drum.

EFFECT: expanded performances and higher efficiency.

8 dwg

Description

The invention relates to devices for screening rocks, building materials in preparation for transportation, to perform crushing and screening operations, as well as for the classification of building materials.

Known drum screen (US patent No. 2804975, CL 209-287, publ. 1957), including a rotating cylindrical drum and a mechanism for communicating vibrational movements of the drum during rotation.

A disadvantage of the known drum screen is the low technological capabilities, the need for work to clean the sieve openings is not effective enough and therefore this operation is carried out with a stream of water.

Closest to the proposed invention is a drum screen (AS USSR No. 613830, class B07B 1/22, 1976), containing a screening surface, drive, loading and unloading devices.

A disadvantage of the known screen is limited technological capabilities due to low productivity due to the low mixing intensity, since during the rotation of the drum there is a sliding of the screening mass along the inner surface of the drum, clogging of the sieve holes and the need for additional cleaning work, as well as large dimensions of the screen along the length .

The technical solution to the problem is to expand technological capabilities, increase productivity and self-cleaning screens.

The technical solution is achieved by the fact that in the screen through passage containing a screening surface, a drive, loading and unloading devices, the screening surface is mounted from sections made of eight, ten, twelve, etc. an even number of equilateral triangles connected by two lateral sides, while the sections are connected to each other by the free third sides of the triangles with the formation of a helical drum, along the perimeter of which are four, five, six or more broken right and left helical lines directed towards each other and equipped with internal four, five, six or more screw grooves directed towards each other with the same pitch.

According to the patent literature, no technical solution was found that is similar to the claimed one, which allows one to judge the inventive step of the proposed walk-through screen.

The novelty of the invention lies in the fact that, since the frequency of movement of particles of the screening material in the proposed design is determined not only by the frequency of rotation of the screw drum of the screening surface, but also by the number of flat elements around the perimeter of the screw drum, such a structural design of the drum surface by increasing the number of flat elements in each section along the perimeter increases for each revolution of the screw drum the frequency of collisions of particles of screened materials of material I’m waiting for myself, and with the walls of the screw drum, it increases screening performance, increases technological capabilities.

In addition, the novelty is due to the fact that the elements from which the screw drum is assembled are mounted at certain angles to each other, so the mixing intensity increases, since these elements, working like shelves capture portions of the screened material, direct them towards each other, at walls moving on the opposite side, thus violating not only the stationarity of their movement, but also ensuring the self-cleaning of the sieve openings.

The novelty is seen in the fact that the cross-sectional area and shape of the screw drum changes in each cross-section of the screw drum from loading to unloading, which intensifies the mixing process, increases the energy intensity of the interaction of material particles with each other and with the walls of the screen, and expands technological capabilities.

The novelty is also due to the fact that not only the triangles from which the screw drum sections are assembled, but the sections themselves are mounted at certain angles to each other with the formation of broken helical lines, which increases the miscibility, energy intensity and changes the frequency of interaction of material particles with each other and with the walls of the screw drum, which expands the technological capabilities.

The novelty also lies in the fact that the cross-sectional cross section of the screw drum has the shape of a polygon, the area of which along the length of the screw drum varies many times from loading to unloading, providing periodic compression of the mass of the screened material, which increases the intensity of mixing and the energy intensity of collisions, expanding technological capabilities.

The novelty is due to the fact that the screw drum is equipped with four, five, six, etc. screw broken lines of equal pitch, directed towards each other along the perimeter of the drum and, accordingly, four, five, six, etc. screw grooves inside the drum, also directed towards each other, which ensures the creation of directed towards each other flows of the screened material with maximum energy intensity of collisions of particles to each other and with the walls of the drum at different angles, increases the frequency of interaction of particles of the screened material with each other and with the walls of the drum , increases screening productivity and expands technological capabilities.

The invention is illustrated by drawings, where: in Fig.1 shows a roar through passage, a General view; figure 2 is a section aa in figure 1; figure 3 - sifting surface in the form of a helical drum, front view with sections assembled from 10 triangles; figure 4 is a section bB in figure 3; 5 is a drum, a General view, a front view with sections assembled from 8 triangles; Fig.6 is a section bb in Fig.5, Fig.7 is a drum, a General view, a front view with sections assembled from 12 triangles; Fig.8 is a section GG in Fig.7.

The roar of the passage (Fig. 1, Fig. 2) consists of a screw drum 1, loading 2 pins with loading device 3, unloading 4 pins with unloading device 5 for large fractions and unloading device 6 for small fractions.

The screw drum 1, for example, is assembled from sections 7 (Fig. 3), each of which is formed of ten equilateral perforated triangles 8 (shown in Fig. 3 by a double line) of the same size, connected to each other by two lateral sides 9 and 10, while sections 7 are interconnected by third, free sides 11 of triangles 8.

The vertices of the triangles form around the perimeter of the screw drum 1 five right and five left broken helical lines (figure 3, figure 4) with the same pitch S ₁ and S ₂ . One of the five left broken helical lines in increments of S _{1 is} shown in FIG. 3 with a thickened line 12-13-14-15-16-17-18-18-19-20. One of the five right broken helical lines in increments of S _{2 is} shown in FIG. 3 with a thickened line 21-19-22-23-24-25-14-146-27-27.

Figure 5 shows a helical drum, sections of which are assembled from eight identical equilateral perforated triangles 28 (in figure 5, triangle 28 is shown by a double line) with the formation along the perimeter of the drum four right and four left broken helical lines directed at the same pitch. Figure 5 shows the thickened lines 29-30-31-32-33-34 one of the four right broken helical lines in increments of S ₃ and 35-36-32-37-38-39 one of the four left broken helical lines in increments S ₄ .

Figure 7 shows a helical drum, sections of which are assembled from 24 identical equilateral perforated triangles 40 (shown in Fig. 7 by double lines) with the formation of twelve right and left broken helical lines along the perimeter of the drum, directed towards each other. One of the 12 right broken helical lines in increments of S _{5 is} shown in FIG. 7 with a thickened line 41-42-43-44-45-46-47-48-49-50-51-52. One of the 12 left broken helical lines in increments of S _{6 is} shown in FIG. 7 with a thickened line 53-54-55-56-57-58-46-59-60-61-62-63.

The roar of the checkpoint works as follows. The screw drum 1 is filled with a screening material. During the rotation of the screw drum 1, flat elements — equilateral perforated triangles mounted around the perimeter of the screw drum differently inclined to the axis of rotation of the screw drum and to each other, working like buckets (shelves), grab portions of screens of various sizes in volume, lift them in the direction of rotation of the screw drum slightly higher than the angle of repose, and then send these portions of crashing material in the directions perpendicular to these shelves (buckets), at a certain angle not only to the axis rotation of the screw drum, but also to other mass flows of the mass of the screening material moving inside the screw drum at different angles and at different speeds. The length of the trajectory of motion (amplitude) of the masses of the material largely depends on the diameter of the screw drum, on the angles of inclination of the flat elements to each other and to the axis of rotation. The frequency of movement and collisions of masses of material is determined not only by the frequency of rotation of the screw drum, but also by the number of flat elements around the perimeter of the screw drum. Therefore, in the proposed design of the screen of the walk-through, the frequency characteristics are increased tenfold, and technological capabilities are expanded. Since the shape and dimensions of the cross section having the shape of a polygon change many times along the length of the screw drum from loading to unloading, multiple periodic compression of the mass of the screened material is ensured, which increases the intensity of mixing, the energy intensity of the collisions, and expands technological capabilities. Thus, when the drum 5 is rotated, the classified material performs complex spatial motion along helical trajectories, the material is classified by size and intensively segregated.

Technical and economic advantages arise due to increased screening efficiency by increasing the frequency of interaction of the screened material not only with each other, but also with the walls of the screw drum, which increases the mixing intensity, increases the energy intensity of the interaction of the particles of the screened material, increases productivity and expands technological capabilities.

Claims (1)

A screen through passage containing a screening surface, a drive, loading and unloading devices, characterized in that the screening surface is mounted from sections made of eight, ten, twelve, etc. an even number of equilateral triangles connected by two lateral sides, while the sections are connected to each other by the free third sides of the triangles with the formation of a helical drum, along the perimeter of which are four, five, six or more broken right and left helical lines directed towards each other and equipped with internal four, five, six or more screw grooves directed towards each other with the same pitch.

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