RU2478442C1 - 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. Proposed screen comprises trough closed on all sides with helical hollow drums arranged in tiers, one above the other, vibroexciters and elastic elements, loose material loaders and unloaders. Every drum is composed of, at least, one perforated strip coiled in helical turns interconnected in strip lengthwise edges and bent at angle to flexure lines to make unidirectional helical lines and surfaces representing perforated polygonal pockets. Distance between flexure lines equal the length of every element of polygon. Note here that said pockets on inner surface differ in sixes and shape from those on outer surface.

EFFECT: expanded performances and higher efficiency.

8 dwg

Description

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

Known is a vibrating screw screen (SU 614832 A, 07/05/1978, B07B 1/40), including a housing closed on all sides, with spiral screening surfaces, vibration exciter and elastic elements located underneath and connected into a single technological chain, loading means and unloading.

A disadvantage of the known device is low productivity, limited technological capabilities.

Closest to the proposed invention is a vibrating screw screen (patent No. 2368433, publ. 09/27/2009, bull. No. 27), including a box closed on all sides, with belts located tiered one under the other and connected rigidly into a single technological chain formed by screw drums formed by the perimeter of three or more, rolled up in a vertical plane and sequentially connected to each other, along the length of perforated stripes of curvilinear shape of various orders, vibration exciter and elastic elements, means of loading and and unloading of large and small particles of bulk material.

A disadvantage of the known device is low productivity, limited technological capabilities.

The technical solution to the problem is to expand technological capabilities, increase productivity.

The technical solution is achieved by the fact that in the screen, which includes a box closed on all sides, with belt hollow drums, vibration exciter and elastic elements, means for loading and unloading small and large particles of bulk material, each located tiered one below the other and rigidly connected to a single technological chain the drum is mounted at least from one, rolled into cylindrical coils connected to each other along the longitudinal edges of the perforated strip, bent over placed at an angle to it the home edges of the fold lines, with the formation on the outer and inner surfaces directed to one side of the helical lines and helical surfaces in the form of perforated pockets of a polygonal shape, moreover, the distance between the fold lines is equal to the length of each element of the polygon, while the perforated pockets along the inner surface may differ from the shape and size of the perforated pockets along the outer surface and around the perimeter of the drum can be different not only in size but also in shape.

According to the patent literature not found a technical solution similar to the claimed, which allows to judge the inventive step of the proposed screen.

The novelty of the invention lies in the fact that when the exciter is operating, particles of bulk materials that circulate inside screw drums rigidly fixed in a vibrating housing in planes perpendicular to their horizontal axes receive additional movement from internal perforated surfaces of a polygonal shape, which intensifies the mixing of the loading mass and increases screening performance.

The novelty also lies in the fact that under the influence of the perturbing forces of the vibrator through the walls of the box, the particles of building materials rotate in planes perpendicular to the axis of symmetry of the screw drums, while the screw screening surfaces of the polygonal shape of the screw drums change and give additional movement to the particles of building materials, provide increasing the performance of classification of building materials by size, and also move them from loading to output openings tiyam.

The novelty lies in the fact that such a structural design of the drums allows for the axial movement of particles of building materials from loading to unloading with a horizontal axis of the drum, which simplifies the operation of the screen.

The novelty lies in the fact that due to the broken polygonal internal screw perforated pockets, the vectors of the speed of particles of building materials during their transportation from loading to unloading change, which contributes to the intensification of screening and extends technological capabilities.

The novelty of the proposal also lies in the fact that screw perforated surfaces are formed inside the drum in the form of broken perforated polygonal pockets, which intensifies screening and expands technological capabilities.

The novelty also lies in the fact that helical surfaces and helical grooves of a polygonal shape swirl the flow of materials, which intensifies the screening process.

The novelty also lies in the fact that the pockets around the perimeter of the drum can be different not only in shape but also in size, which expands the technological capabilities.

The novelty also lies in the fact that at the same drum diameters, in the proposed drum design, the length of the path of the passage of particles of materials in comparison with the known drum designs is much larger along the perimeter, which makes it possible to reduce the dimensions of the drum both in length and in diameter, and also contributes to the intensification of the screening process and expands technological capabilities.

The novelty also lies in the fact that the drum is made of one or more perforated tapes, which expands technological capabilities and simplifies manufacturing.

The novelty of the proposal also lies in the fact that around the entire perimeter of the perforated screening surface of the drum, the passage section varies not only in shape, but also in area, which provides alternate compression and expansion of the screening mass in each section of the drum, its self-cleaning, and, therefore, increased productivity , efficiency, reduction in size and expansion of technological capabilities.

Figure 1 shows a General view of the screen: figure 2 - section aa in figure 1; figure 3 is a view of figure 1; figure 4 is one of three screw perforated drums, General view; figure 5 is a section bB in figure 4; figure 6 - perforated strip with marked bend lines in the form of straight lines; 7 is a perforated strip, bent in straight lines with the formation of pockets of a polygonal shape; Fig. 8 is a perspective view of a perforated strip folded into a cylindrical coil.

The screen (figure 1, figure 2) consists of a means for loading 1, means for unloading 2, 3, 4, 5 to output fractions of bulk materials outside the drum screen for classifying building materials, box 6, installed using elastic elements 7 based on 8. In the lower part of the box 6 mounted vibration exciter 9. The screen is equipped with containers 10, 11, 12, 13 for receiving particles of bulk materials after screening. In the box 6, made closed on all sides, mounted on top of each other and connected into a single technological chain screw perforated drums 14, 15, 16.

The drums 14, 15, 16 are made screw, perforated and hollow, one of which, for example 14, is presented in figure 4.

The direction of the helical lines of each half below the installed screw perforated drums 14, 15, 16 is opposite to the direction of the helical lines of the screw perforated drum mounted above, for example the direction of the helical lines of the screw perforated drum 15 is opposite to the direction of the helical lines of the screw perforated drum 14, and the direction of the helical lines of the screw perforated drum 16 is opposite to the direction of the helix lines of the helical perforated drum 15 (FIG. 1). Therefore, during the operation of the screen, continuous movement of bulk materials from loading to unloading is ensured.

The nozzle of the loading device 1 is mounted in the inlet of the screw perforated drum 14. The outlet 17 of the screw perforated drum 14 is closed by a lid 18, which simultaneously covers the inlet 19 of the screw perforated drum 15 and allows the masses of bulk materials to move from the upper - first screw perforated drum 14 to underlying screw perforated drum 15, namely from the outlet 17 of the screw perforated drum 14 into the inlet 19 of the wines a perforated drum 15. The outlet 20 of the second screw perforated drum 15 is closed by a lid 21, which simultaneously covers the inlet 22 of the underlying third screw perforated drum 16, allowing bulk materials to be transferred from the second middle screw perforated drum 15 to the lower third screw perforated drum 16. To receive small fractions of classified material under the first screw perforated drum 14 mounted means for unloading 2, under the WTO With a perforated screw drum 15 - means for unloading 3, under the third perforated screw drum 16 - means for unloading 4. Unloading device 5 is mounted under the outlet 23 of the third screw perforated drum 16.

The drum 14 (Fig. 4, Fig. 5) is made of one perforated strip 24, rolled into cylindrical coils, connected along the longitudinal edges 25 (shown in Fig. 4 by a dash-dot line) by known methods, for example, welding, with the formation of the outer and inner surfaces of helical lines (in Fig. 4, one of the helical lines is shown by a thickened line 26-27-28-29-30-31-32-33-34-35-36-37 and helical surfaces (Fig. 5) of a polygonal shape in the form perforated pockets of the outer surface of a rectangular shape 38, 39, 40, 41, 42, 43 and perforated pockets rectangular hydrochloric shaped inner surface 38, 39, 40, 41, 42, 43.

The perforated strip 14 (FIG. 6, FIG. 7) is bent along the fold lines 44 at equal angles α to the longitudinal edges 25 of the strip 24 placed at distances equal to the length of the polygon elements of the pockets, for example, for pocket 43 at distances L ₁ L ₂ L ₃ . The strip 14 after bending along straight lines (Fig.6, Fig.7) is folded into cylindrical coils (Fig.8), connected to each other along the longitudinal edges 25 by known methods, for example by welding into a drum 1. The screen operates as follows.

By means of a loading device 1, classified granular material is continuously loaded into the upper screw perforated drum 14. Under the influence of the disturbing forces of the rotating vibrator 9, disturbing forces are transmitted to the particles of bulk materials through the walls of the box 6 and rigidly connected to it by screw perforated drums 14, 15, 16. Particles of bulk materials under the influence of these disturbing forces under the influence of vibration rotate in planes perpendicular to the axis of symmetry of the screw perforated drums 14, 15, 16. The screw perforated walls of the rectangular shape of the screw perforated drums 14, 15, 16 change and give additional movement to the particles of bulk materials and provide increased performance classification of bulk materials by size, and also move them from loading to outlet openings, for example, to you one screw hole 17 of the perforated basket 14. As promotion particle bulk materials along the horizontal axis of the screw of the perforated drum 14 separates smaller particles of bulk material and they screw through the openings of the perforated basket 14 are output to a means for discharging and 2 further beyond the screen. Under the influence of vibration and with the help of the cover 18, the particles of bulk materials are reloaded through the hole 19 into the underlying screw perforated drum 15, along the perimeter of which there are helical lines, the direction of which is opposite to the direction of the helical lines of the upper screening perforated drum 14. With their help and under the influence of vibration, small particles bulk materials through the holes of the screw perforated drum 15 are discharged into the means for unloading 3 and further beyond the screen, and larger fractions bulk materials are moved to the outlet 20 and through the cover 21 are moved through the inlet 22 into the inner cavity of the screening surface 16. Under the influence of vibration, screw perforated rectangular walls and helical lines around the perimeter of the screw perforated drum 16 small fractions of bulk materials are discharged into the means for unloading 4 and beyond the limits of the screen, and large particles of bulk materials are moved along the horizontal axis and through the hole 23 and using the unloading device The units 5 are moved outside the screen.

The technical and economic advantages of the invention arise due to an increase in miscibility, imposition on the complex rotational movement of bulk materials from vibration in planes perpendicular to the horizontal axis of the screw perforated drums, additional movement imparted by the rectangular walls of the screw perforated drums, which facilitate the passage of particles through their perforated holes and expands technological capabilities. In the process of moving bulk materials from loading to unloading, their particles make a complex spatial movement, since the direction of their movement under the influence of vibration changes under the influence of triangular walls of screw perforated drums, which intensifies the process of mixing and screening.

Claims (1)

Rumble, including a box closed on all sides, with belt-mounted screw hollow drums, vibration exciter and elastic elements, means for loading and unloading small and large particles of granular material, which are located on each side and rigidly connected into a single technological chain, characterized in that each drum is mounted, at least from one, rolled into cylindrical coils, connected to each other along the longitudinal edges of the perforated strip bent along placed at an angle to its longitudinal edges bending lines, with the formation on the outer and inner surfaces directed to one side of helical lines and helical surfaces in the form of perforated pockets of a polygonal shape, the distance between the folding lines being equal to the length of each polygon element, while the perforated pockets along the inner surface may differ from the shape and the dimensions of the perforated pockets along the outer surface and around the perimeter of the drum may be different not only in size but also in shape.

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