RU2377075C1 - Screen for sizing of loose materials - Google Patents

Abstract

FIELD: building.

SUBSTANCE: invention refers to equipment for sizing loose materials and can be implemented in building, mining, metallurgy and other branches of industry. The screen for sizing loose materials consists of screening surface located between end flanges made in form of broken spiral-shape tunnel with multi-angle pass through cross section assembled out of sections forming interrupted broken screw lines along their perimetre and along ends of inlet and outlet squares inclined to different sides to axis of sections; also each successive section is turned relative to a preceding one at angle of 90°; the screen further consists of charge and discharge facilities and a drive. Each section of screening surface is made with increased dimension of open flow area relative to the preceding section in the direction from charging to discharging; each section is assembled out of two pairs of trapezium, notably, out of two different by size equilateral bigger and smaller trapezium and two equal by size scalene trapeziums connected alternately at right angle one with the other. Lower bases of scalene trapeziums are equal to sides of the bigger equilateral trapezium, while upper bases of scalene trapeziums are equal to sides of smaller equilateral trapezium. Interrupted broken screw lines are made with increment along length of screening surface. Inlet and outlet squares of each section are inclined at different angles to axes of sections.

EFFECT: increased operating capability and efficiency of screening and mixing and enhanced functionality.

10 dwg

Description

The invention relates to techniques for the classification of bulk materials and can be used in the construction, mining, metallurgical and other industries.

A drum screen is known, including a screening surface located between the end cheeks, made in the form of a broken spiral shape of a tunnel assembled from sections, each of which is rotated 90 ° relative to the previous one, loading and unloading devices, drive (see A.S. No. 1808417, B07B 1/22, publ. B.I. No. 14 April 15, 1993).

A disadvantage of the known device is the insufficient classification intensity and limited technological capabilities due to the fact that the classification is carried out with a practically constant longitudinal and cross-section of the screening surface from loading to unloading and insufficient mixing intensity and insufficient intensity of interaction of material particles with each other, as well as the need to create a slope a screening surface for transporting material from loading to unloading.

Closest to the proposed device is a drum screen (see patent No. 2188720, B07B 1/22, publ. BI No. 25.09.09.2002), including a screening surface located between the end cheeks, made in the form of a broken spiral shape a tunnel with a polygonal passage section, assembled from sections with the formation along their perimeter of intermittent broken helical lines and along the ends of the input and output squares, inclined in different directions to the axis of the sections, each subsequent of which is rotated 90 ° relative to the previous one, full-time and handling devices, drive.

A disadvantage of the known device is the insufficient classification intensity and limited technological capabilities due to the fact that the classification is carried out with a practically constant longitudinal and cross-section of the screening surface from loading to unloading and insufficient mixing intensity and insufficient intensity of interaction of material particles with each other, as well as the need to create a slope a screening surface for transporting material from loading to unloading.

The technical solution to the problem is the expansion of technological capabilities due to the formation of intermittent broken helical lines along the perimeter of the screening surface with an increase not only in step from loading to unloading, but also in the size of the passage through the polygonal section of the screening surface.

The technical solution is achieved by the fact that in the screen for the classification of bulk materials, including a screening surface located between the end cheeks, made in the form of a broken spiral tunnel shape with a polygonal passage section, assembled from sections with the formation of discontinuous broken helical lines along the perimeter and along the ends of the input and output squares, inclined in different directions to the axis of the sections, each subsequent of which is rotated relative to the previous one by an angle of 90 °, the loading and unloading device beating, drive, according to the invention, each section of the screening surface in the direction from loading to unloading is made with enlarged passage area dimensions relative to the previous section and is assembled from two pairs of trapezoidal, namely two different in size equilateral large and small trapezoid and two identical in size different-sized trapezoid, alternately connected at right angles to each other, with the lower bases of the versatile trapezoid equal to the sides of the large equilateral trapezoid, and the upper The bases of the versatile trapezoid are equal to the lateral sides of the small equilateral trapezoid, while intermittent broken helical lines are made with an increasing step along the length of the screening surface, and the input and output squares of each section are made inclined at different angles to the axis of the sections.

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

The novelty of the invention lies in the fact that such a design of the screening surface around the perimeter allows not only the axial movement of the classified materials with a horizontal rotation axis of the screening surface, to simplify the drive and increase the operational life, but also to increase the classification intensity due to increased miscibility for the presence on the screening surface of intermittent broken helical lines with a variable length of the screening surface step increases as

the cross-sectional area of the screening surface from loading to unloading, which violates the stationary flow of particles of classified material and increases the classification performance, increases technological capabilities.

In addition, the novelty is due to the fact that the elements from which the screening surface is assembled are different in area, size and configuration and vary along the length of the screening surface, so the mixing intensity increases, since these elements, acting as shelves, capture portions of different volumes classified material, direct them towards each other, thus violating the stationarity of their movement.

The novelty is that the area and cross-sectional shape of the zigzag shape of the screening surface increases in length from loading to unloading, which intensifies the mixing process, changes the amplitude of the material’s movements as it moves from loading to unloading, changing the frequency and energy intensity of the interaction of particles of the classified material, expands technological capabilities.

The novelty is also due to the fact that the axes of the sections of the screening surface intersect with each other at different angles with the formation of zigzag lines with an increasing distance from the axis of rotation and not intersecting the axis of rotation of the screening surface, which increases the miscibility, energy intensity and changes the frequency of interaction of material particles with each other different and with walls of the screening surface, which expands technological capabilities.

The novelty also lies in the fact that the cross sectional passage has the shape of an irregular polygon, which in each cross section is rotated relative to the previous section along the length of the screening surface. Therefore, for each revolution of the screening surface, a cross section in the form of a polygon makes a 360 ° revolution, as a result, the mixing intensity, frequency and energy intensity of collisions increase. This is facilitated by the conical shape of the screening surface and an increase in the bore, which is asymmetric to the axis of rotation of the screening surface and increases along the length of the screening surface, creating a conical surface along the perimeter.

The novelty is also seen in the fact that when connecting the sections of the proposed structures, input and output squares are formed with side sizes that increase along the length of the screening surface and tilted at different angles in different directions to the section axis with the formation of a screening surface around the perimeter after connecting the sections to each other broken broken helical lines with an increasing pitch and diameter along the length of the screening surface and an increasing cross-sectional area of the screening screen radios, which expands technological capabilities.

The novelty is due to the fact that the centers of symmetry of the inner surface of the screening surface in each of its cross-sectional elements along its length are displaced relative to the axis of rotation of the screening surface, which violates the stationary motion of the classified material and expands technological capabilities.

The invention is illustrated by drawings, where: in Fig.1 shows a screen for the classification of bulk materials, General view; figure 2 is a section aa in figure 1; figure 3 - screening surface, General view, front view; figure 4 - sieving surface, top view of figure 3; 5 is a screening surface, side view along arrow A; 6 is one of the sections of the screening surface, axonometric projection; 7 is a front axle layout of the screening surface; Fig - layout of the axes of the sections of the screening surface, top view; Fig.9 is a diagram of the axes of the sections of the screening surface, side view along arrow B in Fig.7; Fig 10 - arrangement of axes of sections of the screening surface, axonometric projection.

The screen for classifying bulk materials (FIGS. 1, 2) contains a frame 1 on which a drive 2 is mounted, an unloading device 3, end cheeks 4 and 5, between which a screening surface 6 is rigidly fixed, a loading device 7, which is made in the form of a rigidly fixed in the shell 8, equipped with a cone 9, screw winding 10. The screening surface 6 is mounted rigidly between the cheeks 4 and 5 and is equipped with a support ring 11, which rests on two support rollers 12 and 13. The cheek 4 is connected by rods 14 to the disk 15 of the drive shaft 2. Supporting the rollers 12 and 13 are mounted on the frame 1. The frame 1 is suspended on rubber-cord pneumocylinders 16, which are mounted on the bed 17. Under the unloading device 3, a receiving tray 18 is fixed for receiving large fractions of the classified material. The screening surface 6 is made in the form of a broken, zigzag-shaped tunnel with a polygonal cross-section that increases along the length of the screening surface 6 from loading to unloading and is mounted from sections 19 (Figs. 3, 4,). When mounting the screening surface 6, each section 19 relative to the previous one is rotated 90 °. Since each subsequent section is larger than the previous one, discontinuous broken helical lines with increasing increments S ₁ , S ₂ , etc., for example, 20, 21, 22 with increments of S ₁ and 23, 24, 25 s are formed on the surface of the screening surface 6 step S ₂ shown in FIGS. 3-5 by thickened lines. Each section 19 (FIG. 6) of the screening surface 6 in the direction from loading to unloading is made with enlarged passage area sizes relative to the previous section and is mounted from two pairs of trapezoidal, namely two different-sized equilateral large trapezoid 26 and small trapezoid 27 and two identical in size versatile trapezoid 28 and 29, connected alternately at right angles (90 °) with each other. The lower bases 30, 31 of the miscellaneous trapezoid 29 and 28 are equal to the lateral sides 32 and 33 of the large equilateral trapezoid 26. The upper bases 34 and 35 of the miscellaneous trapezoid 29 and 28 are equal to the lateral sides of the 36 and 37 small equilateral trapezoid 27. Since the upper base 38 of the large trapezoid 26 and the upper base 39 of the small trapezoid 27 are equal to each other and equal to the small sides 40 and 41 of the versatile trapezoid 28 and 29, then the small inlet of the section 19 has the shape of a small square, inclined to the axis of the section at an angle α. Since the lower base 42 of the small equilateral trapezoid 27 and the lower base 43 of the large equilateral trapezoid 26 are equal to each other and equal to the sides 44 and 45 of the various trapezoid 28 and 29, the outlet of the section 19 has the shape of a large square, inclined to the axis of the section at an angle β . These angles of inclination of the small inlet square opening α and the large outlet square hole β are not equal to each other. Under the screening surface 6 is mounted a receiving tray 46 for receiving fine fractions of classified material and a receiving tray 47 for receiving medium fractions of classified material. Thus, in the screen for the classification of bulk materials, there are, for example, three zones (figure 1):

- zone L ₁ for separation of fine fractions of classified material;

- zone L ₂ for separation of the middle fractions of the classified material;

- zone L ₃ for the separation of large fractions of classified material.

When mounting the screening surface and turning the sections 19 counterclockwise, a screening surface is formed with the left direction of the spiral shape of the internal passage opening, increasing from loading to unloading with discontinuous helical broken lines with an increasing step from loading to unloading and the movement of masses of materials clockwise ( 7-10). The movement of the masses of the material shown in Fig.7-10 thickened lines with arrows parallel to the axis of symmetry of the sections of the screening surface. The axis of the sections, including the axis l ₁ -l _{1 of the} first section (Fig.7-10), to which the second section is attached with the axis l ₂ -l ₂ ; then the third section is connected with the axis l ₃ -l ₃ , then the fourth section is connected with the axis l ₄ -l ₄ , then the fifth section is connected with the axis l ₅ -l ₅ , then the sixth section with the axis l ₆ -l ₆ and so on, relative to the axis of rotation of the screening surface intersect each other at different angles with the formation of zigzag lines with increasing distance from the axis of rotation of the screening surface and do not intersect this axis itself.

This structural design of the screening surface 6 provides a change in the length of the screening surface not only the size of the passage section of the screening surface, but also the shape of the passage section of the screening surface. Moreover, the centers of symmetry of the inner surface of the screening surface 6 in each of its cross-sectional elements along its length are shifted relative to the axis of rotation of the screening surface 6, which violates the stationary motion of the particles of the material.

The screen for the classification of bulk materials works as follows. The classified material enters the loading device 7, from which, by means of screw winding 10, is fed to the input of the screening surface 6. The screening surface 6 is filled with the classified material. When the screening surface rotates, particles of different particle sizes are given complex spatial movement along zigzag lines with material moving from loading to unloading. The classification process is intensified by the fact that the distance from the axes of the sections along the length of the screening surface 6 relative to its axis of rotation increases, an imbalance arises. As a result, the stationary movement of the masses of material by the polygonal shape of the cross-section of the screening surface is not only violated, but also there is an imbalance not only of the screening surface of the broken shape, but also an imbalance of the masses of classified material inside the screening surface 6 due to an increase in the distance from the axes of the sections to the axis of rotation of the screening surface along its length from loading to unloading. This is facilitated by intermittent broken helical lines around the perimeter of the screening surface, the step of which increases from loading to unloading. There is an intensification of miscibility, an increase in the energy intensity and frequency of interaction of material particles, an increase in the classification intensity and an expansion of technological capabilities

Technical and economic advantages arise due to increased mixing intensity, increased energy intensity and the frequency of interaction of particles of the classified material not only with each other, but also with the walls of the screening surface, which performs not only rotational, but also oscillatory motion, which increases productivity and expands technological capabilities.

Claims (1)

The screen for the classification of bulk materials, including a screening surface located between the end cheeks, made in the form of a broken spiral shape of a tunnel with a polygonal passage section, assembled from sections with the formation along their perimeter of broken broken helical lines and along the ends of the input and output squares, inclined in different sides to the axis of the sections, each subsequent of which is rotated relative to the previous one by an angle of 90 °, loading and unloading devices, drive, characterized in that each the section of the screening surface in the direction from loading to unloading is made with enlarged dimensions of the cross-sectional area relative to the previous section and is assembled from two pairs of trapezoidal, namely two different-sized equilateral large and small trapezoidal and two equally sized miscellaneous trapezoid, connected alternately at right angles with each other, with the lower bases of the versatile trapezoid equal to the sides of the large equilateral trapezoid, and the upper bases of the versatile trapezoid equal the sides of the small equilateral trapezoid, with intermittent broken helical lines made with an increasing step along the length of the screening surface, and the input and output squares of each section are made inclined at different angles to the axis of the sections.

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