RU139734U1 - DIRECT RATTER - Google Patents

Abstract

A direct-flow screen containing a screening surface, loading and unloading devices and a drive, characterized in that the screening surface is made in the form of a broken spiral tunnel shape with intermittent zigzag shaped broken helical lines around its perimeter with a rectangular cross section through passage of sections, each of which is mounted from large and small perforated rectangles and two identical perforated trapezes, the lower bases of which are equal to the side of the large perforated the rectangle, and the upper bases are equal to the side of the small perforated rectangle, while the sides of the perforated trapezoid are equal to the other two sides of the large and small perforated rectangles with the formation at the ends of the sections of squares, inclined in different directions to the axis of the section, and the square of each subsequent section is rotated relative to the square of the previous section by an angle corresponding to the rotation of the section on one of its sides so that the axes of the section are inclined to each other from the condition of their transition echeniya, wherein the sieving surface is arranged on a frame by frame unit introduced into a bellows.

Description

The utility model 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 device, 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 of the screening material surfaces 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 rectangular cross-sectional area of equal length in length, assembled from sections mounted from large and small rectangles and two identical trapeziums, the lower bases of which are equal to the side of the small rectangle, while the sides of the trapezoid are equal to the rest two sides of the large and small rectangles with the formation at the ends of the sections of squares, diagonally inclined in different directions to the axis of the section, each subsequent of which is rotated relative to the previous one by an angle of 90 °, loading and unloading 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.

The technical solution to the problem is the expansion of technological capabilities.

The technical solution is achieved by the fact that in a direct-flow screen containing a screening surface, loading and unloading devices and a drive, the screening surface is made in the form of a broken spiral tunnel shape with intermittent zigzag shaped broken helical lines along its perimeter with a rectangular cross sectional passage from sections, each of which is mounted from large and small perforated rectangles and two identical perforated trapezoid, the lower bases of which are equal to the side with a large perforated rectangle, and the upper bases are equal to the side of the small perforated rectangle, while the sides of the perforated trapezoid are equal to the other two sides of the large and small perforated rectangles with the formation of squares at the ends of the sections, inclined in opposite directions to the section axis, the square of each subsequent section rotated relative to the square of the previous section by an angle corresponding to the rotation of the section on one side thereof, so that the axes of the section are inclined to each other gu from the condition of their intersection, the screening surface being placed on the bed by means of a frame with pneumatic balloons inserted into the device.

According to the patent literature not found a technical solution similar to the claimed, which allows us to judge the usefulness of the proposed utility model straight-through screen.

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

The novelty is also seen in the fact that the axes of the sections of the screening surface intersect straight lines and they are located not only to the axis of rotation at an angle, but also to each other, which violates the stationary motion of the screened material and accelerates the screening process and expands technological capabilities.

The novelty also lies in the fact that, since the position of the cross-section of the screening surface together with the masses of the screening material located in them changes relative to each other and the distance of these masses of materials relative to the axis of rotation of the screening surface changes, there is an intensification of the screening process.

The novelty is also seen in the fact that at the junction of the sections the cross-section of the screening surface changes from a triangle or rectangle to a polygon and again to a triangle or rectangle, there is a complication of the trajectory of the particles of the screened material, which intensifies the screening process.

The novelty of the proposed utility model lies in the fact that technological capabilities are expanded by giving the particles of the screened material complex spatial motion and the simultaneous influence of vibrations on them in three mutually perpendicular directions excited by the geometry of the screening surface during asymmetric movement of the masses of the screened material as a result of a violation of their stationary motion flows in a zigzag shape of the screening surface.

The novelty of the proposed utility model is that due to the implementation of the screening surface from sections, the elements of which, when mounting the screening surface, are mounted at certain angles not only to each other, but also to the axis of rotation, and therefore, when working as shelves, they capture portions of particles of the screened material and direct them towards not only each other, but opposite walls of the rotating screening surface. Therefore, the screening intensity increases, the technological capabilities of the single-flow screening increase.

The novelty is due to the fact that, since the area, shape and size of the cross-section of the screening surface along its length varies from loading to unloading, the process of interaction of the particles of the screened material is intensified, not only does the activity of their interaction with each other and with perforated walls, but also the frequency of their interaction and the amplitude of movement with each other change as a result of which the technological capabilities of the direct-flow screen grow.

The novelty of the proposed utility model lies in the fact that technological capabilities are expanded by giving particles of materials complex spatial zag-like movement and simultaneous exposure to vibrations in three mutually perpendicular directions excited by the geometry of the screening surface during asymmetric movement of the masses of materials as a result of a violation of the stationary motion x flows geometric zigzag shape of the screening surface, their relative position from ositelno each other and to the axis of rotation.

The novelty also lies in 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 particles of materials and expands technological capabilities

The novelty also lies in the fact that the centers of symmetry of each cross-section of the screening surface along its length are displaced not only relative to each other, but also relative to the axis of rotation of the drum, which provides a significant increase in the energy intensity, intensity and frequency of interaction of material particles and expands technological capabilities, provides self-cleaning screening surface.

The novelty is also due to the fact that the elements from which sections of the screening surface are assembled, different in area, size and configuration, interact with the material moving inside the screening surface, are directed to each other at certain angles and therefore direct this material at different angles, which increases the miscibility of the material , energy intensity and frequency of interaction of material particles and expands technological capabilities.

The essence of the utility model is illustrated by drawings, where: in Fig.1 shows a direct-flow screen, a general view; figure 2-section aa in figure 1; figure 3 is a screening surface, front view; figure 4 - sieving surface, top view; figure 5 is a screening surface, view along arrow B in figure 3; figure 6 - one of the sections of the screening surface with end holes of a quadrangular shape, a visual image; Fig.7 is a diagram of the axes of the sections of the screening surface, front view; on Fig - arrangement of the axes of the screening surface, top view.

Direct-flow screen (figure 1, figure 2) consists of a screening surface 1, boot 2, unloading devices 3, 4 and a drive (not shown). The screening surface 1 is provided with sleeves 5 and 6 rotatably in the bearings 7 and 8. The toe 9 of the loading device 2 enters the hole of the sleeve 5 of the screening surface 1. The loading device 2, the bearing supports 7 and 8, with the screening surface 1 mounted therein, fixed on the frame 10. The frame 10 is placed on four pneumatic cylinders 11, which are mounted on the frame 12.

The screening surface 1 (Fig. 3, Fig. 4, Fig. 5) is made in the form of a broken, spiral-shaped tunnel with a rectangular passage section, mounted from sections 13. Each section 13 is mounted (Fig. 6) from two rectangles large 14, small 15 and two lateral trapezoids 16 and 17, the lower bases of which are equal to the lateral side of the rectangle 14, and the upper bases of the trapezoids 16 and 17 are equal to the lateral side of the small rectangle 15, while the remaining two free sides of the rectangles 14 and 15 are equal to the lateral sides of the trapezoid 16 and 17. When mounting a section of two straight of rectangles and two trapezoid squares are formed at the ends of the sections, tilted in different directions to the axis of the section.

When assembling the screening surface 1, each subsequent section is rotated relative to the previous section by an angle corresponding to rotation on one side of the square so that the axes of the sections are inclined to each other from the condition of their intersection (Fig. 7, Fig. 8). Thus, when mounting the screening surface 1, each section 13 is rotated relative to the previous section by an angle corresponding to the rotation of the section on its one side, so that the axes of the sections are inclined to each other from the condition of their intersection.

As a result of joining the sections, a screening surface 1 is formed (Fig. 3, Fig. 4, Fig. 5) in the form of a broken spiral shape of a tunnel with a rectangular passage and with intermittent broken helical lines around the perimeter 18-19-20, 21-22-13 24-25-26.

When mounting the screening surface 1 and turning the sections 13 clockwise, a screening surface is formed with the right direction of the spiral shape of the tunnel, with the right direction of interrupted helical broken lines. In Fig. 7, Fig. 8, the direction of movement of the screened materials is shown by arrows parallel to the axes of the sections.

The axis of the sections, including: the axis i ₁ -i _{1 of the} first section (Fig. 7, Fig. 8), to which the second section is connected with the axis i ₂ -i ₂ , then the third section is connected with the axis i ₃ -i ₃ , then the fourth section is connected with the axis i ₄ -i ₄ , then the fifth section is connected with the axis i ₅ -i ₅ , then the sixth section with the axis i ₆ -i ₆ and so on intersect each other.

Direct-flow screen operates as follows. The material to be screened enters the loading device 2, from which with the help of the sock 8 is fed to the input of the screening surface 1. The screening surface 1 is filled with a screening material. When the screening surface 1 of a particle of various particle sizes rotates, complex spatial motion along zigzag lines is reported with the material moving from loading to unloading. The screening process is intensified by the fact that the axes of the sections along the length of the screening surface 1 relative to its axis of rotation are differently inclined not only to each other, but also to the axis of rotation of the screening surface 1, so an imbalance occurs. As a result, the stationary movement of the masses of material by the polygonal shape of the passage 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 the screening material inside the screening surface 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. There is an intensification of miscibility, an increase in the energy intensity and frequency of interaction of material particles, an increase in screening intensity, an expansion of technological capabilities, and self-cleaning of the holes of the perforated side surfaces of the sections of the screening surface 1.

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

Claims (1)

A direct-flow screen containing a screening surface, loading and unloading devices and a drive, characterized in that the screening surface is made in the form of a broken spiral tunnel shape with intermittent zigzag shaped broken helical lines around its perimeter with a rectangular cross section through passage of sections, each of which is mounted from large and small perforated rectangles and two identical perforated trapezoids, the lower bases of which are equal to the side of the large perforated the rectangle, and the upper bases are equal to the side of the small perforated rectangle, while the sides of the perforated trapezoid are equal to the other two sides of the large and small perforated rectangles with the formation at the ends of the sections of squares, inclined in different directions to the axis of the section, and the square of each subsequent section is rotated relative to the square of the previous section by an angle corresponding to the rotation of the section on one of its sides so that the axes of the section are inclined to each other from the condition of their transition echeniya, wherein the sieving surface is arranged on a frame by frame unit introduced into a bellows.

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