RU2511135C2 - Vibration 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. Screen comprises screening surface, drive, loader and unloader. Screening surface is arranged at the bed, equipped with vibrator and shaped to toroid with polygonal perforated helical surface over inner and outer edges. The latter are made up of bands flexed in one side along straight creases inclined to band edges and coiled to form, over band length, the different-side equilateral and isosceles perforated triangles. Bases of two identical isosceles triangles are located on both sides of the largest equilateral perforated triangle, lateral sides of said two identical isosceles triangles being located on both sides of perforated equilateral triangles with adjoining lateral sides of two identical isosceles perforated triangles, equilateral perforated triangle being attached to one of them. Sides of smaller equilateral perforated triangles differ from those of larger equilateral perforated triangles by linear magnitude delta. After coiling the band, band edges of lines magnitude smaller by four deltas than the side of largest equilateral triangle are interconnected to make subsections. Said subsections have square-like opening on their one side, opening side being smaller than that of the largest equilateral triangle by delta. On opposite side, they have opening shaped to isosceles trapezium with larger base equal to side of the largest equilateral triangle and smaller base smaller than larger base by two deltas. Aforesaid subsections are connected by trapezium-shape openings to make square-like sections with inlets and outlets, square sides being equal and openings being arranged at angle α its magnitude defining screening surface toroid diameter. Said sections are connected to make screening surface without relative turn to make opposed zigzag helical lines and helical perforated surfaces over inner and outer surfaces of toroidal screening surface.

EFFECT: expanded operating performances, decreased overall dimensions.

12 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. In 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, self-cleaning of 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, a 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 in length .

The technical solution to the problem is the expansion of technological capabilities, the reduction of dimensions along the length.

The technical solution is achieved by the fact that in a vibrating screen containing a screening surface, a drive, a loading and unloading device, a screening surface is resiliently mounted on a bed, equipped with a vibrator and made of a toroidal shape with a polyhedral perforated screw surface along its inner and outer perimeters and assembled from sections, mounted from two subsections made of perforated strips bent to one side along straight fold lines placed at an angle to the edges of the perforations shaped strips, and rolled into a ring with alternating formation along the length of the perforated strip of equal-sized equilateral and isosceles perforated triangles, while on the two sides of the largest equilateral perforated triangle are located their bases two identical isosceles perforated triangles, on the sides of which are two identical equilateral perforated triangles with their equal sides two identical isosceles and perforated triangles, one of which is attached an equilateral perforated triangle, and the sides of smaller equilateral perforated triangles differ from the sides of large equilateral perforated triangles by the same linear value Δ, while after bending the perforated strip along the fold lines into the ring, the ends of the perforated strip are connected with the formation of subsections, in which on one side holes are formed in the form of squares, the sides of which are smaller than the sides of the largest of an equilateral perforated triangle by a linear value Δ, and on the other side of the subsections, holes are formed in the form of isosceles trapezoids, the large base of which is equal to the side of the largest equilateral triangle, and the small base is smaller than the large base by 2Δ, and the subsections are connected to each other by holes in the form of trapezoid with the formation of sections with inlet and outlet openings in the form of squares whose sides are equal to each other, and these openings are located at an angle α, the value of which is determined fissioning diameter toroidal shape sieving surface, wherein the sections are joined in screening surface without turning the sections relative to each other to form at the outer and inner surfaces of the toroidal surface toward directed screening each other polygonal helical line and the helical perforated surfaces arranged at an angle to each other.

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

The novelty is due to the fact that the screening surface is made in a toroidal shape with multi-helical surfaces and multi-helical lines along its outer and inner perimeters, which provides not only the intensification of the interaction of particles of materials, but also expands technological capabilities.

The novelty of the invention lies in the fact that the implementation of the screening surface of a toroidal shape ensures the transfer of disturbing forces from the vibrator to the particles of bulk materials and the change under the influence of differently inclined walls in the form of triangles of the direction of their movement in planes perpendicular to the passage section of the toroidal working chamber, which intensifies the process of mixing particles of bulk materials , provides a reduction in the size of the screen vibrating along the length and expands the technological capabilities.

The novelty of the proposal also lies in the fact that along the entire perimeter of the screening surface, the passage section varies not only in shape, but also in area, which provides alternate compression and mass expansion of particles of bulk materials in each section of the screening surface, which means an increase in productivity and screening efficiency and expanding technological capabilities.

The novelty of the invention lies in the fact that the perforated triangles of the perforated strips from which the subsections of the screening surface are mounted are not only inclined to each other, but also to the axis of symmetry of the screening surface, therefore, the compression ratio of the material particles increases, the screening process is accelerated, and technological capabilities expand.

The novelty is also due to the fact that the pitch of the broken helix is variable, i.e. varies around the entire perimeter of the screening surface, which intensifies the process of mixing particles of bulk materials, reduces screening time, and therefore, allows to reduce the size of the vibrating screen.

The novelty also lies in the fact that the screening surface is made of sections, the perforated walls of which are not only inclined to each other, but also to the direction of the rotational movement of particles of materials moving under the influence of vibration in planes perpendicular to the cross-section of the screening surface, which complicates the trajectory of their movement , increases the intensity of their interaction and expands technological capabilities.

The novelty lies in the fact that the manufacture of a toroidal screening surface with multifaceted elements of various shapes and perimeter sizes located along screw perforated surfaces and broken helical lines provides an intensification of the process of mixing particles of materials, increases the energy intensity and frequency of their interaction, ensuring the continuity of the screening process when their movement from loading to unloading.

The invention is illustrated by drawings, where: in Fig.1 shows a vibrating screen, General view; figure 2 - screening surface, top view; figure 3 is a section aa in figure 2; figure 4 is one of the sections from which the screening surface is mounted, top view; figure 5 is one of the sections from which the screening surface is mounted, view along arrow B in figure 4; figure 6 is one of the subsections, sections of the screening surface, axonometric projection; Fig.7 is a second subsection, sections of the screening surface, axonometric projection; on Fig - perforated strip with marked straight lines; figure 9 - assembly diagram of the section from the subsections; figure 10 - section bB in figure 2; figure 11 is a section bb in figure 2; in Fig.12 is a section GG in Fig.2.

The screen (FIG. 1) consists of a bed 1, on which a screening surface 4 is elastically fixed and equipped with a vibrator 3 by means of springs 2. Loading and unloading devices are not shown in FIG. 1.

The screening surface 4 (FIG. 2, FIG. 3) is made of a toroidal shape with a polyhedral perforated helical surface along its inner and outer perimeters and made of sections 5 (one of the sections in FIG. 2 is highlighted by solid double lines 33- (34) ≡55 -53- (74) ≡54-75- (35) ≡55-95- (34) ≡94), interconnected by known methods, such as welding, adhesive, etc. Each of the sections 5 is made in the form of a circular sector (Fig. 4, Fig. 5) from subsections 6 and 7. Subsections 6 and subsections 7 are made of perforated strips 8 (Fig. 8), bent to one side along straight lines of fold A, B, C, D, D, E, G, placed at an angle to the lateral edges of the perforated strip 8, with the formation of different-sized perforated equilateral triangles 9, 10, 11, 12 and perforated isosceles triangles 13, 14, 15, 16, with on both sides of the largest equilateral perforated triangle 10 are located their base two identical isosceles perforated triangles 14 and 15, on the sides of which are two identical equilateral perforated triangles 9 and 11 with two identical isosceles perforated triangles 13 and 16 located to them, to one of which an equilateral perforated triangle 12 is attached, and the sides of smaller equilateral perforated triangles differ from the sides of large equilateral perforated triangles by the same line Δ.

After bending the perforated strip 8 along the fold lines A, B, C, D, D, E, G into the ring, the ends L and M of the perforated strip 8 are connected to form subsections 6 (Fig. 6) and subsections 7 (Fig. 7), of which, on the one hand, holes are formed in the form of a square 17 and 18, whose sides are smaller than the sides of the largest equilateral perforated triangle 10 of the perforated strip 8 by a linear value Δ, and on the other hand of subsection 6 and 7, holes are formed in the form of an isosceles face 19 and 20, whose base is equal to the side of the greatest equality ronnego perforated triangle, and a small base smaller than the large base on the value 2Δ.

Subsections 6 and 7 (Fig. 9) are connected to each other by openings in the form of trapezoid 19 and 20 with the formation of sections 5 with inlet and outlet openings in the form of squares 17 and 18, the sides of which are equal to each other, and these openings are located at an angle α, the value of which determines the diameter of the toroidal shape of the screening surface 4, while sections 5 are connected to the screening surface 4 without turning sections 5 relative to each other by squares 17 and 18 with the formation of broken screws on the outer and inner surfaces of the toroidal screening surface 4 output lines, for example, as shown in FIG. 2 by a thickened line: a closed broken helix 21-22-23-24-25-25-26-27-28-29-30-31-32-33-34-35-36- 37-38-39-40-41-42-43-44-45-46-47-48-49-50-51-52-53-54-55-56-57-58-59-60-21 and closed broken helix 60-61-62-63-64-65-66-67-68-69-70-71-72-73-74-75-76-77-78-79-80-81-82- 83-84-85-86-87-88-89-90-91-92-93-94-95-96-97-98-99-60 (in Fig.2, the invisible sections of helical lines are shown by two parallel lines - solid and dashed, and the invisible points of the broken helix are taken in parentheses). As a result, screw surfaces are formed on the inner and outer screening surfaces between the broken helical lines from alternately mounted, different in shape and area, equilateral and isosceles perforated triangles, and the perforated screening surface itself has a cross-section that varies in shape, size of sides and cross-sectional area (figure 10, figure 11, figure 12).

The vibrating screen works as follows.

The perturbing force of the vibrator 3 through the walls of the screening surface 4 is transmitted to the particles of materials inside the screening surface 4. The particles of materials make a complex movement, during which the screening process occurs. Particles of materials interact intensively with each other and, under the influence of vibration, rotate in planes perpendicular to the bore of the perforated sieving surface 4. Since the dimensions of the cross section along the length of the sieving surface 4 vary, the shape and location of the particles change, the disturbance of the movement of particles of materials is aggravated, t. e. there is an increase in screening intensity. The presence of screw perforated surfaces and helix lines around the perimeter of the screening surface 4 contributes not only to the complication of the trajectories of the movement of particles of materials, but also to their movement along the bore of the screening surface 4 from load to discharge. When moving along the cross-sectional area of the screening surface 4 particles of working materials due to changes in the cross-sectional area in shape and size, compression and rarefaction zones are formed in each section of the screening surface 4 throughout its volume, which also intensifies the screening process and expands technological capabilities.

Technical and economic advantages arise due to the implementation of the screening surface of the screen of a toroidal shape with multiple changes in the bore in shape and size along its entire length and with the formation of multiple perforated helical surfaces and multi-helical lines along its outer and inner perimeters, which provide a change in direction of movement particle flow of materials and the expansion of technological capabilities.

Claims (1)

A vibrating screen containing a screening surface, a drive, loading and unloading devices, characterized in that the screening surface is resiliently mounted on the bed, equipped with a vibrator and made of a toroidal shape with a polyhedral perforated screw surface along its inner and outer perimeters and assembled from sections mounted of two subsections made of perforated strips bent to one side along straight fold lines placed at an angle to the edges of the perforated strips, and In a ring with alternating formation along the length of the perforated strip of equal-sized equilateral and isosceles perforated triangles, at the same time two identical isosceles perforated triangles are located on the two sides of the largest equilateral perforated triangle, on the sides of which are two identical equilateral perforated triangles with the same to them with their sides two identical isosceles perforated tr polygons to one of which an equilateral perforated triangle is attached, and the sides of smaller equilateral perforated triangles differ from the sides of large equilateral perforated triangles by the same linear value Δ, while after bending the perforated strip along the fold lines into the ring, the ends of the perforated strip are connected to form subsections, on which square holes are formed on one side, the sides of which are smaller than the sides of the largest equilateral perforation of the oriented triangle by a linear value Δ, and on the other side of the subsections, holes are formed in the form of isosceles trapezoids, the large base of which is equal to the side of the largest equilateral triangle, and the small base is smaller than the large base by 2Δ, and the subsections are connected to each other by holes in the form of trapezoid with the formation of sections with inlet and outlet openings in the form of squares whose sides are equal to each other, and these openings are located at an angle α, the value of which determines the diameter of the toroid the shape of the screening surface, while the sections are connected to the screening surface without turning the sections relative to each other with the formation on the outer and inner surfaces of the toroidal screening surface directed towards each other broken helical lines and screw perforated surfaces located at an angle to each other.

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