RU2368433C2 - Vibration screw screen - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: vibration screw screen includes a box covered on all the sides and having screw screening surfaces located in tiers one under the other and combined into a unique process flow, vibration exciter and elastic elements, loading and unloading means of fine and coarse loose material particles. Each screening screw surface is hollow and is formed along the periphery with three and more curve-shaped perforated straps of various order, which are folded in a vertical plane and connected in-series between each other lengthwise. Centres of curved screening surfaces are located inside their cross section. Loading and unloading means of coarse particles on each tier are made in the form of inlet and outlet holes. Inlet hole of the upper screening surface is connected to the loading device nozzle, which supplies loose material inside the screening surface. Outlet hole of each tier of the screening surface is interconnected with the inlet hole of the screening surface located below by means of the cover plate covering inlet and outlet holes of coarse particles of each tier of the screening surface.

EFFECT: improving screening efficiency, capacity and enlarging technological capabilities.

6 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 (USSR AS No. 725720, class B07B 1/18, 1980) containing a support frame, a rotating drum mounted thereon, formed by flat longitudinally sectional sieves and a mechanism for communicating vibration fluctuations of the drum during rotation.

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

Closest to the proposed invention is a vibrating screw screen (SU 614832 A, 07/15/1978, B07B 1/40), including a box closed on all sides with spiral screening surfaces located underneath and connected into a single technological chain, vibration exciter and elastic elements, means of loading and unloading.

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

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

The task is achieved in that in a vibrating screw screen, including a box closed on all sides with a belt located one below the other and connected in a single technological chain by screw screening surfaces, vibration exciter and elastic elements, means for loading and unloading small and large particles of bulk material, each the screw screening surface is made hollow and is formed along the perimeter of three or more rolled up in a vertical plane and connected in series with each other lengthwise perforated curved strips of various shapes, the centers of the curves of the screening surfaces being located inside their cross section, while the means for loading and unloading large particles on each tier are made in the form of inlet and outlet openings, the inlet of the upper screening surface is connected to the nozzle of the loading device feeding bulk material inside the screening surface, and the outlet of each tier of the screening surface is in communication with the inlet izhelezhaschey screening surface by means of the lid overlapping the inlet and outlet of large particles each tier screening surface.

According to the scientific and technical literature, no technical solution was found that is similar to the claimed one, which allows one to judge the inventive step of the proposed design of a vibrating screw screen.

The novelty of the invention lies in the fact that such a design of screening surfaces, the presence of three or more running lines along their perimeter allows not only to provide longitudinal movement of masses of bulk materials from loading to unloading, but also to provide intensive mixing with a complex trajectory, which expands technological capabilities and increases screening performance.

The novelty is also due to the fact that due to the internal helical surfaces of a curvilinear shape of various types of screening surfaces, the vectors of the speed of movement of bulk materials during transportation from loading to unloading change, which contributes to the intensification of the screening process and expands technological capabilities.

The novelty of the invention lies in the fact that when the exciter is operating, particles of bulk materials circulating inside the screening surfaces in planes perpendicular to their horizontal axis receive additional movement from curvilinear walls of various orders of screening surfaces, which intensifies the mixing of bulk materials and increases productivity screening.

The novelty is also due to the fact that the cross-section of sifting surfaces of a curvilinear shape of various orders as the bulk materials move from loading to unloading changes their location relative to the axis of symmetry, which violates the stationary motion of the bulk materials and contributes to an increase in screening productivity.

The invention is illustrated by drawings, where figure 1 shows a vibrating screw screen, General view; figure 2 is a section aa in figure 1; figure 3 is a view a in figure 1; figure 4 - screw screening surface; figure 5 is a section bB in figure 4, while the perforated stripes of the screw screening surface are described by curves of various orders and degrees of curvature of a concave shape, in which the centers of curvature are located outside its cross section; Fig.6 is a section bB in Fig.4, while the perforated stripes of the screw screening surface are described by curves of various orders and degrees of curvature of a convex shape, in which the centers of curvature are located inside its cross section.

Vibrating screw screen (figure 1, figure 2, figure 3) consists of a means for loading 1, means for unloading 2, 3, 4, 5 to output fractions of bulk materials beyond the vibration of a screw screen, box 6, installed using elastic elements 7 on the base 8. In the lower part of the box 6 is mounted a vibration exciter 9. The vibrating screw 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, screw sieving surfaces 14, 15, 16 are mounted under each other and connected in a single technological chain. Screw sieving surfaces 14, 15, 16 are made hollow, one of which, for example, 14, is shown in FIG. .4, made around the perimeter of three or more vertically rolled and serially connected to each other along the length of the screw perforated strips 17, 18, 19 of a curved concave or convex shape relative to the axis of rotation (Figs. 4, 5, 6) and described by curves different order and degree of curvature, for example, by lines of the second order of curvature -

; параболой y²=2рх; гиперболой

; линиями третьего порядка кривизны выше - Декартов лист х³+у³-3а·х·у=0; локон Аньези у=а³(а²+х²); Строфоида

; улитка Паскаля (х²+у²-2Rx)²-а²(х²+y²)=0 и т.п. линиями n-го порядка кривизны - кривыми, описанные полиномами.ellipse

; parabola y ² = ² px; hyperbole

; the third-order lines of curvature above - Cartesian sheet x ³ + y ³ -3a · x · y = 0; Agnesi curl y = a ³ (a ² + x ² ); Strofoid

; Pascal snail (x ² + y ² -2Rx) ² -a ² (x ² + y ² ) = 0, etc. lines of the nth order of curvature - curves described by polynomials.

The connection lines of the perforated strips rolled into a screw form a distinct unidirectional three-way and more helical screening surface such as, for example, in FIG. 4.

The direction of the helical lines of each half below the installed screw sifting surfaces is opposite to the direction of the helical lines of the screw sifting surface mounted above, for example, the direction of the helical lines of the sifting surface 15 is opposite to the direction of the helical lines of the sifting surface 14, and the direction of the helical lines of the sifting surface 16 is opposite to the direction of the helical lines of the sifting surface 15 (figure 1). Therefore, during the operation of a vibrating screw 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 screening surface 14. The outlet 17 of the screening surface 14 is closed by a lid 18, which simultaneously covers the inlet 19 of the screening surface 15 and allows the masses of bulk materials to move from the upper - first - screening surface 14 to the underlying second screening screen surface 15, namely from the outlet 17 of the screening surface 14 to the inlet 19 of the screening surface 15. The outlet 20 of the second pros the screening surface 15 is closed by a cover 21, which simultaneously closes the inlet 22 of the underlying third screening surface 16, ensuring the transfer of bulk materials from the second middle screening surface 15 to the lower third screening surface 16. For receiving fine fractions of the classified material under the first screw screening surface 14 mounted means for unloading 2, under the second screw screening surface 15 - means for unloading 3, under the third screw screening surface 16 - redstvo for discharging 4. Under the third outlet 23 of the screening surface 16 of the discharge device 5 is mounted.

Vibrating screw screen works as follows. By means of a loading device 1, classified granular material is continuously charged into the upper screening surface 14. Under the influence of the disturbing forces of the rotating vibrator 9 through the walls of the box 6 and rigidly connected to the sieving surfaces 14, 15, 16 disturbing forces are transmitted to the particles of bulk materials. 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 sieving surface 14, 15, 16. The screw perforated walls of a curvilinear shape of various orders of sifting surfaces 14, 15, 16 change and give additional movements to the particles of bulk materials and provide an increase in the performance of classification of bulk materials by size, and also move them from loading to outlet openings, for example to one hole 17 of the screening surface 14. As the particles of bulk materials move along the horizontal axis of the screening surface 14, small particles of bulk materials are separated and they are discharged through the holes of the screw screening surface 14 into the means for unloading 2 and then beyond the vibration of the screw screen. Under the influence of vibration and using the cover 18, the particles of bulk materials are reloaded through the hole 19 into the underlying screening surface 15, along the perimeter of which there are three helical lines whose direction is opposite to the direction of the helical lines of the upper screening surface 14. With their help and under the influence of vibration, small particles of bulk materials through the holes of the screw screening surface 15 are discharged into the means for unloading 3 and further beyond the vibration of the screw 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 internal cavity of the screening surface 16. Under the influence of vibration of screw perforated walls of curvilinear shape of various orders and helical lines around the perimeter of the screening surface 16 small fractions of bulk materials are discharged into the means for unloading 4 and beyond the limits of a vibrating screw screen, and large particles of bulk materials move along the horizontal axis and through the hole e and 23 via discharging device 5 are displayed outside the helical vibratory 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 screening surface, additional movement imparted by curvilinear walls of different orders of screw screening surfaces, which facilitate the passage of particles through openings of screening surfaces 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 curvilinear walls of various orders of screw screening surfaces, which intensifies the process of mixing and screening.

Claims (1)

Vibrating screw screen, including a box closed on all sides, with belt sifting located underneath one another and connected in a single technological chain, vibration exciter and elastic elements, means for loading and unloading small and large particles of bulk material, characterized in that each screw sifting the surface is hollow and formed around the perimeter of three or more rolled up in a vertical plane and sequentially interconnected along the length of the perforation with curved stripes of various shapes, the centers of the curves of the screening surfaces being located inside their cross section, while the means for loading and unloading large particles on each tier are made in the form of inlet and outlet openings, the inlet of the upper screening surface is connected to the nozzle of the loading device, which feeds loose material inside the screening surface, and the outlet of each tier of the screening surface is communicated with the inlet of the underlying screening the surface by means of a cover overlapping the inlet and outlet openings of large particles of each tier of the screening surface.

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