RU2478439C1 - Vibratory screen for sizing construction materials - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to loose material classification and may be used in metallurgy, construction, chemical industry, etc. Proposed screen comprises screening surface, loader and unloader, and drive. Screening barrel-like surface is composed of sections to expand toward center, first from loader to screening surface medium point and connected in turns by one equilateral trapezoid, two identical inequilateral perforated trapezoids with height smaller than of first trapezoid. Lower bases of said perforated trapezoids are equal and smaller than equal top bases to square at faces of said sections. Square of every nest section is turned relative to square of previous section through 180 degrees. Note here that every connected section has bottom base square sides equal to those of top base square. Screening surface, from center to unloader, is composed of interconnected one equilateral perforated trapezoid, two identical inequilateral perforated trapezoids and second perforated equilateral trapezoid. Lower bases of said perforated trapezoids are equal and larger than equal top bases to square at faces of said sections. Square of every nest section is turned relative to square of previous section through 180 degrees. Note here that every connected section has bottom base square sides equal to those of top base square. Screening surface is mounted on the frame suspended by rubber cord air cylinders at the bed.

EFFECT: expanded performances and higher efficiency.

9 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 device, drive (see AC No. 1808417, B07B 1/22, published in BI No. 14, 04/15/93).

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. In BI No. 25, 09/10/2002), including a screening surface located between the end cheeks, made in the form of a broken spiral tunnel shape with a rectangular cross-sectional area along its length, assembled from sections mounted from large and small rectangles and two identical trapezoids, 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 the two sides of the large and small rectangles to form the ends of sections squares raznonaklonennyh in different directions to the axis of the section, each subsequent of which is rotated relative to the preceding by an angle of 90 °, the loading and unloading tools drive.

A disadvantage of the known device is the lack of 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 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 vibrating screen for classifying building materials containing a screening surface, loading, unloading devices and a screening drive, the screening surface is made expanding along the length to its center of a barrel-shaped form from sections mounted along the length of the screening surface around the perimeter, first from the loading device to the middle of the screening surface of alternately connected one equilateral perforated trapezoid, two identical inequalities perforated trapezoid trapezoid and a second, smaller in height than the first, equilateral perforated trapezoid, the lower bases of which are equal to each other at each of the perforated trapezoid and smaller than the upper bases, which are also equal to each other for all four perforated trapezoid, with the formation of square sections at the ends, at the same time, the square of each subsequent section is rotated relative to the square of the previous one by an angle of 180 °, moreover, each attached section has sides of the square of the lower base equal to the sides of the square of the upper about the base of the previous section, and after the middle of the hull to the unloading device from alternately connected one equilateral perforated trapezoid, two identical non-equilateral perforated trapezoid and a second, lower in height than the first, equilateral perforated trapezoid, the lower bases of which are equal to each other at each of the perforated trapezoid and more than the upper bases, also equal to each other for all four perforated trapezes, with the formation of square sections at the ends, with each square subsequent section is rotated relative to the previous square by 180 °, wherein each attachment section has a square side of the lower base equal to the sides of a square of the upper base of the previous section.

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

The novelty of the invention lies in the fact that such a design of a rotating screening surface allows for consistent compaction and discharge of material flows as they move from loading to unloading, which expands technological capabilities and increases the efficiency of screening.

The novelty also lies in the fact that due to the barrel-shaped shape of the rotating screening surface, its eccentricity relative to the axis of rotation increases, which provides vibration excitation in three mutually perpendicular directions of the frame suspended from the cylinders with a rotating screening surface, which are transmitted moving from loading to unloading materials, which provides increased screening intensity and expands technological capabilities.

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 along its length are shifted 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 is also seen in the fact that the axes of the sections of the screening surface are intersecting straight lines and they are located not only to the axis of rotation of the screening surface at an angle, but also to each other, which violates the stationary motion of particles of materials and intensifies the process of their preparation.

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

The novelty is also seen in the fact that the elements from which the rotating surface is assembled are different in area, size and configuration, so the intensity of screening of materials increases, since these elements, working as shelves, capture portions of materials of different volumes and direct them towards each other friend, thus violate the stationary nature of their movement, increase their intensity of interaction, expand technological capabilities.

The novelty of the invention lies in the fact that due to the execution of the rotating surface of the sections, the elements of which when mounting the screening surface are mounted at some angles not only to each other, but also to the axis of rotation, and therefore they, working like shelves, capture portions of particles of materials and direct them towards not only each other, but opposite walls of the rotating surface. Therefore, the intensity and activity of mixing particles of materials increases, the technological capabilities of the vibrating screen for classifying building materials increase, and self-cleaning of the screening surface is provided.

The novelty is due to the fact that, since the area, shape and dimensions of the cross-section of the screening surface along its length vary from loading to unloading, first to increase and then decrease, the process of mixing is intensified, not only the activity of interaction of particles of materials with walls increases of a rotating surface, but the frequency of their interaction and the amplitude of movement with each other also change, as a result, technological capabilities increase and self-cleaning of the screening surface is provided .

The novelty of the invention 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 them in three mutually perpendicular directions, excited due to 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 relative to 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 shifted relative to the axis of rotation of the screening surface, which violates the stationary motion of the 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 miscibility material, energy intensity and frequency of interaction of material particles and expands technological capabilities.

The invention is illustrated by drawings, where figure 1 shows a vibrating screen for the classification of building materials, General view; figure 2 is a section aa in figure 1; figure 3 is a screening surface, front view; figure 4 - sieving surface, top view; 5 is a screening surface, axonometric projection; 6 is one of the sections of a rotating surface, axonometric projection; Fig.7 - the first (large) equilateral perforated trapezoid; Fig - one of two identical non-equilateral perforated trapezoid; Fig.9 - the second (small) equilateral perforated trapezoid.

The vibrating screen for classifying building materials (FIG. 1, FIG. 2) consists of a screening surface 1, loading 2, unloading devices 3, 4, 5. The screening surface 1 is provided with bushings 6 and 7. The toe 8 of the loading device 2 enters the hole of the sleeve 6 of the screening surface 1. Loading device 2, bearing bearings 9, 10 with the screening surface 1 mounted in them are fixed on the frame 11. The frame 11 is placed on four air cylinders 12, which are mounted on the frame 13 (the drive is not shown in the drawings).

The screening surface 1 (figure 3, figure 4, figure 5) is made expanding along the length to its middle (center) of the barrel-shaped form of sections 14 and 15 mounted along the length of the screening surface 1 around the perimeter, first from the loading device 2 to the middle screening surface 1 of sections 14. Each section 14 is mounted from alternately connected by one equilateral perforated trapezoid 16 (Fig.7), two identical non-equilateral perforated trapezoid 17 (Fig.8) and the second, smaller in height than the first, equilateral perforated trapezoid 18 (Fig. 9), the lower bases M of which are equal to each other at each of the perforated trapezoid and smaller than the upper bases of N, which are also equal to each other for all four perforated trapeziums, with the formation of square sections at the ends, and the square of each subsequent section rotated relative to the square of the previous one by an angle of 180 °, and each attached section has sides of the square of the lower base equal to the sides of the square of the upper base of the previous section, and after the middle (center) the screening surface 1 is mounted of the sections 15 and the discharge device 5. Each of the sections 15 are mounted as well as the section 14, but the section 15 and deployed prisoedinyaemy during assembly to each other in reverse order, i.e. from alternately connected one equilateral perforated trapezoid 16, two identical non-equilateral perforated trapezoid 17 and the second, smaller in height than the first, equilateral perforated trapezoid 18, whose lower bases M are equal to each other at each of the perforated trapezoid and more than the upper bases N, also equal with each other at all four perforated trapeziums, with the formation of square sections at the ends, while the square of each subsequent section is rotated relative to the previous square by an angle of 180 °, each attached side section has a square bottom base equal sides of the square of the upper base of the previous section. Thus, the screening surface 1 of the barrel-shaped form (Fig. 3, Fig. 4, Fig. 5) is made of sections 14 and sections 15, which are mounted (Fig. 6) from one large equilateral perforated trapezoid 16 (Fig. 7), two identical non-equilateral perforated trapezoid 17 (Fig. 8) and one small equilateral perforated trapezoid 18 (Fig. 9), the lower bases M of which are equal to each other at each of their perforated trapezes and are smaller than the upper bases N, which are also equal to each other for all four perforated trapezes . Moreover, at first, from the load along the length of the screening surface 1, each attached section has sides of the lower bases M equal to the sides N of the upper bases of the previous section. The sides N of the upper bases of the sections 14 are larger than the sides of the smaller bases M. The sections 14 are connected to the screening surface 1 by the remaining free sides S and T remaining equal to each other and forming a square after each section rotates through 180 ° relative to the previous section (Fig. 5). And then from the middle of the screening surface 1, each attached section 15 is made in the form of sections 14, but deployed and joined to each other in the reverse order, i.e. each attached section 15 has sides of the upper bases N, equal to the side M of the lower previous section 15. For clarity, the rotation of the sections 14 relative to each other 180 °

A small equilateral perforated trapezoid with a side equal to S is shown in FIG. 5 by a thickened line and shaded. Thus, a zigzag screening surface 1 is created, in which the axis of each section, rotated 180 ° relative to the previous one, is located at an angle to the transport line, i.e. to the axis of rotation with an increasing bore of the screening surface 1 of the barrel-shaped from loading to unloading. The axes of the sections, including: the axis i ₁ -i _{1 of the} first section (Fig. 3), 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 and so on, intersect with each other and are located at an angle not only to each other, but also to the axis of rotation of the screening surface 1.

Vibrating screen for the classification of building materials works as follows.

The screening surface 1 through the loading device 2 is filled with a continuous stream of particles of building materials (sand, gravel, etc.). When the screening surface 1 is rotated, the particles of materials are given complex spatial motion with the imposition of oscillations in three mutually perpendicular directions excited by the geometry of the screening surface 1 with asymmetric movement of the loading masses and the occurrence of unbalance as a result of violation of the stationary motion of the material flows by the geometric shape of the sections, their relative position relative to each other and to the axis of rotation. In this case, the centers of symmetry of the inner surface of the screening surface 1, in each of its cross-sectional elements along its length, are displaced relative to the axis of rotation, which violates the stationary motion of the particles of materials. Due to the simultaneous effect of the complex spatial motion of the particles of materials and their low-frequency vibrations, the miscibility of the particles of materials increases, their intensity of interaction between themselves and with the perforated walls of the screening surface 1. The masses of the particles of materials, mixing, move inside the screening surface 1 from loading to unloading. Such a design of the rotating screening surface 1 allows for consistent compaction and discharge of the material flows as they move from loading to unloading, which extends technological capabilities and increases the efficiency of screening and ensures self-cleaning of the screening surface. Since the screening surface 1 is made in the form of a barrel-shaped form, its eccentricity relative to the axis of rotation increases, which ensures, without a vibration activator, the excitation of vibrations in three mutually perpendicular directions of the frame suspended on balloons with a rotating screening surface 1, which are transmitted to particles moving from loading to unloading building materials, which provides increased screening intensity and expands technological capabilities. Moreover, since the centers of symmetry of the inner surface of the screening surface 1 in each of its cross-sectional elements are displaced along the axis of rotation along the axis of rotation, and the axes of the sections of the screening surface 1 are intersecting straight lines and they are located not only to the rotation axis of the screening surface 1 at an angle, but also to friend, the stationary movement of particles of building materials is violated and technological capabilities expand. The elements from which the rotating screening surface 1 is assembled are different in area, size and configuration, therefore the screening intensity increases, since these elements, working like shelves, capture portions of materials of different volumes and direct them towards each other, thus violating stationarity their movements, increasing the intensity and energy intensity of their interaction, expand technological capabilities. With the further movement of particles of building materials and their passage from the beginning of loading to unloading, a process of their classification takes place. Large building materials are unloaded through the sleeve into the unloading device 5.

Thus, the screening surface 1 is filled with classified material. When the screening surface 1 is rotated, 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 axes of the sections along the length of the screening surface 6 relative to its axis of rotation are not only inclined towards each other, but also to the axis of rotation of the screening surface 1, so an imbalance occurs. As a result, not only the stationary motion of the material mass with the polygonal shape of the cross-section of the screening surface is violated, but also there is an imbalance not only of the screened surface of the broken shape, but also an imbalance of the masses of classified material inside the screening surface 1 due to an increase in the distance from the axes of 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 the classification intensity, an expansion of technological capabilities and self-cleaning of the openings of the screening surface.

Technical and economic advantages arise due to giving particles of building materials a complex spatial zigzag motion and simultaneous exposure to vibrations in three mutually perpendicular directions, which increases the intensity of mixing, increases the energy intensity of the interaction of particles of materials with each other, with the walls of the screening surface 1 and extends technological capabilities. Since the cross-sectional dimensions, shape and location, center of symmetry vary along the length of the screening surface 1 of the barrel-shaped shape, the disturbance of the movement of particles of materials is aggravated, i.e. there is an increase in the intensity of their interaction, expansion of technological capabilities. This also contributes to the barrel-shaped shape of the screening surface, which provides sequential compaction and discharge of streams of particles of building materials as they move from loading to unloading, which expands technological capabilities and increases the efficiency of screening.

Claims (1)

Vibrating screen for the classification of building materials, containing a screening surface, loading, unloading devices and a drive, characterized in that the screening surface is made expanding along the length to its center of a barrel-shaped form from sections mounted along the length of the screening surface around the perimeter, first from the loading device to the middle screening surface of alternately connected one equilateral perforated trapezoid, two identical non-equilateral perforated trapezoid and a second, smaller in height than the first, equilateral perforated trapezoid, the lower bases of which are equal to each other in each of the perforated trapezoid and smaller than the upper bases, which are also equal to each other for all four perforated trapezoid, with the formation of square sections at the ends, at the square of each subsequent section is rotated relative to the square of the previous one by an angle of 180 °, and each attached section has sides of the square of the lower base equal to the sides of the square of the upper base of the previous section, and after the middle of the hull to the unloading device from alternately connected one equilateral perforated trapezoid, two identical non-equilateral perforated trapezoid and a second, lower in height than the first, equilateral perforated trapezoid, the lower bases of which are equal to each other at each of the perforated trapezoid and more than the upper bases, also equal to each other for all four perforated trapeziums, with the formation of square sections at the ends, while the square of each subsequent section along returned relative to the square of the previous one at an angle of 180 °, with each attached section having the sides of the square of the lower base equal to the sides of the square of the upper base of the previous section, the screening surface mounted on a frame suspended by rubber cord pneumocylinders on the bed.

Images