RU2444411C2 - Screen for sizing construction materials - 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. Proposed sizing screen comprises shells with grizzly bars arranged at an angle to drum axis and alternating in height to make grid drum, loading and unloading chutes and drive. Grid drum represents a multi-start screw grid cylindrical surface secured in ring shells made up of crosswise grizzly bar consisting of, at least, one coiled solid rod with round or polygonal cross section deformed to make alternating triangular or rectangular, or wavy ledges and recesses. Equal-pitch spiral lines are made all over the length of said screw grind cylindrical surface. Note here that lengthwise grizzle bars are fitted into said ledges or recesses and rigidly attached thereto. Said grizzle bars feature round or polygonal cross section and are pre-coiled along spiral lines of diameter of recesses of crosswise grizzly bar spiral coils.

EFFECT: expanded performances and higher efficiency.

17 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 roar (and.with. No. 360979, class B07B 1/22, 1970) containing shells with grates fixed therein, forming a trellised drum, loading and unloading trays and a drive.

The perpendicular arrangement of the slots relative to the direction of rotation of the drum does not contribute to an increase in productivity, since when the drum rotates, the screened material crosses the grates at an angle close to 90 °, which creates additional resistance to screening. The disadvantage of this drum screen is low productivity, limited technological capabilities.

Closest to the proposed invention is a rumble (a.s. No. 914114, class B07B 1/18, 1982) containing shells with alternating heights fixed therein and installed at an angle to the axis of the drum, grid-irons forming a trellised drum, and their angle the inclination is equal to the angle of repose of the screened material, loading and unloading trays and drive.

The disadvantage of this screen is low productivity, limited technological capabilities.

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

The technical solution is achieved by the fact that in the screen for classifying building materials, containing shells with grates fixed in them and alternating in height and set at an angle to the axis of the drum, forming a trellis drum, loading and unloading trays and a drive, the trellis drum is made in the form of fixed in circular the shells of a multi-helical helical lattice of a cylindrical surface mounted from a transverse grate made of at least one solid bar with a round or many a carbon cross-sectional shape deformed with the formation of alternating protrusions and hollows of a triangular, rectangular, or wave-like shape and coiled into spiral coils, while helical lines of the same pitch are created along the entire length of the helical lattice cylindrical surface, moreover, in the protrusions and / or longitudinal grates with a round or polygonal cross-sectional shape pre-twisted along the helical lines of the diameter of the hollows with eral turns transverse grate.

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

The novelty lies in the fact that the cross section of the longitudinal and transverse grates, from which the trellised drum is mounted, is made of round, polygonal shape, while the transverse grate is deformed with the formation of alternating protrusions and hollows of a triangular, or rectangular, or wavy shape and folded into spiral coils, at the same time, helical lines of the same pitch are created along the entire length of the helical trellised cylindrical surface along these protrusions and troughs, and, thus, due to the design features of etchatogo drum not only created lattice cell surface of different shape and dimensions of the perimeter of the drum of the grill, but also provides an increase in frequency and energy of interaction of the particles being classified pieces of material, not only with each other but also with the grill grate drum that expands the technological possibilities screening.

The novelty lies in the fact that the cells of the lattice surface of the screen drum are differently inclined not only to each other, but also to the axis of rotation of the drum, which increases productivity and expands technological capabilities.

The novelty of the proposal also lies in the fact that with the same diameter of the drum in the proposed design, the contact area of the grate of the drum with particles of classified material increases compared with the known design of the drum, which expands the technological capabilities.

The novelty also lies in the fact that with the same diameter of the drum in the proposed design of the drum, the path of the mass of classified material is much larger, which expands the technological capabilities and makes it possible to reduce the dimensions of the drum, and hence the screen as a whole, both in length and according to the diameter of the drums, and therefore, the width and height of the screen.

The novelty is seen in the fact that longitudinal grates, twisted along the helical lines of the diameter of the protrusions and troughs, not only pull along the outer and inner diameters (protrusions and troughs) of the transverse grate of the spiral shape of the coil into a single lattice-shaped drum without additional methods and ways of attaching the longitudinal and transverse grates, for example by welding or other mechanical methods, but also provide an increase in the intensity of mixing of particles of the mass of building materials, a change in the direction of movement towards to each other and along helical lines, which increases screening productivity and expands technological capabilities.

The novelty also lies in the fact that during the rotation of the trellis drum the spiral coils of the transverse grate with hollows and protrusions and the longitudinal grates fixed therein, forming the walls of the cells of the trellis drum, working like buckets, capture portions of building materials with different volumes and lift them in the direction of rotation the lattice drum is slightly higher than the angle of repose and then send these portions of the masses of building materials not only at some angle to the axis of rotation of the lattice drum, but also to other flows of similar masses of building materials at different angles and at different speeds. The length of the trajectory of the trajectory of the masses of building materials, more precisely, their "throw", the energy intensity of collisions of particles of masses of building materials depend on the diameter of the drum, on the magnitude of the angles of the cells to each other and to the axis of rotation of the trellis drum, on the speed of rotation of the trellis drum. Moreover, such a wavy lattice inner surface of the trellis drum allows to increase the rotational speed of the trellis drum in comparison with the known structures, and therefore, to increase the energy intensity of the collision of particles of masses of building materials, increase the intensity of screening, expand the technological capabilities of the screen.

The novelty also lies in the fact that since the shape and dimensions of the cross-section of the lattice drum change repeatedly along the length of the grating drum from loading to unloading (due to the different inclination of the cells of the grating surface to each other and to the axis of rotation of the drum), the multiple compression of the moving masses of building masses is ensured materials, which increases the intensity of mixing, the energy intensity of collisions, expands technological capabilities.

Figure 1 shows a rumble, a General view; figure 2 is a cross section aa the working surface of the screen in figure 1 with a transverse grate deformed to form alternating protrusions and troughs of a triangular shape; figure 3 is a cross section aa the working surface of the screen in figure 1 with a transverse grate deformed to form alternating protrusions and depressions of a rectangular shape; figure 4 is a cross section aa the working surface of the screen in figure 1 with a transverse grate deformed with the formation of alternating protrusions and depressions in a wavy shape; figure 5 - working surface of the screen, General view; in the hollows of the transverse grate which longitudinal grates are mounted and rigidly attached; figure 6 is a view of figure 5; Fig.7 is a transverse grate in the form of spiral turns, a General view; on Fig - longitudinal grate, pre-twisted along the helical lines of the diameter of the hollows of the transverse grate; Fig.9 is a view of B in Fig.8; figure 10 - transverse grate, made of at least one solid bar with a round or polygonal cross-sectional shape, deformed with the formation of alternating protrusions and depressions of a triangular shape and rolled into spiral coils, while created along the entire length of the spiral transverse shape the grate along these protrusions and troughs are helical lines of the same pitch, and longitudinal grates with a round or polygonal cross-sectional shape are pre-twisted into the troughs and rigidly attached e along helical lines spiral turns diameter depressions transverse grate; 11 - the working surface of the screen, a General view, in the protrusions of the transverse grate of which are mounted and rigidly attached longitudinal grates; in Fig.12 is a view In Fig.11; on Fig - longitudinal grate, pre-twisted along the helical lines of the diameter of the protrusions of the transverse grate; Fig.14 is a view of G in Fig.13; on Fig - transverse grate, made of at least one solid bar with a round or polygonal cross-sectional shape, deformed with the formation of alternating protrusions and depressions of a triangular shape and rolled into spiral coils, while created along the entire length of the spiral transverse shape the grate along these protrusions and troughs helical lines of the same pitch, and longitudinal grates with a round or polygonal cross-sectional shape are mounted and rigidly attached to the protrusions, pre-twisted helical lines on the projections diameter spiral turns cross the grate; in Fig.16 - the working surface of the screen, a General view, in the protrusions and troughs of the transverse grate of which are mounted and rigidly attached longitudinal grates; on Fig - view D in Fig.15.

The screen for classifying building materials contains a working surface 1 fixed in circular shells 2 forming a trellised drum 3. On one of the shells 2 there is a crown gear 4. The trellised drum 3 of the screen is mounted on supporting rollers 5.

A drive including a motor 6, a gearbox 7 and gear 8 is mounted on the side of the ring having a ring gear. The screen is equipped with loading 9 and unloading 10 and 11 trays. The working surface 1 is made in the form of a multi-helical helical latticed cylindrical surface (Figs. 1-4) mounted from a transverse grate 12 made of at least one solid bar rolled up by spiral coils 13 with a round or polygonal cross-sectional shape, with the formation alternating protrusions 14 and depressions 15 of a triangular shape (FIG. 2), or rectangular shape (FIG. 3), or a wavy shape (FIG. 4) and creating along the entire length of a helical lattice cylindrical surface (working surface 1) along this protrusion s 14 and depressions 15 of screw lines S (5) of the same step. In this case, longitudinal grates 16 with a round or polygonal cross-sectional shape, pre-twisted along the helical lines of the diameter of the troughs 15 or the diameter of the protrusions 14 of the transverse grate 12 of the helical cylindrical surface 1 (working surface rumble). Moreover, along the inner perimeter of the trellis drum 3, cells are formed that are mounted at an angle not only to each other, but also to the axis of rotation of the trellis drum 3.

Thus, the working surface 1 is a helical lattice cylindrical surface, may consist of spiral turns 13 of the transverse grate 12 (Fig.5, 6), made of at least one solid bar, deformed with the formation of alternating protrusions 14 and depressions 15, for example, a triangular shape (Fig.6), rolled into a cylindrical spiral shape of a coil 13 (Fig.7) of a given diameter of the protrusions D and the diameter of the depressions d (Fig.6) with a step S (Fig.5, 7) and the formation along the entire length lattice cylindrical surface (working surface 1) tim depressions 15 helices of the same pitch S (Figure 5), which are mounted in the longitudinal grate 16 (5, 6) is twisted along helical lines depressions diameter d transverse grate 12 with step S ₁ (8, 9). In Fig. 5, one of the longitudinal grates, for example A-G ¹ , is shown by the thickened line A-17-18-19-G ¹ . The number of longitudinal grates corresponds to the number of troughs of the spiral turns 13 of the transverse grate 12, for example, in FIG. 6 there are twelve troughs, and accordingly, there are twelve longitudinal grates, namely A-G ¹ , B-D ¹ , G-E ¹ , D-Zh ^1, E-W ^1, and ^{W-1 W-1} K AND ^{L-1, K-1,} M, L-H ¹ M ^1-A, H-B ¹ (Figures 5, 6). Figure 10 shows a detailed drawing of one of the longitudinal grates 16, namely B-D ¹ , mounted (attached) in the hollows 15 of the spiral turns 13 of the transverse grate 12. The longitudinal grates 16 together with the transverse grate 12, rolled into cylindrical spiral-shaped coils 13 form a stable spatial structure in which the longitudinal grates 16 not only transmit forces to the cylindrical spiral-shaped coils 13 of the transverse grate 12 from moving inside a rotating helical grating cylindrical the surface (working surface 1) of the mass of building materials, but also, since they are made (longitudinal grates 16) of a helical shape, they tighten the spiral grating cylindrical surface (working surface 1) along the inner diameter d of the turns 13 of the transverse grate 12 into a single rigid structure methods and methods of attaching longitudinal grates 16. For the reliability of the design of the working surface 1 (helical lattice cylindrical surface) and strengthening the fastening of longitudinal grates 16 with turns 13 of the transverse grate 12 it is possible to use other methods of fastening, including welding, etc.

The working surface 1 is a helical lattice cylindrical surface, may also consist of spiral turns 13 of the transverse grate 12 (11, 12), made of at least one solid bar, deformed with the formation of alternating protrusions 14 and depressions 15, for example, a triangular shape (Fig. 12), coiled into a cylindrical spiral shape of a coil 13 (Fig. 11) of a given diameter of the protrusions D and the diameter of the depressions d (Fig. 12) with a step S (Fig. 11, 12) and the formation along the entire length of the lattice cylindrical surface (work surface 1) on these ystupam helical lines 14 of the same pitch S (11), which are mounted in the longitudinal grate 20 (11, 12) twisted helical lines on the diameter D of the projections 12 with the lateral grate step S ₂ (13, 14). On Fig.13-15 one of the longitudinal grid-irons, for example Y-X ¹ , is shown by the thickened line U-21-22-23-23-X ¹ . The number of longitudinal grates 20 corresponds to the number of protrusions 14 of the spiral turns 13 of the transverse grate 12, for example, in FIG. 12 there are twelve such protrusions, and accordingly, there are twelve longitudinal grates, namely PT ¹ , C ¹ , T ¹ , U -X ¹ , F-C ¹ , H-W ¹ , C-E ¹ , W- ¹ , E- ¹ , S- ¹ , Y-P ¹ , B- ¹ (Fig. 11). On Fig shows a detailed drawing of one of the longitudinal grates 20, namely PT ¹ inserted (attached) in the protrusions 14 of the transverse grate 12.

The longitudinal grate 20 together with the transverse grate 12, rolled into a spiral-shaped cylindrical coil 13, form a stable spatial structure in which the longitudinal grate 20 not only transmit forces to the cylindrical spiral-shaped coils 13 of the transverse grate from the masses of building materials moving inside the rotating helical grating cylindrical surface 1 materials, but also, since they are made (longitudinal grates 20) of a helical shape, spiral coils 13 of the transverse spine are stretched along the outer diameter D 12, thus forming a single, integral lattice working surface 1 without additional methods and methods for attaching longitudinal grates 20 with a transverse grate 12. For the reliability of the design of a helical grating cylindrical surface - working surface 1, and strengthening the fastening of longitudinal grates 20 with turns 13 transverse grate 12, it is possible to use other methods of fastening, including welding, etc.

The working surface 1 can also be made in the form of a multi-helical helical lattice of a cylindrical surface (Fig. 16, 17) and consist of a transverse grate 12 (Fig. 16, 17) made of at least one solid bar rolled into spiral coils 13 with a round or polygonal cross-sectional shape with the formation of alternating protrusions 14 and depressions 15, for example, a triangular shape, as well as the creation along the entire length of the helical lattice cylindrical surface - the working surface 1, along these protrusions 14 and the depressions 15 screw lines of the same pitch S, the given diameter of the protrusions D and the diameter of the depressions d (Fig. 17) and the formation along the entire length of the helical lattice cylindrical surface - the working surface 1, helical lines into the hollows of which are inserted (attached), for example, longitudinal grates 24 (Fig. .17), twisted along the helical lines of diameter d of the depressions 15 of the transverse grate 12, and also longitudinal grates 25, twisted along the helical lines of diameter D and inserted from the inside into the protrusions 14 of the spiral shape of the turns 13 of the transverse grate 12. The longitudinal grates 24 in FIG. are shown by a solid main line. Longitudinal grates 25 are shown by a dash-dotted thickened line. The number of longitudinal grates 24 and 25 corresponds to the number of hollows and protrusions of the spiral turns 13 of the transverse grate 12, namely, twelve longitudinal grates 24 and twelve longitudinal grates 25. As a result of the connection of the transverse grate of a spiral shape and the longitudinal grates rolled into a screw, they are created around the perimeter of the mesh drum of the cell, which are located around the perimeter of the trellis drum not only at an angle to each other, but also to the axis of rotation of the drum 3. In this case, the variety of cell tilt angles increases also by the projections and depressions on the perimeter spiral shaped windings cross the grate, which are mounted in the longitudinal grate. The sizes of the cells of the helical lattice cylindrical surface - the working surface 1, the lattice drum 3 of the screen provide the passage of pieces of building material of the required size, can be different and depend on the pitch of the spiral turns of the transverse grate, on the number, size and cross-sectional shape of the longitudinal grates mounted in the hollows and protrusions of the turns of the cross grate, from the size and shape of the cross-section of the cross grate. As a result of connecting the transverse grate of a spiral shape and the longitudinal grates rolled up into a screw, cells are created along the perimeter of the trellised drum not only at an angle to each other but also to the axis of rotation of the drum 3. Cells are different in size and shape, for example, in FIG. 5, FIG. 11, FIG. 16, some cells are shown by a double line and are shaded.

The roar works as follows.

The masses of building materials are continuously loaded through the loading chute 9. The lattice drum 3 is rotated by the engine 6 through the gearbox 7 and gears 8 and 4. When the lattice drum 3 rotates, the spiral coils 13 of the transverse grate 12 with hollows and protrusions and longitudinal grates fixed therein form the walls of the cells of the trellis drum, working like buckets, capture portions of masses of building materials of different volumes, raise them in the direction of rotation of the trellis drum 3 slightly above the angle e natural to the slope and then directing these portions of the masses of construction materials not only under a certain angle to the axis of rotation of the drum 3 lattice, but also to other portions of such streams by weight building material at different angles and with different speeds. The length of the trajectory of the masses of building materials, more precisely, their "throw", the energy intensity of collisions of particles of masses of building materials depend on the diameter of the drum 3, on the magnitude of the angles of the cells to each other and to the axis of rotation of the trellis drum 3, on the speed of rotation of the trellis drum. Moreover, such a wavy lattice inner surface of the drum 3 allows you to increase the speed of rotation of the trellised drum in comparison with the known structures, and therefore, increase the energy intensity of the collision of the particles of the mass of building materials, increase the intensity of screening, expand the technological capabilities of the screen.

Since the frequency of collisions of particles of building materials is determined not only by the frequency of rotation of the drum 3, but also by the number of cells of the lattice surface around the perimeter of the drum 3, the proposed design of the screen provides an increase in the frequency response of the masses of building materials, expanding technological capabilities.

Moreover, due to the fact that along the length of the trellis drum 3 from loading to unloading many times (due to the different inclination of the cells of the trellis surface to each other and to the axis of rotation of the drum), the shape and dimensions of the cross section of the trellis drum 3 change, providing multiple compression of the moving masses of building materials, which increases mixing intensity, energy intensity of collisions, technological capabilities expand.

When the lattice drum 3 is rotated, the masses of particles of building materials using spiral coils 13 of the transverse grate 12 and helical longitudinal grates 16 (FIG. 5), grates 20 (FIG. 11), grates 24 and 25 (FIG. 16) perform complex spatial motion and move along helical paths from loading to unloading. Thanks to the spiral coils of the transverse grate and the screw longitudinal grates of the trellis drum 3, the velocity vectors of the particles of masses of building materials change, which contributes not only to an increase in the energy intensity of their interaction with each other and with the grates of the trellis drum 3, but also their intensive passage through the holes of the trellis drum 3 and admission to unloading devices 10 and 11.

Technical and economic advantages also arise due to an increase in the frequency and energy intensity of the interaction of particles of building materials not only with each other, but also with spiral turns of the transverse grate, with its alternating protrusions and hollows of a triangular, or rectangular, or wave-like shape, located along helical lines along the entire length of the trellis drum, due to the interaction of the masses of building materials also with longitudinal grates twisted along helical lines, which increases the intensity of the mix tions, increases the power consumption of the interaction of mass construction materials, improves performance and extends the technological capabilities of screen.

Claims (1)

A screen for classifying building materials, containing shells with grate-mounted alternating in height and installed at an angle to the axis of the drum grates, forming a grating drum, loading and unloading trays and a drive, characterized in that the grating drum is made in the form of a multi-helical screw fixed in circular shells lattice cylindrical surface mounted from a transverse grate made of at least one solid bar with a round or polygonal shape across a cross-section, deformed with the formation of alternating protrusions and depressions of a triangular, rectangular, or wave-like shape and coiled into spiral coils, while helical lines of the same pitch are created along the entire length of the helical lattice cylindrical surface, moreover, into protrusions and / or longitudinal grates with a round or polygonal cross-sectional shape, pre-twisted along the helical lines of the diameter of the hollows of the spiral turns across, are mounted and rigidly attached to the troughs grate grate.

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