RU2537443C1 - Screw drum screen - Google Patents

Abstract

FIELD: mining.SUBSTANCE: screw drum screen includes a drum, a drive, and loading and unloading devices. A drum is made along the perimeter in the form of a multi-turn screw perforated screening surface with screw grooves inside the screening surface in the form of pockets of a curved shape with centres of curvature of the pockets of the curved shape of the screw perforated screening surface, which are located inside its cross section. It is made of three and more similar perforated strips of a rectangular shape, which are twisted in longitudinal direction relative to the longitudinal axis and bent along a screw line in cross direction on a cylindrical mandrel, with formation along the screening surface perimeter of three and more internal curved perforated surfaces of a convex shape with curvature centres inside the screening surface and formation inside it of overlaps in the form of screw blades throughout the length of the screening surface from an inlet hole to an outlet hole. Throughout the length of the screening surface there mounted is a spring of a wave-like shape with a flat section of turns, which is equipped with a device for changing of a pitch of turns by its tension or compression.EFFECT: increasing screening intensity and improving efficiency.7 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. 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 in the form of a drum, 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 the need to tilt the drum to the horizon , which complicates the operation of the screen.

The technical solution to the problem is to expand technological capabilities, ensure operation of the screen without tilting to the horizon, simplifying operation, and increasing productivity.

The technical solution is achieved by the fact that in a screw drum screen containing a drum, a drive, loading and unloading devices, the drum is made around the perimeter in the form of a multiple screw perforated screening surface with screw grooves inside the screening surface in the form of curved pockets with curvature centers of curved pockets of a curved shape perforated screening surface located inside its cross section, made of three or more identical perforated strips of rectangular shape, twisted in the longitudinal direction relative to the longitudinal axis and curved in a helical direction in the transverse direction on the cylindrical mandrel, with the formation of three or more internal curved perforated surfaces of convex shape along the perimeter of the screening surface with centers of curvature inside the screening surface and the formation of voids in it in the form of screw blades along the entire length of the screening surface from the inlet to the outlet, while along the entire length of the screening surface rhnosti mounted spring wavelike shape with a flat section turns, which is equipped with a device for changing a pitch of the turns by stretching or compressing it.

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 roar screw drum.

The novelty lies in the fact that such a design of the screening surface allows for axial movement of particles of bulk material from loading to unloading with a horizontal axis of rotation, which simplifies operation due to the lack of a slope of the drum.

The novelty lies in the fact that the drum is made around the perimeter in the form of a multi-pass perforated sifting screw surface with screw grooves inside it in the form of pockets of curved shape with centers of curvature of pockets of a curved shape of a screw perforated sieving surface located inside its cross section, which increases the efficiency of screening, expands technological capabilities.

The novelty is that the screening surface is made of three or more identical perforated rectangular strips, twisted in the longitudinal direction relative to the longitudinal axis and curved in a transverse direction on a cylindrical mandrel with the formation of three or more internal curved perforated surfaces around the screening surface convex in shape with centers of curvature inside it and the formation of laps inside the screening surface in the form of helical blades along this length of the screening surface from the inlet to the outlet, which increases the efficiency of screening, expands the technological capabilities.

The novelty also lies in the fact that by twisting rectangular perforated strips in the longitudinal direction and curved in the transverse direction, curved perforated surfaces of various curvatures are formed inside the screening surface with slits inside it in the form of blades in each cross section along its length, which not only changes the trajectory of the movement of particles of materials at each point on the curved surface of the screening surface violates the stationarity of their movement, but also intensifies the percentage ess screening, expanding technological capabilities.

The novelty is due to the fact that the screening surface around the perimeter is equipped with three, four, five, six, etc. helical lines, the step of which varies from loading to unloading, and accordingly three, four, five, six, etc. helical grooves inside the screening surface with curved perforated surfaces of various curvatures with laps inside the screening surface in the form of blades, which not only increases the speed of movement of material particles from the inlet to the outlet, but also increases the swirl of their flows, increasing the frequency of their interaction with each other and with walls of the screening surface, increases the energy intensity of collisions, productivity and expands technological capabilities.

The novelty lies in the fact that thanks to the internal perforated screw surfaces of double curvature with puffs inside the screening surface in the form of blades, technological capabilities expand, the screening intensity increases, and technological capabilities expand.

The novelty is that due to the screening surface with perforated screw surfaces and inlets inside the screening surface in the form of blades, the vectors of the speed of movement of particles of materials from its inlet to outlet openings are changed, which contributes to the intensification of the screening process, expanding technological capabilities.

The novelty of the proposal also lies in the fact that inside the screening surface with a complex perforated inner surface with inlets in the form of blades at each point there are multidirectional motion components, which intensifies the screening process, expands technological capabilities.

The novelty also lies in the fact that a wave-shaped spring with a flat section of coils is mounted inside the entire length of the screening surface, which not only ensures the movement of material particles from loading to unloading, but also creates their compression inside the screening surface, which expands technological capabilities and makes the process more intense screening.

The novelty also lies in the fact that the wave-shaped spring mounted inside the screening surface is equipped with a device for changing the pitch of the turns, which allows you to influence the nature of the movement of material particles inside the screening surface and provides control of the speed of their movement from loading to unloading.

The novelty of the proposal lies in the fact that such a structural design of a screw drum screen with a wave-shaped spring fixed inside the coil with a flat section of coils not only creates countercurrent flows of material particles inside the screening surface, but also ensures their longitudinal movement from loading to unloading when it is horizontal and their intensive interaction, which expands technological capabilities, simplifies the design and operation.

The invention is illustrated by drawings, where: in Fig.1 shows a drum screw drum, general view; figure 2 - sieving surface, General view, mounted from five perforated rectangular stripes; figure 3 - section aa in figure 2; figure 4 - one of the perforated strips with a lap; figure 5 is a view of a perforated strip with an inlet after twisting its ends relative to the longitudinal axis; Fig.6 is a view of a perforated strip with an inlet after bending it on a cylindrical mandrel; Fig.7 is a section bB in Fig.6.

The screw drum screen contains a drum with a screening surface 1 fixed in circular shells 2. On one of the shells 2 there is a ring gear 3. A drum with a screening screen 1 of a screen together with circular shells 2 is mounted on the support rollers 4. On the shell having a ring gear 3 , a drive is installed, including an engine 5, a gearbox 6 and a gear 7. The screen is equipped with a loading 8 and unloading device 9 for large fractions of the material, as well as a unloading device 10 for small fractions of the material.

To provide additional longitudinal movement in the opposite direction of the material particles inside the screening surface 1, a wave-shaped spring 11 with a flat section of coils is mounted, which is equipped with a device for changing the pitch of the coils of the spring 11 by tension or compression (not shown). The direction of the turns of the spring 11 may coincide with the direction of rotation of the screening surface 1 or may be opposite to its rotation. The adjustment of the pitch of the turns of the spring 11 can also be carried out during the operation of the screw drum screen. Depending on the characteristics of the processed materials, the required processing time, a spring pitch 11 is set that meets the optimum screening conditions. For example, if a large processing time is required, then the pitch of the spring 11 is reduced and, thus, the flow of the processed materials in the opposite direction changes, which means that their movement speed from loading to unloading changes accordingly. When processing, requiring a short residence time of the processed material in the screening surface 1, the step of the turns of the spring 11 is increased and, thus, their speed of movement from loading to unloading changes accordingly. In the desired position, the spring 11 is fixed with known devices (not shown). The adjustment of the step size of the spring 11 can also be carried out during the operation of the screen.

The screening surface 1 (FIG. 2, FIG. 3) is made around the perimeter in the form of a multi-screw perforated surface with helical lines along the perimeter and helical grooves inside the screening surface 1 in the form of curved pockets, for example, in FIG. 3, five - 12, 13, 14, 15, 16.

Multiple helical hollow perforated screening surface 1 (figure 2, figure 3) is made of three or more, for example in figure 3 of five perforated strips of rectangular shape 17, 18, 19, 20, 21 with the formation along the perimeter of the screening surface 1 of an internal curved convex-shaped surfaces with centers of curvature inside the screening surface and the formation of lumps 22, 23, 24, 25, 26 (Fig. 3) in the form of screw blades along the entire length of the screening surface (in Fig. 4, the screw blades are darkened). Thus, helical grooves are formed inside the screening surface in the form of pockets of curved shape 12, 13, 14, 15, 16 with centers of curvature located inside the transverse screening surface 1 (Fig. 3).

The screening surface 1 is made of three or more perforated strips of a rectangular shape, for example in FIG. 2, FIG. 3 of five perforated strips 17, 18, 19, 20, 21. Each of the perforated strips of a rectangular shape is made with an inlet 27 and with side edges 28 and 29 (FIG. 4 shows a perforated strip 17). The inlet 27 is shown in FIG. 4, separated, for example, from the strip 17 by a dashed line 30. The strip 17 is twisted along a helical line in the longitudinal direction (FIG. 5) with respect to the longitudinal axis O ₁ -O ₁ and curved in a transverse direction on a cylindrical mandrel 31 (Fig.6, Fig.7).

Strips 17, 18, 19, 20, 21 with inlets 27 after bending are removed from the mandrel 31 and connected to each other by the lateral side 29 of one strip with a dashed line 30 of another strip by known methods, for example by welding, with the formation of a perforated hollow screening surface 1 around the perimeter helical lines and helical perforated surfaces in the form of helical grooves 12, 13, 14, 15, 16 inside the screening surface 1 and helical lines on the outer surface of the screening surface 1 with a constant step S. A part of one of the helical lines 32-33 is shown in figure 2tolschennoy line.

For example, strip 17 with its helical edge 29 (FIG. 3) is connected to strip 18 along the dashed line 30 with its convex side, for example by welding, in turn, strip 18 is connected with its helical edge 29 to strip 19 along its dashed line 30, etc. d., with the formation of a multiple screw perforated surface in the form of a hollow screening surface 1 with inlets 22, 23, 24, 25, 26 (Fig. 3) in the form of screw blades along the entire length of the screening surface 1 (in Fig. 3, the screw blades are darkened) . The twisting of each perforated strip provides an additional curvature of the inner perforated surface, the screening surface 1, due to which the swirl of the flows of the screened materials increases, the screening productivity increases, and technological capabilities expand.

Rumble screw drum works as follows.

Bulk building materials are continuously loaded into the drum with a screening surface 1 through the loading device 8. During the rotation of the drum with a screening surface 1, particles of materials are captured by the pockets of the inner screw surface 12, 13, 14, 15, 16 and in the direction of rotation are lifted by the blades 22, 23, 24, 25, 26 upward, moving towards the discharge side. Upon reaching a certain height under the influence of gravitational forces and the angle of repose formed, the particles of materials move towards each other at certain angles and to the perforated walls of the rotating drum with a screening surface 1 and move towards the discharge side. At the same time, due to pockets and blades, particles of materials rise significantly higher than in drums with a screening surface of known structures. Since the screening surface of the drum 1 is continuous, the process of movement of subsequent portions of materials that rise up and fall down, is moving at different angles. Since the pockets of the inner perforated screening surface of the drum 1 are located at an angle to the axis of rotation, then in each portion the particles of materials move along their direction vector towards the discharge side, which greatly intensifies the process of screening, breaking them into small fractions and grinding particles of material with each other with the other and with perforated walls of the screening surface 1 of the drum, the interaction of particles of materials increases and technological capabilities expand.

Since screw perforated surfaces are formed inside the drum with a screening surface 1 in the form of curved perforated pockets with blades, the range of changes in the resulting displacement vectors of material particles is significantly expanded, and each particle moves in different direction vectors, which provides a greater probability of collisions at the initial moment of separation of these particles from the perforated walls of the screening surface 1, where they have a certain supply of kinetic energy and move with pain kinetic energy, therefore, provides the intensification of the process of their destruction into small fractions. This ensures their grinding into smaller fractions and self-cleaning of the screening surface.

The presence in the design of the screw drum screw perforated surfaces in the form of perforated pockets of curved shape 12, 13, 14, 15, 16 with blades 22, 23, 24, 25, 26 intensifies the screening process, increases the reliability of the screen and expands the technological capabilities, provides self-cleaning screening surface 1.

Thus, the particles of mass of the screened materials during continuous rotation of the screening surface 1 make a complex movement, during which the screening process occurs. Particles of the mass of the screened materials not only intensively interact with each other, but also under the influence of screw perforated surfaces directed in the same direction at an angle to the longitudinal axis of the screening surface 1 in the form of curved-shaped pockets along the inner surface, make a complex movement with a large amplitude in a plane perpendicular to the passage cross-section of the screening surface 1. Since the cross-sectional dimensions along the length of the screening surface 1, the shape and location change, it is aggravated by breakability of the movement of particles of the screening material, i.e. there is an increase in the intensity of screening. The presence of screw perforated surfaces and helix lines around the perimeter of the screening surface 1 contributes not only to the complication of the trajectories of their movement, but also to the movement along the passage section of the screening surface 1. Since a spring 11 has a wave-shaped shape with a flat section of coils inside the entire length of the screening surface 1, then not only is the movement of material particles from loading to unloading ensured, but also their compression is created inside the screening surface 1, which expands the technological capabilities and tensifies screening process. When the masses of the screened material move along the cross-section of the screening surface 1, small particles pass through the screening surface 1 into the unloading device 10, and large fractions of building materials are discharged into the unloading device 9.

Technical and economic advantages arise due to the widening of the range of changes in the resulting vectors of displacement of particles of materials, increasing the intensity of their screening and reorientation, as well as the speed of their movements from loading to unloading, which increases the intensity and energy consumption of the interaction of particles of materials with each other and with perforated walls of the screening surface 1, improves productivity, expands technological capabilities, increases the reliability of the screen and its performance.

Claims (1)

A drum screw drum containing a drum, a drive, loading and unloading devices, characterized in that the drum is made around the perimeter in the form of a multiple screw perforated screening surface with helical grooves inside the screening surface in the form of curved pockets with centers of curvature of the pockets of a curved shape of a screw perforated screening surface located inside its cross section, made of three or more identical perforated strips of rectangular shape forms twisted in the longitudinal direction relative to the longitudinal axis and curved in a helical direction in the transverse direction on a cylindrical mandrel, with the formation of three or more internal curved perforated surfaces along the perimeter of the screening surface with convex centers with curvature centers inside the screening surface and the formation of screw-shaped inlets blades along the entire length of the screening surface from the inlet to the outlet, while the entire length of the screening surface is mounted a wave-shaped spring with a flat section of coils, which is equipped with a device for changing the pitch of the coils by stretching or compressing it.

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