RU2533407C1 - Pass-through screen - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: pass-through screen comprises a deck plate, drive, loading and unloading devices. The deck plate is formed by the sections series connected to each other along the deck plate by their end polygonal holes. Each section is assembled from two subsections. The first subsection along the perimeter is formed by even amount (minimum four) of identical first isosceles perforated triangles series connected by their lateral sides to the lateral sides of minimum four identical second isosceles perforated triangles, the bases of which are greater than the bases of the first four isosceles perforated triangles with formation of small and large end polygonal holes. The second subsection is mounted from series connected along the perimeter four (minimum) identical isosceles perforated triangles with the lateral sides equal to the bases of the second isosceles perforated triangles of the first subsection with the lateral sides of four (minimum) identical isosceles perforated triangles with the apex angle 90° with forming of small and large end polygonal holes. The large end polygonal hole of the first subsection is equal to a small end polygonal hole of the second subsection. Along the length of the deck plate a conic spring with a flat section of turns is mounted, which is fitted with a device for changing of pitch of turns by means of its extension or compression.

EFFECT: increasing screening intensity and improving efficiency.

9 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 (AS USSR No. 613830, class B07B 1/22, 1976) containing a screening surface, drive, loading and unloading devices.

A disadvantage of the known screen is the 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 for length.

Closest to the proposed invention is a walk-through screen (RF patent No. 2456094, class B07B 1/22, 2012) containing a screening surface mounted from sections made of eight, ten, twelve, etc. an even number of equilateral triangles connected by two lateral sides, while the sections are connected to each other by the free third sides of the triangles with the formation of a helical drum, along the perimeter of which are four, five, six or more broken right and left helical lines directed towards each other and equipped with internal four, five, six or more helical grooves directed towards each other with the same pitch.

The drawback of a passing screen is the limited technological capabilities due to low productivity due to the low mixing intensity, since during rotation of the drum there is a sliding of the screening mass in the same size and shape of the elements of the inner surface of the screening surface, as well as the need to create a slope of the screening surface for transporting material from loading to unloading.

The technical solution to the problem is to expand technological capabilities, increase productivity and ensure the transportation of material from loading to unloading by increasing the size of the passage polygonal section of the screening surface from loading to unloading.

The technical solution is achieved by the fact that in the screening passage containing the screening surface, the drive, loading and unloading devices, the screening surface is mounted from sections alternately connected to each other along the length of the screening surface with their end openings in the form of polygons, each of the sections is assembled from two subsections, the first perimeter subsection is mounted from an even number of at least four identical first isosceles perforated triangles, alternately connected by their sides sides with sides of at least four identical second isosceles perforated triangles, the bases of which are larger than the bases of the first four isosceles perforated triangles with the formation of small and large end holes in the form of polygons, and the second subsection is mounted from at least four identical equilateral perforated triangles alternately connected along the perimeter with sides equal to the bases of the second isosceles perforated triangles of the first th subsection with the sides of at least four identical isosceles perforated triangles with an apex angle of 90 ° with the formation of small and large end holes in the form of polygons, and the large end hole in the form of a polygon of the first subsection is equal to the small end hole in the form of a polygon of the second subsection, the subsections are connected to each other in the section by their end openings in the form of polygons and a conical spring is mounted along the entire length of the screening surface with a flat section of turns, which is equipped with a device for changing the 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 screen roar.

The novelty is also seen in the fact that the area and cross-sectional shape of the screening surface increases in length from loading to unloading due to the conditionally conical shape of the screening surface, which not only intensifies the screening process, since it violates the stationary motion of the flows of the screened materials, changing the vibration amplitude as their movement, but also provides their movement in the axial direction, expands technological capabilities.

The novelty of the invention lies in the fact that since the frequency of movement of particles of the screening material in the proposed structures is determined not only by the frequency of rotation of the screw drum of the screening surface, but also by the number of flat elements around the perimeter of the screw drum, such a structural design of the drum surface due to an increase in the number of flat elements in each section along the perimeter increases for each revolution of the screening surface the frequency of collisions of particles of screened materials between the wallpaper and the walls of the screw drum, screening improves performance, increases the technological possibilities.

In addition, the novelty is due to the fact that the elements from which the screening surface is assembled are mounted at certain angles to each other, therefore the intensity of the interaction of materials increases, since these elements, working as shelves, capture portions of the screened material, direct them towards each other, on the walls of the screens moving on the opposite side of the walls, violating in this way not only the stationarity of their movement, but also providing self-cleaning of the sieve openings, expand technological capabilities.

The novelty is seen in the fact that the cross-sectional area and shape of the screening surface changes in each cross-section from loading to unloading, which intensifies the mixing process, increases the energy intensity of interaction of material particles with each other and with the walls of the screen, and expands technological capabilities.

The novelty also lies in the fact that the cross-sectional cross-section of the screening surface has the shape of a polygon, the area of which along the length of the screening surface varies many times from loading to unloading, providing periodic compression of the mass of the screened material, which increases the intensity of mixing and the energy intensity of collisions, expanding technological capabilities.

The novelty is due to the fact that the screening surface is equipped with four, five, six, etc. screw broken lines of equal pitch, directed towards each other along the perimeter and, accordingly, four, five, six, etc. screw grooves inside the screening surface, also directed towards each other, which ensures the creation of streams of screened materials directed towards each other with maximum energy intensity of particle collisions with each other and with the walls of the screening surface at different angles, increases the frequency of interaction of the particles of the screened material with each other and with walls of the screening surface, increases screening productivity and expands technological capabilities.

The novelty is seen in the fact that the area and shape of the cross-section and longitudinal sections of the screening surface vary along the entire length, from loading to unloading, which changes the speeds and trajectories of movement of the screened materials, and expands technological capabilities.

The novelty lies in the fact that thanks to mutually directed broken helical lines, the vectors of the velocity of particles of the screened material during transportation from load to unload change, which helps to intensify the screening process and expands technological capabilities.

The novelty also lies in the fact that along the inner perimeter of the screening surface, broken helical surfaces are formed along the length of the screening surface, which violates the stability of their flows inside the screening surface, increases the intensity of screening, and enhances technological capabilities.

The novelty of the proposal also lies in the fact that a conical spring with a rectangular coil section and a coil direction matching or opposite to the rotation direction of the screening surface is mounted along the entire length of the screening surface, which ensures not only the movement of particles of the screened materials in a radial direction, the same or opposite direction the slope of the conditionally conical shape of the screening surface, but also contributes to the intensification of the screening process due to the fact that Particles of materials circulating inside the screening surface in planes perpendicular to its axis of symmetry, meeting with rectangular coils of a conical spring, change their motion path and move to the periphery of the screening surface, increase the intensity of their interaction with each other and with the perforated walls of the screening surface, expand technological capabilities.

The novelty also lies in the fact that a spring of a conical shape, mounted along the entire length of the screening surface, with a rectangular section of coils, is equipped with a device for changing the pitch of the coils by stretching or compressing it, which allows you to influence the nature of the movement of particles of the screened material and change their speed of movement from loading to unloading, expanding technological capabilities.

The novelty also lies in the fact that the direction of the coils of a spring of a conical shape with a rectangular cross-section of coils coincides or may be opposite to the direction of rotation of the screening surface, which ensures the creation of counter-directed flows of movement of particles of the screened material, increases the intensity of screening, and extends technological capabilities.

The invention is illustrated by drawings, where figure 1 shows the roar of the passage, General view; figure 2 is a section aa in figure 1; figure 3 - screening surface conditionally conical shape; figure 3 is a screening surface, front view; figure 4 is a view of B in figure 3; figure 5 is a view In figure 4; figure 6 is a first subsection, a visual image; in Fig.7 - the second subsection, a visual image; on Fig - assembly diagram of a section of two subsections, a visual image; Fig.9 is a diagram of the assembly of sections with each other in a sieving surface.

The roar of the passage (Fig. 1, 2) consists of a screw drum 1, a loading pin 2 with a loading device 3, a loading pin 4 with a discharge device 5 for large fractions and a discharge device 6 for small fractions.

The screening surface 1 (Figs. 3, 4, 5) is mounted from sections 7, alternately connected to each other by their end holes in the form of polygons. Each section is assembled from two subsections 8 and 9.

The first subsection 8 (Fig.6) around the perimeter is mounted from an even number of at least four identical first isosceles triangles 10, alternately connected along the perimeter of subsection 8 with their sides with the sides of the same four second isosceles triangles 11, whose bases 12 are larger than the bases 13 of the first isosceles triangles 10. At the ends of subsection 8, a small end hole in the form of a polyhedron 14 and a large end hole in the form of a polygon 15 are formed.

The second subsection 9 (Fig. 7) is mounted around the perimeter of at least four identical equilateral triangles 16, the sides of which are equal to the base 12 of the second isosceles triangles 11 of the first subsection 8, alternately connected along the perimeter with their sides and sides of at least four identical isosceles triangles 17 with an apex angle of 90 °. At the ends of the subsection 9, a small end hole in the form of a polyhedron 18 and a large end hole in the form of a polyhedron 19 are formed.

In the section of subsections 8 and 9 are mounted (Fig. 8) by the sides of the large end hole 15 with the sides of the small end hole 18 of the subsection 9.

The screening surface 1 is mounted (Fig. 9) by attaching a large end hole in the form of a polyhedron 19 of the first section 7 to a small end hole 18 of the second section 7. Sections 7 of the first, second and subsequent are the same in shape and assembly, but different in size. Thus, a screening surface 1 of conditionally conical shape with mutually directed broken helical lines is mounted.

For example, in FIG. 3, one of the right broken helical lines is shown by a thickened line 20-21-22-23-24 and one of the left broken helical lines is shown by a thickened line 25-26-22-27-28.

Broken helical lines form along the inner perimeter of the screening surface 1 broken helical surfaces consisting of faces in the form of equilateral and isosceles triangles 10 and 11 of the first subsection 8, and equilateral triangles 16 and isosceles triangles 17 of the second subsection 9.

Helix lines on the outer surface of the screening surface 1 have the same position designations with their corresponding grooves on the inner surface.

Since subsection 8 has a small end hole 14 and a large end hole 15 and subsection 16 has a small end hole 18 and a large end hole 19, sections 8 have variable longitudinal and variable bore sections along the entire length of the conditionally conical shape of the screening surface resulting from the assembly one.

A conical spring 29 with a rectangular coil section and a coil direction matching or opposite to the rotation direction of the screening surface, which provides not only radially moving particles of screened materials in the opposite direction of the slope of the conical screening surface 1, is mounted along the entire length of the screening surface 1, but also contributes to the intensification of the screening process due to the fact that particles of the screening material, making a circulating movement inside sifting surface in planes perpendicular to its axis of symmetry, meeting with coils of rectangular shape of a conical spring 29, change the trajectory of their movement and move to the periphery of the sifting surface 1, increase the intensity of their interaction with each other and with the perforated walls of the sifting surface 1, expand technological capabilities.

The roar of the checkpoint works as follows.

The screening surface 1 is filled with a screening material. When the screening surface 1 rotates, flat elements - equilateral perforated triangles mounted around the perimeter of the screw drum are differently inclined to the axis of rotation of the screening surface 1 and to each other, working as buckets (shelves), capture portions of screens of various sizes in volume, lift them in the direction of rotation of the screening machine surface 1 is slightly higher than the angle of repose, and then these portions of screened material are directed in the directions perpendicular to these shelves (buckets), under some not only the angle to the rotational axis of the screening surface 1 but also to the other mass flows by weight grohotimogo material moving inside the sieve surface 1 at different angles and with different speeds. The length of the trajectory of movement (amplitude) of the masses of the material largely depends on the diameter of the screening surface 1, on the angles of inclination of the flat perforated elements to each other and to the axis of rotation. The frequency of movement and collisions of the masses of material is determined not only by the rotation frequency of the screening surface 1, but also by the number of flat perforated elements around the perimeter of the screening surface 1. Therefore, the proposed design of the screen of the walk-through ensures an increase in frequency characteristics by a factor of tens, and technological capabilities are expanded. Since the shape and dimensions of the cross section having the shape of a polygon change many times along the length of the screening surface 1 from loading to unloading, multiple periodic compression of the masses of the screened material is ensured, which increases the intensity of mixing, the energy intensity of the collisions, and extends technological capabilities. Thus, when the screening surface rotates, the classified material makes difficult spatial motion along helical trajectories, the material is classified by size and intensively segregated.

Technical and economic advantages arise due to an increase in the frequency of interaction of the screened material not only with each other, but also with the walls of the screening surface, which increases the intensity of screening, increases the energy intensity of the interaction of particles of the screened material, increases productivity and expands technological capabilities.

In other words, the roar of the gate works as follows.

In the rotating screening surface 1 through the means for loading 3 continuously loaded screen material. When the rotating surface 1 rotates, the particles of the screening material move along the helical grooves and are discharged from the screening surface 1 into the unloading device 5. Small particles of the screening material are discharged through the perforated holes of the triangles of sections 7 and subsections 8 and 9 into the unloading device 6.

When the screening surface 1 rotates, particles of the screened material are captured by the faces of the internal screw surface and in the direction of rotation rise up and move to the discharge side. Upon reaching a certain height under the influence of gravitational forces and the angle of repose formed, the particles of the screened material move towards each other at certain angles and to the walls of the rotating screening surface 1 and move towards the discharge side. Since the broken inner surface of the screening surface 1 is continuous, the process of movement of subsequent portions of the screened material, which rise up and fall down, moves at different angles. Since the inner surface of the screening surface 1 is mounted from different in shape equilateral and isosceles perforated triangles that are located at different angles not only to each other, but also to the axis of rotation of the screening surface 1, each portion of the particles of the screened materials moves in its direction vector to the side unloading, which significantly intensifies the process of interaction of particles of screening materials with each other and with the walls of the screening surface 1, increases the int Screening intensity and expand technological capabilities. Since, due to the broken shape of the inner surface of the screening surface 1, the range of changes in the resulting displacement vectors of particles of the screened materials is significantly expanded, each particle of the screened material moves along different direction vectors, which provides a greater chance of collisions at the initial moment of their separation from the walls of the screening surface 1 , where they have a certain supply of kinetic energy and move with high kinetic energy, therefore, the process is intensified screening.

The speed of movement of the workpieces is determined not only by the conicity of the conditionally conical shape of the screening surface 1, but also by the step size of the spring 29, the turns of which coincide or are opposite to the screening surface 1.

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

Claims (1)

A screen rumble containing a screening surface, a drive, loading and unloading devices, characterized in that the screening surface is mounted from sections alternately connected to each other along the length of the screening surface with their end openings in the form of polygons, each section is assembled from two subsections, the first subsection is the perimeter is mounted from an even at least four identical first isosceles perforated triangles, alternately connected by their sides with the side sides of at least four identical second isosceles perforated triangles, the bases of which are larger than the bases of the first four isosceles perforated triangles with the formation of small and large end holes in the form of polygons, and the second subsection is mounted from at least four identical equilateral perforated triangles alternately connected along the perimeter with the sides, equal bases of the second isosceles perforated triangles of the first subsection with lateral at least four identical isosceles perforated triangles with an apex angle of 90 ° with the formation of small and large end holes in the form of polygons, and the large end hole in the form of a polygon of the first subsection is equal to the small end hole in the form of a polygon of the second subsection, while the subsections are connected to each other another in the section with its end openings in the form of polygons and along the entire length of the screening surface mounted conical spring with a flat section of coils, otorrhea equipped with a device for changing a pitch of the turns by stretching or compressing it.

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