RU57646U1 - DRUM Sieve - Google Patents

Abstract

The utility model relates to devices for separating granular materials into fractions by particle size and can be used in chemical, food, mining, agriculture and other industries, in particular, for separating granular fine dispersed mineral abrasive materials of low density into fractions. The objective of the utility model is to create a drum sieve with improved multifractional separation of particles of finely dispersed loose abrasive material of low density by improving its dispersion and movement along the screening surface, through a new implementation of the product elements and their bonds. The problem is solved due to the fact that in a drum sieve containing a cylindrical drum located in the housing with a screening surface, a rotation drive, a storage hopper, loading and unloading nozzles, respectively, of a utility model, the cylindrical drum consists of disks transversely mounted on the shaft, fastened together equally spaced from each other and rods parallel to the shaft, and installed with the possibility of rotation around its own conventional longitudinal axis of symmetry and with an inclination upward of the end, opposite to which the loading nozzle is located at an angle in the range from 4 ° to 6 ° to the horizontal, with each disk having concentrically located through holes, and the edge of each disk has concentrically located cutouts, in addition, the sifting surface of the cylindrical drum is made in the form of a mesh, covering the disks and attached to the protruding surfaces of the edges of the disks, and contains two zones differing in cell sizes, while both zones are delimited by a conditional circle located along the edge of one of the disks e, the rotary drive shaft connected to the cylindrical drum.

Description

The utility model relates to devices for separating bulk materials into fractions according to particle sizes and can be used in chemical, food, mining, agriculture and other industries, in particular, for fractioning granular fine-dispersed mineral abrasive materials of low density into fractions.

As is known, mechanical devices with elements representing a screening surface are most often used to distribute fractions of granular fine materials into fractions to limit the movement of particles of material larger than a given size.

A classifier is known that contains a housing with drain chambers and a classifying surface mounted in the housing, made in the form of a tubular lattice, and a loading tank made in the form of a body of revolution, which has a nozzle and a discharge opening (USSR copyright certificate No. 882646, IPC B 07 V 01 / 00, publ. 11/23/1981).

According to the description of the corresponding copyright certificate, during the operation of the specified classifier, the material for distribution into fractions is supplied under pressure to the loading tank, where under the influence of centrifugal forces the heavy fraction moves to the walls of the tank with the subsequent exit to the nozzle and discharge opening, and the light fraction, continuing rotation, enters the classifying surface, where further separation occurs.

Significant disadvantages of this classifier is the low efficiency of the initial separation of the heavy fraction of the material, as well as the need to use a device to create pressure, which complicates

the design of the product and leads to additional costs during its operation.

Also known is a granulometer containing a drum mounted rotatably in supports and made in the form of a bent helical spiral, a loading hopper located inside the drum, and collections of individual fractions (USSR author's certificate No. 546391, IPC B 07 V 01/00, publ. 15.02 .1977).

According to the description of the corresponding copyright certificate, during the operation of this product, when the spiral spiral is rotated, together with the hopper, the granules enter its coils and, accordingly to their size, are poured into the collections of individual fractions through the gaps between the coils.

The most significant drawbacks of the described granulometer are the complexity of the manufacturing process and maintenance during operation, due to the complexity of the execution and placement of the elements of the device. In addition, the use of this product to distribute fractions of abrasive bulk material will lead to rapid wear of the surface of the helical spiral.

The closest in technical essence to the claimed drum sieve and chosen as the closest analogue is a device for sifting bulk materials containing a cylindrical drum for sifting located in the housing, inside of which is placed a rotor in the form of a helical spiral with rounded working edges of the coils, connected with a rotation drive (USSR copyright certificate No. 1613199, IPC В 07 В 01/20, publ. 15.12.1990).

According to the description to the indicated copyright certificate, distribution vanes are fixed on the inner surface of the helical spiral of this device. The device is provided with a storage hopper, inlet and outlet pipes.

During the operation of the device, bulk material flows through the inlet pipe into the middle of the cylindrical drum, where it is captured

turns of the rotor and moves along the screening surface of the cylindrical drum.

Signs of the closest analogue that coincide with the essential features of the proposed utility model are the presence of a cylindrical drum located in the housing with a screening surface, a rotation drive, a storage hopper, loading and unloading nozzles.

The most significant drawback of the described device is that with an increase in the content of the fine fraction in the starting material, it is carried out by a helical spiral, as a result of which the accuracy of separation into fractions is significantly impaired.

In addition, the use of this device for separating into fractions of finely divided material of low density, the particles of which are in the form of hollow spheres, the destruction of the particles of the material occurs, which does not provide the desired product.

In addition, the use of the described device for sifting abrasive material will lead to significant wear of the helical spiral and, consequently, the rapid failure of the product.

The objective of the utility model is to create a drum sieve with improved multifractional separation of particles of finely dispersed loose abrasive material of low density by improving its dispersion and movement along the screening surface, through a new implementation of the product elements and their bonds.

The problem is solved due to the fact that in a drum sieve containing a cylindrical drum located in the housing with a screening surface, a rotation drive, a storage hopper, loading and unloading nozzles, respectively, of a utility model, the cylindrical drum consists of disks transversely mounted on the shaft, fastened together equally spaced from each other and rods parallel to the shaft, and mounted rotatably around its own

conditional longitudinal axis of symmetry and with an upward inclination of the end, opposite which the loading nozzle is located, at an angle in the range from 4 ° to 6 ° to the horizontal, each disk containing concentrically located through holes, and the edge of each disk has concentrically located cutouts, moreover the sifting surface of the cylindrical drum is made in the form of a grid covering the disks and attached to the protruding surfaces of the edges of the disks, and contains two zones differing in cell sizes, while both zones are demarcated They are provided with a conditional circle located along the edge of one of the disks; in addition, the rotation drive is connected to the shaft of the cylindrical drum.

It is these signs that are necessary and sufficient to solve the task.

In addition, the storage hopper is divided by a partition into two chambers, while the partition is made so that its upper part is in the plane of the conditional circle delimiting the two zones of the grid, and the lower part of each of these chambers has a separate discharge opening.

At the same time, the loading nozzle is made with a downward inclination of the output part so that the center of its outlet is located on a conditional longitudinal axis of symmetry of the shaft of the cylindrical drum.

In addition, the end face of the cylindrical drum, opposite which the loading nozzle is located, is made with an end wall in the form of a truncated cone, the apex of which is directed outward and the base of a smaller diameter contains a hole that coincides with the outlet of the loading nozzle.

It is the implementation of a cylindrical drum with disks transversely mounted on the shaft, fastened by rods equally spaced from each other and parallel to the shaft, that makes it possible to create a reliable chamber for the efficient movement of bulk material during its rotation, as well as provide restraining

longitudinal movement of particles of the material of the zone, thereby increasing the efficiency of sieving.

The presence in each disk of concentrically located through holes and concentrically located on the edges of the cutouts allows optimal conditions for the movement of particles of bulk material along the cavity of a cylindrical drum.

The installation of a cylindrical drum with the possibility of rotation around its own conventional longitudinal axis of symmetry and with an upward inclination of the end face opposite which the loading nozzle is located at an angle in the range from 4 ° to 6 ° to the horizontal, as well as the connection of the rotation drive to the shaft of the cylindrical drum, allows for optimal the movement and distribution of particles of bulk material on the inner surface of a cylindrical drum due to the action of gravitational and centrifugal forces and to avoid the destruction of material particles .

Due to the screening surface of the cylindrical drum in the form of a grid covering the disks and attached to the protruding surfaces of the edges of these disks, containing two zones with different cell sizes, and the separation of these zones with a conditional circle located along the edge of one of the disks, it is possible to ensure multifractional separation of bulk material .

The separation of the hopper by a partition into two chambers in such a way that the upper part of this partition is in the plane of the conditional circle delimiting the two zones of the grid, and the execution of each of these chambers with a separate discharge opening ensures the efficiency and reliability of multifractional separation of bulk material.

The implementation of the loading pipe with a downward inclination of the output part so that the center of its outlet is located on the conditional longitudinal axis of symmetry of the shaft of the cylindrical drum, and also, the end of the cylindrical drum, opposite which is located

a loading nozzle with an end wall in the form of a truncated cone, the apex of which is directed outward and the base of a smaller diameter contains an opening that matches the outlet of the loading nozzle, which ensures uniform flow and distribution of bulk material over the surface of the cavity of a cylindrical drum and eliminates the possibility of formation of congestion.

The essence of the utility model is illustrated by drawings, where:

figure 1 shows a front view of a drum sieve;

figure 2 shows a General view of a cylindrical drum drum sieve.

One of the possible embodiments of the drum sieve consists of a housing 2 located on the frame 1, inside of which, in the upper part, on the shaft 3, a cylindrical drum 4 is installed. The lower part of the housing 2 is a hopper divided by a partition 5 into two parts to form a chamber 6 and cameras 7. The shaft of the cylindrical drum 4 is connected to the gear motor 8, which is also mounted on the frame 1.

The cylindrical drum 4 contains seven transversally mounted on the shaft 3 disks 9, fastened by six equally spaced from each other and parallel to the shaft rods 10. Each of these disks 9 is formed by connecting a flat metal hexagon 11 with six wooden segments 12. Moreover, each metal hexagon 11 contains a significant number of concentrically arranged through holes 13, and the edge of each disk, with the exception of one extreme, is formed by wooden segments 12 containing numerous concentrically located cutouts 14. The specified extreme disk, the edge of which does not contain cuts, is connected to the end wall 15 of the cylindrical drum 4. The end wall 15 is made in the form of a truncated cone, the apex of which is directed outward and the base of a smaller diameter contains a hole. The surface of the cylindrical drum 4 is formed by a grid 16, covering the disks 9 and attached to the protruding surfaces of the edges of the disks, containing a zone 17 and a zone 18, which

differ in cell sizes, while both zones are delimited by a conditional circle located along the edge of the disk located in the center of the shaft 3. Zone 17, which is located on the side of the end wall 15, has cells smaller than the cells of zone 18.

The shaft 3 of the cylindrical drum 4 is mounted in bearings 19 with a rotary bearing mounted on the end walls of the housing 2, with the possibility of rotation and tilting upward of the part with the end wall 15 at an angle in the range from 4 ° to 6 ° to the horizontal.

The end wall of the housing 2 contains a loading pipe 20 mounted with a downward inclination of the output part so that its output opening coincides with the hole of the end wall 15 of the cylindrical drum 4. On the inner surface of the opposite end wall of the housing 2, below the shaft 3, the output pipe 21 is installed, pointing down.

The partition 5, which separates the lower part of the housing 2 into the chamber 6 and the chamber 7, is made in such a way that its upper part is in the plane of the conditional circle delimiting the two zones of the grid 16. In this case, the lower parts of the chambers 6 and 7 are narrowed to the center due to inclined surfaces, which contains the discharge pipes 22 and 23, respectively.

The work of the drum sieve is as follows.

After starting the gear motor 8, which rotates the cylindrical drum 4, bulk material is fed through the loading pipe 20, which moves along the inner surface of the pipe and the end wall 15 and enters the cavity of the cylindrical drum 4. Given the angle of inclination and due to the rotation of the cylindrical drum 4, under the action of gravitational and centrifugal forces, particles of bulk material begin to move to the opposite end of the cylindrical drum and disperse along the surface of its cavity. Particles of material pass through holes 13 and cutouts 14 of disks 9,

which form a zone of delay in the longitudinal movement of the flow of bulk material for more thorough sifting through the mesh cells 16.

Moreover, in the process of longitudinal movement of bulk material, particles of material with a size smaller than the size of the cells of zone 17 enter the chamber 6, while others move further and those that are smaller than the size of the cells of the zone 18 fall into the chamber 7, and those that are not sifted in zones 17 and 18 fall into the outlet pipe 21.

Through the discharge pipes 22 and 23 of the housing 2, the bulk material of the obtained fractions is discharged from the chambers 6 and 7, respectively.

The implementation of the elements and bonds of the drum sieve described above, can significantly increase the efficiency of multifraction separation of particles of finely divided loose abrasive material of low density, as well as provide a non-destructive screening process.

Claims (4)

1. A drum sieve containing a cylindrical drum located in the housing with a screening surface, a rotation drive, a storage hopper, loading and unloading nozzles, characterized in that the cylindrical drum consists of disks transversely mounted on the shaft, fastened together by rods equally spaced from each other and parallel to the shaft, and installed with the possibility of rotation around its own conventional longitudinal axis of symmetry and with an upward inclination of the end, opposite which the loading pipe is located, at an angle in the range e from 4 to 6 ° to the horizontal, with each disk containing concentrically located through holes, and the edge of each disk having concentrically located cutouts, moreover, the sifting surface of the cylindrical drum is made in the form of a mesh covering the disks and attached to the protruding surfaces of the edges of the disks, and contains two zones differing in cell sizes, while both zones are delimited by a conditional circle located along the edge of one of the disks, in addition, the rotation drive is connected to the shaft of a cylindrical Rabban. 2. The drum sieve according to claim 1, characterized in that the storage hopper is divided by a partition into two chambers, the partition being made in such a way that its upper part is in the plane of the conditional circle delimiting the two mesh zones, and the lower part of each of these chambers has a separate discharge opening. 3. The drum sieve according to claim 1, characterized in that the loading nozzle is made with a downward inclination of the outlet so that the center of its outlet is located on the conditional longitudinal axis of symmetry of the shaft of the cylindrical drum. 4. The drum sieve according to claim 1, characterized in that the end face of the cylindrical drum, opposite which the loading nozzle is located, is made with an end wall in the form of a truncated cone, the apex of which is directed outward, and the base of a smaller diameter contains an opening that matches the outlet of the loading nozzle .