RU2572141C1 - Inertial thickener - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: inertial thickener comprises a housing, in which there are fixed helical guides, a perforated filter, a loading device, a device for removing the filtrate and thickened fraction. The filter is mounted from the perforated sections connected successively and alternately. The first section is made of two perforated sub-sections, one of which is mounted of two large scalenous perforated triangles connected with their bases to the lateral sides of the large equilateral perforated trapezium, and the second perforated sub-section is assembled from a small equilateral perforated trapezium, which lateral sides are connected to two small scalenous perforated triangles with their smaller lateral sides, the bases of which are equal to large lateral sides of the perforated triangles of the first perforated sub-section, which connect the perforated sub-sections to each other.

EFFECT: increase in productivity, increase in technological capabilities of the device.

9 dwg

Description

The invention relates to agriculture, in particular to equipment for separating the waste of feeding and feeding complexes into liquid and solid phases suitable for transportation to fields as fertilizers in liquid or solid state, to the food industry, for example, for dehydration of raw materials in the production of pectin, separation of the liquid phase from bulk materials, when drying materials.

Known inertial thickener (AS No. 1389815, class B01D 33/02, 1988), comprising a housing with a cylindrical filter installed in it, an inlet pipe, a screw insert and pipes for draining the filtrate and condensed fraction.

A disadvantage of the known design is low productivity and limited technological capabilities.

Closest to the proposed invention is an inertial thickener (patent No. 2496552, class B01D 33/27, 2013), including a housing with a filter installed inside it, an inlet pipe, a screw insert and nozzles for draining the filtrate and condensed fraction, while the filter is multi-start , conical and mounted from sections in the form of polyhedra, assembled from alternately connected along the perimeter of perforated equilateral and perforated isosceles triangles, alternately assembled with their free sides to each other .

A disadvantage of the known design is the lack of performance and limited technological capabilities.

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

The problem is achieved in that in an inertial thickener, including a housing, inside which screw guides are fixed,

a perforated filter, a loading device, devices for draining the filtrate and thickened fraction, a perforated filter is mounted from perforated sections made in various shapes and sizes, increasing from loading to unloading, connected in series and alternately, while the first perforated section is made of two perforated subsections, one of which is mounted from two large different-sided perforated triangles connected by their bases to the sides of the large equatorial perforated trapezoid, and the second perforated subsection is mounted from a small equilateral perforated trapezoid, to the sides of which are attached two small miscellaneous perforated triangles, the bases of which are equal to the large sides of the perforated triangles of the first perforated subsection, by which the perforated subsections are connected to each other moreover, the upper bases of the perforated trapezoid of two perforated subsections are equal to each other are equal to the small sides of the perforated triangles of the first perforated subsection to form a small inlet of the perforated section, and the lower bases of the perforated trapezoid are equal to each other and equal to the large sides of the perforated triangles of the second perforated subsection to form a large outlet of the perforated section to which the second perforated section is attached, made in the form of a straight triangular perforated prism formed by a cube section along d Iagonals.

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

The novelty of the invention lies in the fact that by increasing the flow area of the perforated filter from loading to unloading, i.e. conditionally conical shape of a perforated filter, the stationary motion is disrupted, the productivity of separating the liquid phase from the material is increased, technological capabilities are expanded.

The novelty is that the elements from which the perforated sections and perforated subsections of the perforated filter are assembled are different in shape and size, therefore the stationarity of movement is violated, the productivity of separating the liquid phase from the material is increased, since these elements, working like shelves, capture different in the volume of a portion of the material, for example, manure, directing them to the walls of the perforated filter, which expands the technological capabilities.

The novelty is also due to the fact that since the number of visits of screw broken lines of the main direction is twice as large as the number of screw broken lines of the opposite direction and the pitch of these helical lines increases from loading to unloading, an increase in productivity is provided, and technological capabilities are expanded.

The novelty also lies in the fact that the centers of symmetry of each cross section of the perforated filter along its length are displaced not only relative to each other, but also relative to the axis of rotation of the perforated filter, which provides a significant increase in the energy intensity, intensity and frequency of interaction of material particles and extends technological capabilities.

The novelty is also due to the fact that the elements from which the perforated sections of the perforated filter are assembled, different in area, size and configuration, interact with moving particles of material, are directed to each other at certain angles and therefore direct these particles at different angles, which increases the intensity of separation liquid phase from a material, energy intensity, amplitude and frequency of interaction of material particles and expands technological capabilities.

The novelty also lies in the fact that since the length of the perforated filter changes not only the dimensions of the passage section, but also the shape of the passage section, which increase from loading to unloading, the process of separation of the liquid phase from the material is intensified, the amplitude of oscillations of the particles of the material increases, t .e. the length of the path of their movement to meet other portions of particles of material increases, productivity increases and technological capabilities expand.

The novelty of the invention lies in the fact that, since the frequency of movement of the material flows in the proposed design of the inertial thickener is determined not only by the frequency of rotation of the perforated filter, but also by the number of perforated flat elements around its perimeter, such a structural design of the surface of the perforated filter by increasing the number of perforated flat elements in each section along the perimeter increases the frequency of collisions of manure flows between themselves and with the walls of the perforation vannogo filter improves drainage performance of the material increases the technological possibilities.

In addition, the novelty is due to the fact that the flat perforated elements from which the perforated filter is assembled are mounted at some different angles to each other, so the intensity of dewatering of the material increases, since these perforated elements, working like shelves capture portions of the material flows and direct them towards each other, thus violating the stationarity of their movement, providing increased dehydration performance and expanding technological capabilities.

The novelty is that the area and cross-sectional shape of the perforated filter changes in each cross-section along its entire length from loading to unloading, which intensifies the dehydration of the material, increases the energy intensity of the interaction of material flows, increases productivity, and expands technological capabilities.

The novelty is that the area and shape of the elements from which the perforated filter is assembled, including perforated trapezoid and perforated triangles, change in its entire length from loading to unloading, which intensifies the dehydration of the material, increases the energy intensity of the interaction of material flows, increases performance, expanding technological capabilities.

The novelty is also due to the fact that not only perforated isosceles triangles and perforated isosceles trapezoid, from which subsections of perforated sections of the perforated filter are assembled, but the perforated sections themselves are mounted at some angles to each other with the formation of broken helical lines, which increases the energy intensity and changes the frequency of interaction particles of material with each other and with the walls of a perforated filter, which expands technological capabilities.

The novelty also lies in the fact that the cross section of the perforated filter has the shape of a polygon, the area of which varies many times in length from loading to unloading, providing periodic compression of the masses of the material flows, which increases the intensity of dehydration of the material and the energy intensity of the collisions, expands technological capabilities.

The novelty is also seen in the fact that the area and shape of the cross-section and longitudinal sections of the perforated filter change along the entire length from loading to unloading, which changes the speeds and trajectories of material flows, and expands technological capabilities.

The novelty also lies in the fact that along the perimeter of the perforated filter helical perforated surfaces are formed from flat perforated elements of various shapes and sizes, which ensures a violation of the stationary flow of the material inside the perforated filter and intensifies the dehydration process, expands technological capabilities.

The invention is illustrated by drawings, where: in FIG. 1 schematically shows an inertial thickener, a longitudinal section; in FIG. 2 is a section AA in FIG. one; in FIG. 3 - perforated filter, general view, front view; FIG. 4 - perforated filter, top view of FIG. 3; FIG. 5 - the first perforated section of the perforated filter assembly, axonometric projection; FIG. 6 - the first perforated filter subsection of the first perforated section of the perforated filter assembly, axonometric projection; FIG. 7 - second perforated subsection of the perforated filter of the first perforated section of the perforated filter, axonometric projection; FIG. 8 - second perforated section of a perforated filter, axonometric projection; FIG. 9 is a diagram of an assembly of a perforated filter from sections.

The inertial mixer contains a frame 1, made in the form of a welded frame. A drive is mounted on the bed, consisting of an electric motor 2, a chain drive 3 and two pairs of roller bearings 4 and 5, on which two circular shells 6 and 7 are mounted, in which a housing 8 is fixed with a perforated filter coaxially mounted in it 9. The housing 8 is made in in the form of a cylinder, inside of which screw guides 10 are fixed, and is provided with perimeter holes 11 for draining the liquid phase from the filter.

The section of the outer drum 8 with holes 11 is mounted in the casing 12, which in its lower part is equipped with a window 13 - the outlet pipe. On the bed 1 mounted boot device in the form of a funnel 14 - (inlet). The device is equipped with a conveyor 15 for receiving the solid phase of the material, for example, manure - (pipe for draining the condensed fraction) and a tank 16 for receiving the liquid phase of the material, for example, manure.

The perforated filter 9 (Fig. 3, Fig. 4) is mounted from two different perforated sections alternately connected - the first perforated section - A (Fig. 5) and the second perforated section - B (Fig. 8) and is equipped with multidirectional broken conical helical lines with variable along the length of the perforated filter 9 step S ₁ and S ₂ . The pitch of four broken conical helical lines S ₁ , one of which is shown in FIG. 3, FIG. 4 with a thickened line 17-18-19-20-21-22-23-24-25-26 twice the pitch of two broken conical helical lines of the opposite direction S ₂ , one of which is shown in FIG. 3, FIG. 4 double line -27-28-29-30-31-21-22-32-33-34-35-36-37-38.

Perforated sections A and B differ from each other not only in shape but also in size. The first perforated section A (Fig. 5) is mounted from two perforated subsections 39 (Fig. 6) and 40 (Fig. 7) connected to each other by sides. 41 and 42 (Fig. 5). The perforated subsection 39 (Fig. 6) is mounted from a large equilateral perforated trapezoid 43 and two different-sided perforated triangles 44 and 45, the bases of which are equal to the sides of the perforated trapezoid 43, along which they are connected at an angle of 90 °. The sides 46 and 47 of the perforated triangles 44 and 45 are equal to the upper perforated base 48 of the perforated trapezoid 43 with the lower base 49. The second perforated subsection 40 (Fig. 5) is mounted (Fig. 7) from a small equilateral perforated trapezoid 50, which is connected by its lateral sides 51 and 52 at an angle of 90 ° with the small sides of the perforated triangles 53 and 54. The large sides 55 and 56 of the perforated triangles 53 and 54 are equal to the lower base 57 of the small perforated trapezoid 50 and the lower base 49 ( Fig. 6) a large perforated trapezoid 48 with the formation of a large outlet of the first perforated section. The upper base 58 of the small perforated trapezoid 50 of the second perforated subsection (Fig. 7) is equal to the upper base 48 of the perforated trapezoid 43 and the sides 41 and 42 of the perforated triangles 44 and 45 of the first perforated subsection (Fig. 6) to form a small inlet of the first perforated section. Therefore, when connecting the perforated subsections 39 and 40 (Fig. 5), since the sides 46, 47, 48, 58 that form the inlet of the first perforated section are equal to each other and are located at an angle of 90 °, an inlet of a square shape is formed, and the sides 49, 55, 56, 57, forming the outlet of the first perforated section, are also equal to each other and are also located at an angle of 90 °, then the outlet is also square in shape, along which the second perforated section B is attached to the first perforated section A (Fig. . 9).

The second perforated section B (Fig. 8) is made in the form of a straight triangular perforated prism formed by a cube section diagonally with the formation of perforated sides 59, 60, 61, along which the second perforated section B is attached to the outlet of the first perforated section A after turning 90 ° (Fig. 9).

Installation of the perforated filter 9 (Fig. 9) is carried out in the following sequence: - to the first perforated section A with a square inlet equal to, for example, a = 400 mm and a square outlet, for example b = 500 mm, attached after turning 90 ° the second perforated section B with the dimensions of the sides, B = 500 mm, to which, in turn, after turning 90 °, the next first perforated section A is attached with the dimensions of the square inlet already equal to = 500 mm, and the output square hole d = 600 m m The next second perforated section B is connected to the outlet of this perforated section already with side dimensions w = 600 mm, etc. the installation of the perforated sections of the filter 9 is further carried out by the perforated sections A and B, with the dimensions of the inlet and outlet square holes increasing from loading to unloading sequentially and alternately. This structural design of the filter 9 provides a change in the length of the filter 9, not only the size of the passage section of the filter 9 (Fig. 1, Fig. 2, Fig. 3, Fig. 4), but also the shape of the passage section of the filter 9. Moreover, the centers of symmetry of the inner surface the filter 9 in each of its cross-sectional elements along its length are displaced relative to the axis of rotation of the filter 9, which violates the stationary motion of material particles, for example, manure.

Inertial thickener works as follows.

Material, for example manure (Fig. 1, Fig. 2), is fed through a loading device 14 into a rotating perforated filter 9, where portions of material, for example, manure, are captured like shovels, perforated walls of the filter 9 and rise up in the direction of rotation. Upon reaching a certain height under the influence of gravitational forces and the angle of repose formed, the portions of the material, depending on their own mass, are separated from the walls of the perforated filter 9 and from different heights and at different angles move towards other portions of the material moving inside the perforated filter 9 with subsequent simultaneous movement of the screw grooves of the perforated filter 9 towards the discharge side. The process of movement of subsequent portions of material that rise up and move towards other portions is continuous. Since the inner perforated walls of the perforated filter 9 are located at an angle not only to each other, but also to the axis of rotation of the perforated filter 9, each portion moves along its direction vector towards the discharge side, which greatly intensifies the process of dewatering portions of material, for example, manure and their interaction with each other and with the walls of the perforated filter 9, increases the productivity of dehydration and expands technological capabilities. In the perforated filter 9, due to the movement of material flows along complex paths and at different angles to the axis of the holes of the perforations of the perforated filter 9, the unsteady nature of the movement of flows of particles of material inside the perforated filter 9, their intense interaction and cascade movement relative to each other and to the axis rotation of the perforated walls, increasing the power and frequency of interaction of the flows of particles of material with each other and with the walls of the perforated filter 9, is provided I have a favorable hydrodynamic environment for the efficient conduct of the dehydration of the material, for example, manure and separation of the liquid phase.

Thus, when moving the material inside the perforated filter 9, its liquid phase is discharged through the perforated holes into the cavity of the outer drum 8, where it is transported by screw guides 10 to the holes 11. Through the holes 11, the liquid phase is discharged from the cavity of the outer drum 8 into the cavity of the casing 12 and through the window 13 enters the container 16. The solid phase of the materials is discharged through the outlet of the perforated filter 9 to the conveyor 14.

Technical and economic advantages arise due to the variety of geometry of the perforated walls of the perforated filter and their different inclination to each other and to the axis of rotation of the perforated filter, which increases the frequency and power of interaction of portions of material particles, increases the area of working perforated elements involved in the dehydration of the material, for example, manure , with the same dimensions of the perforated filter, which provides not only the intensification of the process of separation of the liquid phase from the solid phase material But also extends the technological capabilities of the inertial thickener.

Claims (1)

An inertial thickener, including a housing, inside which screw guides, a perforated filter, a loading device, devices for removing the filtrate and thickened fraction are fixed, characterized in that the perforated filter is mounted from perforated sections made in different shapes and sizes, increasing from loading to unloading, connected in series and alternately, with the first perforated section made of two perforated subsections, one of which is mounted two large times of perforated triangles connected at their bases to the sides of a large equilateral perforated trapezoid, and the second perforated subsection is mounted from a small equilateral perforated trapezoid, two small miscellaneous perforated triangles, the bases of which are equal to the large lateral sides of the first perforated triangles, are attached to their sides perforated subsections by which perforated subsections are connected each other, and the upper bases of the perforated trapezoid of the two perforated subsections are equal to each other and equal to the small side of the perforated triangles of the first perforated subsection with the formation of a small inlet of the perforated section, and the lower bases of the perforated trapezoid are equal to each other and equal to the large side sides of the perforated triangles of the second perforated subsections with the formation of a large outlet of the perforated section to which the second ne forirovannaya section, designed as a perforated line triangular prism formed by a section of a cube diagonal.

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