RU2550074C1 - Installation for livestock manure dehydration - Google Patents

Abstract

FIELD: agriculture.SUBSTANCE: installation for livestock manure dehydration contains casing, input branch pipe, helical insert and branch pipes for liquid and concentrated faction removal. Inside the casing filter 8 is installed, it is made multi-entry, cone and made out of sections 16, connected one-by-one along length by their end face holes in form of polygons. Each section 16 is made of two sub-sections 17, 18. First sub-section 17 along perimeter is made out of even, at least four similar first isosceles perforated triangles, connected one-by-one by their sides with sides of at least four similar second isosceles perforated triangles. Bases of the second isosceles perforated triangles are larger then bases of the first second isosceles perforated triangles 19. Second sub-section 18 is made out of connected one-by-one along perimeter at least four similar isosceles perforated triangles with sides equal to bases of second isosceles perforated triangles of the first sub-section with sides of at least four similar isosceles perforated triangles with top angle 90°, with creation of small and large end holes in form of polygons. At that larger end hole in form of polygon of the first sub-section is equal to smaller end hole in form of polygon of the second sub-section. The sub-sections are connected with each other in sections by end holes in form of polygons.EFFECT: higher installation capacity, expanded process performances.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. 2495552, class B01D 33/27, publ. 05/20/2013, bull. No. 14), comprising a housing, an inlet pipe, a screw insert and pipes for draining the liquid phase and condensed fraction and a filter mounted inside the housing, made by multiple entry, conical and mounted from sections assembled from alternately connected along the perimeter of perforated equilateral and perforated isosceles triangles, alternately assembled with their free sides to each other, at m side equilateral perforated and perforated isosceles triangles are equal to each other, and the bases of isosceles triangles perforated over their side faces, wherein the number of the perforated and perforated equilateral isosceles triangle in section as well as a minimum of six must be an even number.

The disadvantages of the known design are insufficient productivity and limited technological capabilities.

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

This object is achieved by the fact that in the installation for dehydration of manure, including a housing, an inlet pipe, a screw insert and pipes for draining the liquid phase and the condensed fraction and a filter mounted inside the housing made by multiple inlet, conical and mounted from sections, the filter is made of sections alternately connected each other along the length of its end holes in the form of polygons, each of the sections is assembled from two subsections, the first subsection along the perimeter is mounted from an even number of at least four of the first isosceles perforated triangles alternately connected by their sides with the sides of at least four identical second isosceles perforated triangles, the bases of which are larger than the base 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 alternately connected perimeter of at least four identical equilateral perforated triangles with side sides equal to the bases of the second isosceles perforated triangles of the first subsection with the sides of at least four identical isosceles perforated triangles with an angle at apex 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 a hole in the form of a polygon of the second subsection, while the subsections are connected to each other in the section by their end holes in the form of ougolnikov.

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 design of the installation for dehydration of manure.

The novelty is also seen in the fact that the area and cross-sectional shape of the filter along the length increases from loading to unloading due to the conditionally conical shape of the filter and the variety of shapes, sizes and areas of flat elements from which the filter surface is mounted, which not only intensifies the process of manure dehydration, since it violates the stationary motion of their flows, changes the amplitude of the oscillations as they move, but also ensures 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 manure flows in the proposed structures is determined not only by the frequency of rotation of the filter, but also by the number, as well as the variety of geometry and area of flat perforated elements around the perimeter of the filter, such a structural design of the filter surface increases each revolution of the filter, the frequency of collisions of the manure flows between each other and with the walls of the filter, increases dewatering performance, expands technological capabilities.

In addition, the novelty is due to the fact that the elements, diverse in shape and size, the area from which the filter is assembled, are mounted at certain angles to each other, so the intensity of the interaction of manure flows increases, since these elements, working like shelves capture portions of manure , direct them towards each other, as well as onto the walls of the filter walls moving on the opposite side, thus violating not only the stationarity of their movement, but also providing self-cleaning of the holes of the filter perforations, expanding nological opportunities.

The novelty is that the area and cross-sectional shape of the filter varies in each cross-section from loading to unloading, which intensifies the process of manure dehydration, increases the energy intensity of the interaction of manure flows with each other and with the walls of the filter, and expands technological capabilities.

The novelty also lies in the fact that the filter cross-sectional area has the shape of a polygon, the area of which along the length of the filter changes many times from loading to unloading, providing periodic compression of the manure masses, which increases the intensity of manure dehydration and the energy intensity of collisions, expanding technological capabilities.

The novelty is due to the fact that the filter around the perimeter is multi-start, conical, equipped with directional towards each other along the perimeter and, accordingly, helical grooves inside the filter, also directed towards each other, which ensures the creation of directed towards each other manure flows with maximum energy intensity of their collisions to each other to each other and with the filter walls at different angles, increases the frequency of interaction of manure flows with each other and with perforated filter walls, increases the production of flax manure dehydration 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 filter vary along the entire length from loading to unloading, which changes the speed and trajectory of the movement of manure flows, and expands technological capabilities.

The novelty is that thanks to the broken helical lines directed towards each other, the vectors of the speed of movement of the manure flows during transportation from loading to unloading change, which contributes to the intensification of the process of dehydration of manure and expands technological capabilities.

The novelty also lies in the fact that along the inner perimeter of the filter broken screw surfaces are formed at an angle of up to 90 ° along the length of the filter, which violates the stationarity of their flows inside the filter, increases the intensity of manure dehydration, and enhances technological capabilities.

The invention is illustrated by drawings, where: in Fig.1 shows a plant for dehydration of manure, a General view; figure 2 is a section aa in figure 1; figure 3 - filter conditionally conical shape, General 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 the filter.

Installation for dehydration of manure 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 four roller bearings 4, on which two circular shells 5 and 6 are installed, in which the housing 7 is fixed, with the filter 8 coaxially mounted in it. The housing 7 is made in the form of a cylinder, inside of which screw guides 9 are fixed and provided with perimeter holes 10 for draining the liquid phase from the filter.

A section of the outer drum 7 with holes 10 is mounted in the casing 11, which in its lower part is equipped with a window 12 - a pipe for draining the liquid fraction. On the bed 1 mounted boot device in the form of a funnel 13 - inlet pipe. The device is equipped with a conveyor 14 for receiving the solid phase of manure - a pipe for removing the condensed fraction, and a capacity of 15 for receiving the liquid phase of manure.

The filter 8 (figure 3, figure 4, figure 5) is mounted from sections 16, alternately connected to each other by their end holes in the form of polygons. Each of the sections is assembled from two subsections 17 and 18.

The first subsection 17 (Fig.6) around the perimeter is mounted from an even number of at least four identical first isosceles triangles 19, alternately connected along the perimeter of subsection 17 with their sides with the sides of the same four second isosceles triangles 20, the bases 21 of which are larger than the bases 22 of the first isosceles triangles 19. A small end hole in the form of a polyhedron 23 and a large end hole in the form of a polygon 24 are formed at the ends of the subsection 17.

The second subsection 18 (Fig. 7) is mounted around the perimeter of at least four identical equilateral triangles 25, the sides of which are equal to the base 21 of the second isosceles triangles 20 of the first subsection 17, alternately connected along the perimeter with their sides and sides of at least four identical isosceles triangles 26 with apex angle of 90 °. At the ends of the subsection 18, a small end hole in the form of a polyhedron 27 and a large end hole in the form of a polyhedron 28 are formed.

In the section, the subsection 17 and 18 are mounted (Fig. 8) by the sides of the large end hole 24 with the sides of the small end hole 27 of the subsection 18.

The filter 8 is mounted (Fig. 9) by attaching a large end hole in the form of a polyhedron 28 of the first section 16 to a small end hole 27 of the second section 16. Sections 16 of the first, second and subsequent are the same in shape and assembly, but different in size. Thus, a conditionally conical filter 8 is mounted with mutually directed broken helical lines.

For example, in FIG. 3, one of the right broken helical lines is shown by a thickened line 29-30-31-32-33 and one of the left broken helical lines is shown by a thickened line 34-35-31-36-37.

Broken helix lines form broken helical surfaces along the inner perimeter of filter 8, consisting of faces in the form of equilateral and isosceles triangles 19 and 20 of the first subsection 17 and equilateral triangles 25 and isosceles triangles 26 of the second subsection 18.

Helical lines along the outer surface of the filter 8 have the same position designations with their corresponding grooves on the inner surface.

Since the subsection 17 has a small end hole 23 and a large end hole 24 and the subsection 18 has a small end hole 27 and a large end hole 28, sections 17 have variable longitudinal and variable passage sections along the entire length of the conditionally conical filter 8 created as a result of the assembly. .

Installation for dehydration of manure works as follows. Manure (Fig. 1, Fig. 2) is fed through a loading device 13 into a rotating perforated filter 8, where manure portions are captured like shovels, perforated walls of the filter 8 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, manure portions, depending on their own weight, are separated from the walls of the perforated filter 8 and from different heights and at different angles move towards other manure portions moving inside the perforated filter 8, with subsequent simultaneous movement screw grooves of the perforated filter 8 in the direction of discharge. The process of movement of subsequent portions of manure, which rise up and move towards other portions, is continuous. Since the inner perforated walls of the filter 8 are located at an angle not only to each other, but also to the axis of rotation of the filter 8, each portion moves along its direction vector towards the discharge side, which greatly intensifies the process of dehydration of the manure portions and their interaction with each other and with the walls of a perforated filter 8, it increases the dewatering capacity and expands the technological capabilities. In the filter 8 due to the movement of manure flows along complex trajectories and at different angles to the axis of the holes of the perforations of the filter 8, the unsteady nature of the movement of manure flows inside the filter 8, their intensive mixing and cascade movement, relative to each other and to the axis of rotation of the perforated walls, increasing the power and frequency of interaction of manure flows with each other and with the walls of the filter 8 provides a favorable hydrodynamic environment for efficient dehydration processes Nia manure and liquid phase separation.

Thus, when moving manure inside the filter 8, its liquid phase is discharged through the perforated holes into the cavity of the outer drum 7, where it is transported by screw guides 9 to the holes 10. Through the holes 10, the liquid phase is discharged from the cavity of the outer drum 7 into the cavity of the casing 11 and through the window 12 enters the tank 15. The solid phase of the materials is discharged through the outlet of the filter 8 to the conveyor 14.

Technical and economic advantages arise due to the variety of geometries, shapes and sizes of the perforated filter walls and their different inclination towards each other and to the axis of rotation of the filter, which increases the frequency and power of interaction of manure portions, increases the area of working perforated elements involved in manure dehydration, while the same dimensions of the filter, which provides not only the intensification of the process of separation of the liquid phase from the solid phase of manure, but also expands the technological capabilities of the device. In other words, when the filter 8 is rotated, the manure flows are captured by the faces of the inner 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 manure flows towards each other at certain angles and to the walls of the rotating filter 8 and move towards the discharge side. Since the broken inner surface of the filter 8 is continuous, the process of movement of subsequent portions of manure flows, which rise up and fall down, moves at different angles, is continuous. Since the inner surface of the filter 8 is mounted from different in shape and size of equilateral and isosceles perforated triangles, which are located at different angles not only to each other, but also to the axis of rotation of the filter 8, each portion of the manure flows and moves along its direction vector towards unloading, which significantly intensifies the process of interaction of manure flows with each other and with the walls of the filter 8, increases the intensity of manure dehydration and extends the technological st. Since, due to the broken shape of the inner surface of the filter 8, the range of changes in the resulting vectors of displacement of manure flows is significantly expanded, each particle of the manure stream moves in different direction vectors, which provides a greater probability of collisions at the initial moment of their separation from the walls of the filter 8, where they have a certain reserve of kinetic energy and move with high kinetic energy, therefore, the intensification of the process of dehydration of manure is provided.

Technical and economic advantages arise due to the widening of the range of changes in the resulting displacement vectors of particles of manure streams, increasing the intensity of their mixing and reorientation, as well as increasing the speed of their movements from loading to unloading, which increases the mixing intensity, increases the energy consumption of the interaction of particles of manure streams with each other and with walls of the filter 8, increases productivity, expands technological capabilities.

Claims (1)

Installation for manure dewatering, including a housing, an inlet pipe, a screw insert and pipes for draining the liquid phase and thickened fraction and a filter mounted inside the housing made by multiple entry, conical and mounted from sections, characterized in that the filter is made of sections alternately connected to each other along the length of its end openings in the form of polygons, each of the sections is assembled from two subsections, the first subsection along the perimeter is mounted from an even number of at least four identical first equal parts perforated triangles alternately connected by their lateral sides to the sides of at least four identical second isosceles perforated triangles, the bases of which are larger than the bases of the first isosceles perforated triangles with the formation of small and large end holes in the form of polygons, and the second subsection is mounted from alternately connected along the perimeter of less than four identical equilateral perforated triangles with sides equal to the second isosceles perforated triangles of the first subsection with the sides of at least four identical isosceles perforated triangles with an apex angle of 90 ° with the formation of a small and a large end hole in the form of polygons, and the large end hole in the form of a polygon of the first subsection is equal to a small end hole in the form of a polygon the second subsection, while the subsections are connected to each other in sections by their end openings in the form of polygons.

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