RU2651336C1 - Device for evaporation of manure - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to agriculture, in particular to equipment for separation of wastes fodder complexes in liquid and solid phases, suitable for transportation to fields as fertilizers in a liquid or solid state, to food industry, for example, for evaporation of raw materials in production of pectin, separation of liquid phase from manure, during drying of materials. Machine for evaporation of manure contains a filter mounted on base, charging device, discharging devices for withdrawing the liquid phase and thickened fraction. Filter is made in form of spiral shape of a hollow tunnel fixed on platform installed elastically on bed, while the filter is rigidly fixed on a platform with a vibrator with horizontal axis of rotation mounted horizontally under the platform parallel to the longitudinal axis of the filter, and is made in form of spiral hollow tunnel with multi entrance screw perforated surface, along perimeter coiled along spiral axis 0₁-0₁ around central rectilinear axis 0₂-0₂ a spiral filter, equipped with helical grooves inside at an angle to its spiral axis in form of pockets with three or more lateral sides inside and outside of its cross section, and assembled of sections in form of identical shape and size rings, coiled from identical diamond shaped perforated strips, on which areas like trapezium are placed, lateral sides of which are located on lateral sides of diamond-shaped perforated strip, and upper and lower bases of trapezium are located at acute angle to axis of symmetry of diamond-shaped perforated strip 0₃-0₃ and are flexure lines located at distances from each other equal to the length of sides of the pockets. Ring sections are interconnected by lateral sides of trapezes.

EFFECT: higher efficiency and expanded performance.

1 cl, 7 dwg

Description

The invention relates to agriculture, in particular to equipment for separating waste feed systems in liquid and solid phases, suitable for transportation to the field as fertilizers in liquid or solid state for dehydration of raw materials in the production of pectin, separation of the liquid phase from bulk materials, during drying materials.

A device for isolating the liquid phase from materials is an inertial thickener (RF patent No. 2469768, MKI B01D 33/27, publ. 2.12.2012, bull. No. 35), including an outer drum, inside which a screw insert is fixed, a filter made around the perimeter in the form of a multi-start screw perforated surface with screw perforated grooves inside and outside the filter at an angle of 5-45 ° to the axis of rotation of the filter in the form of perforated pockets of curvilinear shape with centers of curvature alternately located outside and inside the cross section the filter is mounted from one, rolled into cylindrical coils, connected to each other along the longitudinal edges of the perforated strip of the same width, bent in a wave-like fashion along fold lines placed at an angle to its longitudinal edges with the formation on the outer and inner surfaces of the filter screw perforated surfaces directed to one side in the form of pockets of curved shape on the outer and inner surfaces.

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

Closest to the proposed invention is a device for separating the liquid phase from materials (patent No. 2486942, class B01D 33/27, publ. 07/10/2013 Bull. No. 19), containing mounted on the base of the outer drum, inside which is fixed a screw insert , loading device, unloading devices for draining the filtrate and thickened fraction and a filter mounted from at least one rolled into cylindrical coils connected to each other along the longitudinal edges of the perforated strip bent at scrap to its longitudinal edges with fold lines, with the formation on the outer and inner surfaces of one-way helical lines and helical surfaces in the form of perforated pockets of a polygonal shape, the distance between the fold lines is equal to the length of each polygon element, while the perforated pockets along the inner surface may differ from the shape and size of the perforated pockets along the outer surface and around the perimeter of the drum can be different not only in size but also in shape.

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 device for dewatering manure.

The technical solution is achieved by the fact that in the device for dehydration of manure containing a filter, a loading device, unloading devices for draining the filtrate and the condensed fraction, the filter is made in the form of a spiral form of a hollow tunnel mounted on a platform mounted elastically on a bed, while the filter is rigidly fixed to a platform with a vibrator, with a horizontal axis of rotation mounted horizontally below the platform parallel to the longitudinal axis of the filter and made in the form of a hollow tunnel with many ozahodnoy screw perforated surface around the perimeter of the folded spiral axis 0 ₁ -0 ₁ around a central linear axis 0 ₂ -0 ₂ helical filter provided with helical grooves inside at an angle to its helical axis in the form of pockets with three or more sides inside and outside cross-section of the filter and assembled from sections in the form of rings of the same shape and size, rolled up from the same perforated diamond-shaped strips, on which trapezoidal sections are located, the sides of which are located on the the sides of the rhomboid perforated strip, and the upper and lower bases of the trapezoid are located at an acute angle to the axis of symmetry of the rhomboid perforated strip 0 ₃ -0 ₃ and are fold lines located at distances from each other equal to the length of the sides of the pockets, with sections in the form of rings connected to each other by the lateral sides of the trapezoid.

According to the patent literature not found a technical solution similar to the claimed, which allows us to promise about the inventive step of the proposed design of a device for dehydration of manure.

The novelty is seen in the fact that the filter is made spiral with a multi-start screw surface around the perimeter, which increases the dewatering capacity and expands the technological capabilities.

The novelty is due to the fact that due to the installation of a vibrator horizontally below the platform with the filter, the shape of the filter oscillation path is changed from circular to vertical ellipse, which provides an increase in the specific gravity of the total kinetic energy (E _p ) by 1.3-1.5 times and increases productivity.

The novelty is that the spiral filter with a multi-start screw surface around the perimeter is equipped with screw grooves inside at an angle to the axis of the spiral of the center of symmetry axis 0 ₁ -0 _{1 of the} spiral tunnel with the central straight axis 0 ₂ -0 ₂ , which increases productivity.

The novelty is that the helical grooves of the spiral filter are made in the form of pockets with three or more sides, which also increases productivity.

The novelty is that the spiral filter is mounted from sections in the form of identical rings, folded from the same perforated diamond-shaped strips, the sides of which are located on the sides of the perforated diamond-shaped strips, and the upper and lower bases of the trapezoid are at an acute angle to the axis of symmetry of the perforated diamond-shaped strips 0 ₃ -0 ₃ and are bend lines located at distances from each other, equal to the length of the sides of the pockets, while the sections are connected to each other by side Onami trapezoid, which increases productivity.

The novelty of the proposal also lies in the fact that along the entire perimeter of the spiral filter, the passage section varies not only in shape but also in area, which provides alternate compression and expansion of bulk materials in each section of the spiral filter, which means increased productivity and expanded technological capabilities.

The novelty of the invention lies in the fact that the trapezoid of rhomboid perforated strips from which the sections are mounted are not only inclined to each other, but also to the axis of symmetry of the spiral filter, therefore, the degree of compression of particles of bulk materials increases, the process of dehydration of bulk materials is intensified.

The novelty also lies in the fact that the spiral filter is made of sections, the walls of which are not only inclined to each other, but also to the direction of the rotational movement of the manure particles moving under the influence of vibration in planes perpendicular to the passage section of the spiral filter, which complicates the trajectory of their movement, increases the intensity of manure dehydration and expands technological capabilities.

The novelty is due to the fact that the sections from which the spiral filter is assembled are mounted around the perimeter from rhomboid perforated strips with trapeziums of different sizes and sizes marked on them, so the intensity and efficiency of manure dehydration increases and technological capabilities expand.

The invention is illustrated by drawings, where in FIG. 1 shows a device for dewatering manure, a general view; in FIG. 2 is a section AA in FIG. one; in FIG. 3 - a visual image of a spiral filter; in FIG. 4 - a visual representation of the relative position of the spiral 0 ₁ -0 ₁ , along which a hollow tunnel with a multiple helical surface is rolled around a central straight axis 0 ₂ -0 ₂ ; in FIG. 5 - one of the strips of a rhomboid perforated shape, on which trapezoids are placed, the upper and lower bases of which are located at an acute angle to the axis of symmetry of the strip 0 ₃ -0 ₃ in the form of fold lines; in FIG. 6 - a perforated strip of a rhomboid shape, bent along the fold lines - the upper and lower bases of the trapezoid; in FIG. 7 is a visual representation of a diamond-shaped perforated strip rolled into a ring when connecting the upper base 90, 91 of the trapezoid mnn'm with the lower base of the trapezoid 42, 43, 45, 44.

The device for dehydration of manure (Fig. 1, Fig. 2) contains a hollow spiral filter 1, rigidly fixed to the platform 2 elastically using four rubber-cord cylinders 3 mounted on the base 4. On the platform 2, the loading device 5 is rigidly fixed, and from below to the platform 2 is attached rigidly to a vibrator 6 with a horizontal axis of rotation mounted under the platform parallel to the longitudinal axis of the filter. The device for dehydration of bulk materials is equipped with an unloading device 7 for removing the condensed fraction using slice 8 and unloading devices 9 and 10 for removing the filter, equipped with slides 11 and 12, mounted on the platform 2.

The filter 1 (Fig. 1, Fig. 2, Fig. 3) is made spiral. In FIG. 4 shows a visual representation of the relative position of the axis of the spiral - the center of the axis of symmetry 0 ₁ -0 _{1 of the} hollow tunnel of the spiral filter 1 (figure 4 shows a spiral casing with a conditionally cross section 8 of a hollow tunnel with a multi-helical perforated surface) and a central straight axis 0 ₂ -0 ₂ spiral filters 1.

Thus, around the perimeter, the spiral filter 1 is made in the form of a spiral-shaped tunnel with a multi-screw perforated screw around the perimeter and is equipped with screw grooves inside and outside, arranged at an angle α to the axis of symmetry of the spiral 0 ₁ -0 _{1 of the} center of the axis of symmetry (Fig. 3) spiral tunnel, coiled in a spiral 0 ₁ -0 ₁ around the central axis 0 ₂ -0 _{2 of the} spiral filter 1.

The helical grooves of the spiral filter 1 are made in the form of pockets 14, 15, 16, 17, 18, 19 along the inner surface and pockets along the outer surface 20, 21, 22, 23, 24, 25 of the spiral-shaped tunnel (Fig. 3 and Fig. 4) with three or more sides mounted from sections in the form of identical rings (Fig. 7), connected to each other by the sides 27 and 28.

The result is a hollow tunnel of the spiral filter 1 (Fig. 1, Fig. 2, Fig. 3) with the axis of the spiral - the center of the axis of symmetry 0 ₁ -0 _{1 of the} spiral filter 1, twisted around the central straight axis 0 ₂ -0 _{2 of the} spiral filter 1 diameter D _cp with the formation of a spiral filter 1 with an outer diameter of D _max and with an inner diameter of D _min (Fig. 4).

In this case, the hollow spiral housing 1 with a multi-helical perforated screw surface is provided with helical grooves in the form of pockets 9-14 on the inner surface and pockets 20-25 on the outer surface of the spiral filter 1 (Fig. 4).

Thus, a hollow tunnel with its own spiral axis of symmetry 0 ₁ -0 _{1 is} folded along this spiral 0 ₁ -0 ₁ around a central rectilinear axis 0 ₂ -0 ₂ and forms a spiral filter 1 (Fig. 4).

Section 26 is made in the form of a ring (Fig. 7), mounted from a diamond-shaped perforated strip 29 (Fig. 5), on which trapeziums are placed, the sides of which are located on the sides of the diamond-shaped perforated strip 29, and the upper and lower bases of these trapezoids (Fig. 7) 5) are located at an acute angle β to the axis of symmetry of the diamond-shaped perforated strip 0 ₃ -0 ₃ and are fold lines (Fig. 5 and Fig. 6) located at distances from each other equal to the length of the sides of the pockets of the spiral filter 1, made in spiral void spruce perforated tunnel.

In FIG. 5 shows the trapezoid:

42, 43, 45, 44 - the first trapezoid,

43, 46, 48, 45 - the second trapezoid,

46, 47, 49, 48 - the third trapezoid,

47, 50, 48, 51 - the fourth trapezoid,

50, 51, 53, 52 - the fifth trapezoid,

51, 54, 53, 56 - the sixth trapezoid,

54, 55, 56, 57 - the seventh trapezoid,

55, 56, 60, 57 - the eighth trapezoid,

58, 59, 61, 60 - the ninth trapezoid,

59, 62, 64, 61 - the tenth trapezoid,

62, 63, 65, 64 - the eleventh trapezoid,

63, 66, 67, 65 - the twelfth trapezoid.

Moreover, 42, 44 is the smallest of all the upper bases of the trapezoid located on the rhomboid perforated strip 29, below the fold line 66, 68 ', and 66, 68 is the largest of all the lower bases of the trapezoid located on the rhomboid perforated strip 29, below the fold line 66, 68 and the above twelve trapezoids.

In FIG. 5 also shows the trapezoid:

66, 67, 69, 68 - the thirteenth trapezoid,

67, 70, 71, 69 - the fourteenth trapezoid,

70, 71, 73, 72 - the fifteenth trapezoid,

71, 74, 76, 73 - the sixteenth trapezoid,

74, 75, 77, 76 - the seventeenth trapezoid,

75, 78, 80, 77 - the eighteenth trapezoid,

78, 79, 81, 80 - the nineteenth trapezoid,

79, 82, 84, 81 - the twentieth trapezoid,

82, 83, 85, 84 - the twenty-first trapezoid,

83, 86, 88, 85 - twenty-second trapezoid,

86, 87, 89, 88 - twenty-third trapezoid,

87, 90, 91, 89 - the twenty-fourth trapezoid.

Moreover, nn 'is the smallest base of all the upper bases of the trapezoid located on the diamond-shaped perforated strip 29, above the fold line 66, 68, which for all trapezoids, in turn, is the largest of all the lower bases from the thirteenth to the twenty-fourth trapezoid.

Thus, the fold line 66, 68 is not only the lower base of the trapezoid 63, 66, 68, 65, but also the upper base of the trapezoid 67, 66, 68, 69 and the longest fold line of the ring 26 and the diamond-shaped perforated strip 29.

Moreover, the fold lines 42, 44 and 90, 91 are the shortest of all the fold lines of the diamond-shaped perforated strip 29 and the ring 26.

The ratio of the length of the bend line 66, 68 and 42, 44 (90, 91) determines the value of step S, spiral 0 ₁ -0 ₁ , and therefore the pitch of winding the hollow perforated tunnel around the straight axis 0 ₂ -0 _{2 of the} spiral filter 1.

The diamond-shaped strip 29 bends along the straight fold lines, which are the bases of twenty-four trapezoids, as shown in FIG. 6, parallel to each other, and then rolled into a ring 26 (vig. 7) with a multifaceted surface.

Edges 90, 91 and 42, 44 are joined by known methods, for example by welding, soldering, etc. with the formation of the section in the form of rings 26 (Fig. 7).

Sections in the form of identical rings 26 are connected to each other sequentially by the lateral sides 27 and 28 so that all the fold lines are a continuation of the same fold lines of the previous ring.

As a result of such an assembly around the perimeter of the hollow spiral tunnel in the form of a filter 1, helical lines are formed, shown in FIG. 3, for example, with a thickened line 30-31-32-33-34-35-36-37-38-39-40.

Thus, the spiral filter 1 (Fig. 1, Fig. 2, Fig. 3) is made around the perimeter in the form of a multi-helical spiral perforated surface with helical lines around the perimeter of the spiral filter 1 (one of the helical lines shown in Fig. 3 with a thickened line 30 -31-32-33-34-35-36-37-38-39-40, and screw grooves inside and outside of the spiral perforated filter 1 in the form of pockets of a polygonal shape 14, 15, 16, 17, 18, 19 on the inner surface and 20, 21, 22, 23, 24, 25 along the outer diamond-shaped perforated surface in the form of pockets of a polygonal shape at an angle scrap α to the spiral axis of the hollow tunnel of the spiral shape of the spiral filter 1.

A spiral filter 1 (Fig. 1, Fig. 2, Fig. 3) in the form of a spiral hollow perforated tunnel with a helical surface along its inner and outer perimeter with the formation of pockets of a polygonal shape can be made in another way.

A device for dewatering bulk materials works as follows.

The disturbing force of the vibrator through the walls of the spiral filter 1 is transmitted to the manure particles inside the spiral filter 1 and entering the spiral housing 1 in a continuous stream through the loading device 5. The manure particles rotate along vertical elliptical trajectories, during which the manure dehydration occurs. In this case, the manure particles not only interact intensively with each other, but also under the influence of vibration rotate in a plane perpendicular to the through section of the spiral filter 1. Since the spiral filter 1 has a cross-sectional size, the shape of the spiral filter 1 changes, the disturbance of movement is aggravated particles of manure, which in this case interact with pockets of the polygonal shape of the inner perforated walls of the spiral filter 1, i.e. there is an increase in the intensity of manure dehydration. The presence of screw perforated surfaces and helical lines around the perimeter of the spiral filter 1 contributes not only to the complication of the trajectories of particles of bulk materials, but also to their movement along the passage section of the spiral filter 1 in the direction of unloading and unloading device 7.

When the manure particles move along the cross section of the spiral filter 1 due to changes in the cross section in shape and size, compression and vacuum zones are alternately formed in each cross section of the spiral filter 1 over its entire volume, which also intensifies the process of manure dehydration and expands technological capabilities.

The thickened fraction through the discharge window 41 is discharged using slice 8 in the discharge device 7. The liquid phase through the perforations of the filter 1 is discharged onto the slides 11 and 12 into the discharge device 9 and 10.

Technical and economic advantages arise due to the fact that the spiral filter is made spiral from a hollow tunnel with a multi-start screw surface along the perimeter, coiled in a spiral, which provides increased productivity and expansion of technological capabilities, as well as due to the installation of a vibrator horizontally below the platform with a spiral case 1 , which provides an increase in the specific gravity of kinetic energy by 1.3-1.5 times and increases productivity, as well as the manufacture of a filter with grooves in the form of polygonal armanas.

Claims (1)

A device for manure dewatering, comprising a filter mounted on the base, a loading device, discharge devices for draining the liquid phase and the condensed fraction, characterized in that the filter is made in the form of a spiral form of a hollow tunnel mounted on a platform mounted elastically on a bed, while the filter is rigidly mounted on a platform with a vibrator with a horizontal axis of rotation mounted horizontally below the platform parallel to the longitudinal axis of the filter, and made in the form of a spiral hollow of a tunnel with a multi-start screw perforated surface around the perimeter, rolled along a spiral axis 0 ₁ -0 ₁ around a central rectilinear axis 0 ₂ -0 _{2 of a} spiral filter equipped with screw grooves inside and outside at an angle to its spiral axis in the form of pockets with three or more sides, and assembled from sections in the form of rings of the same shape and size, rolled up from the same perforated diamond-shaped strips, on which trapezoidal sections are placed, the sides of which are located on the sides of mbovidnoy perforated strip and the upper and lower bases of the trapezoids are arranged at an acute angle to the axis of symmetry of diamond perforated strip ₃ -0 0 ₃ and fold lines are located at distances from each other equal to the length of the sides of the pockets, the section in the form of rings are connected to each with the other sides of the trapezoid.

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