RU182072U1 - Seed cleaning machine - Google Patents

Abstract

The utility model relates to agricultural engineering, namely to machines for cleaning seeds from litter. To expand operational and technological capabilities, to improve the quality of separation of seeds from litter in a seed cleaning machine containing a screening surface elastically installed by means of elastic elements, a drive, loading and unloading devices, the screening surface is made from a spiral perforated hollow tunnel with a perforated multi-screw screw surface rolled around the perimeter the spiral axes 0 ₁ -0 ₁ around a central linear axis 0 ₂ -0 _2, provided with the screw channel inside inside at an angle to its spiral axis in the form of pockets of curvilinear shape with centers of curvature located inside the cross section of a hollow perforated tunnel assembled from sections in the form of identical perforated rings of the same shape and size, folded from the same perforated diamond-shaped strips on which trapeziums are placed whose sides are located on the sides of the rhomboid perforated strip, and the upper and lower bases of the trapezoid are at an acute angle to the axis of symmetry of the rhombo visible perforated strip 0 ₃ -0 ₃ and are bending lines located at distances from each other equal to the length of the pockets of a curved shape along the inner perforated surface of the hollow perforated tunnel of the spiral sifting surface, while sections in the form of perforated rings are connected to each other by the lateral sides of the trapezoid .

Description

The utility model relates to agricultural engineering, namely to machines for cleaning seeds from litter.

A device for cleaning seeds is known (see patent No. 2176563, class B07B 1/22, 2001), containing loading and unloading devices, a drive and a screening surface installed by means of elastic elements, made in the form of spatial sections connected in series, each of which made in the form of isosceles prisms or in the form of oblique parallelepipeds, rotated relative to the previous one by an angle of 90 ° around the axis of the screening surface with the formation along the perimeter of zigzag or helical lines with a variable pitch .

A disadvantage of the known device is the lack of operational and technological capabilities.

Closest to the proposed technical solution is a toroidal device for separation of seeds (RU 2347615 C1, 02.27.2009, B02B 1/00, 11 sec.), Containing loading and unloading devices, a drive and a screening surface elastically mounted by means of elastic elements, made in the form a torus with a screw surface around the perimeter of sections connected to each other and mounted from a bent perforated strip, with the alternating formation along the length of the perforated strip of different sizes of sieves in the form of equilateral and equal depleted triangles, while on the two sides of the largest equilateral triangle two identical isosceles triangles are located with their bases, on the sides of which are two identical equilateral triangles with two identical isosceles triangles located to them with their bases, on one of which is an equilateral triangle, and the sides smaller equilateral triangles differ from the sides of large equilateral triangles by the same line the value, and the sections are connected to each other by the free sides of the mentioned triangles with the formation on the outer and inner screening surface of the broken helical lines and screw screening surfaces.

A disadvantage of the known device is insufficient operational and technological capabilities, insufficient quality of separation of seeds from litter.

The technical result of the task is to expand operational and technological capabilities, improving the quality of separation of seeds from litter

The technical result is achieved by the fact that in a seed cleaning machine containing a screening surface elastically installed by means of elastic elements, a drive, loading and unloading devices, the screening surface is made spiral from a hollow perforated tunnel with a multi-helical perforated surface rolled around the perimeter along the spiral axis 0 ₁ -0 ₁ around the central rectilinear axis 0 ₂ -0 _{2 of the} spiral perforated body provided with helical grooves inside at an angle to its the spiral axis in the form of pockets of curvilinear shape with centers of curvature located inside the cross section of the hollow perforated tunnel and assembled from sections in the form of the same shape and size of perforated rings, rolled from the same perforated diamond-shaped strips on which trapeziums are placed, the sides of which are located on the lateral sides of the rhomboid perforated strip, and the upper and lower bases of the trapezoid are at an acute angle to the axis of symmetry of the rhomboid perforated strip s 0 ₃ -0 ₃ and are fold lines located at a distance from each other, equal to the length of the pockets of a curved shape along the inner perforated surface of the hollow perforated tunnel of the spiral perforated body, while sections in the form of perforated rings are 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 to judge the inventive step of the seed cleaning machine.

The novelty is due to the fact that the casing is made spiral with a multi-helical screw perforated surface, which increases the intensity of the interaction of seeds and litter, increases the productivity and quality of separation of seeds from litter, and expands technological capabilities.

The novelty is that the installation of a vibrator under the base with a perforated body provides a path of oscillation of the perforated body along with seeds and litter in the form of a vertical ellipse, which increases the specific gravity of the total kinetic energy (E _n ) and increases productivity.

The novelty is that the spiral perforated case with a multi-screw perforated screw around the perimeter is provided with screw grooves inside and outside at an angle to the spiral axis of symmetry 0 ₁ -0 ₁ hollow perforated spiral tunnel with a central straight axis 0 ₂ -0 ₂ , which increases the intensity of the interaction of seeds and litter, increases the productivity and quality of separation of seeds from litter, expands technological capabilities.

The novelty is that the helical grooves of the spiral perforated casing are made in the form of pockets of a curvilinear shape located inside the cross section of a hollow perforated tunnel, which expands technological capabilities and increases the productivity of separating seeds from litter.

The novelty is seen in the fact that the spiral perforated case is assembled from sections in the form of perforated rings of the same shape and size, rolled up from the same perforated diamond-shaped strips, on which trapeziums are located on the sides of the diamond-shaped perforated strip, and the upper and lower bases of the trapezoid are located under a sharp angle to the axis of symmetry of diamond perforated strip ₃ -0 0 ₃ and fold lines are located at a distance from each other equal to the length of the pockets of the curved shape of ext nney perforated surface of the hollow tunnel spiral housing, the sections in the form of perforated rings connected to each other sides of the trapezoid, which increases the intensity of litter compartment seeds, increases productivity and quality of seeds separated from the litter, expands technological possibilities.

The novelty of the proposal also lies in the fact that along the entire perimeter of the spiral perforated casing, the passage section varies not only in shape but also in area, which provides alternate compression and expansion of seed and litter flows in each section of the spiral perforated casing, increases productivity and expands technological capabilities .

The novelty of the proposed technical solution lies in the fact that the trapezoid of rhomboid perforated strips, from which sections are mounted, are inclined differently not only to each other, but also to the axis of symmetry of the spiral perforated body, therefore, the degree of compression of the seeds and litter streams increases and the process of their separation is intensified.

The novelty lies in the fact that the perforated body is made of perforated sections, the walls of which are inclined not only to each other, but also to the direction of the rotational movement of the seeds and litter streams moving under the influence of vibration in planes perpendicular to the through section of the perforated body, this complicates their trajectory movement and increases the intensity of their separation and expands technological capabilities.

The essence of the technical solution is illustrated by drawings, where in FIG. 1 shows a seed cleaner, general view; in FIG. 2 is a section AA in FIG. one; in FIG. 3 is a pictorial representation of a spiral perforated case with curved pockets; in FIG. 4 is a visual representation of the relative position of the helix 0 ₁ -0 ₁ , along which a hollow perforated tunnel with a multiple helical perforated surface around a central straight axis 0 ₂ -0 ₂ is folded; in FIG. 5 - one of the perforated diamond-shaped strips on which trapeziums are located, the upper and lower bases of which are located at an acute angle to the axis of symmetry of the perforated strip 0 ₃ -0 ₃ in the form of a fold line; 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 perforated ring when connecting the upper base of the trapezoid NN ¹ , the trapezoid NMM ¹ N ¹ with the upper base RR ^{1 of the} trapezoid GRR ¹ G ¹ .

The seed cleaning machine (Fig. 1, Fig. 2) contains a perforated body 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 the bottom to the platform 2 is also rigidly attached vibrator 6 with a horizontal axis of rotation.

The seed cleaning machine is equipped with an unloading device 7 for receiving litter and a slime 8 for removing litter from the discharge opening 41 of the housing 1 and transferring it to the unloading device 7 and unloading devices 9 and 10 for removing seeds, equipped with slides 11 and 12, mounted on the platform 2. Perforated housing 1 is closed from above with a semicircular lid (not shown in the drawing), which prevents the dispersion of seeds and ensures their direction to the slides 11 and 12.

The vibrator 6 is mounted horizontally under the platform 2 and therefore provides the movement of seeds and litter inside the perforated body 1 under the influence of the vibrator 6 along elliptical trajectories. The perforated housing 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 perforated tunnel - spiral perforated casing 1 (Fig. 4 spiral perforated casing 1 is shown in cross sections 13 of the hollow perforated tunnel with a multi-helical perforated surface) and a central rectilinear axis 0 ₂ -0 ₂ spiral perforated housing 1.

Thus, around the perimeter, the spiral perforated casing 1 is made in the form of a perforated spiral tunnel with a multi-screw perforated surface along the perimeter and provided with helical grooves inside and outside, located 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) a spiral perforated tunnel, coiled in a spiral 0 ₁ -0 ₁ around the central axis 0 ₂ -0 _{2 of the} spiral perforated body 1.

The helical grooves of the spiral perforated body 1 are made in the form of pockets 14, 15, 16, 17, 18, 19 on the inner surface and pockets on the outer surface 20, 21, 22, 23, 24, 25 of the perforated spiral tunnel (Fig. 4, Fig. 7) in the form of pockets of curvilinear shape with centers of curvature located inside the cross section of the hollow perforated tunnel and assembled from the section in the form of perforated rings 26 of the same shape and size, connected to each other by the lateral sides 27 and 28 (Fig. 7).

The result is a hollow perforated tunnel of the spiral perforated body 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 perforated body 1, twisted around the central rectilinear axis 0 ₂ -0 ₂ spiral perforated body 1 in diameter D _cp , with the formation of a spiral perforated body 1 with an outer diameter of D _max and an inner diameter of D _min (Fig. 4).

In this case, the hollow spiral perforated case 1 with a multi-helical helical surface is provided with screw grooves in the form of pockets 14, 15, 16, 17, 18, 19 and pockets 20, 21, 22, 23, 24, 25 along the outer surface of the spiral perforated case 1 (Fig. . four).

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

Section 26 is made in the form of a perforated ring (Fig. 7), mounted from a diamond-shaped perforated strip 29.

A trapezoid 30, 31, 32, 33, 34, 35 is placed on the diamond-shaped perforated strip 29, the sides of which are located on the sides of the diamond-shaped perforated strip 29, and the upper and lower bases of these trapezoid (Fig. 5) are located at an acute angle β to the axis of symmetry rhomboid perforated strip 0 ₃ -0 ₃ and are the fold lines (Fig. 5, Fig. 6) located at a distance from each other, equal to the length of the scan of the perimeter of curved pockets (Fig. 7), spiral perforated body 1, made in the form of a hollow perforated tunnel.

In FIG. 5 shows the trapezoid:

NMM ¹ N ¹ - the first trapezoid;

MFF ¹ M ¹ - second trapezoid;

FEE ¹ F ¹ - the third trapezoid.

Moreover, NN ¹ is the smallest of all the upper bases of the trapezoid located on the diamond-shaped perforated strip 29 below the fold line EE ¹ and the above three trapezoid (first, second, third).

In FIG. 5 also shows the trapezoid:

ESS ¹ E ¹ - fourth trapezoid;

SGG ¹ S ¹ - fifth trapezoid;

GRR ¹ G ¹ - the sixth trapezoid.

Moreover, RR ¹ is the smallest base of all the upper bases of the trapezoid located on the rhomboid perforated strip 29 above the fold line EE ¹ , which for all trapezoids, in turn, is the largest of all the lower bases from the fourth trapezium to the sixth trapezoid.

Thus, the fold line EE ¹ is not only the lower base of the trapezoid ESS ¹ E ¹ , but also the largest base of the trapezoid FEE ¹ F ¹ and the longest of all the lower fold lines of the diamond-shaped perforated strip 29 and perforated ring 26 (Fig. 5, Fig. 7).

Moreover, the fold lines NN ¹ and RR ¹ are the shortest of all the fold lines of the diamond-shaped perforated strip 29 and the perforated ring 26 and NN ¹ ≡RR ¹ .

The ratio of the length of the fold line EE ¹ and NN ¹ (RR ¹ ) determines the value of step S _{1 of the} spiral 0 ₁ -0 ₁ (Fig. 4), and hence the pitch of winding the hollow perforated tunnel around the straight axis 0 ₂ -0 _{2 of the} spiral perforated body 1 .

For example, in FIG. 5 fold lines L ₆ <L ₅ <L ₄ <L ₃ and L ₀ <L ₁ <L ₂ <L ₃ .

The rhomboid perforated strip 29 is bent along the straight fold lines, which are the base of all six trapeziums and are parallel to each other (Fig. 5).

Then the diamond-shaped perforated strip 29 is bent along the fold lines with the formation of semicircles 36 (Fig. 6) and is rolled into a ring (Fig. 7) with pockets of curvilinear shape 14, 15, 16, 17, 18, 19 with centers of curvature located inside the cross section perforated ring 26.

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

As a result of such an assembly, helical lines shown in FIG. 3, for example, thickened lines 37-38, 39-40.

Thus, the perforated spiral housing 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 perforated housing 1 (two of the helical lines are shown in FIG. 3 as thickened lines 37, 38, 39, 40) and helical grooves inside and outside the spiral perforated body 1 in the form of pockets of curved shape 14, 15, 16, 17, 18, 19 on the inner surface and helical grooves on the outer surface 21, 22, 23, 24, 25, 26 at an angle α to the spiral axis hollow perforated spiral tunnel spiral perforated body 1.

Seed cleaning machine operates as follows.

The disturbing force of the vibrator 6 through the walls of the platform 2 and the perforated body 1 transfers the seeds and litter particles inside the perforated housing 1 and entering the perforated casing 1 in a continuous flow through the loading device 5. The seeds and litter particles rotate along vertical elliptical trajectories, in which and there is a process of their separation. In this case, the seeds and particles of litter not only intensively interact with each other, but also under the influence of vibration rotate in a plane perpendicular to the bore of the perforated body 1. Since the dimensions of the cross section along the length of the perforated body 1, the shape and location change, it is aggravated disturbance of the movement of seeds and litter particles, which in this case, interacting with the perforated walls of the housing 1, move from loading to unloading. The presence in the perforated body 1 of screw perforated surfaces around the perimeter of the perforated body 1 contributes not only to the complication of the trajectories of the seeds and particles of litter, but also their movement along the passage section of the perforated body 1 to the discharge side.

When seeds and litter particles move along the passage section of the perforated body 1 due to the change in the passage section in shape and size, compression and discharge zones are alternately formed in each section of the perforated body 1 over its entire volume, which intensifies the process of separation of seeds and particles of litter and expands technological capabilities. Seeds through the perforations of the housing 1 are taken out of it and fall on the slides 11 and 12, and transferred to the unloading devices 9 and 10 for removal of seeds. Litter through the discharge window 41, is discharged into the discharge device 7.

The technical and economic advantages of the seed cleaning machine arise due to the perforated spiral housing with perforated helical surfaces in the form of curved pockets with centers of curvature located inside the cross section of the hollow perforated tunnel, which intensifies the interaction of seeds and litter particles, expands technological capabilities, increases productivity and improves the quality of separation of seeds from litter.

Technical and economic advantages also arise due to the installation of a vibrator horizontally below the platform with a perforated body 1 and a change in the shape of the trajectory of movement in the form of a vertical ellipse, which ensures an increase in the specific gravity of the total kinetic energy (E _p ) and increases the productivity of separation of seeds and litter particles.

Claims (1)

A seed cleaning machine comprising a screening surface elastically mounted by means of elastic elements, a drive, loading and unloading devices, characterized in that the screening surface is made spiral from a hollow perforated tunnel with a multi-helical perforated surface, rolled around the perimeter along a spiral axis 0 ₁ -0 ₁ around the central axis a rectilinear axis 0 ₂ -0 ₂ , equipped with helical grooves inside at an angle to its spiral axis in the form of pockets of a curved shape with centers curvatures located inside the cross section of a hollow perforated tunnel assembled from sections in the form of perforated rings of the same shape and size, rolled up from the same perforated diamond-shaped strips, on which trapezes are placed, the sides of which are located on the sides of the diamond-shaped perforated strip, and the upper and the 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 pockets of a curved shape along the inner perforated surface of the hollow perforated tunnel of the spiral screening surface, while sections in the form of perforated rings are connected to each other by the lateral sides of the trapezoid.

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