RU2176563C2 - Seed cleaning apparatus - Google Patents

Abstract

FIELD: agricultural engineering. SUBSTANCE: seed cleaning apparatus has drum with sieving surface mounted through flexible members, charging and discharge devices and drive. Sieving surface is formed as succession of spatial interconnected similar sections formed as equilateral prism or oblique-angled parallelepipeds. Each section is turned relative to previous section for angle of 90 deg about axis of sieving surface which is arranged so as to define Z-shaped or helical lines of variable pitch along drum length. Each subsequent section exceeds previous section in the ratio of 2-1.5:1. EFFECT: increased seed cleaning efficiency and simplified construction. 9 dwg

Description

 The invention relates to agricultural machinery, and in particular to machines for cleaning seeds from litter in stationary conditions.

 Known seed cleaning machine (patent N 2007226, publ. In B.I. N 3, 1994), containing a drum in the form of installed around the perimeter of the drum between two cheeks on the helical surfaces of the sieves, made of at least three perforated strips of curved shape or in the form of perforated triangles.

 A disadvantage of the known machine is the insufficient intensity of mixing and separation.

A device for cleaning seeds is known (A.S. N 1808417, published in B. I. N 14, 1993), containing a screening surface installed by means of elastic elements, a loading and unloading device and a drive, the screening surface being made in the form of series-connected spatial identical sections in the form of an equilateral prism or in the form of an oblique parallelepiped, each of which in turn is formed flat geometrical figures and rotated with respect to the preceding by an angle of 90 ^o around the axis proseiv the guide surface of the drum to form the same length of the zigzag pitch helical lines, characterized in that each successive section is greater than the previous in the ratio 2-1,5: 1.

 A disadvantage of the known device is the insufficient intensity of sifting and limited technological capabilities in the form of insufficient intensity of mixing, as well as the need to create a tilt of the entire device to move seeds from loading to unloading.

 The technical solution to the problem is to increase the productivity and efficiency of seed cleaning.

The objective is achieved by the fact that the device for cleaning seeds containing a screening surface installed in the form of a drum by means of elastic elements, a loading and unloading device and a drive, the screening surface being made in the form of successively connected spatial identical sections, in the form of an equilateral prism or in the form of an oblique parallelepiped, each of which is rotated relative to the previous one by an angle of 90 ^o around the axis of the screening surface installed with the formation of zigzag silts and helical lines made with a variable pitch along the length of the drum, with each subsequent section being larger than the previous one in a ratio of 2-1.5: 1.

 The novelty of the invention lies in the fact that such a design of the screening surface along the perimeter allows not only the axial movement of seeds in the screening surface (drum) with a horizontal axis of rotation, to simplify the drive and increase the operational life, but also to increase the screening intensity due to the presence on the surface of the drum of helical broken lines with a variable length step that increases as the passage section from loading to unloading increases, which violates the stationary flow of seeds and increases productivity.

 In addition, the novelty is due to the fact that the elements from which the sections and subsections are assembled are different in area, size and configuration, therefore the mixing intensity increases, since these elements, working as shelves, capture portions of seeds of different volumes and direct them towards each other, thus violating the stationary motion of the flow of masses of seeds.

 The novelty is seen in the fact that the pitch of helical lines increases from loading to unloading, which not only ensures the movement of seeds, but also intensifies spatial movement and an increase in unbalance.

 The novelty is also seen in the fact that the area and cross-sectional shape of the screening surface along the length of the drum increases from loading to unloading, which not only intensifies the mixing process, since the stationary motion of the seed mass flows is violated, changing the amplitude of oscillations as the seeds move from loading to unloading , but also improves self-cleaning of sieves (sifting surface).

 In FIG. 1 shows a device for cleaning seeds, General view; in FIG. 2 is a section AA in FIG. 1; in FIG. 3 - screening surface, front view; in FIG. 4 - screening surface, top view; in FIG. 5 is a screening surface, side view along arrow A in FIG. 3; in FIG. 6 - one of the sections, axonometric projection; in FIG. 7 - the first subsection of the section of Fig.6; in FIG. 8 is a second subsection of FIG. 6; FIG. 9 - second section, axonometric projection.

 A device for cleaning seeds (Fig. 1, 2) contains a frame 1 on which a drive 2 is mounted, an unloading device 3, end cheeks 4 and 5, between which a screening surface (drum) 6 is rigidly fixed, a loading device 7, which is made in the form rigidly fixed in the shell 8, equipped with a cone 9 with screw winding 10.

 The drum 6 is mounted rigidly between the cheeks 4 and 5 and is equipped with a support ring 11, which is supported by two support rollers 12 and 13. The cheek 4 is connected rigidly by four rods 14 to the drive shaft 15 of the drive 2. The support rollers 12 and 13 are mounted on the frame 1.

 Frame 1 is suspended on three rubber-cord pneumatic cylinders 16, 17, 18. Two pneumatic cylinders 16 and 17 are mounted under loading device 7, and the third pneumatic cylinder 18 is mounted under unloading device 3 and along the axis of symmetry of frame 1.

 Pneumocylinders 16, 17, 18 are fixed on the bed 19. On the bed 19 under the unloading device 3, a receiving tray 20 for large litter is fixed. The screening surface 6 consists of a frame 21 on which perimeter sieves 22 are mounted, thus creating a screw screening surface in the form of series-connected spatial sections of different sizes and shapes, increasing from loading to unloading in an arithmetic progression.

 Under the screening surface 6, receiving trays 22 for fine litter are fixed, a receiving tray 23 for seeds.

 The screening surface 6 (Figs. 3, 4, 5) is made in the form of spatial alternately connected in series two different sections 24 and 25 (in Fig. 4, the contours of the sections are shown by a thickened line). Sections 24 and 25 differ from each other not only in shape, but also in size. Each of the sections 24 is mounted (Fig. 6) from two subsections connected to each other by the sides 28 and 29.

 Subsection 26 (Fig. 7) is mounted from a large equilateral trapezoid 30 and two miscellaneous triangles 31 and 32, the bases of which are equal to the lateral sides of the trapezoid 30 along which they are connected to each other. The lateral sides 33 and 34 of the triangles 31 and 32 are equal to the upper base 35 of the trapezoid 30 with the lower base 36.

 The second subsection 27 (Fig. 8) is mounted from a small equilateral trapezoid, which is connected by its sides to the small sides of the triangles 38 and 39. The bases 40 and 41 of the triangles 38 and 39, along which the subsection 27 is attached to the subsection 26 are equal to the sides 28 and 29 the trapezoid 37 and the lower base 36 of the trapezoid 30 with the formation of a large outlet section 24.

 The upper base 45 of the small trapezoid 37 of the subsection 27 is equal to the upper base 35 of the trapezoid 30 and the sides 33 and 34 of the triangles 31 and 32 of the subsection 26 to form a small inlet section 24.

 Each of the sections 25 is made in the form of a straight triangular prism formed by a diagonal cube section (Fig. 9).

 Therefore, the sides 46 and 47 forming the inlet and outlet of the section 25 are equal to each other and form a square equal to the corresponding inlet and outlet square of section 24, by which the sections 24 and 25 are connected to each other, forming a sieving surface.

Installation of the screening surface 6 is carried out in the following sequence. To a section with an inlet equal to 40 mm and an outlet in square shape, for example, with a side size equal to the openings equal to 50 mm, section 25 is connected after turning through 90 ^° , with an inlet equal to 50 mm. Then, after a rotation of 90 ^° , a second section 24 is connected to the outlet of section 25 with an inlet and sides equal to 50 mm and an outlet with sides of 60 mm, to which a second section 25 is connected with dimensions of the sides of the inlet of 60 mm. And again, after a rotation of 90 ^o , section 24 is connected with an inlet, the sides of which are 60 mm, and with an outlet of 70 mm, etc., i.e., the sides of each newly connected section increase in arithmetic progression.

 A device for cleaning seeds works as follows. Classified material flows into the loading device 7 in a continuous stream, which is then transferred to a screening device 6, i.e. into a rotating screw rotor. During the rotation of the sieves, the material is given oscillatory motion. Coarse trash is discharged into tray 20, fine trash is discharged into tray 22. A clean seed is discharged into the receiving tray 23. The separation of the proposed method provides not only an increase in productivity, but also provides self-cleaning screens.

Claims (1)

A device for cleaning seeds containing a screening surface installed in the form of a drum by means of elastic elements, a loading and unloading device and a drive, the screening surface being made in the form of successively connected spatial identical sections, in the form of an equilateral prism or in the form of an oblique parallelepiped, each of which is rotated relative to preceding an angle of 90 ^o around the axis of the screening surface mounted to form zigzag or helical lines, characterized by the fact that the zigzag or helical lines formed by variable pitch length of the drum, with each successive section at a ratio higher than the previous 2-1,5: 1.

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