RU2195100C1 - Seeding unit - Google Patents

Abstract

FIELD: agricultural engineering. SUBSTANCE: seeding unit has horizontal cellular drive disk with seed baffle made in the form of cylindrical brush with axis of rotation perpendicular to disk rotation axis. Cylindrical brush inoperative zone is covered with housing. Baffle has drive. Cells in disk are shaped in accordance with shape of seeds to be sown and are defined by group of openings. Openings in each group are spaced from axis of rotation of disk by different distances. Geometric centers of peripheral cells on disk are offset backward from centers of inner cells by value equal to 2-3 sizes of seed length. Connecting members are extending in concentric circles on disk surface at both sides of each cell in offset relation with respect to peripheral edge toward its center, with height of each connecting member exceeding seed thickness by 1.08-1.15 times. Seeding disk of such construction is preferably used for seeding cucurbitaceous crop seeds. EFFECT: increased efficiency, reduced damage to seeds and improved seeding quality. 3 dwg

Description

 The invention relates to agricultural machinery, in particular to sowing apparatus for sowing seeds of melons, mainly watermelons, pumpkins, melons, etc.

 Known sowing apparatus for gourds, including a seed box, a visor, a driving drum, a pallet, a tension drum, cells, active guides, sidewalls, a reflector, additional sidewalls, teeth, a seed drive and a drive (see Abezin V.G. Resource-saving soil-protective technology of mechanized cultivation and harvesting of melons and gourds // Textbook. - Elista, 1993.-120p. -S. 37-40, Fig. 11).

 The disadvantages of the described apparatus include the impossibility of laying seeds with a mutual distance of 3-4 cm from each other within the same nest. This is necessary to preserve the germinated seeds from the destruction of agricultural crops. pests, in particular wireworms.

 The closest technical solution to the claimed object in terms of features is a sowing apparatus comprising a horizontally arranged mesh disk with a seed reflector, in which, in order to reduce damage to the seeds during sowing, the seed reflector is made in the form of a cylindrical brush with an axis of rotation perpendicular to the axis of rotation of the disk, a casing closed in a non-working zone; in order to drive the brush into rotation, the disk is provided with holes in which the teeth of the sprocket enter, which mesh with the sprocket attached to the brush; in order to clean the brush of dirt, a comb is installed on its casing (SU, copyright certificate 375046. M.cl. A 01 C 7/16.

 The sowing apparatus // Lobachevsky P. Ya., Bondarenko P. M. Declared on 11.28.1969, published on 03.23.1973).

 The disadvantages of the described apparatus, despite the possibility of single-grain sowing, that is, dashed sowing during movement, the described sowing apparatus does not provide the required seed output in quantitative terms and by the time of their supply to the vas deferens.

 The invention consists in the following.

 The problem to which the claimed invention is directed is the formation of seed nests with mutual distance from each other at a distance of 5-6 cm.

 The technical result is the preservation of seedlings in the early spring period of growth from damage by agricultural pests and diseases and increased productivity due to the uniform and complete population of melon crops in the allocated area.

 The specified technical result is achieved by the fact that in a known metering apparatus comprising a horizontally arranged mesh drive disk with a seed reflector in the form of a cylindrical brush with an axis of rotation perpendicular to the axis of rotation of the disk, closed by a casing in the inoperative zone, and its drive, according to the invention, cells on the disk with the shape of the seeds of the sown culture, they are formed by groups of through holes, the latter in each group made with different distances from the axis of rotation of the disk, while the geometric centers of the cells and the peripheral part of the disk is shifted back from the centers of the inner cells by an amount equal to 2-3 sizes of the length of the seeds, on the surface of the disk with a shift from the peripheral edge to its center along concentric circles, there are jumpers on the sides of each cell, 1.08-1 high 15 times more than seed thickness.

 This eliminates mechanical damage to the seeds, high-quality and complete (without allowances) filling the cells and ensures the sowing of seeds in the nests in the “line”, as well as the quality of sowing and obtaining the desired productivity of the sown heat-loving culture.

 The invention is illustrated by drawings.

 Figure 1 shows the sowing apparatus, a top view.

 In FIG. 2 - section AA in figure 1, a vertical diametrical section in the plane of placement of the seed reflector.

 Figure 3 - section bB in figure 2, a vertical diametrical section of the sowing apparatus in the plane of placement of the ejector seeds above the sowing window of the bottom.

 Information confirming the possibility of implementing the claimed invention are as follows.

 The sowing apparatus, mainly for sowing seeds of gourds, includes a cylindrical seed jar 1, a bottom 2, a hollow truncated cone tedder 3, a drive disk 4 horizontally located with a seed reflector 5 in the form of a cylindrical brush 6 with an axis of rotation perpendicular to the axis of rotation of the disk 4, closed by a casing 7 in the non-working zone, and its drive, the seed ejector 8, mounted above the sowing window 9 in the bottom 2. The cells on the disk 4 with the shape of the seeds of the sowing culture are formed by groups of through holes 10, 11 and 12.

On the disk in 4 groups, through holes 10, 11 and 12 are made. Holes 10-12 are given a shape in the plane of the disk 4 corresponding to the profile (shape) of the seeds of the melted melon crop with the following parameters:
- the length and width of the hole is 20-30% more than the weighted average sizes of calibrated seeds;
- the thickness of the disk 4 is greater than the thickness of the seeds by 0.1-0.3 mm.

The holes 10, 11 and 12 in each group are made with different distances from the axis of rotation of the disk 4 by the radii ρ ₁ , ρ ₂ and ρ ₃ , while the center of the hole 11 with respect to the center of the hole 10 is shifted by the length of the seed, and the center of the hole 12 is the ratio of the center of the hole 10 is mutually offset by an amount equal to a double-triple length of the seed. With a larger number of cell openings in each group, the geometric centers of the cells on the peripheral part of the disk 4 are shifted back from the centers of the internal cells by an amount equal to 2-3 sizes of the length of the seeds, and the intermediate openings in equal shares of the selected value.

 On the surface of the disk 4 with an offset from the peripheral edge to its center are made concentric circles separated by jumpers 13, 14, 15 and 16 groups of holes 10, 11 and 12. Each group of holes 10-12 on the surface of the disk is placed with an equal angular pitch, and holes 10 and 11 are displaced back from the radius vector 17 of the disk with an increasing linear step: holes 11 from the radius vector 17 are removed by an amount multiple of the length of the sown seed, and holes 10 are removed by an amount twice that of the seed. The jumpers 13-16 made on the sides of each cell have a height of 1.08-1.15 times more than the thickness of the seeds. The length of the jumpers 13 and 16 is 15-20% longer than the length of the seed, and the length of the jumpers 14 and 15 exceeds the size of the seed by 2.2-2.3 times.

 The height of the bridges 13-16 more than the thickness of the seeds by 8-13%.

 The agitator 3 is fixed to the disk 4 by means of fixation 18.

 The metering unit is located on the coulter bracket.

 The disk 4 and the reflector 5 seeds drive rotation is obtained from the supporting-rolling wheels of the coulter (sowing section).

 The metering unit is equipped with a set of interchangeable discs 4.

 The metering device operates as follows.

 Calibrated seeds are poured into seed jar 1. The size of the seeds corresponds to the size of the holes 10-12. When the seeder is moved from the support-rolling wheel, the disk 4, the reflector 5, the ejector 8 and the agitator 3 are rotated. When the disk 4 is rotated due to the agitator 3, the seeds move relative to the inner wall of the can 1. At the same time, due to the internal friction of the seeds and the higher linear speed of the seeds on the peripheral part of disk 4, each seed with its long axis is oriented along the largest axis of the cell, i.e. holes 10-12. Seeds due to backwater of the upper layers fall into holes 10-12. The required seed placement in holes 10-12 is facilitated by jumpers 13-16. The pairs of jumpers 16-15, 15-14, 14-13 form a space above the upper plane of the disk 4. Thanks to these jumpers 16-13, the seeds, with their long axes, orient themselves in the holes 10-12 and sink into them. By rotating the disk 4, the seeds laid in the holes 10-12 between the jumpers 13-16 are fed to the brush 6 of the reflector 5. The seed layer is shifted from the upper cut of the jumpers 13-16. Seeds between jumpers 13-16 are pressed into holes 10-12. The casing 7 eliminates the pressure of the seeds from above on the brush 6. The seeds laid in the openings 10-12 are fed to the elastic disks of the ejector 8 seeds. The first to the ejector 8 is the seed placed in the hole 12 between the jumpers 16 and 15.

With the ejector disk 8, the seed is pushed into the window 9 on the bottom 2. From the window 9, the seed, under its own weight, falls through the channel to the bottom of the open furrow. Following the first seed from the hole 11 on the disk 4, the second seed is ejected by the elastic disk of the ejector 8. It also goes to the opener channel. From the first group of holes 10-12, the last seed is pushed out of the hole 10. Due to the displacement of holes 10-12 from the radius vector 17 and different distances from the axis of rotation of the disk 4, seeds with an equal time interval Δt ₁ enter first in window 9, and then along the opener channel they fall to the bottom of the open furrow. Due to this, the seeds are placed in a nest 3-6 cm long. Soil bridges are formed between the seeds in a row, which exclude damage to the seed germ from the farm. pests.

The next slot is formed when the next group of holes 10-12 approaches the window 9 due to the rotation of the disk 4 by an angle of rotation equal to the angle between adjacent radius vectors 17. The rotation time Δt _{2 of the} disk 4 by this angle corresponds to the time for the formation of the next socket for placement with a given step of melon seeds or any other row crop.

 Thus, the displacement of the cells in the form of holes 10-12 in each group allows you to form a nest of three seeds elongated along the row. This achieves high quality sowing.

Claims (1)

 The sowing apparatus, mainly for sowing seeds of melons, including a horizontally located mesh drive disk with a seed reflector in the form of a cylindrical brush with an axis of rotation perpendicular to the axis of rotation of the disk, closed by a casing in the inoperative zone, and its drive, characterized in that the cells on the disk with the shape of the seeds of the sown culture are formed by groups of through holes, the latter in each group are made with different distances from the axis of rotation of the disk, while the geometric centers of the cells on the peripheral parts of the disk are displaced back from the centers of the inner cells by an amount equal to 2-3 sizes of the length of the seeds; on the surface of the disk with a shift from the peripheral edge to its center along concentric circles, there are 1.08-1.15 times greater jumpers on each side of each cell than the thickness of the seeds.

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