RU2585477C2 - Sowing device - Google Patents

Abstract

FIELD: agriculture; machine building.

SUBSTANCE: seed dispenser comprises hopper, roller-reflector, cellular sowing disc vertically installed in a housing. Latter is composite, where in lateral annular grooves of composite cellular sowing disc there is a solid elastically deformable ring. In centre of outer surface of elastically deformable ring there are hollow thin-walled cylinders made integral with solid elastically deformable ring. Top bases of hollow thin-wall cylinders are part of sphere, convex to axis of rotation of composite cellular sowing disc. Radius of sowing disc is greater than radius of circle drawn at upper bases of hollow thin-wall cylinders of solid elastically deformable ring by 2/3 thickness of sown seeds. Along axis of cells of composite cellular sowing disc at lower base of hollow thin-wall cylinders solid elastically deformable ring is an annular groove whose width is greater than diameter of cells of composite cellular sowing disc.

EFFECT: invention enables sowing of seeds of different size without replacement of sowing disc with minimal damage thereof.

3 cl, 3 dwg

Description

The invention relates to agricultural machinery, in particular to apparatus for the exact sowing of seeds. A known metering device (AS USSR No. 1443835, A1 A01C 7/04, 1988 Bull. No. 46), providing increased accuracy of single-grain sowing of seeds by reducing the number of twins, containing a disk in the annular groove of which, made along the axis of the cells, under the ejector has a sector with increasing cross section height and spring-loaded end and a sowing apparatus (AS USSR No. 1644761 A2, A01C 7/04, 1991 Bull. No. 16) that provides sowing of seeds without replacing the sowing disk and equipped with a leash with focusing on interacting with done on There is a slice of the sector on its inside, with the leash located in the groove of the disk under the sector and connected to the housing with the possibility of longitudinal movement relative to the sector.

The disadvantages of these designs: the complexity of the manufacture and settings of the apparatus for sowing seeds of various sizes. In addition, a cantilevered sector with a spring-loaded end has a small thickness and a tendency to vibrate during operation, which reduces the quality of the sowing process.

Known sowing apparatus (RF Patent No. 2050764, A01C 7/04, 1995), which provides reduction of seed damage and increase the accuracy of sowing seeds of different fractions, containing a sowing disk with cells for seeds and a reflector roller, consisting of a hub on which the bandage is mounted with reflective surface made of resilient material.

The disadvantage of this design. In practice, it is very difficult to create the conditions for obtaining the so-called “flexible communication transmission” under which the seed can be rotated due to the friction force of the stretched part of the elastic surface against the seed surface, as a result of which conditions are created for injuring the seeds with a reflector roller.

Of the known closest in technical essence is a metering device (RF Patent No. 2132603, A01C 7/04, 1999), including a housing, a hopper, a roller-reflector, a vertically mounted honeycomb disc with an annular groove, a seed ejector in the groove and symmetrical annular grooves of rectangular cross-section in its side walls, a sector with a spring-loaded end in the form of a continuous strip placed in the cavity of the grooves and an annular groove, characterized in that the sector on the back side contains a stop resting on the inner cylinder -parameter surface of the annular groove in the cavity between the leaf spring end and a pusher placed freely radial strip, conjugate with the housing sector by a screw mechanism. The screw mechanism is located on the rear side of the housing and includes a protruding part of the sector with a scale and a through hole in which a screw is mounted, mated by a threaded connection to a bracket attached to the rear wall of the metering unit, while a compression spring is placed between the sector and the bracket, the longitudinal axis which coincides with the axis of the screw. The emphasis is made in the form of a cylindrical pin pressed into the sector body, and its axis is perpendicular to the sector plane.

The disadvantages of this sowing apparatus: the complexity of the design and adjustment of the apparatus for sowing seeds of a different size, implying the movement of each sector relative to the bracket, and the gap between the end of the spring and the reflector roller is controlled on a scale installed in the back of the case. The remoteness of the scale from the place of control and the presence of moving parts of the structure will not allow to provide this gap on the first attempt, which will significantly increase the time of preset.

The invention is aimed at eliminating the aforementioned disadvantages of the known. Namely, it significantly simplifies the design of the sowing apparatus and the tuning process for sowing seeds of a different size. The following technical result can be obtained from its use: reduction in the cost of the sowing apparatus, reduction in operating costs due to a decrease in the complexity of settings and maintenance, reduction in trauma to the sown seeds and, as a result, increase in productivity.

The specified technical result is achieved due to the fact that the metering device contains a hopper, a reflector roller, a vertically mounted honeycomb disc with a horizontal axis of rotation.

A feature of the invention is that the cellular sowing disk is made integral for ease of adjustment to sowing seeds of a different size, while a continuous elastically deformable silicone ring is installed in the side ring grooves of the composite mesh sowing disk. In the center of the outer surface of this ring there are hollow thin-walled cylinders made as a unit with a continuous elastically deformable ring, the main purpose of which is the possibility of deformation during the transfer of force from the reflector roller to the seed, as a result of which the cell volume increases and damage to the seeds is prevented.

In addition, the elastic forces of the deformed hollow thin-walled cylinders contribute to the expulsion of seeds when they approach the exhaust window made in the housing of the sowing apparatus, thereby preventing clogging of the cells of the sowing disk. The beginning of the ejection window is located in the third quadrant on the line formed by the intersection of the cylindrical surface of the housing and the plane passing through the axis of rotation of the composite mesh seed disc and deviated from the vertical plane passing through the axis of rotation of the composite mesh seed disk by an angle of 10 ... 20 degrees to the side opposite the rotation of the composite mesh seed disc. The end of the window is in the fourth quadrant on the line formed by the intersection of the cylindrical surface of the casing and the plane passing through the axis of rotation of the composite mesh seed disc and deviated from the vertical plane passing through the axis of rotation of the composite mesh seed disc by an angle of 10 ... 20 degrees in the direction of rotation of the composite mesh sowing disc. The proposed design of the exhaust window maximizes the self-cleaning of the cells of the composite cellular sowing disk.

In order to optimize the process of filling the cell with seeds and to exclude the possibility of two seeds getting into the cell, the upper bases of the hollow thin-walled cylinders are made as part of a sphere convex to the axis of rotation of the composite mesh seed disc, and the radius of the composite mesh seed disc is greater than the radius of the circle drawn along the upper bases hollow thin-walled cylinders of a continuous elastically deformable ring by an amount equal to 2/3 of the thickness of the sown seeds.

In order that hollow thin-walled cylinders during deformation could not injure sowing seeds, an annular groove is made along the cell axis of the composite honeycomb disc under the lower base of the hollow thin-walled cylinders of a continuous elastically deformable ring, the width of which is greater than the diameter of the cells of the composite honeycomb seed disc. This groove reduces the deformation force of hollow thin-walled cylinders.

The remaining signs of the claimed sowing apparatus are private, since they characterize only the specific implementation of a particular node of the sowing apparatus.

Graphic materials.

Figure 1 shows a diagram of the sowing apparatus. Figure 2 is a section aa in figure 1. Figure 3 - the metering unit enlarged.

The proposed metering apparatus includes a housing 1 (figure 1); hopper 2; a vertically mounted composite mesh sowing disk, consisting of two symmetrical parts - left 3 (figure 2) and right 4 with drilled cylindrical cells 5. The left 3 and right 4 parts of the sowing disk are rigidly fastened with screws 6. In the left 3 and right 4 parts of the sowing disk are made of lateral annular grooves in which a continuous elasto-deformable silicone ring 7 is installed (Fig. 1) with hollow thin-walled cylinders radially located in the center, made as a unit with a continuous elasto-deformable si ikonovym ring 7 and placed in the cells 5 of the composite seed disc. The upper bases of the thin-walled hollow cylinders to ensure the specified deformation parameters and reduce the damageability of the seeds 8 are made in the form of a part of a sphere convex to the axis of rotation of the composite mesh seed disc, and the radius of the composite mesh seed disc R _{1 is} greater than the radius R _{2 of the} circle drawn along the upper hollow bases thin-walled cylinders of a continuous elastically deformable ring by an amount equal to 2/3 of the thickness of sown seeds 8. Also, to ensure the specified parameters of deformation of hollow thin cylinder wall and reduce injuries to 8 seeds of seed disc composite honeycomb cells axis 5 under the lower base hollow thin-walled continuous cylinder compliant silicone ring 7, an annular groove 9 (3), the width B ₁ is larger than the diameter D ₁ cells composite porous seed disc.

Composite cellular sowing disk rotates with the shaft 10 (figure 1).

Above the outer surface of the composite honeycomb sowing disk without a gap, a reflector roller 11 is installed, which rotates together with the shaft 12 in the direction opposite to the rotation of the composite honeycomb sowing disk.

The horizontal axis of rotation of the roller-reflector 11 lies in the second quadrant in the plane passing through the axis of rotation of the composite mesh seed disc and deviated from the vertical plane drawn through the axis of rotation of the composite mesh seed disc by an angle α = 20 ... 30 degrees in the direction of rotation of the composite mesh seed meter drive. The surface of the reflector roller 11 is covered with a layer of elastic friction material 13, and its angular velocity is 2 ... 3 times greater than the angular velocity of the composite mesh sowing disk.

The housing 1 of the metering apparatus has a window 14 (Fig. 2), the beginning of which is located in the third quadrant on the line formed by the intersection of the cylindrical surface of the housing and the plane passing through the axis of rotation of the composite mesh metering disk and deviated from the vertical plane passing through the axis of rotation of the composite mesh seed disk at an angle β = 10 ... 20 degrees (figure 1) in the direction opposite to the rotation of the composite mesh seed disk, while the end of the window is in the fourth quadrant on the line, formed the intersection of the cylindrical surface of the housing and a plane passing through the axis of rotation of the composite porous seed disc and deflected from the vertical plane passing through the axis of rotation of the composite porous seed disc at an angle γ = 10 ... 20 degrees in the direction of rotation of seed disc honeycomb composite.

The metering device operates as follows.

Part of the seeds 8 (Fig. 1) located in the hopper 2, when the composite honeycomb disc rotates under the action of gravity, enters the cells 5 (Fig. 3) on the spherical surface of the hollow thin-walled cylinders of a continuous elastically deformable silicone ring 7. The depth of the cell 5 is calculated as follows so that the center of gravity of the seeds is below the outer surface of the composite honeycomb sowing disk. Thus, the seed 8 is firmly fixed in the cell 5. With a further rotation of the composite mesh seed disc, the reflector roller 11 (Fig. 1), covered with a layer of elastic friction material 13, presses on the seed 8 (Fig. 3) located in the cell 5, as a result, the hollow thin-walled cylinders, made as a unit with a continuous elastically deformable silicone ring 7, are deformed, the seeds 8 will be completely inside the cell 5.

The annular groove 9 made along the cell axis of the cells of the composite honeycomb disc under the lower base of the hollow thin-walled cylinders of a continuous elastically deformable ring 7 helps to reduce the strain on the hollow thin-walled cylinders, thereby preventing injury to the seeds 8. Reducing the trauma to the seeds 8 is also facilitated by partly made spheres , convex to the axis of rotation of the composite mesh seed disc, the upper bases of the hollow thin-walled cylinders of continuous elastic deformation uemogo silicone ring 7.

The ability of cell 5 of a composite cellular seed disc with hollow thin-walled cylinders made at the same time as a continuous elastically deformable silicone ring to “adapt” to seeds with different geometric sizes makes the meter more universal.

Another part of the seeds 8, which did not fall into the cell 5, is discharged by the reflector roller 11 (Fig. 1), rotating in the opposite direction to the rotation of the composite cellular seed disc, back to the hopper 2.

With further rotation of the composite cellular seed disc located in the cell 5, the seed 8 will lose contact with the layer of elastic friction material 13 of the reflector roller 11, but will be fixed in the cell 5 with the inner surface of the housing 1 until the cell 5 with the seed 8 as a result of rotation will be in the area of the exhaust window 14 (figure 2). Having lost emphasis, seed 8 under the influence of gravity and elastic forces of deformed hollow thin-walled cylinders of a continuous elastically deformable silicone ring 7 will fall out of cell 5 to the bottom of the furrow.

Thus, the proposed sowing apparatus will provide sowing of seeds of different sizes without replacing the sowing disk and reduce their injury, which ultimately leads to an increase in yield.

Claims (3)

1. The sowing apparatus, comprising a hopper, a roller-reflector, a vertically mounted cell metering disk, characterized in that the cell metering disk is made integral, while in the lateral annular grooves of the composite cell metering disk a continuous elastically deformable ring is installed, with the center of the outer surface hollow thin-walled cylinders are arranged integrally with a continuous elastically-deformable ring, the upper bases of hollow thin-walled cylinders are a part of the sphere that is convex to the axis of rotation of a composite mesh seed disc, the radius of which is greater than the radius of the circle drawn along the upper bases of the hollow thin-walled cylinders of a continuous elastically deformable ring, by an amount equal to 2/3 of the thickness of the sown seeds, and along the axis of the cells of the composite a cellular seed disc, under the lower base of the hollow thin-walled cylinders of a continuous elastically deformable ring, an annular groove is made, the width of which is greater than the diameter of the cells with fixed mesh sowing disc. 2. The metering device according to claim 1, characterized in that the horizontal axis of rotation of the reflector roller lies in the second quadrant in a plane passing through the axis of rotation of the composite mesh metering disk and deviated from the vertical plane drawn through the axis of rotation of the composite mesh metering disk by an angle 20 ... 30 degrees in the direction of rotation of the composite mesh seed disc, and the angular velocity of the reflector roller is 2 ... 3 times greater than the angular velocity of the composite mesh seed disc, while the surface Olika reflector coated with a layer of elastic frictional material and touches the outer surface of the composite porous seed disc. 3. The sowing apparatus according to claim 1, characterized in that the casing has a window whose beginning is in the third quadrant on the line formed by the intersection of the cylindrical surface of the casing and the plane passing through the axis of rotation of the composite mesh sowing disk and deviated from the vertical plane passing through the axis of rotation of the composite mesh seed disc, at an angle of 10 ... 20 degrees to the side opposite to the rotation of the composite mesh seed disc, while the end of the window is in the fourth quadrant on the line, o bounded by the intersection of the cylindrical surface of the casing and the plane passing through the axis of rotation of the composite mesh seed disc and deviated from the vertical plane passing through the axis of rotation of the composite mesh seed disc by an angle of 10 ... 20 degrees in the direction of rotation of the composite mesh seed disc.

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