RU2728425C1 - Pneumatic sowing apparatus - Google Patents

Abstract

FIELD: machine building.SUBSTANCE: pneumatic sowing apparatus includes hopper 10, housing 1 with seed chamber, groove 8 and transport channel 7, vertical sowing disk with dosing elements 4, having holes and projections 5 from elastic material, nozzle of excess pressure and shaft for drive to rotational movement of sowing disk. Each ledge 5 is made in the form of curvilinear polyhedron, flat base of which is fixed to surface of sowing disk. Side faces are composed of cylindrical surfaces conjugated with walls of transport channel 7 and made with radii rand rOn side of dosing elements 4 of vertical sowing disk ledges 5 are limited by cylindrical surface with radius R, which is determined from dependence,where kand kare the coefficients of friction of the surface of the seed transport channel and the surface of the projection, respectively; dis seeding conventional diameter of sown crop; R is the radius of the concentric circle of metering elements and the projections, and the curved upper face projections bounded by a cylindrical surface of radius R, which is determined from the dependencewherein bis the width of the protrusion.EFFECT: invention will make it possible to reduce seizure and damage of seeds, to increase quality of their dosing by a seeding device due to improvement of efficiency of discharge and removal of superfluous seeds.1 cl, 6 dwg

Description

The invention relates to agricultural machinery, in particular to machines for sowing seeds of agricultural crops.

Known pneumatic sowing device, including a hopper, a housing with a seed and pressure chamber, a transport channel and a groove, a channel for creating excess pressure, a shaft, a vertical sowing disc with metering elements. Projections made of elastic material are equally spaced between the holes. The walls of the protrusions on the side of the metering elements of the seeding disc are made radially, and the walls perpendicular to them are limited by arcs of concentric circles. In this case, the cross-section of the protrusions copies the cross-section of the transport channel (see patent RU 2355153 C1, A01C7 / 04, publ. 20.05.2009).

The disadvantage of this sowing device is the low quality of removal of excess seeds, due to the fact that in front of the protrusions, from the side of the metering element opening, the air flow rate is significantly reduced. Ineffective discharge of excess seeds leads to their pinching between the housing of the seeding unit and the surface of the seeding disc at the moment the metering element enters the transport channel of the seeding unit.

The closest technical solution is a pneumatic sowing device, including a hopper, a housing with a seed chamber, a groove and a transport channel, a vertical sowing disc with metering elements with holes and protrusions made of elastic material, an overpressure nozzle, a drive shaft for rotary motion of the sowing disc. In this case, the projections on the side of the metering elements of the seeding disc are made with cut edges, so that the angle between adjacent flat walls of the projection α in radians in the frontal plane of the seeding disc is determined from the dependence

,

,

k where _k and k _in - the coefficients of the edge of the transport channel of the seed sliding friction and the edge protrusion, respectively, d _s - diameter of the seed culture were plated, R - the radius of the concentric circle of metering elements and the projections, and the angle between adjacent walls protrusion β in radians per transverse the horizontal plane of the seeding disc is determined from the dependence

,

,

in this case, the length l of the flat radial wall of the protrusion must be less than the diameter of the seed of the sown crop (see patent for a useful model RU 185950 U1, A01C7 / 04, published on 25.12.2018).

The disadvantage of this sowing device is the ineffective removal of excess seeds, due to the fact that the proposed shape of the protrusions is poorly streamlined and creates aerodynamic resistance, which worsens the distribution of air flow in the area of the metering element of the sowing disc. In particular, it reduces the magnitude of the air flow velocity in front of the walls of the projections. In addition, the actual shape of the seeds of most crops sown differs from spherical and may include flat edges and corners. These forms include pyramidal, lenticular, flat, triangular and others. Therefore, at the moment of pinching the seed with a shape other than spherical, between the edge of the transport channel and the protrusion of the sowing disc, the seed comes into contact with the flat edge of the protrusion in several places or the contact area increases, which leads to the loss of sliding of the seed on the protrusion and its seizure with subsequent damage.

The objective of the present invention is to prevent jamming and reduce damage to seeds, improve the quality of their dosing by the metering device by improving the efficiency of dumping and removing excess seeds.

The essence of the invention lies in the fact that a pneumatic sowing device, including a hopper, a housing with a seed chamber, a groove and a transport channel, a vertical sowing disc with metering elements having holes and protrusions, an overpressure nozzle, a shaft for driving the seeding disc in rotational motion, when In this case, the protrusion is made by a curved polyhedron, the flat base of which is attached to the surface of the seeding disc, and the side faces are composed of cylindrical surfaces mated with the walls of the transport channel and made with radii r ₁ and r ₂ , and from the side of the metering elements of the vertical seeding disc the protrusions are limited by the cylindrical surface radius R ₁ , which is determined from the dependence

,

,

where k _to and k _in - coefficients of sliding friction of the seed on the surface of the transport channel and the surface of the protrusion, respectively; d _c - conditional seed diameter of the sown crop; R is the radius of the concentric circle of the metering elements and protrusions, and the upper curved edge of the protrusion is limited by a cylindrical surface with radius R ₂ , which is determined from the dependence

,

,

.where b _in is the width of the protrusion, in addition, the lateral edge of the protrusion can be limited to one cylindrical surface with a diameter D _in , which is not less than the maximum size of the seeds of the sown crop and is determined by the formula

...

The task is achieved by the fact that the protrusion is made by a curvilinear polyhedron, the flat base of which is attached to the surface of the seeding disc, and the lateral faces are made up of cylindrical surfaces conjugated with the walls of the transport channel and made with radii r ₁ and r ₂ , and from the side of the metering elements of the vertical seeding of the disk, the protrusions are limited by a cylindrical surface with a radius R ₁ , which is determined from the dependence

,

,

where k _to and k _in - coefficients of sliding friction of the seed on the surface of the transport channel and the surface of the protrusion, respectively; d _c - conditional seed diameter of the sown crop; R is the radius of the concentric circle of the metering elements and protrusions, and the upper curved edge of the protrusion is limited by a cylindrical surface with radius R ₂ , which is determined from the dependence

,

,

.where b _in is the width of the protrusion, in addition, the lateral edge of the protrusion can be limited to one cylindrical surface with a diameter D _in , which is not less than the maximum size of the seeds of the sown crop and is determined by the formula

...

The essence of the invention is illustrated by drawings, where on

figure 1 shows a diagram of a pneumatic sowing device;

Fig. 2 is a diagram of a pneumatic sowing device, section A-A;

Fig. 3 is an axonometric projection of the projection of the seeding disc with a lateral compound curved edge.

Fig. 4 is an axonometric projection of the projection of the seeding disc with a lateral cylindrical edge;

Fig. 5 is a diagram of the entry of the projection of the seeding disc into the transport channel;

fig. 6 - diagram of the entrance of the projection of the seeding disc into the transport channel, view B.

The pneumatic sowing device includes a housing 1 (Fig. 1), in which a vertical seeding disc 3 with metering elements 4 and protrusions 5 is installed and fixed on the horizontal drive shaft 2 (Fig. 2) 5. In the housing 1, a seed chamber 6 is made, a transport channel 7 and groove 8. The protrusions 5 of the vertical sowing disc 3 are equidistantly located between the metering elements 4. The protrusion 5 (Fig. 5) is made with a curved polyhedron, which includes a flat base and curved side and top edges. The flat base of the projection 5 is attached to the surface of the seeding disc 3.

The side face of the protrusion 5 (Fig. 3) is made up of several cylindrical surfaces mated with the walls of the transport channel 7 and made with radii r ₁ and r ₂ . In addition, from the side of the metering elements 4 of the vertical sowing disc 3, the protrusions are limited by a cylindrical surface with a radius R ₁ , which is determined from the dependence

,

,

k where _k and k _a - seed sliding coefficients of friction of the surface of the transport channel 7 and the surface of the projection 5, respectively; d _c - conditional seed diameter of the sown crop; R is the radius of the concentric circle of metering elements 4 and projections 5.

The upper curved face of the protrusions is limited by a cylindrical surface with a radius R ₂ , which is determined from the dependence

,

,

where b _in is the width of the projection 5 of the seeding disc.

.Also, the side edge of the protrusion 5 (Fig. 4) can be limited by one cylindrical surface with a diameter D _in , which is not less than the maximum size of the seeds of the sown crop and is determined by the formula

...

The cross section of the transport channel 7 copies the radial section of the projections 5 of the seeding disc 3.

The seed chamber 6 of the pneumatic sowing device is communicated through the inlet window with the hopper 10 (Fig. 1). Also, the seed chamber 6 is connected to an injection source (not shown) through a nozzle 9 to create excess air pressure. The vertical sowing disc 3 in the housing 1 is sealed with a gasket 11, which is fixed with a cover 12.

The pneumatic sowing device works as follows.

From the hopper 10, the seeds through the inlet port enter the seed chamber 6. Through the overpressure nozzle 9, air is supplied to the seed chamber 6 of the seeding device. When the vertical sowing disc 3 rotates, the seeds, under the action of the lateral pressure of the seeds in the layer and the excess air pressure in the seed chamber 6, are captured by the metering elements 4. To enter the protrusions 5 of the seeding disk 3 into the seed chamber 6, a groove 8 is made in the base of the housing 1. elements 4 move to transport channel 7.

In the upper part of the seed chamber 6, when the overpressure nozzle 9 passes and enters the transport channel 7, the air stream removes excess seeds from the metering elements 4.

Once in the transport channel 7, the metering element 4 with the captured seed is completely cut off by the protrusion 5 from the excess pressure in the seed chamber 6. In the transport channel 7 at atmospheric pressure, the seeds under the action of the protrusions 5 move to the outlet and are dumped into the opener.

In this case, the design of the protrusions 5 with lateral and upper cylindrical edges in comparison with the protrusions 5 with flat edges will improve their streamlining in the air flow and reduce the aerodynamic resistance and the effect on the distribution of the air flow in the area of the metering element 4 of the seeding disc 3. This, in turn, will allow keep the air flow rate within the values of the seed hovering rate of the sown crop and improve the discharge of excess seeds. Also, the implementation of protrusions 5 with lateral cylindrical faces of radii R ₁ and an upper cylindrical face of radius R ₂ or with one lateral cylindrical surface of diameter D _in and an upper cylindrical face of radius R ₂ will allow for any shape of the seed, including other than spherical, to reduce it contact with the edge of the protrusion 5 (Fig. 5 and 6) in one line or point and maximally reduce the contact area, which means to prevent loss of sliding with subsequent jamming of the seed. This will provide a more reliable ejection of seeds without pinching between the protrusions 5 of the seeding disc 3 and the surface of the transport channel 7.

Claims (5)

Pneumatic sowing device, including a hopper, a housing with a seed chamber, a groove and a transport channel, a vertical sowing disc with metering elements with holes and protrusions made of elastic material, an overpressure nozzle, a shaft for driving the seeding disc in rotational motion, characterized in that the protrusion is made in the form of a curved polyhedron, the flat base of which is fixed to the surface of the seeding disc, and the side faces are composed of cylindrical surfaces mated with the walls of the transport channel and made with radii r ₁ and r ₂ , and on the side of the metering elements of the vertical seeding disc, the protrusions are limited by the cylindrical surface radius R ₁ , which is determined from the dependence

where k _to and k _in - coefficients of sliding friction of the seed on the surface of the transport channel and the surface of the protrusion, respectively; d _c - conditional seed diameter of the sown crop; R is the radius of the concentric circle of the metering elements and protrusions, and the upper curved edge of the protrusion is limited by a cylindrical surface with radius R ₂ , which is determined from the dependence

where b _in is the width of the protrusion.

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