RU2448444C1 - Pneumatic seed drill with central metering system - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: system contains a source of excess air pressure series-connected with pneumatic pipelines, as well as a hopper with a dispenser of roll type, a distributor of seeds and divider of pneumatic flow. The distributor of seeds comprises a chamber, which lateral surface is made in the form of a rotary body having a lid and a bottom. The chamber is connected by the outlet pneumatic hoses with openers. The bottom of the chamber of the distributor of seeds is made convex, and pipes of outlet pneumatic hoses are located along its perimetre. The final section of pneumatic pipeline is divided to at least two pneumatic channels connected to the lateral surface of the chamber of the distributor of seeds over the pipes of outlet pneumatic hoses. In the pneumatic hoses through holes are made.

EFFECT: pneumatic seed drill with a central metering system is introduced.

5 cl, 9 dwg

Description

The present invention relates to agricultural machinery, in particular to pneumatic seeders that implement the principle of central metering of seeds with pneumatic transportation of seeds to the coulters or other working bodies for planting seeds in the soil.

A pneumatic seeder with a central metering system is known, comprising a frame with support wheels, on which a source of excess air pressure, a hopper with a seed meter and a two-stage seed distributor including a first stage in the form of a dividing head, the inner chamber of which is connected from below to the pneumatic pipe, are connected in series with the pneumatic pipes. which in its final section at the point of connection to the camera of the dividing head is made in the form of a vertical column, and the side surface of the camera is dividing head coupled pnevmorukavami dividing head with five second stage seed distributor. Pnevmorukava connected from below to the chambers of the dividing heads of the second stage, and their end sections are made in the form of vertical columns, and to the lateral surfaces of the chambers of the dividing heads are connected the discharge air hoses connected to the openers of the seeder (Pneumatic sowing complex Tom-10. Prospect LLC Agro ( Kemerovo) at the international agricultural exhibition "Golden Field", Ust-Labinsk, Krasnodar Territory, 2009).

The disadvantages of the known pneumatic seeder with a central metering system are the high uneven distribution of seeds between the coulters of the seeder and, as a result, the high uneven distribution of seeds in the furrow with the ordinary method of sowing and on the surface of the field with scatter subsoil sowing, as well as the low throughput of the central metering systems and the significant complexity of maintenance during the operation of the seeder, the complexity of its design and material consumption.

These disadvantages are due to the following. The central metering system of the known pneumatic seeder, which implements the principle of central metering of seeds with pneumatic transportation of seeds to the coulters, is a two-stage. The total uneven distribution of seeds among the coulters with dividing heads of the first and second stages reaches 16 ... 19%.

The high uneven distribution of seeds between the openers of the seeder leads to significant deviations from the specified seeding rate, increasing the uneven distribution over the surface of the field. This unevenness of the seeding rate leads to the formation of places of excessive density of plant standing in the crop, which increases the competition of cultivated plants for environmental resources: nutritional area, light exposure, moisture. In areas of the field where sowing is sparse in comparison with the optimal density of standing of plants of a particular variety, environmental resources are used irrationally. In both cases, the crop yield is reduced.

In addition, the presence of two stages of seed distribution reduces the throughput of the central metering system of the seeder. This limits the increase in translational speed of the seeder during the sowing process and, as a consequence, its productivity.

To reduce the uneven distribution of seeds between the coulters to 5 ... 7%, two fans are used in the design of the two-stage central metering system of the SZS-14 seeder (see Klenin N.I., Kiselev S.N., Levshin A.G. Agricultural machines. - M .: Kolos, 2008 .-- p. 193 p.). The presence of a second fan and a distribution head on a vertical column of the first stage of the seed distributor increases the material consumption of the seeder, complicates its design and, as a result, reduces reliability and increases the complexity of maintenance.

The process of separating the flow of seeds in the dividing heads of the seed distributor of the known seeder is carried out by hitting the seeds on the surface and reflecting them from it. On impact, the seeds undergo compression deformation. The upper limit of the permissible speed of air movement during pneumatic transportation of seeds in a vertical column of the seed distributor of the seeder is limited by the risk of injury to the seeds and, according to the recommendation, should not exceed 27 m / s (Klenin N.I., Sakun V.A. Agricultural and land reclamation machines. - M .: Kolos, 1994 .-- p. 210). This limits the throughput of the central metering system of the seeder and, as a result, its productivity during sowing.

The limitation of aerodynamic characteristics (air flow velocity, its dynamic pressure, air flow) of the central metering system of the seeder, which appears due to the presence of two stages of seed distribution and the use of shock as the main factor in the separation of seeds in dividing heads, creates the potential for clogging of the discharge air tubes with seeds . Clogging of the discharge pneumatic hoses increases the laboriousness of servicing the drill during sowing.

Seeds remain and accumulate at the bottom of the chamber of the dividing heads of the seed distributors as a result of changes in the aerodynamic characteristics of the air flow during sowing. The need to remove them from the chambers of the dividing heads, in particular when switching to sowing a different variety or crop, increases the laboriousness of servicing the seeder and the time spent on its downtime.

Known pneumatic distributor for seeds of a seeder with a central metering system containing a dividing head connected by outlet pneumatic hoses with furrow dividers and located on a vertical column, which is connected to rows of pneumatic pipes made in the form of a venturi connected by an air chamber that divides the air flow and pneumatically connects blower, two hoppers having metering systems connected to venturi pipes through control valves (RF patent No. 2255455, class A01 7/08, A01S 15704, 2003).

The disadvantages of the known pneumatic distributor of seeds of the seeder are the significant uneven distribution of seeds between the furrowers and the low throughput of the pneumatic distributor for seeds of the seeder.

These disadvantages are due to the following. In the known pneumatic seed distributor, the seed flow is divided according to a single-stage scheme in round dividing heads, i.e. in the form of a body of revolution, having a cover and a bottom. Moreover, the diameter of the dividing head is greater than its height. This ratio of the indicated sizes is performed in order to bring the surface of the lid closer to the inlet of the vertical column located at the bottom of the chamber. This provides a more intense impact of seeds on the lid. The air stream transporting the flow of seeds enters the dividing head through the holes in its bottom, the seeds, hitting the lid and reflecting from it, are distributed along the discharge pneumatic hoses. The uneven distribution of seeds between the furrowers-openers reaches 9 ... 16% (see Klenin N.I., Kiselev S.N., Levshin A.G. Agricultural machines. - M .: Kolos, 2008. - p.192 p.) . The consequence of such a significant uneven distribution of seeds between the furrowers-openers are significant deviations from the set seeding rate allowed by the furrowers-openers. This reduces the uniformity of the distribution of seeds on the surface of the field and, as a result, the yield of the cultivated crop.

Seeds in the process of separation along the discharge pneumatic hoses hit the lid of the dividing head, are subjected to dynamic compression deformation. The upper limit of the permissible air velocity during pneumatic transportation of seeds is limited by the danger of damage to the seeds and, according to the recommendation, should not exceed 27 m / s (Klenin N.I., Sakun V.A. Agricultural and land reclamation machines. - M .: Kolos, 1994. - p. .210). This limits the throughput of the pneumatic seed distributor and, as a result, increases the translational speed of the sowing unit during sowing, reducing its productivity.

In addition, the design of the bottom of the inner part of the dividing head has horizontally located sections on which seeds are delayed and accumulate. When switching to sowing another variety or culture, the removal of these seeds from the dividing head is required, which increases the laboriousness of servicing the seeder during its operation.

The closest in technical essence and the achieved result to the proposed device is a pneumatic seeder with a central metering system, which contains a source of excess air pressure, a hopper with a spool type metering unit and a seed distributor, with one step of dividing the seed stream transported by air and a dividing head, having a chamber with a side surface in the form of a body of revolution, a cover and a bottom, and mounted on a vertical column equipped with a turbulence congestion, made in the form of corrugations or rings attached to the inner surface of the vertical columns. Moreover, the round dividing head of the seed distributor is connected by diverting vas deferens with the openers of the seeder (see the book Klenin N.I., Kiselev S.N., Levshin A.G. Agricultural machines. - M .: Kolos, 2008. S.202-204 - prototype).

The disadvantages of the device adopted for the prototype are the significant unevenness of the distribution of seeds between the openers of the seeder and, as a result, the high unevenness of the distribution of seeds in the furrow with the ordinary method of sowing and on the surface of the field with variable subsoil sowing, as well as the low throughput of the central metering system, significant the complexity of the maintenance of the seeder during operation, the complexity of the design and material consumption.

These disadvantages are due to the following. The design of the round distribution head of the seed distributor allows uneven distribution of seeds among the openers equal to 9-16% (Klenin N.I., Kiselev S.N., Levshin A.G. Agricultural machines. - M .: Kolos, 2008. - p. .192 pp.), Which reduces the uniform distribution of seeds on the surface of the field and, ultimately, the yield of the cultivated crop.

During the distribution of seeds along the discharge pneumatic hoses, the seeds are reflected from the surface of the lid of the dividing head, which can be flat, concave or convex. Seeds hit the surface of the lid, undergo dynamic compression deformation. The upper limit of the permissible air velocity during pneumatic transportation of seeds is limited by the danger of damage to the seeds and, according to the recommendation, should not exceed 27 m / s (Klenin N.I., Sakun V.A. Agricultural and land reclamation machines. - M .: Kolos, 1994. - p. .210). This limits the increase in the translational speed of the sowing unit during the sowing process and, as a result, its performance.

The presence of a turbulator in a vertical column complicates the design of the known pneumatic seeder.

In addition, the design of the chamber of the dividing head has horizontally located sections on which seeds are delayed and accumulated during sowing. When switching to sowing a different variety or culture, the removal of these seeds is required, which increases the complexity of servicing the seeder.

The technical solution to the problem is to increase the uniformity of the distribution of seeds between the openers of the seeder.

The objective is achieved in that in a pneumatic seeder with a central metering system containing a source of excess air pressure, a hopper with a spool type meter and a seed distributor, a pneumatic flow divider and a seed distributor, which includes a chamber whose lateral surface is made in the form of a body of revolution having a cover and a bottom connected by outlet pneumatic hoses with openers, according to the invention, the bottom of the chamber of the seed distributor is made convex along its perimeter p found on the rear pipes for diverting air tubing, the end portion of the air tube divided into at least two pnevmokanala connected to the lateral surface of the chamber above the seed distributor nozzles diverting air tubing, where through holes.

In a preferred embodiment of a pneumatic seeder with a central metering system, the apex of the convex bottom of the seed distributor chamber is located at the level of the connection of the pneumatic channels to the side surface of the seed distributor chamber, and the surface of the convex bottom is provided with ribs installed along its generatrix and between the branch pipes of the outlet pneumatic hoses.

In another preferred embodiment, a pneumatic seeder with a central metering system connecting the pneumatic channels to the seed distributor chamber is located opposite each other.

In a further embodiment of a pneumatic seeder with a central metering system, the through holes of the outlet pneumatic hoses are arranged along their longitudinal axes with the possibility of individual overlap.

In yet another embodiment, a pneumatic seeder with a central metering system, the inner surface of the portion of the pneumatic pipe located in front of the airflow divider is provided with protrusions.

The novelty of the claimed technical solution lies in the fact that due to the convex bottom of the chamber of the seed distributor, the formation of the air flow entering the nozzles of the outlet pneumatic hoses is provided, and at the same time the supply of seeds from the top of the chamber of the seed distributor to the nozzles of the outlet pneumatic hoses separation of the flow of seeds in a downward flow of air is provided, and at the same time, the movement of seeds under the influence of its own weight is used. In addition, areas in the chamber where seeds could accumulate during the operation of the seeder, i.e. self-cleaning of the chamber from seeds is provided, which prevents sorting.

The location of the nozzles for the outlet pneumatic hoses along the perimeter of the bottom also provides for the separation of the seed flow in the downward air flow.

The separation of the final section of the pneumatic pipeline into at least two pneumatic channels and their connection to the lateral surface of the seed distributor chamber above the branch pipes of the pneumatic hoses ensures the formation of a fluidized state of seeds in the upper part of the chamber due to the interaction of the translational air streams emerging from the pneumatic channels passing in the upper part of the chamber into a state of intense turbulent air, along with the seeds moving in it. This provides an increase in the uniformity of the distribution of seeds over the entire volume of the upper part of the chamber and, as a consequence, the uniformity of their distribution when falling down and further along the nozzles of pneumatic hoses.

The connection to the side surface of the chamber of the seed distributor above the branch pipes of the outlet pneumatic hoses ensures the separation of the seed flow in a downward air flow.

The implementation of through holes in the exhaust pneumatic hoses allows you to adjust the air flow in the exhaust pneumatic hoses, preventing them from clogging with seeds and ensuring a steady flow of the process.

The location of the top of the convex bottom of the chamber of the seed distributor at the level of connection of the pneumatic channels to the side surface of the chamber of the seed distributor increases the degree of influence of the bottom on the separation of the flow of seeds in a downward air flow.

The supply of the surface of the convex bottom with ribs installed along its generatrix and between the nozzles of the outlet pneumatic hoses increases the uniformity of supply to the nozzles of the outlet pneumatic hoses of seeds falling down from the turbulent medium of the upper part of the chamber. This is due to the fact that the ribs limit the movement in the transverse plane of the seeds coming down.

The location of the connection of the pneumatic channels with the chamber of the seed distributor against each other increases the turbulent state of the medium and, as a consequence, the intensity of the fluidized state of the seeds in the upper part of the chamber, and hence their uniformity of dispersal in the upper part of the chamber.

The location of the through holes of the exhaust pneumatic hoses along their longitudinal axes with the possibility of individual overlap provides a wide range of adjustment of the aerodynamic characteristics of the air flow in the exhaust pneumatic hoses.

The supply of protrusions to the inner surface of the section of the pneumatic pipe, located in front of the divider of the pneumatic stream, creates a turbulent state of the air flow in this section of the pneumatic pipe, providing intensive mixing of seeds in the cross section of the pneumatic pipe, which ultimately helps to increase the uniformity of the distribution of seeds along the discharge pneumatic hoses, and therefore also on the coulters seeders.

An analysis of the properties of the combination of features of the claimed device and the properties of the combination of features of the detected prototype and analogue showed that the combination of features of the claimed device provides enhanced properties of the prototype - increases the uniformity of seed distribution over the coulters and the throughput of the central metering system of the pneumatic seeder.

Figure 1 schematically shows the proposed pneumatic seeder with a central metering system, side view; figure 2. - seed distributor of the proposed pneumatic seeder with a centrally metering system, in view A of FIG. 1; figure 3 shows a section of the pneumatic pipeline, the inner surface of which is provided with protrusions; in section BB in FIG. 2; figure 4 - seed distributor of the proposed pneumatic seeder with a central metering system, in section along BB in figure 1; figure 5 shows a preferred embodiment of a seed distributor, in cross section of its chamber; figure 6 is the same, in the context of G-D in figure 4; Fig.7 is the same, in another embodiment, a seed distributor, in a longitudinal section of its chamber; on Fig shows another embodiment of a seed distributor, in a longitudinal section of its chamber; figure 9 shows the connection of the outlet pneumatic hose with the opener in the form of a pointed arm.

A pneumatic seeder with a central metering system contains a frame 1 with support wheels 2, on which the engine 3 is placed and the source of excess air pressure is connected in series with the pneumatic conduit 4 - fan 5, a centralized hopper 6 with a batch meter 7, a pneumatic flow divider 8 and a seed distributor 9. The seed distributor 9 includes a chamber 10, the side surface 11 of which is made in the form of a body of revolution, and a bracket 12, which is attached to the frame 1. The chamber 10 has a cover 13 and a bottom 14. The mounting of the bracket 12 can be The touch the wall 11 of the chamber 10 (Figures 7 and 8) or the bottom 14 (Figure 6). The bottom 14 is convex, for example, in the form of a cone (Fig. 6), or in the form of a truncated cone (Fig. 7), in the form of a body of revolution with a cycloid forming in the form of a section (Fig. 8). The diameter of the chamber 10 of the seed distributor 9 is greater than its height. The preferred ratio of diameter to chamber height is 1: 1.5. Along the perimeter of the bottom 14 there are nozzles 15 connected by outlet pneumatic hoses 16 with working bodies for seeding seeds into the soil - by coulters 17, made, for example, in the form of a pointed arm (Fig. 9). The final section of the pneumatic line 4 is divided by the divider of the pneumatic stream 8 into two (Fig. 2 and Fig. 4) or four (Fig. 5) pneumatic channels 18 connected to the side surface 11 of the chamber 10 above the nozzles 15 of the outlet pneumatic hoses 16. The pneumatic channels 18 are connected in the upper part of the lateral the surface 11 of the chamber 10 on its opposite sides (figure 4), and in a preferred embodiment, the junction of the four pneumatic channels 18 are located against each other (figure 5). The top of the convex bottom 14 is at the level of the connection of the pneumatic channels 18 to the lateral surface 11 of the chamber 10 of the seed distributor 9. The surface of the bottom 14 is provided with ribs 19 installed along its convex surface and between the nozzles 15 of the outlet pneumatic hoses 16, through holes 20 s are made at their opposite ends the possibility of individual overlapping sleeve 21 having a latch 22 in the form of a bolted connection.

In addition, the inner surface of the section of the pneumatic line 4, located in front of the seed distributor 9, is provided with protrusions 23.

Pneumatic seeder with a central metering system operates as follows. When the seeder moves across the field, the seeds from the centralized hopper 6, passing through the metering unit 7, enter the pneumatic line 4, are picked up in it by a stream of air created by the source of excess air pressure - fan 5. Passing through the pneumatic pipe 4, located in front of the seed distributor 9 in the place where the inner surface of the plot is provided with protrusions 24, the seeds are mixed in a turbulent flow of air, distributed more evenly in it. The pneumatic flow, transporting the seeds, enters through the pneumatic flow divider 8 and at least two pneumatic channels 11 into the chamber 10 of the seed distributor 9, while losing air velocity in the chamber 10, and the air flows separated by the pneumatic channels 18, interacting, increase turbulence in the upper part of the chamber 10, while the transported seeds here pass into a fluidized state, distributed and twisted throughout the entire volume of the upper part of the chamber 10. Part of the seeds located in the upper part of the chamber of the seed distributor own weight fall down and fall on the convex bottom surface 14, and supplied to the nozzles 15 diverting air tubing 16. Thus the ribs 19 on the convex bottom surface 14 is oriented in the direction of seed motion nozzle openings 15 and prevent their displacement in the cross-sectional plane of the chamber 10.

The air flow coming through the pneumatic pipelines creates excess pressure in the chamber 10 of the seed distributor 9, under the influence of which, entraining seeds randomly moving in the upper part of the chamber 10 and sliding between the ribs 19 along the convex surface of the bottom 14, it leaves through the openings of the nozzles 15 and then along the discharge pneumatic hoses 16 into the openers 11, and then into the soil.

When the connection of the pneumatic conduits 4 with the chamber 10 is opposed to each other, the air flows coming out of them, mixing, quench their kinetic energy and the seeds transported by them. When using in the design of the seed distributor more than two pneumatic channels 18 connected to one chamber 10, the turbulent state of the interacting air flows and the random movement of seeds in the upper part of the chamber increase. The transported stream of seeds goes into a fluidized state, which contributes to an increase in the uniformity of the distribution of seeds in the nozzles 15.

The use of the proposed pneumatic seeder with a central metering system in comparison with the known pneumatic seeders with a central metering system will increase the uniformity of seed supply to the coulters and, as a result, increase their uniform distribution over the surface of the field, increase the throughput of the central metering system of the pneumatic seeder, reduce the complexity of maintenance of a pneumatic seeder during the sowing process.

Claims (5)

1. A pneumatic seeder with a central metering system, comprising a source of excess air pressure in series with a pneumatic line, a hopper with a spool type metering device, a pneumatic flow divider and a seed distributor, which includes a chamber whose lateral surface is made in the form of a body of revolution, having a cover and a bottom connected outlet pneumatic hoses with openers, characterized in that the bottom of the chamber of the seed distributor is made convex, along its perimeter there are nozzles for outlet pneumatic hoses, etc. This end portion of air tube divided into at least two pnevmokanala connected to the lateral surface of the chamber above the seed distributor nozzles diverting air tubing, where through holes. 2. A pneumatic seeder with a central metering system according to claim 1, characterized in that the apex of the convex bottom of the chamber of the seed distributor is located at the level of connection of the pneumatic channels to the side surface of the chamber of the seed distributor, and the surface of the convex bottom is provided with ribs installed along its generatrix and between the nozzles discharge pneumatic hoses. 3. A pneumatic seeder with a central metering system according to claim 1, characterized in that the connections of the pneumatic channels to the seed distributor chamber are located opposite each other. 4. A pneumatic seeder with a central metering system according to claim 1, characterized in that the through holes of the outlet pneumatic hoses are located along their longitudinal axes with the possibility of individual overlap. 5. A pneumatic seeder with a central metering system according to claim 1, characterized in that the inner surface of the section of the pneumatic pipe located in front of the air flow divider is provided with protrusions.

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