RU163299U1 - PNEUMATIC SEEDER - Google Patents

Abstract

A pneumatic seeder containing a seed hopper, an air distribution system including a source of compressed air, a pressure stabilizer, a seed flow synchronizer associated with the drive wheel of the seeder, a communication channel communicating with the dispensers in the form of vortex chambers, each of which has a nozzle and an inlet nozzle, moreover sowing nozzles at the exit of the vortex chambers are made in the form of additional dispensers with an internal cavity in the form of a cone, pneumatically connected through the outlet to the seed hopper and having two nozzles, one of which is located at the apex of the cone and directed towards the other, located on the opposite side against the outlet, and the seed flow synchronizer is pneumatically connected to the nozzles of the additional dispensers and is equipped with a pneumatic flow switch, characterized in that the surface of the internal cavity of the additional dispensers in the form of the cone is equipped with pneumatic channels along its entire length, and the pneumatic cavities of the additional dispensers are connected by compensating pneumatic channels with a vortex chamber for excess air outlet.

Description

The proposed utility model relates to the field of agricultural engineering, in particular to the construction of pneumatic seeders.

Known pneumatic sowing apparatus of the seeder, containing a hopper for seeds, placed in its lower part of the aeration chamber with a metering window and communicating with a source of excess pressure through the slotted hole of the air collector located at the bottom of the bottom of the aeration chamber (RF Patent No. 2263435, class A01C 7/04 , 2005).

A disadvantage of the known pneumatic sowing apparatus of the seeder is the impossibility of single-seeding of seeds in the furrow with a given constant step in the arrangement of plants in a row.

This drawback is due to the fact that the seeds as a result of aerodynamic impact are carried out from the aeration chamber in a continuous stream, and not one after another at predetermined intervals.

Without a seed flow synchronizer, the uneven placement of seeds in a row by a known sowing apparatus increases due to the uneven speed of the translational movement of the seeder during sowing.

As a result, this does not allow for optimal placement of plants on the field surface, which enhances the competition of plants for nutrients and illumination, and ultimately reduces the yield of crops.

The closest in technical essence and the achieved positive effect to the proposed pneumatic seeder is a pneumatic seeder containing a hopper for seeds, an air distribution system including a source of compressed air, a pressure stabilizer, a seed flow synchronizer connected to the drive wheel of the seeder, a communication channel in communication with the dispensers in in the form of vortex chambers, each of which has a nozzle and a sowing nozzle, and the sowing nozzles at the exit of the vortex chambers are made in the form of additional integral dispensers with an internal cavity in the shape of a cone, pneumatically connected through an outlet with a seed hopper and having two nozzles, one of which is located at the top of the cone and directed towards the other, located on the opposite side against the outlet, and the seed flow synchronizer is pneumatically connected to nozzles of additional dispensers and is equipped with a pneumatic flow switch (RF patent No. 2317671, class АСС 7/04, 2008, prototype).

The disadvantage of a pneumatic seeder, adopted as a prototype, is the slow cleaning (removal) of excess (except one) seeds from the vortex chambers back to the hopper. This reduces the working speed of the unit, and therefore productivity, requires an additional number of seeders in order to sow at the optimum time and not reduce the crop yield, i.e. increased costs and reduced competitiveness of products.

The technical result is to accelerate the cleaning of seeds from the vortex chambers back to the hopper.

The technical result is achieved in that in a pneumatic seeder containing a seed hopper, an air distribution system including a source of compressed air, a pressure stabilizer, a seed flow synchronizer associated with the drive wheel of the seeder, a communication channel communicating with the batchers in the form of vortex chambers, each of which has a nozzle and an inlet nozzle, and the inlet nozzles at the outlet of the vortex chambers are made in the form of additional dispensers with an internal cavity in the form of a cone, pneumatically connected through an outlet with a seed hopper, and having two nozzles, one of which is located at the top of the cone and is directed towards the other, located in the opposite side against the outlet, and the seed flow synchronizer is pneumatically connected to the nozzles of additional dispensers and equipped with a pneumatic flow switch, according to the proposed of a useful model, the surface of the inner cavity of the additional dispensers in the form of a cone is equipped with pneumatic channels along its entire length, and the pneumatic cavities of the additional dispensers are connected Nena compensation pnevmokanalami with swirl chamber of excess air to exit.

The implementation of the internal cavity of the additional dispensers in the form of a cone with two nozzles, one of which is located at the top of the cone and directed towards the other, located on the opposite side, is guaranteed to separate one from the mass of seeds during the sowing and feed it into the air flow and further along the sowing nozzle. The pneumatic connection of the additional dispensers through the outlet with the seed hopper and the location of the nozzle of the additional dispenser against the outlet ensures feedback of the dispensers in the form of vortex chambers with the seed hopper, preventing unnecessary overflow of the vortex chambers with seeds.

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 analogues showed that the combination of features of the claimed device exhibits a new property - selection of pneumatic flows from the mass of seeds of single seeds and their piece feed into the furrow at time intervals, as well as an increase in the speed of translational movement of the seeder and her performance.

In FIG. 1 schematically shows a dispenser with an additional dispenser, front view (front wall conditionally not shown); in FIG. 2 is the same, in a section along AA in FIG. one; in FIG. 3 is the same, in a section along BB in FIG. one; FIG. 4 schematically shows a seed flow synchronizer with a drive wheel; in FIG. 5 shows a seed flow synchronizer disk; in FIG. 6 shows a diagram of the internal cavity of additional dispensers with pneumatic channels (top view).

The pneumatic seeder contains a seed hopper 1, an air distribution system 2, including a source of compressed air 3, which through a seed flow synchronizer 4, kinematically connected to the drive wheel of the seeder 5, and pneumatically through communication channels 6, 7 and 8 and nozzles 9, 10 and 11 with dispensers in the form of vortex chambers 12 and additional dispensers 13, the internal cavity of which has the shape of a cone, and the additional dispensers 13 are made of sowing nozzles 14 in areas at the outlet of the dispensers 12.

The seed flow synchronizer 4 consists of a pneumatic chamber 15 and a disk 16, rigidly mounted on the shaft 17 of the drive wheel 5 of the seeder. On the other hand, the disk 16 is in contact with three pneumatic chambers 18, 19 and 20 connected respectively to the communication channels 6, 7 and 8, and the disk 16 has three through holes 21, 22 and 23 of the same shape configuration with the shape of the corresponding pneumatic chambers 18, 19 and 20 in the plane of contact of the latter with the disk 16. The pneumatic chambers 18, 19 and 20 are arranged to combine with the corresponding through holes 21, 22 and 23 of the disk 16. A dispenser in the form of a vortex chamber 12 and an additional dispenser 13 with an internal cavity in the form of a removable cone in behind Depending on the size of the sown seeds, they are made in the housing 24 with the front wall 25 and the rear wall 26. Nozzles 9, 10 and 11 are connected to communication channels 6, 7 and 8 through a pressure stabilizer in the form of three pneumatic cavities 27, 28 and 29, and the nozzle 11 with a vortex chamber 12. Additional dispensers 13 on the side of the seed hopper 1 have outlet openings 30 against which nozzles 9 are located. On the side of the seed hopper 1, outlet openings 30 have valves 31. The dispensers 12 communicate with the seed hopper 1 through an opening 32 s movable shutter 33. Interchangeable cavities 13 in the form of a cone of additional dispensers are provided with pneumatic channels 34 (FIG. 3 and 6) for additional air supply under the seed layer and quick removal (cleaning) of excess (except one) back to the hopper 1, and compensation channels 35 and 36 for the release of excess air.

Pneumatic seeder works as follows.

Seeds from the hopper for seeds 1 by gravity enter the dispensers in the form of vortex chambers 12 through openings 32, the area of which is pre-regulated by the position of the shutter 33 depending on the size of the seeds of the sowing culture and the required level of filling of the vortex chamber of the dispenser 12 with seeds. During the movement of the seeder along the sown field from the drive wheel of the seeder 5, the rotation through the shaft 17 is transmitted to the disk 16 of the synchronizer seed stream 4. The source of compressed air 3 creates excessive air pressure B pneumatic chamber 15 of the synchronizer seed flow 4. When the disk 16 is rotated, its through hole 21 is aligned with the cavity of the pneumatic chamber 18, and the pneumatic flow from the pneumatic chamber 15 through the through hole 21, the pneumatic chamber 18, the communication channel 6, the pneumatic cavity 27 of the pressure stabilizer and the nozzle 9 enters the swirl chamber of the dispensers 12. The action of the aerodynamic vortex flow with seeds sets the latter in motion, as a result of which part of the seeds is supplied from the metering unit 12 to the seed couplings 14. At this time, as a result of the rotation of the disk 16, its through hole 21 comes out of contact with the pneumatic chamber 18 and the flow of air to the nozzle 9 is stopped . A portion of the seeds received in the sowing nozzles 14, settles in the cavities in the form of a cone of additional dispensers 13, equipped with pneumatic channels 34.

As a result of the rotation of the disk 16 of the seed flow synchronizer 4, its through hole 22 is combined with the pneumatic chamber 19. The pneumatic flow from the pneumatic chamber 15 through the through hole 22, the pneumatic chamber 19, the communication channel 7, the pneumatic cavity 28 of the pressure stabilizer and the nozzle 10 is supplied to the internal cavity in the form of an additional cone dispensers 13. As a result of the interaction of the aerodynamic flow with portions of seeds settled in the internal cavities of the additional dispensers 13, seeds, except one located at the top of the cone inside these cavities each additional dispenser 13 overlapping the nozzle 11, fed through the outlet holes 30 in the seed hopper 1. Valve 31 prevents gravity from the seed hopper for seed 1 through the outlet 30 into additional dispensers 13.

As a result of the rotation of the disk 16 of the seed flow synchronizer 4, its through hole 23 is combined with the pneumatic chamber 20. The pneumatic flow from the pneumatic chamber 15 through the through hole 23, the pneumatic chamber 20. The communication channel 8, the pneumatic cavity 29 of the pressure stabilizer and the nozzle 11 are supplied into the internal cavity in the form of an additional cone dispensers 13. The aerodynamic flow flowing out of the nozzle 11. captures the seed remaining in the additional dispenser 13. and feeds it through the sowing nozzle 14 into the furrow formed by the drill coulter.

After that, the cyclical functioning of the air distribution system 2 of the air seeder is repeated in the above sequence.

To change the seed placement step in the furrow, the disk 16 of the seed flow synchronizer 4 is changed to another, with the corresponding geometric parameters of the through holes 21, 22 and 23 and their number. To accelerate the cleaning of seeds through pneumatic channels 34, additional air is supplied under the seed layer, which then leaves through the compensation channels 35 and 36.

Claims (1)

A pneumatic seeder containing a seed hopper, an air distribution system including a source of compressed air, a pressure stabilizer, a seed flow synchronizer associated with the drive wheel of the seeder, a communication channel communicating with the dispensers in the form of vortex chambers, each of which has a nozzle and an inlet nozzle, moreover sowing nozzles at the exit of the vortex chambers are made in the form of additional dispensers with an internal cavity in the form of a cone, pneumatically connected through the outlet to the seed hopper and having two nozzles, one of which is located at the apex of the cone and directed towards the other, located on the opposite side against the outlet, and the seed flow synchronizer is pneumatically connected to the nozzles of the additional dispensers and is equipped with a pneumatic flow switch, characterized in that the surface of the internal cavity of the additional dispensers in the form of the cone is equipped with pneumatic channels along its entire length, and the pneumatic cavities of the additional dispensers are connected by compensating pneumatic channels with a vortex chamber for excess air outlet.

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