SU865165A1 - Pneumatic feed - Google Patents

Description

The invention relates to agricultural machinery, in particular to precision seeders.

A pneumatic metering apparatus is known, including a hopper with a metering shutter, a housing with a sampling chamber ⁵ , in which a metering disc with horizontal axis of rotation is located with cells on its cylindrical surface, mated to the inner surface of the housing, connecting the receiver and the working chamber nozzle and exhaust channel £ 1].

The disadvantage of this sowing apparatus is low quality .vyseva when working at elevated ^'5 GOVERNMENTAL speeds.

The issue of removing excess seeds from the working chamber has also not been resolved, which leads to the possibility of injury during rotation of the disk, and the issue of effective removal of seeds from cells.

The purpose of the invention is improving the quality of seeding.

This goal is achieved by the fact that in a pneumatic metering device including a hopper with a metering flap, a housing with an intake cap meter, in which a metering disk with horizontal axis of rotation is located with cells on its cylindrical surface mating with the inner surface of the housing connecting the receiver and working chambers the nozzle and the ejection channel, the sowing disk is made with radial grooves for connecting the cells inside the ejection channel with the working chamber, and the housing. has a channel for the selection of excess seeds, ory connects the working chamber to the atmosphere.

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In this case, the exhaust channel is installed tangentially to the cylindrical surface of the sowing disk.

This embodiment provides reliable release of cells from seeds in the area of the exhaust channel.

In FIG. 1 - shows a General view of a pneumatic sowing device; in FIG. 2 is a section AA in FIG. one; in FIG. 3 is a section BB in FIG. one; in FIG. 4 - an embodiment of the apparatus with an additionally installed vacuum chamber.

The pneumatic sowing device comprises a hopper 1 with a metering flap 2, a housing 3 with a sampling chamber 4, a metering disk 5 with cells 6 located on its cylindrical surface. The housing has a receiver 7 and a working chamber 8 connected by a nozzle 9 and an exhaust channel 10. The metering disk 5 is made with radial grooves I 1 on the inner surface 12 for connecting the cells 6 to the working chamber 8. The housing 3 has a channel 13 for collecting excess seeds, connecting the working chamber 8 with the atmosphere, and a channel for supplying excess pressure. The exhaust channel 10 is equipped with a cover 15, designed to overlap the outer side of the exhaust channel 10 and the cells 6 of the sowing disk 5, thereby achieving the removal of axial air pressure on the seeds in the ejection zone.

The internal cavity of the exhaust channel 10 and the working chamber 8 are angered by a shutoff valve 16.

When converting a pneumatic metering device to a variant with a vacuum chamber, a vacuum chamber 18 is installed with the outer plane 17 of the metering disk 5, and the “re-closing” valve 16 is replaced by a shut-off valve 19, which overlaps the grooves 11.

Pneumatic metering device operates as follows.

Seeds from the hopper 1 enter the intake chamber 4 of the housing 3; at the same time, overpressure is supplied through the channel 14 to the pivot chamber 7, which through the nozzle 9 enters the chamber 8.

During rotation of the sowing disk 5, the seeds located near its end surface 12, under the action of axial pressure forces fill the cells 6, which then pass by the channel 13, which provides local discharge of excess air pressure over the passing cells 6, as a result of which the cells 6 are released from excess seeds. Cells, 6 with seeds, then passing by sop ·

865165 4 la 9, before entering the exhaust channel 10 are exposed to air flow that enters through the nozzle 9 into the working chamber 8 and removes 5 of the cells 6 excess seeds remaining in them after they pass by channel 13.

The single seeds remaining in cells 6 are transported to the IQ ca. After entering cells 6 with seeds and the ejection channel 10 and opening them from the side of the housing 3 in the radial direction through grooves 11, an air flow pushes seeds out of the bi cells under the action of inertial centrifugal forces and gravity; they freely enter the vas deferens. Moreover, the release of cells 6 from the seeds is carried out during their movement directly inside the cavity of the ejection channel 10, which allows the seeds to freely enter the vas deferens. Excluding their redistribution during the flight into the vas deferens, which improves the quality of seed distribution in the furrow.

The conversion of pneumatic sowing apparatus, operating at overpressure, to the version of the apparatus with a vacuum chamber is carried out as follows.

The air injection system with the overpressure supply channel 14 is turned off, the cover 15 is removed, and the shut-off valve 16 is replaced by a shut-off valve 19, after ³⁵ it is installed a vacuum chamber 18, which is connected to the discharge source by air-: water.

The vacuum chamber 18 provides ^{40 a} vacuum supply to the channel 13 to remove excess seeds from the cells 6, as well as to the sowing disk 5 for transporting seeds to the area of the exhaust channel. about ⁴⁵ .

Claims (2)

FIELD OF THE INVENTION The invention relates to agricultural machinery, in particular to precision seeding. A pneumatic seeding machine is known (its apparatus, which includes a hopper with a metering valve, a housing with an intake chamber in which there is a sowing disc with horizontal axes of rotation with cells on its cylindrical surface, coupled to the inner surface of the housing, connecting the receiver and working chambers the nozzle and the discharge channel J. The disadvantage of the known sowing apparatus is the low quality of the seeding when operating at higher speeds. The question of removing excess seeds from the working chamber is also not resolved, and leads to the possibility of injury during rotation of the disk, and effective removal of seeds from the cells. The purpose of the invention is to improve the quality of sowing. This goal is achieved by having a casing with intake valve in the pneumatic sowing apparatus including a hopper with a metering damper; having a horizontal axis of rotation, a seeding disk with cells on its cylindrical surface, coupled with the inner surface of the housing, connecting a nozzle and an exhaust channel connecting the receiver and working chambers to the seeding disk made with radial grooves to connect the cells inside the discharge channel with the working chamber, and the housing has a channel for collecting excess seeds that connects the working chamber with the atmosphere. At the same time, the discharge channel is installed tangentially to the cylindrical surface of the sowing disc. This embodiment ensures reliable release of the cells from the seeds in the zone of the discharge channel. FIG. 1 shows a general view of a pneumatic sowing unit at 4ig. 2 is a section A-A in FIG. 1; in fig. 3 shows a section BB in FIG. 1} in FIG. 4 shows an embodiment of the apparatus with an additionally installed vacuum chamber. The pneumatic sowing apparatus comprises a hopper 1 with a metering valve 2, a housing 3 with an intake chamber 4, a sowing disk 5 with cells 6 located on its cylindrical surface. The case has a receiver; 7 and a working chamber 8 connected by a nozzle 9 and an outflow channel 10. The sowing disk 5 is made with radial grooves 1 I on the inner surface 12 for connecting the cells 6 with the working chamber 8. The housing 3 has a channel 13 for collecting excess seeds, a working chamber 8 with an atmosphere, and a channel for supplying overpressure. The discharge channel 10 is provided with a cover 15, designed to shut off the outside of the exhaust channel 10 and the cells 6 of the sowing disk 5, which results in a reduction in the zone of emission of the axial air pressure on the seeds. The internal cavity of the discharge channel 10 and the working chamber 8 times; A flap 18 is installed on the version with a vacuum chamber, with the outward plane 17 of the seed disc 5, the aperture valve 16 is replaced with the shut-off valve 19, which closes the grooves 11. The pneumonic seed apparatus operates as follows. Seeds from the hopper 1 enter the intake chamber 4 of the housing 3, simultaneously through the channel 14 an overpressure is supplied to the receiver chamber 7, which through the nozzle 9 enters the par bochgy chamber 8. When the sowing disk 5 rotates, the seeds located near its end surface 12 under the action The axial pressure forces are filled in cells 6, which then pass by channel 13, which provides local relief of air overpressure above cells 6 passing by it, as a result of which cells 6 are released from the ttnx seeds. In other words, the passage then past the nozzle 5 before entering the discharge channel 10 is exposed to the air flow that flows through the nozzle 9 into the working chamber 8 and removes 3 cells 6 excess seeds left in them after they pass by channel 13. Remaining in cells 6 single seeds are transported to the ejection zone. After entering 6 with seeds and exhaust channel 10 and opening them from the housing 3 in the radial direction through the grooves 11, the air flow pushes the seeds out of the cells 6 and under the action of inertial centrifugal forces, the force of gravity, they freely enter this wire. Moreover, the release of the cells 6 from the seeds is carried out during their movement directly inside the cavity of the exhaust channel 10, which allows the seeds to freely fall into this wire, eliminating their redistribution during the flight process into the wire, which improves the quality of seed distribution in the furrow . The re-equipment of the pneumatic sowing apparatus, which operated at overpressure, into the version of the apparatus with a vacuum chamber is made as follows. The air injection system is disconnected with the overpressure supply channel 14, the crust 15 is removed, and the shut-off valve 16 is replaced with the shut-off valve 19, after which the vacuum chamber 18 is installed, which is by means of an air vent; water is connected to the discharge source. The vacuum chamber 18 provides a vacuum to the channel 13 to remove excess seeds from the cells 6, as well as to the seed disc 5 for transporting the seeds to the zone of the discharge channel. . The use of the proposed pneumatic sowing apparatus on sowing machines will improve the quality of seeding due to more reliable and accurate seed ejection from the cells, eliminating the possibility of cell clogging, as well as more reliable removal of excess seeds. Claim 1. Pneumatic sowing unit including a hopper with a metering valve, a casing with an intake chamber in which there is a horizontal axis of rotation, a sowing disk with cells on its cylindrical surface connected to the inner surface of the casing, which connects the sperm and working chambers and discharge channel, making it possible that, in order to improve the quality of sowing, the sowing disk is made with a radial 1 slot to connect the cells inside the exhaust channel 56 to the working chamber, and The cone has a channel for collecting excess seeds that connects the working chamber to the atmosphere. 2. The apparatus according to claim 1, distinguished by the fact that the discharge channel is set tangentially to the cylindrical surface of the seed disc. Sources of information taken into account during the examination 1. Application 1 of Article No. 2376608, cl. A 01 C 7 / Q4, 1977. U / 7 2 (rig 4