RU2216161C2 - Seeding unit for drill - Google Patents

Abstract

FIELD: agricultural engineering. SUBSTANCE: seeding unit has frame, hopper, and seeding device attached to hopper lower part and equipped with drive and casing. Lower throat of hopper is defined by two sleeves, which are rigidly connected to hopper. Sleeves are arranged concentrically with respect to one another and connected through centering rings to one another. Hopper internal cavity is communicated with internal sleeve cavity. Internal sleeve is made longer than external sleeve and has conical part at its end. Support in bore of seeding device casing makes seat for ball bearing outer race. Ball bearing inner race is positioned in holder mounted on outer sleeve so as to be fixed relative to said sleeve in different positions in vertical plane. Support in seeding device casing bore and outer race of ball bearing in support are fixed by stop rings. Connecting surfaces of brackets are uniformly spaced from casing axis. EFFECT: improved quality, enhanced reliability in operation of seeding unit and wider operational capabilities. 2 dwg

Description

 The invention relates to agricultural machinery, in particular to sowing machines.

 A metering apparatus is known comprising a hopper mounted on a machine frame, to the lower part of which a cylindrical metering device is attached on flexible suspensions, the central part of the bottom of which has a conical shape, and the peripheral one is made in the form of a ring with elongated seed holes, a movable ring with similar holes, which is connected to the adjusting device, and a drive for its vibrations [1].

 The disadvantage of this apparatus is not only the different arrangement of the axial lines of elongated sowing holes in relation to the direction of oscillation of the sowing device, but also that with rectilinear vibrations of the casing of this device, zones with different compaction of the seed material are formed inside it, which causes uneven ejection of seeds through the sowing holes. In addition, the flexible suspension of the metering device connecting it to the hopper does not ensure its stable operation.

 Closest to the proposed one is a sowing apparatus containing a hopper mounted on the frame, and a sowing device of also a cylindrical shape, the oscillation path of which is an arc of a circle, is attached to its lower neck with a cylindrical shape. A fixed middle ring is attached to the neck of the hopper, covered on both sides by the lower and upper rings, in which the recesses are made - tracks for separator balls, the mounting bracket of the connecting rod of the drive mechanism and the drive for its vibrations are mounted on the metering device body [2].

 The disadvantage of this apparatus is the increased demands on the accuracy of the manufacture of recesses - tracks for balls. During operation of the sowing device, wear of these tracks will be observed, which can lead to jamming of the rings and disruption of the operation of the oscillating sowing device. In addition, this sowing device does not provide for regulation of the level of seeds in it, which significantly reduces its versatility, since when sowing seeds of various crops, their layer thickness must be quite certain.

 The purpose of the invention is improving the quality and reliability of the working process of the sowing apparatus and the expansion of its functionality.

 This goal is achieved in that, in contrast to the prototype, the lower neck of the hopper is formed by two rigidly connected to the hopper and through centering rings between each other concentrically located one relative to the other bushings, the inner cavity of the hopper communicating with the cavity of the inner sleeve, which is made longer than the outer sleeve and has the conical part at the end, while in the groove of the metering device housing there is a support, which is the seat for the outer cage of the ball bearing, the inner I, the cage of which is installed in a sleeve mounted on the outer sleeve with the possibility of fixing relative to it in various vertical positions, and the support in the groove of the metering device housing and the external ball bearing holder in the support are fixed by snap rings, with brackets attached to the metering device upper part, the connecting planes of which are evenly spaced from the axis of the housing for alternately connecting drive rods to them to change the oscillation amplitude of the metering device va.

 Figure 1 shows the sowing apparatus, rear view; figure 2 is a section along aa of figure 1.

 The sowing apparatus of the seeder contains a frame 1 on which a hopper 2 is located, a sowing device of a cylindrical shape 3 with a drive 4 attached to it from below. The frame 1 is a hollow square beam on which a left hopper 2 is mounted (the right one, symmetrically located relative to the drive 4, not shown). The bunker 2 is attached to the frame 1 by means of quick-detachable brackets 5, mounted on the frame 1 through the plates 6 and bolt connections 7. The bunker 2 is attached to the brackets 5 using the plates 8, welded to the bunker 2 and reinforced with scarves 9. To change the amount of seed, coming from the hopper 2 into the sowing device of a cylindrical shape 3, it has an adjustment flap 10, held in position by the stopper 11. In the middle part of the frame 1, a quick-detachable bracket 12 is installed, a drive is mounted on it d 4 with connecting rods 13 and 14, providing oscillations of the sowing device in antiphase, the path of which is an arc of a circle.

 The sowing device 3 is mounted on the lower neck of the hopper 2. The lower neck of the hopper 2 is formed by two rigidly connected to the hopper 2 and through the centering rings 8 are concentrically arranged one relative to the other bushings - the inner 16 and the outer 17. The inner cavity of the hopper 2 is in communication with the cavity of the inner sleeve 16 and ensures the flow of seed from its internal cavity into the sowing device 3, as well as the regulation of the level of seeds in the sowing device. The inner sleeve 16 is longer than the outer 17 and ends with a cone-shaped part 19. The cone-shaped part of the inner sleeve 16 simplifies the assembly and disassembly of the sowing device 3. The outer sleeve 17 is used to install and fix on it the housing 20 and all other elements of the sowing device 3.

 The sowing device 3 includes a housing 20, which is made in the form of a cylinder, in the upper part of the housing 20 a groove is made for the support 21. The support 21 is a ring with a shoulder, and its outer diameter is made according to the size of the grooves in the housing 20 of the sowing device 3, and the inner one according to the size of the outer race of the ball bearing 22. The support 21 in the groove of the housing 20 of the metering device 3 from axial displacements is fixed by the locking ring 26. In turn, the outer race of the ball bearing 22 from axial displacements in the support 21 is fixed by the retainer ring 25. The inner race of the ball bearing 22 is installed in the sleeve 23. The sleeve 23 is made in the form of a sleeve with a shoulder. The inner diameter of the sleeve 23 is made according to the size of the outer diameter of the outer sleeve 17 with such a gap that allows the sleeve to move freely together with the housing 20 of the metering device 3 vertically relative to the sleeve 17 and can be fixed in any place by the latches 24. The displacement of the sleeve 23 together with the bearing 22, the support 21 and the housing 20 of the metering device 3 relative to the stationary outer sleeve 17 provides a different gap between the conical part of the inner sleeve 16 and the bottom of the housing 20, in which the metering holes are made stia (on the drawings the bottom of the case of the sowing device with sowing holes made in it is not shown). This adjustment ensures the receipt of a different level of seeds in the sowing device 3. Under each sowing hole, the tips of the seed tubes 15 are attached to the bottom of the housing 20 of the sowing device 3.

 In the upper part, brackets 27, 28 and 29 are attached to the housing 20 of the metering device 3. The connecting rods 13 and 14 of the actuator 4 are attached to these brackets. The connection planes 30 of the brackets 27, 28 and 29 of the connecting rods 13 and 14 are evenly spaced from the axis of the housing 20 of the metering device 3 Alternately connecting the connecting rods 13 and 14 to these connecting planes 30 of the respective brackets allows you to change the oscillation amplitude of the sowing device 3, the path of which will be an arc of a circle. With a constant value of the drive eccentric, the closer to the axis of the housing of the metering device 3 the connecting plane 30 is located, the greater the angle of rotation along the arc of a circle. With this adjustment, a different amplitude of oscillations of the sowing device 3 is provided. For connecting the connecting rods 13 and 14 to the connecting planes of the brackets 27, 28 and 29, holes 31 are provided in them.

 The working process of the sowing apparatus is as follows.

 The seed material is poured into the hopper 2, and due to its flowability through the window defined by the adjusting flap 10, it enters the inner sleeve 16 and then to the bottom of the sowing device 3, in which the sowing holes are made. This process will occur until the seed layer reaches the bottom edge of the cone-shaped part 19 of the inner sleeve 16, while the spontaneous outflow of material stops. When the drive 4 is switched on due to oscillations of the sowing device 3, the material in it is evenly distributed around the entire perimeter and, if it does not reach the lower edge of the conical part 19 of the inner sleeve 16, it will continuously come from the hopper 2. This process will end only when the thickness of the seed layer reaches the bottom edge of the cone-shaped part 19 of the inner tube 16 and blocks its hole. During operation of the sowing apparatus due to the drive 4 and the connecting rod 13 connected to the connecting plane 30 of any of the brackets 27, 28, 29, which are rigidly connected to the housing 20, the sowing device 3 will be displaced, while the sleeve 23 and the inner race of the ball bearing 22 will are stationary, and its outer cage together with the support 21 and the housing 20 of the sowing device 3 will be rotated. The trajectory of movement (oscillation) of the housing 20, and therefore of the sowing device 3 will be an arc of a circle. Due to the oscillations of the sowing device 3 along the circular arc, the seed through its sowing holes, the tips of the seed tubes 15 and then through the seed tubes will enter the grooves formed by the openers of the seeder (not shown in the diagram). At the same time, more and more portions of seeds from the hopper will come into the sowing device 3. Moreover, the dosage of the material from the hopper 2 will be determined by its flow rate through the sowing holes, which will ensure its constant level in the sowing device 3.

 The proposed design of the metering device does not involve the use of individual balls, as in the prototype, but a reliable and efficient ball bearing, which significantly improves the working process of the metering device. The ability to control the thickness of the seed layer in the sowing device and the amplitude of its vibrations significantly expands its functionality. All this taken together will provide an increase in the quality of the working process of the sowing device and apparatus as a whole due to a more uniform supply of seed material of various crops to the seeders of the seeder.

 The seeder sowing machine can be easily implemented in agricultural engineering.

Sources of information
1. RF patent 2086088, A 01 C 7/04, 7/16.

 2. RF patent 2161877, A 01 C 7/16.

Claims (1)

 The seeder sowing apparatus, including a frame on which a hopper is placed, attached to it from below and having a drive and a housing, a cylindrical sowing device, the oscillation path of which is an arc of a circle, characterized in that the lower neck of the hopper is formed by two rigidly connected to the hopper and through centering rings between each other concentrically arranged one relative to the other bushings, and the inner cavity of the hopper is in communication with the cavity of the inner sleeve, which is made longer than the outer sleeve and has a cone-shaped part at the end, while in the groove of the metering device housing there is a support, which is a seat for the outer race of the ball bearing, the inner race of which is mounted in a sleeve mounted on the outer sleeve with the possibility of fixing relative to it in various vertical positions, and the support , in the groove of the case of the metering device and the outer cage of the ball bearing in the support are fixed by retaining rings, and in the upper part to the housing of the metering device attached to brackets whose connecting planes are evenly spaced from the axis of the housing for alternately connecting drive rods to them to change the oscillation amplitude of the metering device.

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