RU2698978C1 - Grain dispensing device - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to agriculture. Device for dispensing grains is located on seeder and comprises bearing disc (2) and pipe (3) for discharge of grains (4) towards seeding space. Device also comprises rotary propulsive wheel (6) with at least one propellant surface (7), which adjoins bearing disc (2) for high-speed supply of grains (4) into sowing space. At that, the propulsion of propellant wheel (6) is synchronized with rotation of bearing disc (2). Throwing wheel (6) is arranged in housing (14) with, at least, one guide wall (9).

EFFECT: invention increases seeding accuracy at high seeding rates.

15 cl, 5 dwg

Description

Application area

The invention relates to a device for dispensing grains, in particular, a device for dispensing grains located on a seeder, containing a carrier and a pipe for outputting grains in the direction of the sowing space, which is part of the machine for precision sowing.

State of the art

High-precision seeders are currently known which comprise a dispersion device serving as a device for dispensing grains. The dispensing agent may be in the form of a tape, drum, disk or similar rotating shape with a perforated surface. Sifting is carried out due to different air pressure on each side of the perforated surface. The grains are attached to the perforation in the direction of the differential pressure.

Also, other structural solutions for transferring grains from dosing means in the direction of the sowing space are known in the art.

These structural solutions include, for example, a disk vacuum dosing system, where when withdrawing from a dosing disk, grains usually fall under the influence of gravity into a short pipe called a seed pipe and further into the soil. The disadvantage of this design is a significant decrease in accuracy at a higher frequency of dosing grains and a decrease in accuracy due to vibration of the seeder when moving on the ground. A gravity system is not suitable for precision sowing of crops at a higher frequency.

From the patent application WO 2010059101 A1, a dosing system with a disk is further known, where overpressure is created on one side of the disk, which causes air to flow in the openings of the disk. The pressure-reducing effect is used to suck the grains, which are then transported by the metering disk to the place where the means for interrupting the movement of the air flow is located. Here, the seeds are released from the metering disk and into the outlet pipe for the output of grains, which is located here. Part of the compressed air is discharged through the pipe to remove the grains and creates an air stream that transfers the grains through the pipe to the soil. This solution partially eliminates the drawbacks of the gravity system described above. It is especially suitable for sowing corn. It is not suitable for sowing cereals because of the low initial kinetic energy and low initial speed, which leads to the appearance of a significant inaccuracy in the distance between the seeds after they pass through the outlet pipe.

From another patent application DE 102007062967 A1, a dosing system with a disk is known, where the grains are blown by nozzles into a pipe to output grains in a radial direction, perpendicular to the dosing disk. The disadvantage of this design is a significant change in the direction of movement of the grains after withdrawal from the metering disk, where the grains change their direction of motion by about 90 degrees. This change in the direction of movement of the grains with increasing speed of rotation of the disk increases the inaccuracies of movement in the pipe and, thus, leads to a significant inaccuracy in the final placement of grains in the soil. The big disadvantage is that at a certain speed of the metering disk under the influence of kinetic energy, the grains will not be redirected to the output pipe, and the grains will return to the hopper again, thus, one seeding point will be skipped, which is a significant disadvantage.

CZ 305159 discloses a grain dispensing device located on a seeder, comprising a carrier means and a pipe for withdrawing grains in the direction of the seed area, where the carrier means is pressurized and contains at least one compressed air tube directing the grain into the pipe for withdrawing grains, while the pipe with compressed air is adjacent to the carrier, and its axis forms an angle β = ± 30o with the tangent support. The pipe for outputting grains is also adjacent to the carrier, while its axis forms an angle α = ± 30 ° from the tangent support. Although this solution provides very accurate seeding, it has a significant drawback in increasing the sensitivity to contamination that can occur in difficult operating conditions.

A precision sowing device is further known from EP2747541. The device contains a carrier disk with holes in which individual grains are transferred using vacuum, which are transferred to a seed conveyor by a pair of loading wheels, which transfers individual grains with high precision to the sowing space. The loading wheels are located at a distance from each other, passing grain onto the conveyor at a low speed and at a short distance. If the speed were higher, the grains would come back, and this would lead to inaccurate sowing. The main disadvantage of this device is its structural complexity with a large number of individual parts. Given the difficult operating conditions of the device, the high probability of malfunctions and significant wear, this can lead to high operating costs.

From the above state of the art, it is obvious that the main disadvantage of the prior art is that the known devices do not fully guarantee the accuracy of sowing grains at high speeds, this disadvantage is significantly increased in difficult operating conditions.

The aim of the invention is to provide a device for sowing grains, which will provide the ability to accurately sow at high speeds even in difficult operating conditions.

SUMMARY OF THE INVENTION

The aforementioned disadvantages are largely eliminated and fulfills the objectives of the present invention by a device for dispensing grains, in particular, a device for dispensing grains located on a seeder, which contains a carrier disk, in particular, a high or low pressure hearth disk with holes for supplying grains and a pipe for the output of grains to the sowing space according to the invention, the principle of which is that it includes a rotating throwing wheel for high-speed transfer of grains into the sowing space with, of at least one thrower surface which abuts against the carrier disc, wherein the rotation of the throwing wheel are synchronized with the rotation of the carrier disc and is also located in the housing with at least one guide wall. The advantage is a very accurate feed time for each grain and the associated high-precision sowing, as well as the fact that this device is very reliable even in difficult operating conditions.

It is suitable when the wheel throwing speed is x times higher than the speed of the carrier disk, where x is equal to the number of holes for feeding grains in the carrier disk divided by the number of throwing surfaces of the wheel. The advantage is the accurate synchronization of the movement of the carrier disk and the throwing wheel, which brings periodicity in the movement of individual grains and thereby further increases the accuracy of sowing.

A further increase in the accuracy of sowing occurs when the rotation of the throwing wheel and the carrier disk are synchronized so that at least one throwing surface of the wheel intersects the axis of each hole of the carrier disk for feeding grains. The advantage is the maximum possible increase in the accuracy of grain removal from the surface of the propelling wheel.

In addition, an improvement is the presence of the bevel disk with holes for feeding grains of a beveled edge, where the preferred bevel edge is an angle α = from 0 ° to 30 ° relative to the surface of the bearing disk. The advantage is the easy assembly of all parts of the structure. The main advantage is the optimization of surface settings, which affect the accuracy of the grain feed.

In order to minimize violations of the accuracy of ejection of grains from the surface of the carrier disk, it is also recommended that the feed holes are located on the edge of the transition to the bevel of the edge.

In addition, it is preferable that the throwing wheel was parallel to the beveled edge of the carrier disk, while between the throwing wheel and the carrier disk is the starting segment. The advantage is that the launch segment minimizes disturbance in the movement of grains due to swirling air in the space just above the carrier disk.

According to the most advantageous embodiment, the launch segment is attached to the housing. This design is optimal in terms of simplicity of the overall spatial arrangement of all parts of the structure.

According to another possible embodiment, the trigger segment is preferably attached to the surface of the carrier disk.

In addition, it is preferable if the housing contains a pipe outlet for outputting grains.

In addition, it is preferable that the throwing wheel had at least two throwing surfaces, the inner edge of the first throwing surface being always connected by a spirally rotating rotating surface with the outer edge to the next throwing surface. A smooth transition between the throwing surfaces gives a stable pressure ratio to minimize the possible violation of the exact departure of the grains.

Optimum grain firing occurs when the throwing surface is curved, ideally when the throwing surface is curved in the opposite direction of rotation of the throwing wheel. The curved throwing surface allows you to accurately shoot the grain when it rotates, to ensure uniform passage through the seeder.

Regarding the optimization of grain flight, it is preferable that the guide wall of the body was made in the form of a parabolic deflection. The deflection provides the alignment of the possible different speeds of each grain at the entrance to the grain pipe and thereby increases the accuracy of synchronization of individual grains. Grains tend to slide along the pipe wall in approximately the same manner and speed, while parabolic deflection ensures that the desired pitch is maintained.

With regard to synchronizing the movement of the propelling wheel with the carrier disk, it is preferable that the propelling wheel was connected to the carrier disk by means of a gear transmission. The advantage lies in the simple and accurate determination of the time intervals of individual functional moving parts.

The main advantage of the device for dispensing grains in accordance with the invention is, in addition to high-precision sowing at high speeds, mainly a significant increase in operational reliability compared to the prior art. The device allows to achieve high uniformity of passage of individual grains and their correct location at the exit of the grain tube under the seeder wheel at a given step into the sowing space, especially at a higher frequency of grain movement through the sowing device, which is associated with a higher speed of movement of the sowing machine across the field. Another advantage is the relatively small number of parts that make up the device, which means not only lower production costs, but also lower maintenance costs and overall wear resistance.

Description of graphic materials

The invention will be illustrated in more detail by the drawings, in which: FIG. 1 is a sectional front view of a detailed arrangement of a propelling wheel in a housing and a carrier disk, FIG. 2 is a cross-sectional view of the spatial arrangement of a device with a launch segment; FIG. 3 is a cross-sectional view of the spatial arrangement of a device with a starting segment and a gear connecting a movable propelling wheel and a carrier disk, FIG. 4 is a cross-sectional side view of a detailed arrangement of a propelling wheel, a carrier disc, and a starting segment, and FIG. 5 represents the spatial arrangement of a device for dispensing grains on a seeder.

List of items

1 Dosing device

2 carrier disk

3 Pipe for grain output

4 Grain

5 Conclusion

6 Throwing Wheel

7 Throwing surface I

8 Throwing surface II

9 Guide wall

10 Inner edge

11 rotating surface

12 Outside

13 Transmission

14 Case

15 hole

16 beveled hem

17 Edge

18 Starting segment

19 axis

20 The surface of the carrier disk

21 Pinch wheel

Examples of the invention

Example No. 1

The device 1 for dispensing grains 4 (Fig. 1) is located on the seeder (Fig. 5), while it has a carrier disk 2 with holes 15 for vacuum feeding of grains 4 and a pipe 3 for outputting grains 4 in the direction of the sowing space.

The device 1 for dispensing grains 4 contains a rotating throwing wheel 6 for high-speed transfer of grains 4 to the sowing space, with a pair of throwing surfaces 7 . The throwing wheel 6 and the bearing disk 2 are parallel to each other, while the throwing wheel 6 is adjacent to the bearing disk 2 , and the rotation of the throwing wheel 6 is synchronized with the rotation of the bearing disk 2 . The throwing wheel 6 is also located in the housing 14 having a guide wall 9 .

Since the carrier disk 2 has 30 holes 15 for feeding the grains 4 , and the throwing wheel 6 has a pair of throwing surfaces 7 , the rotation speed of the throwing wheel 6 is 15 times higher than the speed of rotation of the carrier disk 2 .

The rotation of the throwing wheel 6 and the carrier disk 2 are synchronized so that the throwing surface 7 of the throwing wheel 6 always intersects the axis 19 of each hole 15 of the carrier disk 2 for feeding the grains 4 .

The housing 14 contains the output 5 of the pipe 3 for the output of grains 4 .

Throwing surfaces 7 , 8 are curved and allotted against the direction of rotation of the throwing wheel 6 . The inner edge 10 of the first throwing surface 7 is connected by a spirally located, rotating surface 11 with the outer edge 12 of the next throwing surface 8 . The inner edges 10 and the outer edges 12 are rounded.

The guide wall 9 of the housing 14 is made in the form of a parabolic bend.

The throwing wheel 6 and the carrier disk 2 are connected to separate drives, which are not shown.

An apparatus 1 for dispensing the grain runs in such a way that on one side of the carrier disc 2 in place of openings 15 creates a vacuum, the through holes 15 in the support disk 2 moves air and creates a suction effect which draws the other side of the carrier disc 2 grains 4 located in the unloading space, which is not shown. After the grains 4 are sucked into the carrier disk 2, the grains 4 pass through a rotating carrier disk 2 into a zone not shown with a so-called ridge, which cleans the excess grains 4 so that only one grain 4 is sucked into each hole 15 . On the side of the carrier disk 2 opposite the discharge space is a negative vacuum disconnector (not shown). After turning off the vacuum, the grains 4 are released, while the throwing wheel 6 with a curved throwing surface 7 directs it to the wall 9 of the housing 14 , which grains 4 leads to the output 5 of the pipe 3 for the output of grains 4 , which in turn will lead them to the seed furrow under the pressure wheel 21 .

Example No. 2

The device for dispensing grains 4 (Fig. 1, Fig. 2, Fig. 3, Fig. 4) is located on the machine for sowing grains, while it has a vacuum carrier disk 2 with holes 15 for feeding grains 4 and a pipe 3 for outputting grains 4 towards the sowing space.

The device for dispensing grains 4 has a rotating throwing wheel 6 for high-speed feeding of grains 4 into the sowing space using a pair of throwing surfaces 7 .

The carrier disk 2 with holes 15 for feeding grains 4 has a beveled edge 16 at an angle α = 15 ^o to the surface 20 of the carrier disk 2 . The holes 15 for feeding the grains 4 are located on the edge 17 of the transition to the beveled edge 16 .

The throwing wheel 6 is located parallel to the beveled edge 16 of the carrier disk 2 , while between the throwing wheel 6 and the carrier disk 2 there is a launch segment 18 , which is fixed according to the first embodiment to the housing 14 . According to the second embodiment, the launch segment 18 in the form of a hoop is attached to the surface of the carrier disk 2 .

The throwing wheel 6 is closely adjacent to the carrier disk 2 , while the rotation of the throwing wheel 6 is synchronized with the rotation of the carrier disk 2 and is simultaneously placed in the housing 14 with the guide wall 9 .

Since the carrier disk 2 has 30 holes 15 for feeding the grains 4 , and the throwing wheel 6 has a pair of throwing surfaces 7 , the rotation speed of the throwing wheel 6 is 15 times higher than the speed of rotation of the carrier disk 2 .

The rotation of the throwing wheel 6 and the carrier disk 2 are synchronized so that the throwing surface 7 of the throwing wheel 6 always intersects the axis 19 of each hole 15 of the carrier disk 2 for feeding the grains 4 .

The housing 14 contains the output 5 of the pipe 3 for the output of grains 4 .

Throwing surfaces 7 , 8 are curved and allotted against the direction of rotation of the throwing wheel 6 . The inner edge 10 of the first throwing surface 7 is connected by a spirally located rotating surface 11 with the outer edge 12 of the next throwing surface 8 . The inner edges 10 and the outer edges 12 are rounded.

The guide wall 9 of the housing 14 is made in the form of a parabolic bend.

The throwing wheel 1 is connected by a gear 13 with a carrier disk 2 , while the carrier disk 2 is connected to a drive that is not shown.

An apparatus 1 for dispensing the grain runs in such a way that on one side of the carrier disc 2 in place of openings 15 creates a vacuum, the through holes 15 in the support disk 2 moves air and creates a suction effect which draws the other side of the carrier disc 2 grains 4 located in the unloading space, which is not shown. After the grains 4 are sucked into the carrier disk 2, the grains 4 pass through a rotating carrier disk 2 into a zone not shown with a so-called ridge, which cleans the excess grains 4 so that only one grain 4 is sucked into each hole 15 . On the side of the carrier disk 2 opposite the discharge space is a negative vacuum disconnector (not shown). After turning off the vacuum, the grain 4 is released, while the throwing wheel 6 curved throwing surface 7 directs it to the wall 9 of the housing 14 , which grain 4 leads to the output 5 of the pipe 3 for the output of grains 4 , which in turn will lead him to the sowing furrow under the pressure wheel 21 .

Industrial application

The device for dispensing grains in accordance with the invention can be used on agricultural machinery for the precise sowing of grains.

Claims (15)

1. A device for dispensing grains located on a seeder that includes a carrier disk (2) having openings (15) for feeding the grains (4) by vacuum or transmission principle, and a pipe (3) for outputting grains (4) through towards the sowing space, characterized in that it contains a rotating throwing wheel (6) for high-speed feeding of grains (4) into the sowing space with at least one throwing surface (7), which abuts against the carrier disk (2), as a result of which the throwing wheel (6) is synchronized with rotation conductive disc (2) and simultaneously arranged in the housing (14) with at least one guide wall (9). 2. A device for dispensing grains according to claim 1, characterized in that the throwing wheel (6) has a rotation speed x times higher than the rotation speed of the carrier disk (2), while x is equal to the number of holes (15) for feeding the grains ( 4) in the carrier disk (2) divided by the number of throwing surfaces (7) of the throwing wheel (6). 3. A device for dispensing grains according to one of the preceding paragraphs, characterized in that the rotation of the throwing wheel (6) and the bearing disk (2) are synchronized so that the throwing surface (7) of the throwing wheel (6) intersects the axis (19) of each hole (15) the carrier disk (2) for feeding the grains (4). 4. A device for dispensing grains according to one of the preceding paragraphs, characterized in that the carrier disk (2) with holes (15) for feeding the grains (4) has a beveled edge (16). 5. A device for dispensing grains according to claim 4, characterized in that the carrier disk (2) with holes (15) for feeding the grains (4) has a beveled edge (16), with a bevel angle α from 0 ° to 30 ° with respect to to the surface (20) of the carrier disk (2). 6. A device for dispensing grains according to claim 4, characterized in that the holes (15) for feeding the grains (4) are located on the edge (17) of the transition to the beveled edge (16). 7. A device for dispensing grains according to claim 6, characterized in that the throwing wheel (6) is located parallel to the beveled edge (16) of the bearing disk (2), while the starting segment is located between the throwing wheel (6) and the bearing disk (2) (eighteen). 8. A device for dispensing grains according to claim 7, characterized in that the starting segment (18) is attached to the housing (14). 9. A device for dispensing grains according to claim 7, characterized in that the starting segment (18) is attached to the surface of the carrier disk (2). 10. Device for dispensing grains according to one of the preceding paragraphs, characterized in that the housing (14) contains the output (5) of the pipe (3) for the output of grains (4). 11. Device for dispensing grains according to one of the preceding paragraphs, characterized in that the throwing wheel (6) has at least two throwing surfaces (7), the inner edge (10) of the first throwing surface (7) always connected spirally a rotating surface (11) with an outer edge (12) to the next throwing surface (8). 12. A device for dispensing grains according to one of the preceding paragraphs, characterized in that the throwing surface (7, 8) is curved. 13. A device for dispensing grains according to one of the preceding paragraphs, characterized in that the throwing surface (7, 8) is allotted against the direction of rotation of the throwing wheel (6). 14. Device for dispensing grains according to one of the preceding paragraphs, characterized in that the guide wall (9) is made in the form of a parabolic bend. 15. Device for dispensing grains according to one of the preceding paragraphs, characterized in that the throwing wheel (1) is connected to the carrier disk (2) by a gear transmission (13).

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