RU185546U1 - Seeder vibrating meter - Google Patents

Abstract

The claimed technical solution for a utility model relates to agricultural engineering, in particular to a seeder sowing machine. The seeder vibrating sowing device contains a hopper mounted on the frame, a rectangular sowing device suspended from below on flexible pendants with the tips of the vas deferens and a drive for its vibrations. In the proposed sowing apparatus, two-level regulation of the supply of seeds from the hopper to the sowing device is carried out. The first level is the choice of the gap between the lower bevels of the cylindrical tube of the stabilizer body and the upper sections of the slopes of the gable tray. The second level is the choice of the slot width S. The size of its section should be correlated with the total section of all working sowing holes of the sowing device. The proposed design changes of the vibratory sowing apparatus of the seeder expand its functionality and provide high-quality sowing of seeds of various crops, with a stable level in the sowing device of the vibrating apparatus. Vibrating metering unit can be easily implemented in agricultural production.

Description

The claimed technical solution for a utility model relates to agricultural engineering, in particular to a seeder sowing machine.

The vibrating sowing device of the seeder includes a hopper 2 mounted on the frame 1, a sowing device 8 with a drive for its vibrations 10 and tips of the seed tubes 9 is attached to it from below on flexible suspensions 7. The lower neck of the hopper in the form of a cylindrical nozzle 20 is placed inside the sowing device 8. It inserted a cylindrical tube 21, fixed in a certain position by the locking screw 26. The second end of the tube with beveled edges is connected with a seed level stabilizer 22. Inside it is placed a flat gable tray 25 including two slopes independent from each other. The slopes of the tray are pivotally mounted on a common axis 31 and can be mounted at various angles of inclination.

Each of the end walls 32 of the stabilizer body 23 is hinged on an axis 33 fixed in the holes of the side walls 35. The desired position of the wall 32 in the angle of rotation relative to the side 27 is fixed due to the grooves 34 in the side walls 27 and the ears 38 provided on the sides of the end wall 32 The change in the length of the end wall 32 is provided by the extension 39, which in the right place is fixed by a screw connection 41 due to its longitudinal groove 40 and the holes in the end wall 32.

Known vibration metering device (RF patent No. 2437266, АСС 7/16 Bull. No. 36. 12/27/2011) which includes a hopper placed on the frame of the seeder. At the bottom of the hopper on flexible suspensions is a sowing device. The latter is rectangular in shape and has the tips of the vas deferens and a drive for its vibrations. Inside the case of the metering device, the lower neck of the rectangular hopper is located, the bottom of which is a gable visor. Tips are attached to opposite walls of the lower neck of the hopper adjacent to the slopes of the visor, to which corrugated rubber hoses are attached. The second ends of the hoses are fixed in the tips in the form of tubes attached to a solid partition installed inside the metering device. A solid partition has the ability to move vertically parallel to the bottom of the metering device and lock in place. This movement provides the ability to change the level of seeds in an oscillating sowing device.

The disadvantages of this apparatus are: the complexity of the design of the sowing device, the possibility of re-compaction of the oscillating layer of seeds due to pressure on the last vertically moving stream from the hopper, especially when sowing large and heavy seeds. In addition, this apparatus does not provide for the regulation of the intensity of the flow of seeds of various crops entering the sowing device, up to its complete shutdown.

The closest in technical solution is a seeder vibrating sowing apparatus (RF patent No. 2530517, АСС 7/16 Bull. No. 28. 10.10.2014), which includes a hopper to which a metering device is attached from below on flexible suspensions. The latter is rectangular in shape with the tips of the vas deferens attached to it from below. The sowing device is equipped with a drive for its oscillations. The lower neck of the hopper is located inside the metering device and ends with a cylindrical nozzle. A cylindrical tube is inserted into the nozzle. The latter is fixed in the cylindrical pipe with a locking screw. The lower end of the cylindrical tube with beveled edges enters the ring, rigidly connected to the housing of the seed level stabilizer, the latter is fixed in the right place on the tube with a locking screw. The stabilizer body has a rectangular shape, made of thin-walled metal sheet and placed in the metering device with a blank wall up. In the side walls of the stabilizer body made ears with holes. The bottom of the stabilizer is a removable gable flat tray made of thin-walled sheet. Along the edges of the tray adjacent to the side walls of the stabilizer body, ears with holes matching the ears of the latter are also made. The gable flat tray is fixed to the stabilizer body with metal spokes so that gaps are formed only between the end walls of the latter and the edges of the gable tray. Along the rest of the perimeter, the tray is adjacent to the walls of the stabilizer body.

The disadvantage of this apparatus is the design of the seed level stabilizer, which does not provide for the possibility of adjusting the angle of inclination of the slopes of the gable tray, which negatively affects the reliability of the movement of seeds along the slopes, which significantly differ from each other by their friction coefficients on the slope material and the internal friction coefficients between the seeds. This circumstance reduces the functional capabilities of the stabilizer design, and, consequently, the versatility of the vibration metering device itself.

In addition, the inability to control the size of the slots between the edges of the slopes of the gable tray and the end walls of the stabilizer body through which the seeds enter the sowing device and their vertical position negatively affects the stability of the seed level in the sowing device during operation of the sowing device.

Violation of the stability of the seed level in the sowing device leads to a change in their flowability, which ultimately reduces the uniformity of sowing seeds through calibrated sowing holes, especially at different sizes and sowing rates of these seeds.

The objective of the utility model is to expand the functionality of the vibrating apparatus of the seeder and to ensure high-quality sowing of seeds of various crops, with their adjustable and stable level in the sowing device of the vibrating apparatus.

This problem is solved due to the fact that, unlike the prototype, the gable tray consists of two slopes of equal size, pivotally mounted on the common axis (in the form of a metal spoke), fixed in the center of the stabilizer body in the holes made in its side walls and can be placed at different angles of inclination, freely leaning back sides on the axis, which are fixed in the holes made in the side walls of the stabilizer at different levels vertically, in addition Each of the end walls of the stabilizer body is pivotally mounted on the axis, the latter is fixed in holes also made in its side walls, and its fixing during turns is provided by longitudinal grooves in the side walls and ears made on the sides of the end wall, with the length of each the end wall is regulated by the extension, and their fixation by screw connection to each other at the desired length is provided by the longitudinal vertical groove in the extension and the holes in the end wall.

In FIG. 1 shows a general view of the metering apparatus, front view; in FIG. 2 is a general view of the seed level stabilizer of the sowing device together with a part of the cylindrical nozzle of the lower neck of the hopper; in FIG. 3 - housing stabilizer seed level in the sowing device; in FIG. 4 - end wall of the housing of the stabilizer seed level; in FIG. 5 is a view along arrow B of FIG. four.

The seeder sowing unit is made of vibration and contains a frame 1 (Fig. 1), on which the hopper 2 is fixed by means of an arm 3, for which plates 4 reinforced with kerchiefs are welded to the hopper 5. The hopper 2 is attached to the arm 3 and the bracket to the frame 1 by bolt connections 6. To the bunker 2 from below through a flexible suspension 7 is attached a sowing device 8 of a rectangular shape with the tips of the seed tubes 9. The drive 10 of the sowing device is mounted on a horizontal shelf 11, welded to a vertical bracket 12 and reinforced kerchiefs 13. The bracket 12 of the actuator 10 is mounted on the frame 1 by means of the upper 15 and lower 14 pads attached to the bracket 12 by a bolt connection 16. The transmission of vibrations from the actuator 10 to the left metering device 8 and the right one (due to the symmetry of the right metering device is not shown) is carried out by connecting rods 17 and 18, and from the left to the next - connecting rod 19. Oscillations of all left and right sowing devices are performed in antiphase.

The lower neck of the hopper 2 ends with a cylindrical pipe 20, into which a cylindrical tube 21 of the seed level stabilizer 22 is inserted.

The seed level stabilizer 22 of the sowing device 8 includes a stabilizer body 23, a stabilizer ring 24 and a gable tray 25 (Fig. 2).

The cylindrical tube 21 of the seed level stabilizer 22 can be displaced vertically relative to the cylindrical nozzle 20 of the lower neck of the hopper 2 and fixed in the right place with the locking screw 26 through the ring 25. The stabilizer body 23 is made of thin-walled metal sheet and is a P-shaped box with side 27, and the top 28 walls. A hole is provided in the upper wall 28 of the stabilizer body 23 for attachment of the ring 29 screws 29 to it. The inner diameter of the ring 24 allows the stabilizer body 23 to be displaced along the cylindrical tube 21 and fixed in place by the locking screw 30 (Fig. 2).

Inside the case of the seed level stabilizer 23 there is a gable tray 25 with independent movement of the ramps along the angle of rotation relative to each other. The slopes of the gable tray 25 are pivotally mounted on a common axis 31 installed in the side walls 27 of the stabilizer body 23. Between the side walls 27 of the stabilizer body 23, removable rotary end walls 32 are placed on its axes 33. To fix these walls relative to the side walls 27 of the housing stabilizer 23 in the last grooves 34 are made (Fig. 2, 3).

For the installation of the axes 33 of the end walls 32 of the housing of the seed level stabilizer 23, holes 35 are made in each side wall thereof, and for the installation of the common axis 31 of the slopes of the gable tray 25, an opening 36 is made (Fig. 3).

The upper wall 28 of the housing of the stabilizer 23 is made shorter (its size is shaded) of its side walls 27.

The location of each of the slopes of the gable tray 25 at different angles of inclination to the horizons is provided by installing the supporting axis of the spokes in the holes 37, indicated by numbers from 1 to 5. Number 1 corresponds to the angle of inclination of the ramp at an angle of 10 °, number 2-15 °, number 3 -20 °, the number 4-25 ° and the number 5-30 ° (Fig. 3).

The width of each end wall 32 of the body of the stabilizer 23 should provide free, but with a minimum gap, its movement between the side walls 27. Fixing in the desired position of the end walls 32 is carried out by screw connection due to the holes in the ears 38 provided on the sides of the end walls 32 and longitudinal grooves 34 in the side walls 27 of the housing of the stabilizer 23 (Fig. 3, 4).

Preparation for operation of the vibrating device is carried out in the following sequence.

Depending on the state of the seed material, characterized by friction coefficients and the angle of repose, the size of the seeds, the seeding rate of the slopes of the gable tray 25 is selected (Fig. 2). The more bulk material, the smaller the angle of inclination of the ramps. To change the angle of inclination of the slopes of the tray 25 rearrange the support axis (spokes) in the corresponding holes 37 made in the side walls 27 of the stabilizer body 23 (Fig. 3). Depending on the seeding rate and seed size of the sowing culture, a gap is established between the lower bevel of the cylindrical tube 21 and the slopes of the gable tray 25, after loosening the locking screw 30 (Fig. 2). At small angles of inclination of the slopes of the gable tray 25, it is necessary to install a cylindrical tube 21, which has a shallow bevel of its lower edge. At slope angles of more than 20 °, the tube should have a deeper bevel. With the selected gap, the position of the housing of the seed level stabilizer 27 is fixed with a locking screw 30. The thickness of the layer of oscillating seeds in the sowing device 8 (Fig. 1) is changed by the position of the housing of the stabilizer 23 together with its cylindrical tube 21 relative to the cylindrical pipe 20 of the lower neck of the hopper 2. The thickness oscillating seeds in the sowing device 8 will be determined by the vertical position of the slit S (Fig. 2) between the edges of the slopes of the gable tray 25 and the lower edge of the end wall 32 of the stabilizer body 23. Slit S at different angles of inclination of the slopes of the gable tray 25 determines the amount of incoming seed material from the stabilizer body 23 to the sowing device 8. Therefore, its dimensions must correspond to the total area of all working sowing holes of the sowing device 8. Regulation of the sizes of slots S at different angles of inclination of the slopes of the gable tray 25 is provided due to the hinge connection of each end wall 32 with the axis 33 and the possibility of fixing it in the desired position due to the grooves 34 (Fig. 3) made in the side walls 27 of the body of the stabilizer 23 and the ears 38 - on the sides of the end wall 32 (Fig. 4).

The vertical location of the edges of the slopes of the tray 25 and the lower edges of the end walls 32 of the housing of the seed level stabilizer 23, forming a gap S, at different angles of inclination of the first, provides better conditions for the seeds to enter the sowing device 8. These conditions are realized by the adjustable length of the end walls 32 due to its extension 39 (Fig. 5). The extension 39 can be displaced relative to the end wall 32 due to the vertical groove 40 and fixed in the right place with a screw connection 41 (Fig. 4, 5).

The workflow of a vibrating meter is as follows.

The seeds poured into the hopper 2 enter the cylindrical pipe 20 of the lower neck of the hopper 2 and then into the cylindrical tube 21 of the stabilizer. Then, through the slots formed between the bevels of the lower edge of the cylindrical tube 21 and the slopes of the gable flat tray 25, the seed is divided into two streams and slides along its planes to the slits S, and then enters the sowing device 8. Spontaneous filling of the sowing device with 8 seeds will occur until the tops of the seed slides reach the level of the slots S. When you turn on the drive of the sowing device 8 due to its fluctuations, the seed material will level out in it. If at the same time its level is lower than the level of arrangement of the cracks S, it will go along the slopes of the tray 25 to the sowing device 8. This will happen in all similar cases until the top layer of the oscillating seeds reaches the level of the arrangement of cracks S.

During the operation of the vibrating sowing device, the seed material from the sowing device 8 through its sowing holes, the tips of the seed tubes 9 and then through the seed tubes (not shown in Fig. 1) will go to the coulters forming grooves and be sealed with soil. The top layer of seeds in the sowing device 8 will lower and the seeds will be replenished, moving along the planes of the gable tray 25. Moreover, the flow of seeds through the seed level stabilizer 22 will be determined by their flow rate through the sowing holes of the sowing device 8, i.e. there will be a process of self-regulation, ensuring the constancy of their upper level in the sowing device 8.

The seed level stabilizer 22 almost completely eliminates the pressure of the vertical column of seeds, especially when sowing large and heavy seeds located in the hopper 2 on the seeds coming out through the slots S of the stabilizer 22 into the sowing device 8, which allows to keep their set level constant in the oscillating sowing device 8.

In the proposed sowing apparatus, two-level regulation of the supply of seeds from the hopper 2 to the sowing device is carried out 8. The first level is carried out by choosing the gap between the lower bevels of the cylindrical tube 21 of the stabilizer body 23 and the upper sections of the slopes of the gable tray 25. The second level is the choice of slot width S. Its size the cross-section should correspond with the total cross-section of all working sowing holes of the sowing device 8.

The proposed design changes of the vibratory sowing apparatus of the seeder expand its functionality and provide high-quality sowing of seeds of various crops, with a stable level in the sowing device of the vibrating apparatus. Vibrating metering unit can be easily implemented in agricultural production.

Claims (1)

A seeder vibrating metering device containing a hopper mounted on the frame, a rectangular metering device suspended from below on flexible suspensions with a tip of the seed tubes and a drive for its vibrations, while the hopper neck in the form of a cylindrical nozzle is placed inside the metering device, a cylindrical nozzle enters the nozzle at one end a tube, the other end of which with beveled edges through a ring is connected with the housing of the seed level stabilizer, made in the form of a rectangular box with rkhnei, side and end walls, and the cylindrical tube relative to the nozzle of the neck of the hopper and the stabilizer body relative to the cylindrical tube can be displaced and fixed in the right place, and inside the stabilizer housing there is a gable tray that acts as the bottom of the stabilizer body, characterized in that the gable tray consists of two independent from each other, uniformly sized rajids, which are pivotally mounted on a common axis in the form of a metal spoke fixed in the center of the stabilizer housing congestion in the holes of its side walls, and have the ability to be placed at different angles of inclination, while the slopes are freely supported by the backs on the axis, which are fixed in the holes made in the side walls of the stabilizer body at different vertical levels, in addition, each of the end walls the stabilizer body is pivotally mounted on an axis, which is fixed in the holes also made in the side walls of the stabilizer body, and the axis is fixed during rotation due to longitudinal grooves in the side walls of the stabilizer body and the ears, made on the sides of the end wall, while the length of each end wall is controlled by the extension, and they are fixed to each other at the desired length by screw connection due to the longitudinal vertical groove in the extension and the holes in the end wall.

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