RU157879U1 - SPHERICAL CARVED DISC - Google Patents

Abstract

1. A spherical slotted slotted disk with slots located radially or at an angle to the radius of the disk, characterized in that the spaces between the slots form spokes of uniform cross section located radially or at an angle to the radius of the disk, and the outer part of the slot is part of a circle made from the center the disk, while the outer part of the slot and the outer edge of the disk form the rim of the disk, while the pairing between adjacent spokes and the pairing between each spoke and the rim of the disk is made in a radius of 1 to 3 thicknesses in disk. 2. A spherical slotted disk according to claim 1, characterized in that the spokes are straight and, in the case of a spokes located at an angle to the radius of the disk, the direction of the spokes can be either right or left. 3. A spherical slotted disk according to claim 1, characterized in that the spokes are made arcuate, and if the spokes are arranged at an angle to the radius of the disk, the direction of inclination of the spokes can be either right or left. A slotted spherical disk according to claim 1, characterized in that the outer edge of the disk is smooth. A slotted spherical disk according to claim 1, characterized in that the outer edge of the disk is made with cutouts. 6. A slotted spherical disk according to claim 5, characterized in that the outer edge of the disk has from 10 to 16 cutouts with a depth of 20 ± 5 mm, a width of 55 ± 8 cm and from 6 to 9 slots. 7. A slotted spherical disk according to claim 5, characterized in that the outer edge of the disk has 8 or 9 cutouts with a depth of 35 ± 5 mm, a width of 85 ± 8 cm and, accordingly, 8 or 9 cuts, with each cut located between two adjacent cutouts.

Description

The utility model relates to the working bodies of disk tillage implements.

Known spherical disk with slots around the perimeter (see German patent DE-OS No. 2828203), containing a perforation located around the disk, close to its perimeter in the form of a drop-shaped punch and the base of the drop turned to the edge of the disk. Such a disk passes part of the soil through the slots, improving soil crumbling, and throws the soil to the side less, reducing the traction resistance of the disk. However, the shape of the slot and its location are not optimal.

Known spherical disk, patent RU No. 151655 from 04/10/2015, having a cutting edge, slots and holes in the central part for mounting and fixing the bearing housing or axis. In this case, the slots are located on the disk within a circular ring, the outer diameter of which is the minimum diameter of the disk, at which the permissible height of the ridges at the bottom of the furrow is still preserved, and an inner diameter equal to the diameter of the housing of the bearing assembly. In this case, the slots in the circular ring are made with the maximum possible total area, while maintaining the minimum required disk strength.

However, the essence of the utility model is not disclosed. It is not clear how the authors perform slots with the maximum possible total area while maintaining the strength of the disk. In the presented figure, the slots are also made in the form of a drop-shaped punching and with the base of the drop turned towards the edge of the disk. Moreover, as a result, spokes of different widths, that is, uneven strength, were obtained between the slots. This will cause the disk to break off in a thin place, while in a wide place the disk would still work.

The number of slots and their location on the disk is also not optimal. Obviously, the places where the slots are located opposite the cuts along the edge of the disk are much thinner than the places where the cuts are located between adjacent cuts along the edge of the disk. This will cause the disk to break off in a thin place, while in a wide place the disk would still work.

Known spherical disk (prototype), patent RU No. 78621 from 12/10/2008, equipped with cutouts and slots placed on the disk sphere radially and / or at an angle to the radius of the disk, with the total area of the slots ranging from 10 to 30% of the disk area, and the gaps between the slots form a system of spokes, the width of which is from 0.7 to 1.5 of the average value of the width of the slots. Six versions of slotted discs are presented.

Shown in FIG. 1 type of slots is not optimal, since the resulting slots are too narrow. Large and medium soil lumps will not wake up and will not linger through narrow slots, therefore, there will be no additional grinding of the soil and there will be no noticeable decrease in traction. Other types of slots are also not optimal, in the sense of the maximum possible total area of the slots, provided that the required disk strength is maintained.

The purpose of this technical solution is to increase the crumbling of the soil and reduce traction resistance of the disk. Obviously, for slotted discs, the maximum reduction in traction resistance of the disc will occur at the maximum possible total area of the slots, while maintaining the required strength of the disc

The technical result is achieved due to the fact that the spherical slotted slot contains slots located radially or at an angle to the radius of the disk. The gaps between the slots form spokes of uniform cross section, located radially or at an angle to the radius of the disk. In the case of the location of the spoke at an angle to the radius of the disk, the direction of inclination of the spoke can be either right or left. The outer part of the slot is a part of a circle made from the center of the disk. In this case, the outer part of the slot and the outer edge of the disk form the rim of the disk. And the pairing between adjacent spokes and the pairing between each spoke and the rim of the disk is made in a radius of 1 to 3 thicknesses of the disk. In this case, the spokes can be either straight or arcuate, and the outer edge of the disk can be either smooth or with cutouts.

The essence of the technical solution is illustrated by drawings. In FIG. 1 shows a spherical slotted disk with arcuate spokes located at an angle to the radius of the disk. In FIG. 2, 3, 4, 5, 6, and 7 show variants of a spherical slotted disk with straight and arched spokes located radially or at an angle to the radius of the disk in various combinations.

The spherical slotted disk contains slots located radially or at an angle to the radius of the disk. The gaps between the slots form spokes of uniform cross section a located radially or at an angle to the radius of the disk, and the outer part of the slot is part of a circle b made from the center of the disk. In this case, the outer part of the slot and the outer edge of the disk form the rim of the disk. The mating between adjacent spokes and the mating between each spoke and the rim of the disk is made along a radius R of a value from 1 to 3 thicknesses of the disk. Thus, the maximum possible total area of the slots is achieved, while maintaining the required strength of the disk

In FIG. Figures 2, 3, 4 and 5 show versions with straight knitting needles and with the number of slots from 6 to 9. A further increase in the number of slots will lead to a decrease in the size of the slot itself and a deterioration in disk performance.

In FIG. 1, 6, and 7 show embodiments with arcuate spokes.

The spherical slotted slot is buried in the ground due to the sharpened outer edge. Therefore, for working in fields with a small amount of crop residues, smooth disks without cuts along the outer edge are preferable.

For better engagement with the ground, in the presence of a large number of crop residues, discs are used with cutouts along the outer edge of the disc.

For processing fields with coarse crop residues, discs are used with cutouts with a depth of c = 35 ± 5 mm and a width of d = 85 ± 8 cm (Figs. 2 and 3). Number of cutouts 8 or 9 pcs. In this case, the number of slots will also be 8 or 9 pieces, respectively. At the same time, to comply with the condition of equal strength, each slot is located between two adjacent cutouts.

In FIG. Figures 1, 4, 5, 6, and 7 show spherical slotted disks with cutouts with a depth of c = 20 ± 5 mm and a width of d = 55 ± 8 cm. The number of cuts from 10 to 16 pieces and the number of slots from 6 to 9 pieces. In this case, the depth of cut is small. Such cuts do not have a great value on the strength of the disk. Therefore, in this case, the relative position of the cuts and slots is not observed.

A spherical slotted disk works as follows. When the gun moves, the disk, rotating, penetrates the soil, cuts off part of the soil and throws it to the side. At the same time, part of the soil passing through the slots is additionally subjected to crumbling by the spokes of the disk and is not thrown away by the disk, which reduces the traction resistance of the disk.

Thus, this technical solution will increase soil crumbling and reduce traction resistance of the disk.

Claims (7)

1. A spherical slotted slotted disk with slots located radially or at an angle to the radius of the disk, characterized in that the spaces between the slots form spokes of uniform cross section located radially or at an angle to the radius of the disk, and the outer part of the slot is part of a circle made from the center the disk, while the outer part of the slot and the outer edge of the disk form the rim of the disk, while the pairing between adjacent spokes and the pairing between each spoke and the rim of the disk is made in a radius of 1 to 3 thicknesses in drive. 2. A spherical slotted slot according to claim 1, characterized in that the spokes are straight, and if the spokes are arranged at an angle to the radius of the disk, the direction of inclination of the spokes can be either right or left. 3. A spherical slotted slot according to claim 1, characterized in that the spokes are arcuate, and if the spokes are arranged at an angle to the radius of the disk, the direction of inclination of the spokes can be either right or left. 4. A spherical slotted slotted disk according to claim 1, characterized in that the outer edge of the disk is smooth. 5. A spherical slotted slotted disk according to claim 1, characterized in that the outer edge of the disk is made with cutouts. 6. A spherical slotted disk according to claim 5, characterized in that the outer edge of the disk has from 10 to 16 cutouts with a depth of 20 ± 5 mm, a width of 55 ± 8 cm and from 6 to 9 slots. 7. A spherical slotted disk according to claim 5, characterized in that the outer edge of the disk has 8 or 9 cutouts with a depth of 35 ± 5 mm, a width of 85 ± 8 cm and, accordingly, 8 or 9 slots, with each slot located between two adjacent cutouts.

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