RU2806218C1 - Disc harrow section - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: disk harrow section contains a bearing assembly (1) with a stand (2) and a shaft (3), on which needle disks (4) are installed on one side of the bearing assembly (1), and on the other side the first spherical disk (5) is fixed, facing the convexity of the sphere to the bearing unit (1). The second spherical disk (6) with its convex part is movably connected with the concave part of the first spherical disk (5). The disks (5 and 6) are mutually fixed along the radius by at least three fastening means (7). On the second disk (6), the holes of the fastening means (7) are made with grooves (8) providing one-sided displacement relative to the first disk (5). The radius of placement of the fastening means (7) and the grooves (8) on the second disk ensure its displacement relative to the first disk (6) to control the depth of the water-retaining grooves.

EFFECT: increased operational and technological performance of the disk harrow section.

1 cl, 1 dwg

Description

The invention relates to the field of agriculture, to tillage machines with devices for forming anti-erosion water-retaining intermittent furrows.

There are known devices for water-retaining intermittent furrowing, made in the form of a spherical disk with a bridge-forming cutout installed in a disk section with an angle of attack (patent RU 2615341).

The disadvantage of the device is that the upper part of the slopes of the furrows formed by the disks at a small angle of attack is located almost vertically, is not compacted and is therefore prone to crumbling and floating during precipitation. At the same time, the capacity of the furrows and the efficiency of furrowing decreases.

Needle harrows are known that loosen the top layer of soil while preserving plant residues on its surface (Gribanovsky A.P. et al. Complex of anti-erosion machines. "Agropromizdat", 1989, pp. 50-53). When using well-known harrows, soil-protective mulch is preserved on the field, preventing deflation, promoting the accumulation of snow and reducing moisture loss due to evaporation. However, when cultivating slopes, needle harrows do not create water-retaining unevenness.

A disc harrow with double-disc sections is known, in which the discs of the subsequent row are placed in strips between the discs of the previous row, and its double-disc sections contain a needle-shaped disc that preserves stubble and soil-protective mulch on the field surface, and a spherical disc made with a cutout in a sector of 50...90° at depth 0.4...0.6 of the disk radius (RF patent No. 2567008, IPC A01B 21/08).

Three-disk sections are known, containing two needle-shaped disks on one side of the bearing assembly and a spherical disk with a cutout, facing the concavity of the sphere outward, on the other side (RF patent No. 2615341 A01B 21/08 - prototype). The plane in which the disk blade is located is perpendicular to the axis of the shaft carrying the disk. Sections facing the concavity of the disks in one direction and installed in a row can work without clogging, since the soil thrown away by the spherical disk of one section does not fall under the other. A harrow with such sections performs erosion control: the strips treated with needle discs preserve stubble and prevent deflation, and the intermittent furrows created by cut-out discs retain water, prevent runoff and erosion.

A disadvantage of the known disc harrow section is the inability to regulate the depth of the water-retaining holes, regardless of the operating depth of the main discs.

The objective of the invention is to increase the anti-erosion properties of the treated soil and the ability to regulate the capacity of water-retaining intermittent furrows, regardless of the operating depth of the main disks of the section.

The technical result is an increase in the operational and technological performance indicators of the disc harrow section.

The technical result is achieved by a disc harrow section containing a bearing assembly with a stand and a shaft, on which needle disks are installed on one side of the bearing assembly, and on the other side a spherical disk is fixed, facing the convexity of the sphere towards the bearing assembly, and additionally contains a second one, which with its convex partly movably coupled with the concave part of the first spherical disk, while the disks are mutually fixed along the radius by at least three fastening means, and on the second disk the holes of the fastening means are made of grooves providing one-sided displacement relative to the first disk, while the radius of the fixing means and the grooves on the second the disk is provided with its displacement relative to the first disk to regulate the amount of deepening of the water-retaining grooves.

The proposed disc harrow section is illustrated in the figure.

In fig. Figure 1 shows a section of a disc harrow.

The disc harrow section is made in the form of a bearing unit 1 with a stand 2 and a shaft 3. On one side of the shaft 3 of the bearing unit 1, needle disks 4 are installed, and on the other side a spherical disk 5 is fixed, with the convexity of the sphere facing the bearing unit 1. Spherical disk 5 is additionally contains a second spherical disk 6, which with its convex part is movably coupled with the concave part of the first spherical disk 5. The first spherical disk 5 and the second spherical disk 6 are mutually fixed radially by fastening means 7 by at least three fastening means. On the second disk, spherical disk 6, the holes of the fastening means 7 are made of grooves 8, providing one-sided displacement relative to the first spherical disk 5. The size of the radius of the location of the fastening means 7 and the dimensions of their grooves 8 on the second spherical disk 6 provide displacement of the second spherical disk 6 relative to the first spherical disk 5 to regulate the depth of water-retaining furrows.

The disc harrow section works as follows. During operation, the disc harrow section loosens the soil, maximally preserving soil-protective mulch and stubble on the field surface. Needle discs 4 loosen the soil. Stubble and mulch stored on the field surface prevent deflation. Due to the possibility of installing spherical disks 5 and 6 with an offset of the movable second spherical disk 6 relative to the first spherical disk 5, an asymmetric protrusion is formed, within the limits of regulation along the grooves 8, which cuts an intermittent furrow. The conjugation of the convex part of the second spherical disk 6 with the concave part of the first spherical disk 5 and their fixation by at least three means of fastening makes it possible to prevent soil from getting between the first 5 and second 6 spherical disks. The ability to smoothly regulate the installation of the spherical disks of the second 6 relative to the first 5 allows you to adjust the size of the recess and change the capacity of the water-retaining intermittent furrows, regardless of the depth of operation of the main needle disks 4 of the harrow section.

Thus, the declared design of the disc harrow section provides an increase in the anti-erosion properties of the treated soil and the ability to regulate the capacity of water-retaining intermittent furrows, regardless of the operating depth of the main disks of the section.

Claims (1)

A section of a disc harrow containing a bearing assembly with a stand and a shaft, on which needle disks are installed on one side of the bearing assembly, and on the other side a spherical disk is fixed, facing the convexity of the sphere towards the bearing assembly, characterized in that it additionally contains a second spherical disk, which the convex part is movably coupled with the concave part of the first spherical disk, while the disks are mutually fixed along the radius by at least three fastening means, and on the second disk the holes of the fastening means are made of grooves, providing a one-sided displacement relative to the first disk, while the radius of the fastening means and the grooves on the second disk, it is shifted relative to the first disk to regulate the amount of deepening of the water-retaining grooves.

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