RU172900U1 - Spherical Tillage Disc - Google Patents

Abstract

The utility model relates to agricultural engineering, in particular to the working bodies of disk cultivators and harrows. A soil-cultivating spherical disk made of high-quality structural steel, having a continuous cutting edge, sharpening from the convex side of the working surface and a hardfacing layer, with a hardfacing layer made in the form of a sinusoidal roller 2-4 mm thick, some vertices of which are located along the length of the cutting edge at the same distance from each other no more than 5 times the width of the weld bead, and the opposite peaks of the sinusoidal bead are located on an auxiliary circle parallel to the cutting edge at a distance from the cutting edge of not more than 0.1 of the diameter of the spherical disk. the contact layer in the areas of greatest friction with compacted soil during its interaction with the surface of the sinusoidal face of the alloy on the thickness of the deposited layer. 1 ill.

Description

The utility model relates to agricultural engineering, in particular, to the working bodies of disk cultivators and harrows.

Known tillage spherical disk having a smooth cutting edge, a flat bottom, a central square hole, sharpening a solid blade from the convex side of the working face (Wear and corrosion of agricultural machines / N.N. Podlekarev, V.O. Kitikov; edited by M.M. Severneva. - Minsk: Belarus Navuka, 2011, pp. 26-27, Fig. 1.9, Table 1.9; RF patent for utility model No. 50360, АВВ 7/00).

A disadvantage of the known spherical disk is the high wear rate of a continuous blade when processing compacted soil, which reduces the diameter of the disk when the cutting edge is blunted and reduces its resource.

The closest analogue to the claimed utility model includes a disk of a tillage implement (RF patent for utility model No. 71851, АВВ 15/16; АВВ 23/06) with a spherical segmented surface made of high-quality structural steel, having a smooth cutting edge, sharpening from the convex side the surface of the disk, and in the area of the working face, the cutting edge is hardfaced.

The disadvantage of this utility model is the high wear rate of the working surface of a continuous spherical disk in the zones of greatest friction with compacted soil.

The objective of the utility model is to reduce the wear rate of the working surface of a continuous spherical disk in the areas of greatest friction with compacted soil.

The problem is solved due to the fact that the soil cultivating spherical disk made of high-quality structural steel, having a solid cutting edge, sharpening from the convex side of the working surface and a hard alloy surfacing layer, while the hard alloy surfacing layer is made in the form of a sinusoidal roller with a thickness of 2-4 mm, some vertices of which are located along the length of the cutting edge at the same distance from each other no more than 5 times the width of the weld bead, and opposite vertices of the sinusoidal bead Position the auxiliary circle in parallel to the cutting edge at a distance from the cutting edge is not more than 0.1 diameter of a spherical disc.

New significant features.

1. The hard alloy surfacing layer is made in the form of a sinusoidal bead with a thickness of 2-4 mm, one of whose vertices are located along the length of the cutting edge at the same distance from each other no more than 5 times the width of the weld bead.

2. Opposite vertices of the sinusoidal roller are located on the auxiliary circle parallel to the cutting edge, at a distance from the cutting edge of not more than 0.1 of the diameter of the spherical disk.

The listed new essential features, together with the known ones, allow to obtain a technical result in all cases to which the requested amount of legal protection applies.

The technical result of the utility model is to reduce the wear rate of the working surface of a continuous spherical disk in the areas of greatest friction with compacted soil due to loosening and lowering the density of the surface contact layer when it interacts with the surface of a sinusoidal hard alloy roll by the thickness of the deposited layer.

The implementation of a spherical disk with the proposed arrangement of a sinusoidal roll with a hard-alloy hardfacing of 2-4 mm allows to increase the cooling rate of the working surface in the heat-affected zone with a decrease in welding deformations and the wear rate of the working surface of the spherical disk in the areas of greatest friction with compacted soil.

At the applied speeds of moving the working surface of disk cultivators and disk harrows, deformation of the near-surface contact layer of the soil under conditions of impact interaction with the lateral surface of the sinusoidal roller increases the rate of loosening of the near-surface contact layer of compacted soil by braking, crushing, and chipping particles to the thickness of the hardfacing layer, at stresses, exceeding the tensile strength of the soil with a decrease in mechanical stress on the base metal and the wear rate Ania working surface of the spherical disk.

In FIG. 1 schematically shows the location of a sinusoidal carbide roller on the working surface of a continuous spherical disk.

The device and operation of a spherical disk.

The tillage spherical disk 1 has a continuous cutting edge 2, a flat bottom 3, a central square hole 4, sharpening from the convex side of the working surface of the disk 1.

The hard alloy surfacing layer is made in the form of a sinusoidal roller 5 with a thickness of 2-4 mm, one of the peaks 6 of which are located along the length of the cutting edge 2 at the same distance t from each other no more than 5 times the width b of the weld bead.

Opposite peaks 7 of the sinusoidal roller 5 are located on the auxiliary circle 8 parallel to the cutting edge 2, at a distance S from the cutting edge 2 of not more than 0.1 diameter D _{c.d of the} spherical disk 1.

When a working surface of a spherical disk 1 is introduced into the soil at the applied displacement velocities, the deformation of the near-surface contact layer of the soil when it is pinched and jammed under the conditions of impact interaction with the surface of the sinusoidal roller 5 of the hard alloy increases the rate of loosening of the near-surface contact layer of the soil by braking, crushing, and chipping of particles at stresses exceeding the tensile strength of the near-surface contact layer of the soil with decreasing density of the contact layer of soil with the back of the sinusoidal roller 5 with the formation of zones 9 of stagnation of soil on both sides of the deposited layer, reducing the wear rate of the working surface of the spherical disk 1.

On the back of the sinusoidal roller 5, less connected particles of the surface contact layer of the soil undergo mixed relative movement, including sliding, rolling, rotating and rolling abrasive particles in the direction of rotation V, which reduces the mechanical effect of abrasive particles on the working surface of the spherical disk 1 when processing compacted soil.

The intensive development of leading cracks in the interaction of the contact layer of the soil with the peaks 6 of the sinusoidal roller 5 located on the cutting edge 2 reduces the degree of slipping of the spherical disk 1 in the direction of rotation V, contributing to the formation of stable self-sharpening of the working surface between the adjacent peaks 6 of the convex side of the spherical disk one.

Claims (1)

A cultivating spherical disk made of high-quality structural steel, having a solid cutting edge, sharpening from the convex side of the working surface and a hard-alloy surfacing layer, characterized in that the hard-alloy surfacing layer is made in the form of a sinusoidal roller 2-4 mm thick, one of whose vertices are located along the length of the cutting edge at the same distance from each other no more than 5 times the width of the weld bead, and the opposite vertices of the sinusoidal bead are located on the auxiliary window tools parallel to the cutting edge, at a distance from the cutting edge of not more than 0.1 of the diameter of the spherical disk.

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