RU154852U1 - SHOOT Paw - Google Patents

Abstract

1. Arched paw containing paw wings having an electric arc surfacing of wear-resistant material and a paw shank on the surface of the working part, characterized in that the electric arc welding is made on the outer working surface in the form of a central and side rollers, alternately located at an angle α = 12- 17º to the axis of symmetry in the direction of movement of the working surface. 2. The paw according to claim 1, characterized in that the central and side rollers are made with a length of 30-50 mm and a layer height of 3-4 mm. The paw according to claim 1, characterized in that the side rollers are located at the same distance from each other in increments of 2-4 mm and with a layer width of 5-7 mm, and the central roller is made with a layer width of 10-18 mm.

Description

The utility model relates to agricultural machinery, in particular to the working cutting bodies of tillage tools and can be used in the manufacture and repair of working bodies of tillage machines.

Known flat-cutting working body for soil cultivation in the form of a pointed arm, containing the wings of the leg and the shank of the legs, and on the outer working surface of the wings of the legs discrete sections of the reinforcing layer are arranged in the form of strips directed at an angle to the direction of application of the traction force, and on the other side of the wings the legs are additionally made a reinforcing layer with similar sections, and the reinforcing sections are made using the spark method (see RF patent No. 2366139 for IPC A01B 35/20, published on 09/10/2009).

A disadvantage of the known method of surface hardening of the base material is the relatively small depth of the hardened layer, which after its wear leads to very rapid wear of the wings of the legs.

The closest in technical essence is a lancet paw, containing symmetrical paw wings, having an electric arc cladding of wear-resistant material on the inner working surface, and a paw shank, and the electric arc cladding on the inner working surface is made along the reinforcement lines in the form of points of wear-resistant material with a layer thickness of 0, 8-2.0 mm located at a distance from each other, providing overlapping gaps of the base metal between adjacent points in the direction moved I work surface (see. RF patent №2464358 IPC B23K 9/04, publ. 20.10.2012).

A disadvantage of the known lancet paw is that the surfacing is performed on the inner working surface of the wings of the paw, which leads to a high wear rate of the base metal in the region of the highest friction intensity of the external working surface with the soil, the formation of step wear in the transition zone (heat-affected zone), and an increase in thickness the sharp edges of the wings of the legs, increasing traction resistance, especially on soils with high viscosity.

The technical result of the utility model is to reduce the wear of the lancet paw, which is provided by increasing the resistance to abrasive wear during direct interaction with the soil in the active friction zone of the outer working surface.

The technical result is achieved by the fact that in a lancet paw containing symmetrical paw wings having an electric arc cladding of wear-resistant material on the working part, and a paw attachment shank, according to a utility model, electric arc cladding is made on the outer working surface in the form of a central and side rollers, alternately located under angle α = 12-17 degrees to the axis of symmetry in the direction of movement of the outer working surface. The central and side rollers are made with a length of 30-50 mm and with a layer height of 3-4 mm. The side rollers are located at the same distance from each other in increments of 2-4 mm and with a layer width of 5-7 mm, and the central roller is made with a layer width of 10-18 mm.

In FIG. 1 shows a lancet paw, general view from above; in FIG. 2 - section along aa; in FIG. 3 shows a fragment of the wing of a paw with metal wear between the weld beads after running-in.

The lancet paw contains a shank for attaching the paw 1, the wings of the paw 2 and 3 with the inner working surface 4 and the outer working surface 5. On the outer working surface 5, arc welding is performed in the form of side rollers parallel to each other 6, welded at an angle α = 12-17 degrees to the axis of symmetry, coinciding with the direction of movement of the "S" lancet paws. Side rollers 6 are made of the same size with a length of 30-50 mm, a layer height of 3-4 mm, a layer width of 5-7 mm and are located at the same distance from each other in increments of 2-4 mm. On the bow of the paw there is a central roller 7 in the direction of movement of the lancet paw with an increased layer width of 10-14 mm.

Side rollers 6 are stiffeners at a certain distance from each other. This distance is determined by the geometric parameters of the side rollers 6 to ensure the necessary overlap of the gaps of the main material between adjacent side rollers 6 and create a frame structure. In this case, conditions are created to ensure proper strength under the influence of the soil environment, thereby reducing the tendency to destruction. The voids formed between the side rollers 6 serve as cavities that are filled with soil particles, which in this case play the role of an anti-abrasion medium that is resistant to wear. The central roller 7 is deposited along the line of movement of the soil with an increased size, which gives the bow of the lancet paw the shape of a bit. The central roller 7 with its high hardness of 65-68HRC and a chisel shape provides high wear resistance of the nose of the lancet paw as the most loaded part of the outer working surface, experiencing soil pressure 3-4 times higher than the pressure acting on the edge of the wings of the legs 1 and 2.

The operation of the lancet paw used in the example of a specific implementation on the cultivator is as follows.

When the cultivator moves, the wings of paws 2 and 3, penetrating into the soil, cut the formation with vegetation and intensively crumble the soil. When the wings of the paws 2 and 3 are deepened, the interaction of the contact layer of the soil with the outer working surface 5 increases. When the lancet paws move in the direction of movement under normal pressure, the soil fills the gaps between the side rollers 6 on the base metal with its compaction and crushing. In this case, stagnant zones of immovable soil are formed, which reduce the friction of the contact layer of the soil with the base metal of the outer working surface 5, or there is a sharp decrease in the speed of movement of the soil in the intervals between the deposited rollers, which is determined by the angle of deposition of the side rollers 6 with respect to the movement of the soil and leading to a change in the direction of movement of the soil falling into the gaps.

During the operation of the lancet paw, the non-melted sections (the cutting edge of the gaps between the rollers) wear out more and take on a crescent shape as a result of the initial running-in process. The cutting edges of the weld beads in this case take a toothed wedge-shaped shape. Soil particles move along the outer working surface of the 5 wings of the legs 2 and 3 along a certain path and experience frontal resistance of only the front faces of the deposited rollers, both on the outer working surface and on the back side. In this case, the side faces of the side rollers 6 do not have much contact with the soil, which reduces soil unloading (stagnation) in front of them.

The serrated shape of the working surface (edge) of the wings of the legs 2 and 3 reduces the soil pressure along the line of the cutting edge, thereby reducing traction resistance and wear of the working surface of the lancet paw.

Depreciation of the base metal of the inner working surface 4 of the wings of the legs 2 and 3, having a lower surface density compared to the areas on which the deposited rollers are located, ensures self-sharpening of the working edge.

Side rollers 6 reduce the degree of interaction of the contact soil layer with the base metal by loosening the contact soil layer by braking and squeezing the thickness of the deposited layer with the formation of stagnant soil zones, increased density in the spaces between the side rollers 6 from different sides of the axis of symmetry of the lancet paw, which coincides with the direction of movement "S".

The location of the axis of symmetry in the direction of movement of the "S" lancet paws provides a symmetrical distribution of the frontal resistance of the soil with the formation of a stable friction surface of the contact layer of the soil with the surface of the side rollers 6 and stagnant zones of the soil with high density. This reduces the wear rate of the base metal in the region of greatest friction intensity of the outer working surface 5.

The proposed lancet paw improves the conditions for cutting weeds, reduces the rate of deformation of the treated formation due to the emerging dynamic processes in the zone of contact of the soil with the working edge of the deposited rollers.

The proposed design of the lancet paw ensures reliable performance of the process, provides high operational reliability under various working conditions, including post-harvest loosening of compacted soil, allows to increase the service life of the lancet paw and treat soil of various moisture, hardness and mechanical composition.

Claims (3)

1. Arched paw containing paw wings having an electric arc surfacing of wear-resistant material and a paw shank on the surface of the working part, characterized in that the electric arc welding is made on the outer working surface in the form of a central and side rollers, alternately located at an angle α = 12- 17º to the axis of symmetry in the direction of movement of the working surface. 2. The paw according to claim 1, characterized in that the central and side rollers are made with a length of 30-50 mm and a layer height of 3-4 mm. 3. The paw according to claim 1, characterized in that the side rollers are located at the same distance from each other in increments of 2-4 mm and with a layer width of 5-7 mm, and the central roller is made with a layer width of 10-18 mm.

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