RU2086080C1 - Soil tillage working member - Google Patents

Abstract

FIELD: agricultural engineering. SUBSTANCE: working member has wedge with nose portion and blade and strengthening layer on one of wedge working surfaces. One of wedge working surfaces is made with undercutting, and strengthening layer is made in form of wear resistant covering with additional blade projecting beyond the limits of wedge. Covering is arranged in undercutting of working surface and is rigidly connected with the latter. EFFECT: increased wear resistance and improved quality of soil tillage. 7 cl, 3 dwg

Description

 The invention relates to agricultural machinery, in particular to cutting tools for surface tillage.

 Known flat-cutting paw for surface tillage, consisting of a rack with a wear-resistant working edge and lancet flat paws; lancet paw to the cultivator, including lancet working body with an overlay on the upper working surface; the working body of the agricultural machine, which contains an annular liner of a deposited wear-resistant material.

 The disadvantages of the known paws and working bodies for surface tillage are: the absence of a hardened cutting blade on a lancet flat paw (provided only on the rack), which significantly reduces the wear resistance of the working body; thermal strengthening of the lining on the lancet paw is not provided, which is also fastened with a bolt connection, the head and nut of which will wear out, which also significantly reduces the wear resistance of the paw; the limited scope of the working body in the form of a disk and the low-tech and unreliable fastening in the U-shaped groove of a wear-resistant ring-shaped liner.

 The closest to the claimed object in terms of features is a cutting working body for tillage, which contains a wedge with a bow and a sawtooth blade, protrusions and notches located on one of the working surfaces of the wedge, and a reinforcing layer, which helps to increase the operational reliability of the working body, adopted for the prototype.

 The reasons that impede the achievement of the required technical result when using a well-known object adopted as a prototype include: increased complexity and low-tech manufacturing; insufficiently high wear resistance, since the reinforcing layer is made of the same material as the cutting tool, made of 65G steel; decrease in the quality of surface treatment (cultivation) of the soil, in particular insufficiently reliable cutting of weeds due to the sawtooth blade and the presence of protrusions and depressions on the working surface, which often grab without cutting (enveloping) the roots and stems of the weeds, and additionally swell the soil, making the lower (wet) soil layers on the day surface.

 The objective of the invention is to increase the efficiency of use of the working body.

 The technical result that can be obtained by carrying out the invention is to increase the wear resistance of the working body and the quality of the soil treatment.

 The specified technical result is achieved by the fact that in the known cutting working body for soil treatment, containing a wedge with a bow and a blade, a reinforcing layer located on one of the working surfaces of the wedge, one of the wedge working surfaces is made with undercut, and the reinforcing layer is made in the form of wear-resistant lining with an additional blade protruding beyond the wedge, while the lining is located in the undercut of the working surface and is rigidly connected to it. In addition, undercutting is performed on the back of the working surface of the wedge; wear-resistant pad is made of heat-strengthened high-alloy steel, for example, quick cutting; the overlay is made of two parts with a joint in the nose of the wedge; thermal hardening of the lining is made after giving it the final geometric shape and fit to undercut; the pad is connected to the working surface by rivets or explosion welding.

 Figure 1 shows a General view of the cutting working body for tillage, side view in section; figure 2 is the same, plan view; figure 3 section aa in figure 2.

 Information confirming the possibility of carrying out the invention are as follows.

 The cutting working body for tillage, made, for example, in the form of a cultivator paw, has 1 wedge 2 with a bow and a blade 3 on each of its wings. On each wedge 2, the outer 4 and the opposite rear working surfaces are distinguished. Wings 1 and wedges 2 smoothly mate with each other along the geometric axis 1-1, which is the axis of symmetry of the paw. On this axis, the paw has a bulge to give it rigidity, swelling of the soil and for fastening (on the back side) of the working rack (not shown); holes 1 for the rack are also provided on the axis 1-1. Advantageously, an undercut 6 is made on the rear working surface of each wedge 2, and a sample of metal is made with respect to the base metal of the paw. In undercut 6, a reinforcing layer of the working body is provided in the form of a wear-resistant lining 7 with an additional blade 8. The wear-resistant lining 7 is rigidly connected in undercut 6 with the back of each wedge 2 using, for example, rivets 9 (with countersunk head), as shown in FIG. 1-3, or by explosion welding. The additional blade 8 of the lining 7 has a bevel opposite to the bevel of the blade 3 on the wedge 2, the blade 8 protrudes beyond the wedge; both blades 3 and 8 together form a single cutting part of the working body.

Wear plate 7 is made of heat-strengthened high-alloy high-strength (especially wear-resistant) steel, for example, relatively inexpensive and non-deficient high-speed steel of the type P6M5 from sheet metal. The thickness of the lining (rolled) varies from 1.2 to 2.0 mm; preferred pad thickness 1.4-1.6 mm. The patch 7 may be made as shown in FIG. 2, in the form of a single swept detail. As an option, it is possible to make a two-piece overlay with a joint in the bow of the wedge 2 along the axis 1-1, in this embodiment, each part of the overlay can be made of strip rolled products of the indicated thicknesses. In both cases, heat hardening is carried out after giving the trim or its part the final geometric shape, bevels are formed that form the blade 8, holes for rivets 9, if any, and adjustments to undercut 6. This sequence of manufacturing of wear-resistant lining 7 is explained by the fact that after special heat hardening the hardening after heating to a temperature of 1240-1300 ^o C, multiple tempering at a temperature of 560-620 ^o C, etc. high hardness is achieved over the entire thickness of the part while reducing the ductility of the metal. In parallel with this hardening, the base metal of the paw is exposed, as usual, high-carbon alloy steel type 65G, the mechanical properties of which, however, are lower than the corresponding parameters of the metal of the lining. On the other hand, joint hardening of the paw metals and pads 7 after their rigid connection is not provided due to significantly different heat treatment modes. As you know, high-carbon heat-hardened steels, and especially high-speed steels, practically do not undergo welding by traditional methods. This explains the above examples of fastening the wear-resistant lining 7 to the undercut 6 by means of rivets 9 and explosion welding.

 The cutting tool for tillage is used as follows.

 During the operation of the cutting working body during surface treatment (cultivation) of the soil, the paw wears out. The wear of the heat-strengthened wedge 2 and the wear-resistant lining 7 is manifested in a slow mode, but the outer working surface 4 and the blade 3 of each wedge are subjected to more wear and tear, while the blade 3 is slightly displaced, exposing the wear-resistant lining 7. The latter also wears out, becomes thinner, but less intensively. In this regard, and taking into account the initial limited thickness of the lining, the well-known effect of self-sharpening of the paw is fully manifested, where the function of the knife is carried out by the lining 7 and its blade 8. The very high strength (hardness) and wear resistance of the lining 7, its uniform thickness over the entire length, preclude the appearance on the cutting surface of the working body flaws and unacceptable blunting of the blade 8. Due to this, the quality of surface treatment of the soil increases, in particular, weeds are cut more. Along with this, due to the absence of irregularities on the cutting part of the protrusions and recesses, the blade 8 is more self-cleaning. As the wedge 2 and the cover 7 wear out, the rivets 9 also partially wear out, but being “covered” by the metal of the wedge and the cover and due to its practical absence the cylindrical part (figure 3), rivets until a certain point continue to hold the pad in undercut 6. The rest of the working body manifests itself in a known manner.

 Thus, the proposed technical solution improves the wear resistance of the working body and the quality of surface tillage, which is achieved without any significant complication of the design and manufacturing technology.

Claims (7)

 1. The cutting working body for tillage, containing a wedge with a bow and a blade located on one of the working surfaces of the wedge reinforcing layer, characterized in that one of the working surfaces of the wedge is made undercut, and the reinforcing layer is made in the form of a wear-resistant lining with an additional a blade protruding beyond the wedge, while the pad is located in the undercut of the working surface and is rigidly connected to it.  2. The working body according to claim 1, characterized in that the undercut is made on the back of the working surface of the wedge.  3. The working body according to claim 1, characterized in that the wear-resistant pad is made of heat-strengthened high-alloy high-strength steel, for example, high-speed.  4. The working body according to claim 1, characterized in that the pad is made of two parts with a joint in the bow of the wedge.  5. The working body according to claims 1, 3 and 4, characterized in that the hardening of the lining is made after giving it the final geometric shape and fitting to undercut.  6. The working body according to claims 1, 3 and 5, characterized in that the plate is connected to the working surface by means of rivets.  7. The working body according to claims 1, 3 and 5, characterized in that the plate is connected to the working surface by explosion welding.