RU2503811C1 - Solid material destruction tool - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: tool includes a housing and a hard-alloy insert that is fixed on the housing. The insert includes a head part, an intermediate part, a base and a shank. Intermediate part of the insert, and/or its base represent a stepped pyramid-shaped body, the stages of which are made in the form of regular right-angle prisms and/or prismatoids.

EFFECT: optimisation of geometrical parameters of a hard-alloy insert.

10 cl, 8 dwg

Description

The invention relates to mining and construction, in particular, to cutting tools for machines used for the destruction of rocks and artificial coatings.

A known tool for the destruction of solid materials, containing a carbide insert fixed in the socket of the working head. The insert includes a pointed tip to the apex and a cylindrical body. The generatrix of the side surface of the carbide insert head has the shape of a circular arc. the center of which is located at the intersection of the normal to the tangent to the arc of a circle at the apex of the point angle of the insert head and the base of the insert body. The beginning of the arc of the circle forming the lateral surface of the head of the insert is located at the apex of the angle of sharpening of the head of the carbide insert (see paragraphs of the Russian Federation No. 2018659 according to CL E21C 25/38, E21C 35/18 decl. 11.09.91, publ. 30.08.94 " Cutter of a mining machine for the destruction of predominantly hard rocks ").

The disadvantage of this tool is the low efficiency of its work. due to the fact that the destruction of the material is carried out only by a pointed insertion head, which is subject to rapid wear and dullness.

Also known is a tool for the destruction of solid materials, comprising a housing and a carbide insert that is mounted on the housing and contains a head and intermediate parts, a base and a shank for placement in the housing socket. The base of the insert is in the form of a cylinder, the longitudinal axis of which is located on the longitudinal axis of the insert. The head part of the insert is formed by a body of revolution with an outer lateral surface of a convex shape. The intermediate part of the insert is formed by a body of revolution with an external lateral surface of a concave shape. The lateral surface of the head of the insert smoothly mates with the lateral surface of the intermediate part of the insert. The length of the intermediate part of the insert along its longitudinal axis does not exceed the length of the head part of the insert along the same axis (see paragraphs of the Russian Federation No. 2052099 according to CL E21C 35/18, E02F 9/28 declaring 28.01.93, publ. 10.01.96 " Tool for the destruction of solid material ").

The implementation of the intermediate part of the carbide insert in the form of a body of revolution with a concave outer side surface is more optimal in terms of consumption of carbide material compared to the above tool, in which the outer side surface of the carbide insert is convex. However, in this tool, the destruction of the material is also carried out by the centrally located head part of the insert. It has a minimum radius of curvature of the surface and, therefore, creates maximum loads in the material, leading to its destruction. The intermediate part of the insert and its base are made with a smooth outer surface and therefore practically do not participate in the destruction of the material. This reduces the efficiency of the process of destruction of the material and leads to intensive wear of the tool as a whole.

The objective of the present invention is to increase the efficiency of the destruction of the material while ensuring high wear resistance of the tool.

The technical result obtained by the implementation of the invention is the optimization of the geometric parameters of the carbide insert.

This problem is solved due to the fact that in the known tool for the destruction of solid materials, comprising a housing and a carbide insert, which is mounted on the housing and contains a head part, an intermediate part, a base and a shank for placement in the housing socket, according to the invention, the intermediate part of the insert and / or its base is a stepped pyramidal body, the steps of which are made in the form of regular direct prisms and / or prismatic.

The prismatic steps of the pyramidal body can be located relative to each other with rotation around the longitudinal axis of the insert.

The angle of rotation of the faces of adjacent prismatic steps of the pyramidal body relative to each other can be at least 5 °.

Each of the prismatic steps of the pyramidal body can be made so that the sharp edges of the edges of the polyhedron are blunted.

The length of the tool body, counting from the base of the insert to the fist of the working body of the rock cutting machine, can be at least 0.1 of the total length of the head part, the intermediate part, and the base of the insert.

The dimensions of the cross section of the base of the insert may exceed the dimensions of the cross section of the shank of the housing.

The insert may have a nest for accommodating a protrusion of the housing, and the bottom of the nest can be made with a protrusion inside the nest, designed to be placed in the corresponding recessed part of the housing, and the height of the protrusion inside the nest is at least 0.5 mm

The insert shank can be made in the form of an annular element having radial grooves and / or channels, the longitudinal axis of which is located on the longitudinal axis of the insert,

On the supporting surface of the base of the insert, designed to interact with the surface of the housing, on the supporting surface of the shank, designed to interact with the bottom of the socket of the housing, on the bottom of the socket of the insert, on the protrusion made on the bottom of the socket of the insert, there may be auxiliary protrusions 0.03-0 in height 5 mm.

Studies conducted on the sources of patent and scientific and technical information have shown that the claimed tool is unknown and does not follow explicitly from the studied prior art, i.e. meets the criteria of novelty and inventive step.

The tool can be manufactured at any enterprise specializing in this industry, as This requires well-known materials and standard equipment, and is widely used for the destruction of hard rocks, i.e. is industrially applicable.

Made in the claimed form, the tool acts on the array of destructible material at the same time as the centrally located head part of the insert, and with sharp cutting protrusions uniformly located along the entire outer surface of the intermediate part of the insert and its base. It is obvious that the introduction of a tool with numerous sharp cutting edges into the material to be destroyed requires less power consumption than the introduction of a tool (according to the prototype) having only a pointed head portion. This allows you to increase the cutting speed and, therefore, the productivity of the tool. Increases productivity and a larger, compared with the prototype, the size of the zone of destruction arising from the impact of the tool. In addition, such a simultaneous effect of numerous cutting protrusions creates stresses in the whole array of destructible material, leading to the formation of microcracks, which facilitates the introduction of the tool into the material and reduces its wear. The specific geometric parameters of the carbide insert are selected depending on the properties of the material being destroyed. So for the destruction of hard rocks can be used carbide insert, the intermediate part and the base of which is made in the form of a stepped pyramidal body of complex shape. The geometrical parameters of this insert are such that there are many cutting edges on its lateral surface that serve to cut the destructible solid material. The intersection of the numerous planes of the insert forms strong, in particular rectangular and / or obtuse-angled wedges uniformly distributed over the outer surface of the insert. The length of the head part of the insert, the intermediate part of the insert, and the base are selected empirically depending on the properties of the material being destroyed. With a small consumption of carbide material, this form of the insert provides high wear resistance by minimizing the likelihood of spalling and chips of the hard alloy, as well as due to the uniformity of wear on the entire outer surface of the insert, both its head part and its intermediate part and base. The specified restriction for the angle of rotation of the faces of adjacent prismatic steps of the pyramidal body relative to each other, which should be at least 5 °, is caused by the following. At an angle of less than 5 °, the cutting edges on the surface of the carbide insert are so small that they have little effect on the fracture efficiency of the material being cut. In addition, the implementation of the insert with an angle of less than 5 ° reduces the manufacturability of its manufacture.

The durability of the tool as a whole also depends on the strength and durability of the case below the base of the carbide insert. Studies have shown that the length of the tool body should be as small as possible. It was empirically established that it is most expedient to ensure the necessary strength and wear resistance of the tool as a whole, so that the length of the tool body along its longitudinal axis, which coincides with the longitudinal axis of the carbide insert, is at least 0.1 of the total length along the longitudinal axis of the head part, the intermediate part, and insert base, i.e. insert length without shank. It was also empirically established that to eliminate the likelihood of a carbide insert falling out of the tool body and the case falling out of the working body of the rock cutting machine, the dimensions of the cross section of the base of the insert should approach the dimensions of the head of the body and exceed the dimensions of the cross section of the shaft end. For example, when making the base of the insert and the tool body cylindrical, the ratio of the diameter of the base of the insert to the diameter of the shank of the housing should be at least 1.05. This provides the necessary strength and durability of the housing below the base of the carbide insert.

The use of a carbide insert with multiple cutting edges in the tool in some cases necessitates and reinforces the means of holding the insert in the housing. This can be achieved by increasing the contact area of the insert and the housing. The insert can be made with an internal socket, and, if necessary, with an additional protrusion into the socket. Those. the insert can contact the housing not only through its shank, but also by introducing the protrusion of the housing into the insert socket. The implementation of the insert with the socket also allows you to achieve uniform distribution of the load in the volume of the body of the insert and the housing.

On the strength and wear resistance of the tool as a whole, the quality of fixing the carbide insert on the body also has an important influence. To ensure uniformity of the soldered seam on all surfaces of the carbide insert, which are designed to interact with the corresponding surfaces of the housing, small auxiliary protrusions are made. These protrusions allow you to drain through the grooves and / or channels in the shank of the carbide insert formed during the soldering gas. This significantly reduces the likelihood of the formation of areas where the soldered seam is not formed or has defects.

Thus, the inventive tool for the destruction of solid materials by optimizing the geometric parameters of the carbide insert increases the efficiency of the destruction of the material while ensuring high wear resistance of the tool.

The claimed technical solution is illustrated by the drawings:

Figure 1. General view of the carbide insert of the inventive tool with an intermediate part of the insert, made in the form of a stepped pyramidal body, the prismatic steps of which are located relative to each other with rotation around the longitudinal axis of the insert.

FIG. 2. Top view of the carbide insert shown in figure 1.

Figure 3. The section on the carbide insert shown in figure 1.

Figure 4. Bottom view of the carbide insert shown in figure 1 and figure 4.

Figure 5. A tool for the destruction of solid materials, fixed in the fist of the working body of a rock cutting machine.

The tool for destruction of solid materials according to the present invention comprises a housing 1 and a carbide insert that is mounted on the housing 1 and includes a head part 2, an intermediate part 3, a base 4 and a shank 5 for placement in the housing socket 1. The intermediate part 3 of the insert and / or its base 4 is made with cutting protrusions on the outer surface. The intermediate part 3 of the insert and / or its base 4 are a stepped pyramidal body, steps 6 of which are made prismatic. Prismatic steps 6 can be polyhedra, for example, prisms at the base of which have a triangle, or a quadrangle, or a pentagon, or a hexagon, etc. These prisms can be correct - with bases in the form of regular n-gons, or incorrect - with bases in the form of irregular n-gons. Prisms can be direct and indirect. A prismatoid can also act as stage 6, i.e. a polyhedron in which two faces (bases) lie in parallel planes, and the rest are trapezoids or triangles having a common side or apex with the bases. The prismatic steps 6 of the pyramidal body can be located relative to each other with rotation around the longitudinal axis of the insert. The specific choice of the shape of the steps 6 forming the intermediate part 3 of the insert depends on the conditions of use of the tool for the destruction of solid material. The sharp edges of the ribs of the steps 6 forming the intermediate part 3 of the insert can be blunted either by making bevels or by rounding, for example, with a radius of 0.5 mm.

The length (indicated in the drawing as L ₁ ) of the tool body 1, counting from the base 4 of the insert to the fist 7 of the working body of the rock cutting machine, is 0.1-0.9 of the total length (marked as L ₂ in the drawing) of the head part 2, the intermediate part 3 and base 4 inserts. The diameter of the base 4 of the insert (indicated as D ₂ in the drawing) exceeds the diameter of the shank 12 (indicated as D ₁ in the drawing) of the housing 1.

The insert may have a socket 8 to accommodate the protrusion 13 of the housing 1, and the bottom of the socket 8 can be made with the protrusion 9 inside the socket 8, designed to be placed in the corresponding recessed part of the housing 1. The height of the protrusion 9 can be at least 0.5 mm and is selected depending on the existing need to increase the contact area of the carbide insert and the housing 1.

The shank 5 of the insert can be made in the form of an annular element having radial grooves 10 and / or channels, the longitudinal axis of which is located on the longitudinal axis of the insert. On the supporting surface of the base 4 of the insert, designed to interact with the surface of the housing 1; on the supporting surface of the shank 5, designed to interact with the bottom of the housing socket 1; at the bottom of the insertion socket 8, on a protrusion 9 made at the bottom of the insertion socket 8; there are auxiliary projections 11 with a height of 0.03-0.5 mm.

Tool for the destruction of solid materials works as follows. A carbide insert mounted on the tool body 1 interacts with a destructible material. In this case, a groove (collapse) is formed on the surface of the material to be destroyed, and particles of the destroyed material enter the gaps between the cutting edges of the pyramidal step body or into the recesses on the body surface with cylindrical steps of the intermediate part of the insert and without breaking the insert with compressed products of destruction, they are removed from it. The optimal geometrical parameters of the insert with a plurality of cutting edges along the entire surface of the intermediate part of the insert provide high efficiency in the destruction of the material, and also allow the insert to maintain high cutting properties for a longer time without chips and defects of the hard alloy. At the same time, the optimum ratio of the dimensions of the cross section of the tool body and the insert base, as well as the tool body length and the insert length, protects the body from premature wear-abrasion, and the reliable fixing of the insert in the body prevents it from breaking out of the body, and the body from the working body of the rock cutting machine.

Thus, the inventive tool for the destruction of solid materials by optimizing the geometric parameters of the carbide insert increases the efficiency of the destruction of the material while ensuring high wear resistance of the tool.

Claims (10)

1. A tool for the destruction of solid materials, comprising a housing and a carbide insert, which is mounted on the housing and contains a head part, an intermediate part, a base and a shank for placement in the housing socket, characterized in that the intermediate part of the insert and / or its base are stepped a pyramidal body, the steps of which are made in the form of regular direct prisms and / or prismatic. 2. The tool according to claim 1, characterized in that the prismatic steps of the pyramidal body are located relative to each other with rotation around the longitudinal axis of the insert. 3. The tool according to claim 2, characterized in that the angle of rotation of the faces of adjacent prismatic steps of the pyramidal body relative to each other is at least 5 °. 4. The tool according to claim 1, characterized in that each of the prismatic steps of the pyramidal body is made so that the sharp edges of the edges of the polyhedron are blunted. 5. The tool according to claim 1, characterized in that the length of the tool body, counting from the base of the insert to the fist of the working body of the rock cutting machine, is at least 0.1 of the total length of the head part, the intermediate part and the base of the insert. 6. The tool according to claim 1, characterized in that the dimensions of the cross section of the base of the insert exceed the dimensions of the cross section of the shank of the housing. 7. The tool according to claim 1, characterized in that the insert has a socket for accommodating the protrusion of the housing. 8. The tool according to claim 7, characterized in that the bottom of the socket is made with a protrusion inside the socket, designed to be placed in the corresponding recessed part of the housing, and the height of the protrusion is not less than 0.5 mm 9. The tool according to claim 1, characterized in that the insert shank is made in the form of an annular element having radial grooves and / or channels, the longitudinal axis of which is located on the longitudinal axis of the insert, 10. The tool according to any one of claims 1, 7, 9, characterized in that on the supporting surface of the base of the insert, designed to interact with the surface of the housing, on the supporting surface of the shank, designed to interact with the bottom of the socket of the housing, at the bottom of the socket of the insert, the protrusion made at the bottom of the insertion socket, there are auxiliary protrusions 0.03-0.5 mm high.

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