RU2555295C1 - Insert and face cutter - Google Patents

Abstract

FIELD: process engineering.SUBSTANCE: invention relates to cutting of hard-to-machine metals. Insert comprises top surface and bottom thrust surface, side surface or multiple side surfaces connecting the latter to make cutting edges, and central bore. Top surface has angular ledges dividing it into identical sectors to make upward surface abutting on front surface and downward surface abutting on central bore ledge. Ledges of bulged smoothly varying shape are arranged radially between said angular ledges to enter the recesses at front surface and to abut on central bore ledge. Ratio between front surface area between cutting edges and central bore to plane extending through cutting edges its projection on said plane is selected to make 1.05?1.3. Or, ratio between cutting edge length and wavy line length extending over upper surface in cross-section of ledges and recesses through intersection of projections of radial ledges and sections of front surfaces between radial lines extending through angular ledges of top surface and insert bore axis makes 1.1?1.5.Insert is fitted in seats or cassettes of face cutter.EFFECT: higher hardness in machining of hard-to-cut materials.13 cl, 12 dwg

Description

Technical field

The present invention relates to devices used in the processing of materials by cutting, in particular to a cutting insert and a tool for its use, mainly for processing difficult materials.

The level of technology.

When processing difficult materials, for example, titanium alloys, at the same time there is a need to remove chips from the cutting zone, especially when processing deep grooves, and to increase the resistance of the wear-resistant coating applied to the working surfaces, and to increase the resistance of the cutting edges themselves, thereby improving the overall performance at higher cutting tool modes as a whole. To remove chips from the cutting zone, cutting inserts equipped with chipbreakers are usually used and therefore have a complex shape on the front surfaces of the cutting inserts. Moreover, during the cutting process, due to the stress-strain state of the cutting inserts, the internal stresses in them increase significantly, which negatively affects the resistance of the wear-resistant coating and the cutting edges themselves.

In the patent of the Russian Federation RU 2492970 a cutting insert is disclosed comprising at least one cutting edge, a front surface extending from the cutting edge and having a positive rake angle, a concave portion adjacent to and behind the front surface when viewed from the cutting edge, and at least one protrusion protruding from the bottom surface of the concave part. Moreover, the entire protrusion is located closer to the lower surface of the concave part than to the surface formed by the continuation of the front surface. Moreover, the location of the protrusions in the concave part of the cutting insert, according to the authors, limits the growth of the deformation resistance of the chips, which is its advantage.

However, for the cutting insert disclosed in the patent of the Russian Federation RU 2492970, it is difficult to obtain effective chip removal while increasing the resistance of the cutting edges and wear-resistant coating when processing, for example, deep grooves in products from titanium alloys with milling cutters.

In the patent of the Russian Federation RU 2417864 a polygonal cutting insert having an upper and lower surface, a plurality of side surfaces connecting the upper and lower surfaces, a central hole made in its central part is disclosed. For the most efficient chip removal, a flat supporting surface is formed at the highest level of the upper surface, a plurality of sections of the side cutting edge are formed at the boundary of the upper surface and the side surfaces, and a corner cutting section is formed at the border of two adjacent sections of the side cutting edge. Moreover, along the diagonals of the cutting insert in the direction of the central hole, inclined surfaces, depressions and protrusions are successively arranged. A pair of protrusions is formed on both sides of the diagonals.

According to the authors, the mentioned design of the cutting insert allows you to effectively remove chips from the cutting zone during turning.

At the same time, the design of the cutting insert disclosed in the patent of the Russian Federation 2417864 also does not allow to achieve positive results when machining difficult-to-process materials with milling cutters.

The present invention is the creation of improved designs of the cutting insert for its use in the processing of difficult to process materials by increasing the efficiency of chip removal and reducing internal stresses in the cutting plate when it is stress-strain state and, as a result, increasing the resistance of the cutting insert.

The present invention is also the creation of a face-cylindrical cutter for fixing and using the proposed cutting insert.

The problem is solved by means of a set of features given in the relevant claims. In particular, a cutting insert is proposed in which the configuration and relative position of the protrusions and depressions on its upper surface is given, and a ratio of a part of the upper surface area of the cutting plate extending from the cutting edges to the central hole to the plane passing through the cutting edges to its projections on this area, equal to 1.02 ... 1.3, and the ratio of the length of the cutting edge to the length of the wavy line running along the upper surface in the section of protrusions and depressions through the intersection of the projections is radially located protrusions and portions of the front surfaces of the cutting plate on its side a = 1.1 ... 1.5.

Also proposed is the design of the end-cylindrical mill, comprising a housing with sockets made directly in the housing or in cassettes installed in the housing, with each socket having one supporting surface and side contact surfaces for mounting the proposed cutting insert.

SUMMARY OF THE INVENTION

In accordance with the present invention, there is provided a cutting insert comprising an upper surface, a supporting lower surface, a side or a plurality of side surfaces connecting the upper and lower surfaces to form cutting edges with an upper surface, and a central hole formed in the central part of the insert.

According to the proposed invention, angular protrusions are made on the upper surface, dividing it into identical sectors A and forming an ascending surface adjacent to the elevation of the central hole and a descending surface adjacent to the elevation of the central hole, and protrusions of a convex continuously varying shape entering the depressions radially located between the angular protrusions the front surface of the cutting insert, and adjacent to the elevation of the central hole.

In this case, the maximum heights of the angular protrusions are located above the cutting edges and are located in the radial direction further from the vertical axis of the hole of the cutting insert, and in the horizontal direction, further from the cutting edge of the cutting plate to the parallel to the cutting axis of the hole axis, than the maximum heights of the radially arranged protrusions.

Moreover, the intersection points of the projections of the radially located protrusions and portions of the front surfaces extending from the cutting edges into the upper surfaces, in a side view in cross section of the cutting insert with a plane generally perpendicular to the lower surface, are closer to the cutting edge than the maximum height of the angled protrusions.

The ratio of the part F of the area of the upper surface of the cutting insert, from the cutting edges to the central hole to the plane P passing through the cutting edges, to its projection onto this plane is selected in the range of 1.05 ... 1.3 or the ratio of the length L to the cutting edge to the length of the wavy line passing over the upper surface in the section of the protrusions and depressions through the intersection of the projections of the radially arranged protrusions and portions of the front surfaces between the radial lines passing through the angular protrusions of the upper surface and the hole axis the plate is in the range of 1.1 ... 1.5.

According to one preferred embodiment, the junction of the cutting edges on the side surfaces is made with radiuses or corner bevels, and the cutting edges are made with horizontal reinforcing bevels located on the front surface along the cutting edges.

According to another preferred embodiment, the angled protrusions are made with equal maximum heights.

According to another preferred embodiment, the angled protrusions are made with maximum heights pairwise diagonally equal to each other.

According to another preferred embodiment, the axis of symmetry of sectors A of the upper surface are the axes of the hole.

According to another preferred embodiment, the radially arranged projections are made with a maximum height, the magnitude of which is greater, less than or equal to the maximum height of the corner projections.

According to another preferred embodiment, the radially arranged protrusions adjacent to the elevation of the central hole are arranged in a row parallel to the cutting edge or are arranged in a plan view of the cutting insert in a wavy curve.

According to another preferred embodiment, the radially arranged protrusions are made with maximum heights located in a plane parallel to the plane passing through the cutting edges, along a curve that is convex or concave relative to the cutting edge.

According to another preferred embodiment, the radially arranged protrusions are made with the greatest height greater than or equal to the height of the cutting edge.

According to another preferred embodiment, the angled protrusions and the radially arranged protrusions are made with the shape of second-order surfaces, preferably a sphere, cylinder, cone or torus.

According to another preferred embodiment, smooth transitions are made between the angular protrusions and the radially arranged protrusions, depressions, front surface and elevation of the central hole.

According to another preferred embodiment, the radially spaced protrusions and / or their number and / or their shape are individual for each sector A mentioned.

In accordance with the present invention, there is provided a face-cylindrical milling cutter comprising a housing, sockets made in the housing or in cassettes installed in the housing, and having one supporting surface and side contact surfaces intended for mounting the cutting insert according to any embodiment of the cutting insert.

For a better understanding, but only as an example, the invention will be described with reference to the attached drawings, which depict a tetrahedral cutting insert with positive rake and rear angles, with a symmetrical arrangement of protrusions and depressions in four sectors divided by the angular protrusions of the upper surface of the cutting insert.

In order to simplify the drawings, the structural elements of the cutting insert are indicated and further described for individual sectors, which is related to the entire cutting insert as a whole. Wherein:

in FIG. 1 shows a perspective view of a cutting insert in accordance with the present invention;

in FIG. 2 shows a top view of the upper surface of the insert shown in FIG. one;

in FIG. 3 shows a partially cross section of the insert shown in FIG. 2, along line CC along the angled protrusions;

in FIG. 4 shows a partially cross-section of the insert shown in FIG. 2, on the line BB;

in FIG. 5 shows a partially cross-section of the insert shown in FIG. 2, along line AA;

in FIG. 6 is a perspective view of a section by a plane P passing through the cutting edges of the insert shown in FIG. one;

in FIG. 7a shows a perspective view of a cutting insert with a section by a plane D passing through the intersection of the projections of the radially arranged protrusions and portions of the front surfaces in the side view of the cutting insert shown in FIG. one;

in FIG. 7b shows a partial cross section of FIG. 2, 5 and 7a, the plane D along the line D-D;

in FIG. 8a and 8b show in perspective a partial embodiment of the joints of the cutting edges on the upper surface, respectively, in the form of the radius and angular edge of the cutting insert shown in FIG. one;

in FIG. 9 is a perspective view of a cylindrical end mill using the insert shown in FIG. 1-8;

in FIG. 10 is a perspective view of a socket of a face-cylindrical milling cutter shown in FIG. 9 for fastening the insert shown in FIG. 1-8.

Detailed description of the drawings.

Consider FIG. 1-10, showing a cutting insert 10 and a face-cylindrical mill 54 in which this insert is used.

In accordance with the present invention, the proposed cutting insert 10 is multifaceted and indexable. It is preferably made by shaped or injection molding and sintering carbide powders.

The cutting insert 10 comprises an upper surface 12, a supporting lower surface 14, a side or a plurality of side surfaces 16 connecting the upper 12 and lower 14 of the surface to form cutting edges 26 with the upper surface 12, and a central hole 18 made in the central part of the insert.

In accordance with the proposed invention, angular protrusions 20 are formed on the upper surface 12, dividing it into identical sectors A and forming an ascending surface adjacent to the front surface 36 and a descending surface adjacent to the elevation of the central hole (Fig. 3).

Between the angular protrusions 20, protrusions 32 are radially located. They have a convex smoothly varying shape and enter the depressions 34 formed on the front surface 36 of the cutting insert (10) and are adjacent to the elevation 38 of the central hole 18.

In this case, the maximum heights 22 of the angular protrusions 20 are located above the cutting edges 26 and are located in the radial direction further from the vertical axis 24 of the hole 18 of the cutting insert 10 (R _{1 is} greater than R ₂ and R ₃ ), and in the horizontal direction is further from the cutting edge 26 of the cutting insert 10 to the parallel to the cutting edge 26 of the axis 28 and 52 of the hole 18, than the maximum heights 30 of the radially arranged protrusions 32 (L ₁ greater than L ₂ ),

Moreover, the intersection points 40 of the projections of the radially located protrusions 32 and sections 42 of the front surfaces 36 extending from the cutting edges 26 into the upper surfaces 12, in a side view in cross section of the cutting insert 10 with a plane generally perpendicular to the lower surface 14, are located closer to the cutting edge 26 than the maximum heights of 22 corner protrusions 20.

The ratio of the portion F of the area of the upper surface 12 of the cutting insert 10, from the cutting edges 26 to the central hole 18 to the plane P passing through the cutting edges 26, to its projection Fр on this plane is selected in the range of 1.05 ... 1.3; or the ratio of the length Lk of the cutting edge 26 to the length of the wavy line 44 extending along the upper surface 12 in section DD of the protrusions 32 and depressions 34 through the intersection 40 of the projections of the radially extending protrusions 32 and the portions 42 of the front surfaces 36 between the radial lines 46 passing through the angled protrusions the upper surface 12 and the axis of the hole 18 of the cutting insert 10, is in the range of 1.1 ... 1.5.

In the manufacture of cutting inserts 10, the ratio of the dimensions of the portion of the upper surface area to its projection onto the plane passing through the cutting edges or the ratio of the lengths of the cutting edge and the wavy line passing along the upper surface of the cutting insert in the section of protrusions and depressions at the intersection of their projections in the side view on the cutting insert, they are selected depending on the geometric dimensions of the cutting inserts, the grade of the material being processed, the material of the wear-resistant coating of the inserts and the machining scheme of the parts.

This is due to the fact that the stress-strain state of the cutting inserts, which occurs when machining parts from hard-to-work materials, largely depends on the above-mentioned parameters of both the insert itself and its working conditions.

For different working conditions of the cutting inserts there can be various options for their execution. According to one preferred embodiment, the joining points of the cutting edges 26 on the lateral surfaces 16 are made with radiuses 48 or corner bevels 50, and the cutting edges 26 are made with horizontal reinforcing bevels 50a located on the front surface 36 along the cutting edges.

According to another preferred embodiment, the angled protrusions are made with equal maximum heights 22.

According to another preferred embodiment, the angled protrusions 20 are made with maximum heights pairwise diagonally equal to each other.

According to another preferred embodiment, the axis of symmetry 28 and 52 of the sectors A of the upper surface 12 are the axes of the hole 18.

According to another preferred embodiment, the radially arranged protrusions 32 are made with a maximum height of 30, the value of which is greater than, less than or equal to the maximum height of 22 corner protrusions 20.

According to another preferred embodiment, the radially arranged protrusions 32 adjacent to the elevation 38 of the central hole 18 are arranged in a row parallel to the cutting edge 26 or are arranged in a plan view of the cutting insert 10 along a wavy curve.

According to another preferred embodiment, the radially extending projections 32 are made with maximum heights 30 located in a plane parallel to the plane passing through the cutting edges 26 along a curve convex or concave relative to the cutting edge 26.

According to another preferred embodiment, the radially extending projections 32 are made with a maximum height 30 greater than or equal to the height of the cutting edge 26.

According to another preferred embodiment, the angled protrusions 20 and the radially arranged protrusions 32 are made with the shape of second-order surfaces, preferably a sphere, cylinder, cone or torus.

According to another preferred embodiment, smooth transitions are made between the angular protrusions 20 and the radially arranged protrusions 32, the depressions 34, the front surface (36 and the elevation 38 of the central hole 18).

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According to another preferred embodiment, the radially spaced protrusions 32 and / or their number and / or their shape for each of the mentioned sectors A are individual.

According to the present invention, there is provided a cylindrical end mill 54 comprising a housing 56, sockets 58 made in the housing 56 or in cassettes installed in the housing, and having one supporting surface 60 and side contact surfaces 62 for mounting the cutting insert 10 according to any one of the above options.

The proposed group of inventions works as follows. Depending on the material being processed, the shape of the surface being machined and the cutting conditions, cutting inserts of certain geometric sizes are selected, with a certain shape, height and relative position of the protrusions and depressions placed on the upper surface of the cutting insert, as well as the ratio of the sizes of a portion of the surface area to its projection onto plane,

Further, the cutting inserts 10 are mounted in the sockets 58 of the end-cylindrical cutter 54. Moreover, larger cutting inserts are usually mounted on the end of the mill. This is due to more difficult working conditions. The cutter is installed in the spindle of a metal cutting machine and the selected parts are processed.

The aforementioned distinguishing features of the cutting insert, in particular, the shape, height and relative position of the protrusions and depressions located on the upper surface of the cutting insert, as well as the ratio of the dimensions of a part of the area of the upper surface to its projection onto a plane passing through the cutting edges or the ratio of the lengths of the cutting edge and a wavy line running along the upper surface of the cutting insert in the cross section of the protrusions and depressions at the intersection of their projections in the side view of the cutting insert, increase the resistance of the cutting boiling plates when processing hard materials by increasing the efficiency and reducing the chip in the cutting insert and the wear-resistant coating on its working surfaces of internal stress when it is intensely deformed state.

Although the present invention has been described with a certain degree of detail, it should be understood that various changes and modifications can be made without departing from the essence and scope of the invention set forth in the following claims. For example, the cutting edges may have radial curves, angular or horizontal reinforcing bevels up to 0.7 mm in size, and the cutting insert itself can be round or polygonal with an unlimited number of side surfaces that are its faces, each of which corresponds to a cutting edge or its section and a sector of the upper surface of the cutting insert bounded by angular protrusions, between which radially spaced protrusions are located. Moreover, the number of radially spaced protrusions in each sector, at least, can be three or more.

Claims (13)

1. A cutting insert (10) comprising an upper surface (12), a supporting lower surface (14), a side or a plurality of side surfaces (16) connecting the upper (12) and lower (14) surfaces to form cutting edges (26) with the upper surface (12), and a Central hole (18) made in the Central part of the plate, characterized in that on the upper surface (12) are made angular protrusions (20), dividing it into identical sectors (A) and forming adjacent to the front surface (36) ascending and adjacent to the elevation of the central hole neither protruding surfaces, and protrusions (32) radially located between the corner protrusions (20), which have a convex smoothly changing shape, entering the depressions (34) formed on the front surface (36) of the cutting insert (10), and adjacent to the elevation (38) of the central hole (18), while the maximum heights (22) of the angular protrusions (20) are located above the cutting edges (26) and are located radially further from the vertical axis (24) of the hole (18) of the insert (10), and in the horizontal direction further from the cutting edge (26) of the insert (10) to the spacing wedged parallel to the cutting edge (26) of the axis (28, 52) of the hole (18) than the maximum heights (30) of the radially arranged protrusions (32), and the places (40) of intersections of the projections of the radially arranged protrusions (32) and the front sections (42) surfaces (36) going from the cutting edges (26) into the upper surfaces (12), in a side view in cross section of the cutting insert (10) with a plane perpendicular to the lower surface (14), are located closer to the cutting edge (26) than the maximum heights (22) of the angled protrusions (20), and the ratio of the part (F) of the upper surface area (12) ) the cutting insert (10) from the cutting edges (26) to the central hole (18) to the plane (P) passing through the cutting edges (26), to its projection onto this plane, is selected in the range of 1.05 ... 1.3, or the ratio of the length (Lк) of the cutting edge (26) to the length of the wavy line (44) passing along the upper surface (12) in the section of the protrusions (32) and depressions (34) through the intersection (40) of the projections of the radially arranged protrusions (32) and portions (42) of the front surfaces (36) between the radial lines (46) passing through the angular protrusions of the upper surface (12) and the axis of the hole (18) cutting her plate (10), is in the range of 1.1 ... 1.5. 2. A cutting insert according to claim 1, characterized in that the joints of the cutting edges (26) on the side surfaces (16) are made with radiuses (48) or angular chamfers (50), and the cutting edges (26) are made with horizontal reinforcing chamfers (50a) located on the front surface (36) along the cutting edges. 3. The cutting insert according to claim 1, characterized in that the angled protrusions are made with equal maximum heights (22). 4. The cutting insert according to claim 1, characterized in that the angled protrusions (20) are made with maximum heights pairwise diagonally equal to each other. 5. The cutting insert according to claim 1, characterized in that the axis of symmetry (28, 52) of the sectors (A) of the upper surface (12) are the axes of the hole (18). 6. The cutting insert according to claim 1, characterized in that the radially arranged protrusions (32) are made with a maximum height (30), the value of which is greater, less than or equal to the maximum height (22) of the corner protrusions (20). 7. The cutting insert according to claim 1, characterized in that the radially arranged protrusions (32) adjacent to the elevation (38) of the central hole (18) are arranged in a row parallel to the cutting edge (26) or are located in a plan view of the cutting insert ( 10) along a wavy curve. 8. The cutting insert according to claim 1, characterized in that the radially arranged protrusions (32) are made with maximum heights (30) located in a plane parallel to the plane passing through the cutting edges (26) along a convex or concave relative to the cutting edge ( 26) curve. 9. The cutting insert according to claim 1, characterized in that the radially arranged protrusions (32) are made with a maximum height (30) greater than or equal to the height of the cutting edge (26). 10. A cutting insert according to claim 1, characterized in that the angled protrusions (20) and the radially arranged protrusions (32) are made with the shape of second-order surfaces, preferably a sphere, cylinder, cone or torus. 11. The cutting insert according to claim 1, characterized in that smooth transitions are made between the angular protrusions (20) and the radially arranged protrusions (32), depressions (34), the front surface (36) and the elevation (38) of the central hole (18) . 12. The cutting insert according to claim 1, characterized in that the radially arranged protrusions (32) and / or their number and / or their shape for each of the mentioned sectors (A) are individual. 13. End-cylindrical mill (54), comprising a housing (56), sockets (58), made in the housing (56) or in cassettes installed in the housing, and having one supporting surface (60) and side contact surfaces (62) in which the insert (10) according to any one of paragraphs. 1-12.

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