Patent Application
20230278115
The present invention relates to a cutting insert for high-feed milling according to the preamble of claim 1. The invention also relates to a high feed milling tool comprising such a cutting insert.
A milling tool is a rotating cutting tool, which may be provided with one or more cutting inserts. A milling tool may have the form of an end mill tool, which may be used in high-feed milling, for instance in order to perform ramping operations, including pocketing operations.
Indexable cutting inserts for high-feed milling are previously known in various configurations and examples of such cutting inserts are for instance disclosed in U.S. Pat. No. 10,245,659 B2 and EP 3 199 284 A1.
The object of the present invention is to provide a cutting insert of the above-mentioned type that has a new and favourable design.
According to the invention, said object is achieved by means of a cutting insert having the features defined in claim 1.
The cutting insert according to the invention comprises:
The first main cutting edge and the first ramping cutting edge extend at an obtuse angle in relation to each other as seen in a plan view of the cutting insert, wherein the second main cutting edge and the second ramping cutting edge extend at a corresponding obtuse angle in relation to each other as seen in a plan view of the cutting insert. A plan view is a view from above, i.e. a top view, and here corresponds to a view of the cutting insert as seen from directly above the first major face in the direction of the centre axis of the cutting insert. In other words, the plan view is a view as seen along the centre axis toward the first major face. Thus, the plan view of the cutting insert constitutes a viewing plane perpendicular to the centre axis of the cutting insert. If the first and second main cutting edges and/or the first and second ramping cutting edges are curved as seen in the plan view of the cutting insert, the extension direction of anyone of these curved cutting edges in the plan view is defined by a straight line that intersects the two opposite end points of the cutting edge in question. The above-mentioned obtuse angle is normally in the range of 95°-160°, preferably 100°-125°, and more preferably 112°±5°.
An imaginary median plane extends halfway between the first and second major faces of the cutting insert perpendicularly to the centre axis of the cutting insert. This median plane is here introduced in order to enable the invention to be defined in an appropriate manner.
The first main cutting edge has a first end connected to the first secondary cutting edge and a second end connected to the first curved corner cutting edge and the second main cutting edge has a first end connected to the second secondary cutting edge and a second end connected to the third curved corner cutting edge, wherein each one of the first and second main cutting edges has one or more sloping parts between its first and second ends with such slope or slopes that its second end is located closer to the median plane than its first end. Thus, as seen in relation to the median plane, the second end of each main cutting edge that faces the adjacent curved corner cutting edge is located at a lower level, i.e. closer to the median plane, than the first end thereof that faces the adjacent secondary cutting edge.
The first ramping cutting edge has a first end connected to the first secondary cutting edge and a second end connected to the second curved corner cutting edge and the second ramping cutting edge has a first end connected to the second secondary cutting edge and a second end connected to the fourth curved corner cutting edge, wherein each one of the first and second ramping cutting edges has one or more sloping parts between its first and second ends with such slope or slopes that its second end is located closer to the median plane than its first end. Thus, as seen in relation to the median plane, the second end of each ramping cutting edge that faces the adjacent curved corner cutting edge is located at a lower level, i.e. closer to the median plane, than the first end thereof that faces the adjacent secondary cutting edge.
According to the invention, the second end of each one of the first and second main cutting edges is located closer to the median plane than the second end of each one of the first and second ramping cutting edges. Thus, as seen in relation to the median plane, the second end of the first main cutting edge is located at a lower level than the second end of the first ramping cutting edge, and the second end of the second main cutting edge is located at a lower level than the second end of the second ramping cutting edge. This feature gives the cutting insert improved performance in ramping operations, including pocketing operations, due to a softer cutting process and decreased risk for chips becoming wedged between the workpiece and the part of the peripheral relief surface associated to the active main cutting edge and the active corner cutting edge. By the active corner cutting edge it is meant the corner cutting edge adjacent to and between the active main cutting edge and the side cutting edge. Furthermore, in pocketing operations said feature implies a reduced risk for chips becoming wedged against the bottom wall and the vertical wall of the pocket that is being machined in the workpiece.
When the cutting insert is mounted in an insert seat in a tool body of a milling tool, one of the main cutting edges is positioned to form an active main cutting edge in the milling tool, wherein the associated ramping cutting edge is positioned to form an active ramping cutting edge in the milling tool and the curved corner cutting edge adjacent to the active main cutting edge is positioned to form an active corner cutting edge in the milling tool. The active main cutting edge will be arranged with its first end facing radially inward in the tool body towards the axis of rotation of the milling tool and with its second end facing radially outward in the tool body away from the axis of rotation of the milling tool, whereas the active ramping cutting edge will have a position radially inwardly of the active main cutting edge. By having the second end of the active main cutting edge located closer to the median plane than the second end of the active ramping cutting edge, the chips formed by the active ramping cutting edge have improved tendency to move in a direction from the active ramping cutting edge towards the active main cutting edge and the active corner cutting edge, i.e. in a direction radially outward in the tool body, instead of moving radially inward from the active ramping cutting edge. If said chips would move radially inward from the active ramping cutting edge, the chips may reach the area below the active main cutting edge and may become wedged between the work piece and the part of the peripheral relief surface associated to the active main cutting edge and the active corner cutting edge.
According to an embodiment of the invention, each one of the first and second main cutting edges slopes towards the median plane along a major part of its length when going from its first end to its second end, preferably along its entire length from its first end to its second end. Hereby, the chips formed by the active ramping cutting edge may move in a smooth manner along the active main cutting edge. Preferably, also each one of the first and second ramping cutting edges slopes towards the median plane along its entire length from its first end to its second end.
According to another embodiment of the invention, each one of the first and second main cutting edges slopes towards the median plane with a slope that is constant or increases as seen along its entire length from its first end to its second end. Hereby, there is no part on the active main cutting edge that may obstruct the movement of the above-mentioned chips along this main cutting edge.
According to another embodiment of the invention, the first main cutting edge extends along a straight or convex line, or along a line which is a series of one or more straight lines in combination with one or more convex lines, when seen in a viewing direction in parallel with the median plane and perpendicular to a straight first line of intersection that intersects the first and second ends of the first main cutting edge, wherein the second main cutting edge extends along a corresponding line when seen in a viewing direction in parallel with the median plane and perpendicular to a straight second line of intersection that intersects the first and second ends of the second main cutting edge. Hereby, the manufacturing of the cutting insert is facilitated and the movement of the above-mentioned chips along the active main cutting edge is improved.
Each one of the first and third curved corner cutting edges has a first end connected to the adjacent main cutting edge and a second end connected to the adjacent side cutting edge. Each one of the first and third curved corner cutting edges has preferably one or more sloping parts between its first and second ends with such slope or slopes that its second end is located closer to the median plane than its first end. Thus, as seen in relation to the median plane, the second end of each one of the first and third curved corner cutting edges is located at a lower level than the first end thereof, and thereby also at a lower level than the second end of the adjacent main cutting edge. Hereby, the chips formed by the active ramping cutting edge may easily continue to move radially outward along the sloping active corner cutting edge after having moved radially outward along the sloping active main cutting edge. Also the chips formed by the active main cutting edge may easily move radially outward along the sloping active corner cutting edge.
According to another embodiment of the invention, each one of the first and third curved corner cutting edges slopes towards the median plane along its entire length from its first end to its second end. Hereby, the chips formed by the active ramping cutting edge may move in a smooth manner along the active corner cutting edge.
According to another embodiment of the invention, each one of the first and third curved corner cutting edges slopes towards the median plane with a slope that is constant or increases as seen along its entire length from its first end to its second end. Hereby, there is no part on the active corner cutting edge that may obstruct the movement of the above-mentioned chips along this corner cutting edge.
According to another embodiment of the invention, the first and third curved corner cutting edges are so configured that in every point along anyone of the first and third curved corner cutting edges the curved corner cutting edge has a slope which is equal to or larger than the smallest slope of the adjacent main cutting edge in any point along this main cutting edge. Hereby, the active corner cutting edge is efficiently prevented from obstructing the movement of the above-mentioned chips radially outward along the active corner cutting edge.
According to another embodiment of the invention, the first and third curved corner cutting edges are so configured that in every point along anyone of the first and third curved corner cutting edges the distance between the curved corner cutting edge and the median plane is equal to or smaller than the distance between the second end of the adjacent main cutting edge and the median plane. Hereby, the movement of the above-mentioned chips radially outward along the active corner cutting edge is facilitated.
According to another embodiment of the invention, the first main cutting edge and the first curved corner cutting edge are so configured that, when seen in a viewing direction in parallel with the median plane and perpendicular to a straight first line of intersection that intersects the first and second ends of the first main cutting edge, the first curved corner cutting edge is located between the median plane and every tangent that can be drawn to the points along the first main cutting edge, wherein the second main cutting edge and the third curved corner cutting edge are so configured that, when seen in a viewing direction in parallel with the median plane and perpendicular to a straight second line of intersection that intersects the first and second ends of the second main cutting edge, the third curved corner cutting edge is located between the median plane and every tangent that can be drawn to the points along the second main cutting edge. Hereby, the active corner cutting edge is efficiently prevented from obstructing the movement of the above-mentioned chips radially outward along the active corner cutting edge. If the first main cutting edge comprises a section that extends in a straight line when seen in the viewing direction in parallel with the median plane and perpendicular to said first line of intersection, an imaginary straight line that is aligned with and forms an extension of this section is here considered as equivalent to a tangent to any point along this section. If the second main cutting edge comprises a section that extends in a straight line when seen in the viewing direction in parallel with the median plane and perpendicular to said second line of intersection, an imaginary straight line that is aligned with and forms an extension of this section is here considered as equivalent to a tangent to any point along this section.
Another embodiment of the invention is characterized in:
The chip breakers will enhance an advantageous forming or fragmentation of the chips formed by the active main cutting edge and contribute to achieve an advantageous direction of movement of these chips, and will thereby improve the cutting process. The chip breakers will also make it easier for the chips formed by the active ramping cutting edge to move radially outward and will thereby enhance chip evacuation of these chips. The first end of the first chip breaker may adjoin, more or less continuously, to another chip breaker that is associated to the first secondary cutting edge and possibly also to the first ramping cutting edge, and the first end of the second chip breaker may adjoin, more or less continuously, to another chip breaker that is associated to the second secondary cutting edge and possibly also to the second ramping cutting edge.
The second end of the first chip breaker preferably adjoins to the second end of the first curved corner cutting edge, i.e. to the end that is connected to the first side cutting edge, and the second end of the second chip breaker preferably adjoins to the second end of the third curved corner cutting edge, i.e. to the end that is connected to the second side cutting edge. The second end of the first chip breaker preferably adjoins also to a part of the first side cutting edge and the second end of the second chip breaker preferably adjoins also to a part of the second side cutting edge.
Another embodiment of the invention is characterized in:
According to another embodiment of the invention, the first valley has a depth that increases as seen in a direction along the first chip breaker from the first end thereof to the second end thereof, wherein the second valley has a depth that increases as seen in a direction along the second chip breaker from the first end thereof to the second end thereof. The outwardly directed movement of the chips formed by the active ramping cutting edge is further facilitated by this design of the valleys formed by the first and second chip breakers.
According to another embodiment of the invention, the first valley has a width that increases as seen in a direction along the first chip breaker from the first end thereof to the second end thereof, wherein the second valley has a width that increases as seen in a direction along the second chip breaker from the first end thereof to the second end thereof. The outwardly directed movement of the chips formed by the active ramping cutting edge is further facilitated by this design of the valleys formed by the first and second chip breakers. The width of a valley here refers to the distance between two opposite longitudinal edges of the valley as measured in a plane that extends in parallel with the above-mentioned longitudinal plane of the cutting insert.
According to another embodiment of the invention, each one of the first and second main cutting edges, and preferably also each one of the first and second secondary cutting edges, has a nominal rake angle that is positive or neutral. Hereby, the outwardly directed movement of the chips formed by the active ramping cutting edge is facilitated.
The cutting insert of the present invention is with advantage a single-sided and two-way indexable cutting insert, wherein the second major face preferably is flat and extends perpendicularly to the centre axis. Hereby, the manufacturing of the cutting insert is facilitated. However, the cutting insert of the present invention may as an alternative be a double-sided and four-way indexable cutting insert with the same arrangement of cutting edges around both of the above-mentioned major faces of the cutting insert.
Further advantageous features of the cutting insert according to the present invention will appear from the description following below.
The invention also relates to a high feed milling tool comprising a cutting insert of the above-mentioned type.
Further advantageous features of the high feed milling tool according to the present invention will appear from the description following below.
With reference to the appended drawings, a specific description of embodiments of the invention cited as examples follows below. In the drawings:
Two different embodiments of a cutting insert 1 according to the present invention are illustrated in
The cutting insert 1 comprises first and second major faces 2, 3 arranged on opposite sides of the cutting insert 1 and serving as top and bottom faces of the cutting insert. The cutting insert 1 has a centre axis C, which extends between the first and second major faces 2, 3, wherein the cutting insert 1 has 180° rotational symmetry about the centre axis C. A median plane MP, which constitutes an imaginary plane, extends halfway between the first and second major faces 2, 3 perpendicularly to the centre axis C.
In the illustrated embodiments, the cutting insert 1 is provided with a through hole 5, which extends centrally through the cutting insert between the first and second major faces 2, 3. The through hole 5 is configured to receive a fastening element 6 (see
A peripheral relief surface 10 extends around the cutting insert 1 between the first and second major faces 2, 3. The peripheral relief surface 10 comprises a first main side surface 11, a second main side surface 12, a third main side surface 13 and a fourth main side surface 14. The peripheral relief surface 10 also comprises:
The first and third main side surfaces 11, 13 form a first pair of opposing main side surfaces and the second and fourth main side surfaces 12, 14 form a second pair of opposing main side surfaces. A longitudinal plane LP (see
A first side cutting edge 21 extends along the first main side surface 11 and is formed at an intersection between the first main side surface 11 and the first major face 2. A second side cutting edge 22 extends along the third main side surface 13 and is formed at an intersection between the third main side surface 13 and the first major face 2.
A first main cutting edge 31, a first secondary cutting edge 41 and a first ramping cutting edge 51 extend one after the other along the second main side surface 12 and are formed at an intersection between the second main side surface 12 and the first major face 2. The first secondary cutting edge 41 is located between the first main cutting edge 31 and the first ramping cutting edge 51.
A second main cutting edge 32, a second secondary cutting edge 42 and a second ramping cutting edge 52 extend one after the other along the fourth main side surface 14 and are formed at an intersection between the fourth main side surface 14 and the first major face 2. The second secondary cutting edge 42 is located between the second main cutting edge 32 and the second ramping cutting edge 52.
Each one of the first and second secondary cutting edges 41, 42 comprises a surface-wiping cutting edge section 43.
The first and second side cutting edges 21, 22 are located opposite each other on opposite sides of the longitudinal plane LP, as illustrated in
The cutting insert 1 of the present invention has such a shape that the shortest distance d1 between the opposing first and second main cutting edges 31, 32 is equal to or larger than the shortest distance d2 between the opposing first and second side cutting edges 21, 22. The relationship between distance d1 and distance d2 is preferably such that the quota d1/d2 is larger than 1.1, more preferably between 1.1 and 2.0, even more preferably between 1.2 and 1.7, and most preferably between 1.36 and 1.46.
As illustrated in
A first curved corner cutting edge 61 extends along the first corner side surface 15 and is formed at an intersection between the first corner side surface 15 and the first major face 2. A second curved corner cutting edge 62 extends along the second corner side surface 16 and is formed at an intersection between the second corner side surface 16 and the first major face 2. A third curved corner cutting edge 63 extends along the third corner side surface 17 and is formed at an intersection between the third corner side surface 17 and the first major face 2. A fourth curved corner cutting edge 64 extends along the fourth corner side surface 18 and is formed at an intersection between the fourth corner side surface 18 and the first major face 2. The first curved corner cutting edge 61 extends between the first side cutting edge 21 and the first main cutting edge 31, the second curved corner cutting edge 62 extends between the first ramping cutting edge 51 and the second side cutting edge 22, the third curved corner cutting edge 63 extends between the second side cutting edge 22 and the second main cutting edge 32, and the fourth curved corner cutting edge 64 extends between the second ramping cutting edge 52 and the first side cutting edge 21. The first, second, third and fourth curved corner cutting edges 61, 62, 63, 64 extend along a respective radiused corner on the cutting insert. The first and third curved corner cutting edges 61, 63 are located diagonally opposite each other on opposite sides of the longitudinal plane LP and also on opposite sides of the central plan CP. The second and fourth curved corner cutting edges 62, 64 are located diagonally opposite each other on opposite sides of the longitudinal plane LP and also on opposite sides of the central plan CP.
The above-mentioned 180° rotational symmetry about the centre axis C implies:
The first main cutting edge 31 has a first end 31a connected to the first secondary cutting edge 41 and a second end 31b connected to the first curved corner cutting edge 61. The second main cutting edge 32 has a first end 32a connected to the second secondary cutting edge 42 and a second end 32b connected to the third curved corner cutting edge 63. The first main cutting edge 31 has one or more sloping parts between its first and second ends 31a, 31b with such slope or slopes that its second end 31b is located closer to the median plane MP than its first end 31a. The second main cutting edge 32 slopes in the same manner as the first main cutting edge 31 and has one or more sloping parts between its first and second ends 32a, 32b with such slope or slopes that its second end 32b is located closer to the median plane MP than its first end 32a.
The first ramping cutting edge 51 has a first end 51a connected to the first secondary cutting edge 41 and a second end 51b connected to the second curved corner cutting edge 62. The second ramping cutting edge 52 has a first end 52a connected to the second secondary cutting edge 42 and a second end 52b connected to the fourth curved corner cutting edge 64. The first ramping cutting edge 51 has one or more sloping parts between its first and second ends 51a, 51b with such slope or slopes that its second end 51b is located closer to the median plane MP than its first end 51a. The second ramping cutting edge 52 slopes in the same manner as the first ramping cutting edge 51 and has one or more sloping parts between its first and second ends 52a, 52b with such slope or slopes that its second end 52b is located closer to the median plane MP than its first end 52a.
According to the invention, the second end 31b of the first main cutting edge 31 is located closer to the median plane MP than the second end 51b of the first ramping cutting edge 51, as illustrated in
In the illustrated embodiments, each one of the ramping cutting edges 51, 52 slopes towards the median plane MP along its entire length from its first end 51a, 52a to its second end 51b, 52b. Each one of the main cutting edges 31, 32 slopes towards the median plane MP along a major part of its length from its first end 31a, 32a to its second end 31b, 32b. The main cutting edges 31, 32 and/or the ramping cutting edges 51, 52 may as an alternative comprise one or more sections that extend in parallel with the median plane MP. The main cutting edges 31, 32 may have a convex section adjacent to its first end 31a, 32a. As a further alternative, this convex section may have a part that slopes away from the median plane MP, when seen along the main cutting edge from its first end toward its second end, in order to create a smoother transition between the ramping cutting edge 51, 52 and the main cutting edge 31, 32. Each one of the main cutting edges 31, 32 and the ramping cutting edges 51, 52 preferably slopes towards the median plane MP with a slope that is constant or increases as seen along its entire length from its first end 31a, 32a, 51a, 52a to its second end 31b, 32b, 51b, 52b.
In the embodiment illustrated in
The first curved corner cutting edge 61 has a first end 61a connected to the second end 31b of the first main cutting edge 31 and a second end 61b connected to the first side cutting edge 21. The third curved corner cutting edge 63 has a first end 63a connected to the second end 32b of the second main cutting edge 32 and a second end 63b connected to the second side cutting edge 22. The first and third curved corner cutting edges 61, 63 may extend in parallel with the median plane MP. However, in the illustrated embodiments, the first curved corner cutting edge 61 has one or more sloping parts between its first and second ends 61a, 61b with such slope or slopes that its second end 61b is located closer to the median plane MP than its first end 61a, wherein the third curved corner cutting edge 63 slopes in the same manner as the first curved corner cutting edge 61 and has one or more sloping parts between its first and second ends 63a, 63b with such slope or slopes that its second end 63b is located closer to the median plane MP than its first end 63a.
In the illustrated embodiments, each one of the first and third curved corner cutting edges 61, 63 slopes towards the median plane MP along its entire length from its first end 61a, 63a to its second end 61b, 63b, but they may as an alternative comprise one or more sections that extend in parallel with the median plane MP. Each one of the first and third curved corner cutting edges 61, 63 preferably slopes towards the median plane MP with a slope that is constant or increases as seen along its entire length from its first end 61a, 63a to its second end 61b, 63b.
In every point along its extension, the first curved corner cutting edge 61 has preferably a slope which is equal to or larger than the smallest slope of the first main cutting edge 31 in any point along the first main cutting edge 31, wherein the third curved corner cutting edge 63 in every point along its extension has a slope which is equal to or larger than the smallest slope of the second main cutting edge 32 in any point along the second main cutting edge 32.
In every point along the first curved corner cutting edge 61, the distance between the first curved corner cutting edge 61 and the median plane MP is preferably equal to or smaller than the distance between the second end 31b of the first main cutting edge 31 and the median plane MP, wherein the distance between the third curved corner cutting edge 63 and the median plane MP, in every point along the third curved corner cutting edge 63, is equal to or smaller than the distance between the second end 32b of the second main cutting edge 32 and the median plane MP.
Furthermore, the first main cutting edge 31 and the first curved corner cutting edge 61 are preferably so configured that the first curved corner cutting edge 61 is located between the median plane MP and every tangent that can be drawn to the points along the first main cutting edge 31 when seen in a viewing direction in parallel with the median plane MP and perpendicular to a straight line of intersection L1 that intersects the first and second ends 31a, 31b of the first main cutting edge 31, i.e. when seen in the lateral view according to
A first chip breaker 71 associated to the first main cutting edge 31 is with advantage formed on the first major face 2 and configured to extend on the first major face 2 along at least a part of the first main cutting edge 31, wherein a second chip breaker 72 associated to the second main cutting edge 32 is formed on the first major face 2 and configured to extend on the first major face 2 along at least a part of the second main cutting edge 32. The first and second chip breakers 71, 72 are preferably configured to extend all along the first and second main cutting edges 31, 32. In the illustrated embodiments, the first chip breaker 71 extends all along the first main cutting edge 31 and also along the first curved corner cutting edge 61, wherein the second chip breaker 72 extends all along the second main cutting edge 32 and also along the third curved corner cutting edge 63. Thus, the first chip breaker 71 and the second chip breaker 72 are in this case also associated to the first curved corner cutting edge 61 and the third first curved corner cutting edge 63, respectively. The first chip breaker 71 has a first end 71a facing towards the first ramping cutting edge 51 and an opposite second end 71b facing towards the first main side surface 11, wherein the second chip breaker 72 has a first end 72a facing towards the second ramping cutting edge 52 and an opposite second end 72b facing towards the third main side surface 13. In the illustrated embodiments, the second end 71b of the first chip breaker 71 adjoins to the second end 61b of the first curved corner cutting edge 61 and also to a part of the first side cutting edge 21 adjacent to the second end 61b of the first curved corner cutting edge 61, whereas the second end 72b of the second chip breaker 72 adjoins to the second end 63b of the third curved corner cutting edge 63 and also to a part of the second side cutting edge 22 adjacent to the second end 63b of the third curved corner cutting edge 63.
In the embodiment illustrated in
The first chip breaker 71 has preferably an essentially U-shaped or V-shaped profile as seen in a section across the first chip breaker in parallel with the longitudinal plane LP, to thereby form an elongated first valley 73 on the first major face 2 that extends between the first and second ends 71a, 71b of the first chip breaker. In this case, also the second chip breaker 72 has an essentially U-shaped or V-shaped profile as seen in a section across the second chip breaker 72 in parallel with said longitudinal plane LP, to thereby form an elongated second valley 74 on the first major face 2 that extends between the first and second ends 72a, 72b of the second chip breaker. Each one of the first and second valleys 73, 74 has preferably a depth that increases as seen in a direction along the chip breaker from the first end 71a, 72a thereof to the second end 71b, 72b thereof. In the illustrated embodiments, each one of the first and second valleys 73, 74 has a width w that increases as seen in a direction along the chip breaker from the first end 71a, 72a thereof to the second end 71b, 72b thereof, wherein the width w of a valley 73, 74 is measured as the distance, in a plane that extends in parallel with the longitudinal plane LP, between a first longitudinal edge of the valley on a first side of the valley and a second longitudinal edge of the valley on an opposite second side of the valley.
Each one of the first and second main cutting edges 31, 32 and each one of the first and second secondary cutting edges 41, 42 has preferably a nominal rake angle that is positive or neutral. In the illustrated embodiments, the nominal rake angles of the main cutting edges 31, 32 and the secondary cutting edges 41, 42 are positive. Also the nominal rake angle of the first and second ramping cutting edges 51, 52 is positive in the illustrated embodiments.
A reinforcement land 9 in the form of a chamfer with a small width may in a conventional manner be arranged on the first major face 2 between one or more of the cutting edges 21, 22, 31, 32, 41, 42, 51, 52, 61-63 and the associated rake faces. The reinforcement land 9 may have a nominal rake angle that is negative, neutral or positive.
The cutting insert 1 illustrated in
The cutting insert 1 illustrated in
A cutting insert 1 is mounted in each one of the insert seats 84 in the tool body 81. In the embodiment illustrated in
When mounted in an insert seat 84, the cutting insert 1 is so arranged that the second major face 3, or at least a portion thereof, abuts against the tangential support surface 86 in the insert seat and the radial and axial abutment faces 7, 8 of one of said pairs abut against the radial support surface 87 and the axial support surface 88, respectively, in the insert seat. When the cutting insert 1 is so positioned that the radial and axial abutment faces 7, 8 of said second pair are abutting against the radial and axial support surfaces 87, 88, the first side cutting edge 21, the first curved corner cutting edge 61, the first main cutting edge 31, the first secondary cutting edge 41 and the first ramping cutting edge 51 are in an active position and constitute the active cutting edges. When the cutting insert 1 is so positioned that the radial and axial abutment faces 7, 8 of said first pair are abutting against the radial and axial support surfaces 87, 88, the second side cutting edge 22, the third curved corner cutting edge 63, the second main cutting edge 32, the second secondary cutting edge 42 and the second ramping cutting edge 52 are in an active position and constitute the active cutting edges.
In a ramping operation, the active main cutting edge 31, 32, the active ramping cutting edge 51, 52 and possibly also the active curved corner cutting edge 61, 63 perform major cuts into the workpiece, while the surface-wiping cutting edge section 43 on the active secondary cutting edge 41, 42 only performs a shallow surface smoothing cut.
The invention is of course not in any way restricted to the embodiments described above. On the contrary, many possibilities to modifications thereof will be apparent to a person with ordinary skill in the art without departing from the basic idea of the invention such as defined in the appended claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 20194028.5 | Sep 2020 | EP | regional |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2021/073502 | 8/25/2021 | WO |
