1. Field of the Invention
The present invention relates to indexable inserts used for turning. In particular, the present invention relates to an indexable insert that provides enhanced durability of a breaker projection while it maintains favorable chip processability so as to minimize deterioration of the chip processability at an early stage.
2. Description of the Related Art
A known indexable insert (sometimes simply referred to as an “insert” hereinafter) for turning, which is used by being attached to a tool holder, is provided with chip breakers on a rake face of the insert to enhance chip processability. The function of a chip breaker is to cut a chip formed during turning to an appropriate length so as to separate the chip from the workpiece and the cutting tool. Chip breakers having various shapes have been proposed, including those disclosed in Japanese Patent No. 3607288 and Japanese Unexamined Patent Application Publication No. 2002-210604.
The chip breakers disclosed in Japanese Patent No. 3607288 and Japanese Unexamined Patent Application Publication No. 2002-210604 are of the most commonly used projected type. In Japanese Patent No. 3607288, breaker projections are provided on the insert face (i.e., the rake face) at positions adjoining the corners of the insert. Each breaker projection has a curved shape having a concave side facing towards the corresponding corner of the insert and a convex side facing away from the corner.
On the other hand, in Japanese Unexamined Patent Application Publication No. 2002-210604, a first breaker projection and second breaker projections are provided on the rake face. The first breaker projection extends from a boss surface (i.e., a central land portion) toward the respective noses. The second breaker projections each extend from an end of the first breaker projection to a slope continuing from a cutting-edge land of the corresponding nose. In plan view, the second breaker projections at each nose have a concave shape along linear cutting edges and are disposed symmetrically with respect to a bisecting line of the nose.
As mentioned on lines 24 to 29 on column 4 of Japanese Unexamined Patent Application Publication No. 2002-210604, at each of the noses, a rising surface extending from a breaker-groove base of a breaker groove is preferably formed from a midsection of the slope, and the second breaker projections are each formed from the midsection of the slope, as mentioned on lines 49 to 50 on column 4 of the publication.
In the structure disclosed in Japanese Patent No. 3607288, the breaker projections provided near the noses are used to process chips during large-depth cutting so as to effectively prevent the chips from clogging. As shown in
In the structure disclosed in Japanese Unexamined Patent Application Publication No. 2002-210604, a chip formed during small-depth cutting is curled by being restrained by two projections (i.e., left and right second breaker projections) disposed symmetrically with respect to the bisecting line of each nose. Referring to
Accordingly, it is an object of the present invention to provide an indexable insert used for turning, which provides enhanced durability of a breaker projection while it maintains favorable chip processability so as to minimize deterioration of the chip processability at an early stage.
To solve the aforementioned problems, the present invention satisfies both enhanced chip processability and reduction of load received when raking a chip, which were considered to be difficult in the past. In order to achieve this, the present invention provides a polygonal indexable insert used for turning, equipped with a nose cutting-edge and a linear cutting edge extending continuously therefrom. Specifically, the indexable insert includes a rake face; a first ridge formed on the rake face; and a second ridge formed on the rake face. The first ridge protrudes from a boss surface towards a nose. The second ridge extends continuously from the first ridge to a slope connected to a cutting-edge land of the linear cutting edge, the second ridge having a height lower than that of the first ridge and being convex-curved towards a bisecting line of an apex angle of the nose in plan view.
When in use, the insert according to this invention preferably has no directional properties by having the second ridge disposed symmetrically with respect to the bisecting line of the apex angle of the nose.
Furthermore, it is preferable that the second ridge include two second ridges that are disposed symmetrically with respect to the bisecting line of the apex angle of the nose, and that the insert further include a flat breaker base surrounded by the first ridge, the two second ridges, and the nose cutting-edge. In this case, the length of the breaker base in an extending direction of the bisecting line of the apex angle may be set to 30% to 70% of the distance between an apex of the nose and a protruding edge of a top surface of the first ridge, and the depth of the breaker base measured from the cutting edge may be set within a range between 0.03 mm and 0.15 mm.
Moreover, it is preferable that the first ridge have a rising surface defined by a concave-curved slope.
In the insert according to this invention, a chip is processed mainly by the first ridge not only during small-depth cutting, but also during large-depth cutting. The second ridge assists the first ridge during large-depth cutting so as to enhance the protection effect of the first ridge. Specifically, since the second ridge is continuously formed, a chip formed during large-depth cutting is guided along the second ridge, thereby preventing the chip from hitting against the first ridge. Because the height of the second ridge is lower than that of the first ridge, a chip guided by the second ridge subsequently comes into contact with the first ridge. However, since the motion energy of the chip is already attenuated and the load applied to the region of the first ridge in contact with the chip is thus alleviated as compared to when the chip directly hits the first ridge, the protection effect of the first ridge is enhanced.
Since the second ridge is convex-curved, the direction in which a chip is removed while being curled sideways during large-depth cutting is aligned with the curved direction of the second ridge. Therefore, the chip can be removed in a low resistive state. Since this reduces the load on the second ridge, damages to the second ridge rarely occur, thereby enhancing the durability of the first and second ridges. Accordingly, satisfactory chip processability can be maintained over a longer period of time by these ridges, as compared to that of a product of the related art.
As mentioned above, in the insert that further includes the flat breaker base surrounded by the first ridge, the two second ridges, and the nose cutting-edge, the length of the breaker base in the extending direction of the bisecting line of the apex angle of the nose may be set to 30% to 70% of the distance between the apex of the nose and the protruding edge of the top surface of the first ridge, and the depth of the breaker base measured from the cutting edge may be set within a range between 0.03 mm and 0.15 mm. In this case, the chip also comes into contact with the breaker base. Thus, the energy of the chip when it reaches the first ridge is further reduced, thereby further enhancing the effect of alleviating the load on the first ridge as well as the effect of minimizing damages to the first ridge.
Furthermore, in the insert in which the rising surface of the first ridge is defined by a concave-curved slope, the contact area between the first ridge and the chip is increased, thereby further enhancing the effect of alleviating the load on the first ridge.
An indexable insert according to an embodiment the present invention will be described below with reference to
Referring to
When attaching the insert to a holder, the face not involved in turning of the boss surface 1 is used as a seating face.
In each acute corner, the first ridge 2 protrudes toward the nose from the boss surface 1. The height at the top surface of the first ridge 2 is lower than that of the boss surface 1 but is higher than that of the nose cutting-edge 5. Referring to
The second ridges 3 extend continuously from the first ridge 2 towards the cutting-edge land 7 until reaching a slope 8 connected to the cutting-edge land 7. The height of the second ridges 3 is lower than that at the top surface of the first ridge 2 (reference character h in
In each acute corner of the insert shown in the drawings, the second ridges 3 are formed symmetrically with respect to the bisecting line CL of the apex angle. Moreover, an area surrounded by the two symmetrical second ridges 3, the first ridge 2, and the nose cutting-edge 5 acts as the breaker base 9. This breaker base 9 is a flat surface. Referring to
The following are examples of the cross-sectional shape of the second ridges 3. Specifically, the examples include a circular arc shape as shown in a vertical cross-sectional view in
With the shapes shown in
The third ridges 4 are provided on the same linear cutting edges 6 as the second ridges 3 and are curved in the same direction as the second ridges 3. The third ridges 4 are disposed farther away from the nose cutting-edge 5 than the second ridges 3. Although the third ridges 4 are effective in terms of expanding the processable range of the insert against variable machining conditions, these third ridges 4 are considered only as preferable elements.
The breaker base 10 is provided between the cutting-edge land 7 extending along the linear cutting edges 6 and a slope 13 extending along the periphery of the boss surface 1. The third ridges 4 project upward from the breaker base 10. In the insert shown in the drawings, the breaker base 10 is a flat surface and the depth thereof measured from the cutting edge is set greater than that of the breaker base 9 by a depth d1 (see
The following describes preferred embodiments.
1. The depth d of the breaker base 9, shown in
2. The distance L from the apex of the nose to the protruding edge of the top surface of the first ridge 2 shown in
3. The depth d1 measured from the breaker base 9 to the breaker base 10 shown in
4. The height h measured from the breaker base 9 to each second ridge 3 shown in
5. A distance L1 between each linear cutting edge 6 and the nearest second ridge 3 shown in
6. A distance L2 between each linear cutting edge 6 and the nearest third ridge 4 shown in
A region D shown in
In the insert according to this invention, a local temperature increase is alleviated by the effect of the second ridges 3. This is confirmed by performing computer-aided engineering analysis of cutting-edge temperature distribution produced by the cutting heat. With the inserts disclosed in Japanese Patent No. 3607288 and Japanese Unexamined Patent Application Publication No. 2002-210604, a local temperature increase is evident. This is believed to be caused by load concentration. Moreover, in an actual machining process performed under the same conditions, local abrasion occurs in an insert of the related art due to load concentration, resulting in a serious damage to the insert. In contrast, abrasion is effectively minimized in the insert according to this invention so that damages to the ridges are advantageously minimized.
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2008-056289 | Mar 2008 | JP | national |
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