RU2671785C1 - Disk milling cutter for the grooves processing - Google Patents

Abstract

FIELD: technological processes.SUBSTANCE: invention relates to devices used for the materials processing by cutting, and can be used for narrow grooves milling in articles from hard-to-machine materials, including titanium and its alloys. Milling cutter includes body with sockets and a set of cutting plates having different angular cutting edges radius curvatures and thicknesses. Each cutting plate contains upper working and lower base surfaces, between which a central hole is made and side surfaces with side base surfaces are located, main cutting edges, formed at the side surfaces intersection, the auxiliary cutting edges, formed at the upper working surface with the side surfaces intersection, and the corner cutting edges with the curvature radius from 0.5 to 4 mm. At that, the cutting plates with one radius of curvature of the corner cutting edges are installed in the sockets on one and the other side of the body with possibility of their replacing with plates with a different radius of curvature of the corner cutting edges, due to the fact, that thickness of the cutting plates, which provides the milled groove width, is determined from the given mathematical expression.EFFECT: increase in the disk mills technological capabilities during the materials processing.7 cl, 7 dwg

Description

The field of technology.

The present invention relates to devices used for processing materials by cutting, in particular for milling narrow grooves in products from difficult to process materials, including titanium and its alloys.

The level of technology.

To reduce stresses in the corners between the bottom and the side walls of the milled grooves, radius curves are performed, which, depending on the size of the groove and the purpose of the product, have a wide range of radii of curvature. Moreover, in some cases there is a need to mill dimensional grooves in relatively small batches of a fairly rapidly changing product range having different radii of curvature on the machined surfaces. To do this, the corner cutting edges of the inserts must also have corresponding radius curves.

When changing the radial curves on the cutting inserts, their geometric dimensions change, which must be taken into account especially when processing products from hard-to-process materials. Therefore, when milling grooves of the same size, but with different radiuses, it is necessary to have a special cutting insert or other housing of the disk cutter, which allows you to set the cutting insert with a different radius of curvature of the corner cutting edge and get a groove of the same size.

For the manufacture of additional housings for milling cutters or special cutting inserts that are not part of the standard size range of inserts used to complete milling cutters, considerable time and money are required that may not be economically justified. Therefore, it is necessary to develop a number of cutting inserts made using one mold, which allows to have a wide range of radius of curvature of the corner cutting edges due to the technologically and economically acceptable grinding. In this case, it is advisable to have a smaller range of cutting inserts and use one standard size of the disk cutter body for cutting inserts c. different rounding radii of the corner cutting edges, allowing to obtain grooves of the same size with different radiuses.

Known cutting insert (RF patent No. 2584625) containing a housing with a Central part with a hole, the axis of which is the axis of symmetry and rotation of the plate. The housing contains a lower base and upper surface, between which a side surface is located. The lateral surface includes tangentially and radially spaced surfaces, at the intersection of which asymmetrically with respect to the plane passing through the axis of symmetry and rotation of the plate perpendicular to the tangential base of the plate, cutting edges are formed .. Radical curves are formed at the intersection of the upper surface and tangentially spaced surfaces with the formation of angular cutting edges.

This cutting insert having radial curvatures of the corner cutting edges is mounted in the slots of the disk cutter body and a groove with angular radial curves is milled. However, this insert with a different radius of curvature for the corner cutting edges cannot be used with the same disk cutter body for milling a slot of this size.

The objective of the present invention is to create a design of cutting inserts that allows you to use them in combination with a disk mill for milling dimensional grooves with different angular radial curves and using one housing of the disk mill, which will improve the technological capabilities of the disk mill.

SUMMARY OF THE INVENTION

The specified technical result is achieved through a combination of features described in the relevant claims.

A disk mill for processing grooves with different radial curves in products made of hard-to-work materials contains a housing with sockets and a set of cutting inserts mounted on the housing sockets, on one and the other side of it.

Each cutting insert is made with a Central hole and the upper working and lower base surfaces, between which there are side surfaces with side base surfaces.

The main cutting edges are formed at the intersection of the side surfaces. Auxiliary cutting edges are formed at the intersection of the upper working surface with the side surfaces, and the corner cutting edges have radial curves.

In accordance with the invention, the cutting plastids of the kit are made with a radius of curvature of the corner cutting edges in the range of 0.5 ... 4 mm and their corresponding thicknesses, ensuring the width of the milled groove, selected from the conditions:

Si = S (i ± 1) + [(Ri - R (i ± 1)] × cos α × sin β,

where: Si is the thickness of the i - cutting insert, providing the corresponding groove width;

S (i ± 1) is the thickness of the next and previous cutting plates, respectively;

Ri is the radius of curvature of the corner cutting edge i - cutting insert;

R (i ± 1) is the radius of curvature of the corner cutting edge, respectively, of the next and previous thickness of the cutting insert;

α is the angle between the tangent to the radial curvature at the place of its transition to the auxiliary cutting edge, which ensures the formation of the side wall of the milled groove, and the line of location of the centers of curvature of the corner cutting edge of the insert;

β is the undercut angle of the cutting insert installed in the cutter body.

In accordance with one design of the milling cutter, a cross-shaped lowering is made on the upper working surface of the cutting inserts with beams directed towards the side base surfaces, and angular protrusions located near the angular cutting edges, and a wear-resistant coating is applied to the working surfaces.

According to another embodiment of the milling cutter, the main and auxiliary cutting edges of the cutting inserts are arranged pairwise mirror symmetrically with respect to the symmetry axes of the cutting insert.

In accordance with another design of the cutter on the auxiliary cutting edges of the cutting inserts are made stripping cutting edges,

In accordance with another design of the cutter, the cutting inserts are made with a thickness in the range of 3.3 ... 3.7 mm, and the radius of curvature of the corner cutting edges is in the range of 1 ... 2 mm.

In accordance with another design, the milling cutter inserts are made with a thickness in the range of 4.1 ... 4.5 mm, and the radius of curvature of the corner cutting edges in the range of 1 ... 2.5 mm.

In accordance with another design, the milling cutter inserts are made with a thickness in the range of 5.2 ... 7.4 mm, and the radius of curvature of the corner cutting edges in the range of 1 ... 3 mm.

A brief description of the drawings.

For a better understanding, but only as an example, the invention will be described with reference to the attached drawings, which depict the design of the proposed disk cutter complete with cutting inserts for processing grooves with radiuses.

In FIG. 1 is a perspective perspective view of one of the preferred embodiments of a cutting insert;

in FIG. 2 shows a complete disk mill with the inserts shown in FIG. one;

in FIG. 3 is a fragmentary side view of the disk cutter shown in FIG. 2, assembled with cutting inserts in the groove being machined;

in FIG. 4a, b, c, d, in a plane perpendicular to the walls of the groove to be machined, fragments of angular cutting edges with different radius curves of the cutting insert shown in FIG. 1 and installed in the slot of the disk cutter body.

Detailed description of the drawings.

A disk mill for processing grooves with different radial curves in products of difficult materials 34 comprises a housing 38 with sockets 36 and a set of cutting inserts 10 mounted in the housing sockets on one and the other side thereof.

Each cutting insert 10 is made with a Central hole 16 and the upper working 12 and the lower base 14 of the surfaces between which the side surfaces 18 are located with the side base surfaces 20.

The main cutting edges 22 are formed at the intersection of the side surfaces. Auxiliary cutting edges 24 are formed at the intersection of the upper working surface 12 with the side surfaces 18, and the corner cutting edges 26 have radial curves.

In accordance with the invention, the cutting inserts of the set are made with a radius of curvature Ri of the corner cutting edges 26 in the range of 0.5 ... 4 mm and their corresponding thicknesses Si, ensuring the width of the milled groove, selected from the conditions:

Si = S (i ± 1) + [(Ri-R (i ± 1)] × cos α × sin β, [1]

where: Si is the thickness of i - cutting insert 10; providing the corresponding groove width;

S (i ± 1) is the thickness of the next and previous cutting plates, respectively;

Ri is the radius of curvature of the corner cutting edge i - cutting insert;

R (i ± 1) is the radius of curvature of the corner cutting edge, respectively, of the next and previous thickness of the cutting insert;

α is the angle between the tangent to the radial rounding at the point of transition to the auxiliary cutting edge forming the side wall of the milled groove and the line of location of the centers of curvature of the corner cutting edge of the insert;

β is the angle of undercutting of the cutting insert installed in the cutter body 34.

Expression 1 is obtained taking into account FIG. 4e, which depicts the use of a cutting insert 10 with different radii of curvature of the corner cutting edges 26 and the cleaning cutting edges 24a.

Moreover, from FIG. 4 s! it is seen that when passing from one corner cutting edge 26 with one radial rounding to another with another radial rounding, the transition points Ai and Ai ± 1 from their radial rounding to the auxiliary cutting edge 24 (24a), forming the side wall of the milled groove, are shifted along the wall milled groove by the value of N, which can be determined from the triangle Oi With About i ± 1. Then, taking into account the angle β, obtain the thickness Si of the cutting insert 10, ensuring the width of the working part of the cutter (Fig. 3) and, accordingly, the size B of the milled groove.

In accordance with one embodiment of the milling cutter, a cross-shaped lowering 28 is made on the upper working surface 12 of the cutting inserts with beams 30 directed towards the side base surfaces 20 and the angular protrusions 32 located near the angular cutting edges 26, and a wear-resistant coating is applied to the working surfaces.

In accordance with another embodiment of the cutter 34, the main 22 and auxiliary 24 cutting edges of the cutting inserts are arranged pairwise mirror symmetrically with respect to the symmetry axes of the cutting insert 10.

According to another preferred embodiment of the milling cutter 34, stripping cutting edges 24a are provided on the auxiliary cutting edges 24 of the cutting inserts.

The cleaning cutting edges 24a (Fig. 4 c1) are located tangentially to the radius curve at the place of its transition to the auxiliary cutting edge 24 and form the side wall of the milled groove. Their length Li and L i ± 1 for cutting inserts with different rounding radii of the corner cutting edges can be the same or different, while it affects the thickness of the cutting insert taken into account during its manufacture.

In accordance with another embodiment of the cutter 34, the cutting inserts 10 are made with a thickness in the range of 3.3 ... 3.7 mm, and the radius of curvature of the corner cutting edges 26 is in the range of 1 ... 2 mm.

In accordance with another embodiment of the cutter 34, the cutting inserts 10 are made with a thickness in the range of 4.1 ... 4.5 mm, and the radius of curvature of the corner cutting edges 26 is in the range of 1 ... 2.5 mm.

In accordance with another design of the cutter 34 a, the cutting inserts 10 are made with a thickness in the range of 5.2 ... 7.4 mm, and the radius of curvature of the corner cutting edges 26 is in the range of 1 ... 3 mm,

Description of the invention.

Consider the use of cutting inserts 10 with a disk mill 34 with an axis 41 for milling a dimensional groove of width B with radial curves that are symmetrically located between its walls and the bottom, respectively, 1, 1.5 and 2 mm in the product 42.

With this arrangement, the angle a between the tangent to the radial curvature 26 at the place of its transition to the auxiliary cutting edge 24 (24a), forming the side wall of the milled groove, and the line of location of the centers of curvature Oi and Oi ± 1 of the corner cutting edges 26 of the cutting inserts 10 will be 45 hail.

The cutting inserts 10 are mounted, for example, in the sockets 36 on one or the other side of the housing 38 of the disk cutter 34, for example with the most preferred angle of undercut β = 3.5 degrees, and fastened with screws 40.

First, as an example, consider the use of cutting inserts 10 with a radius of curvature Ri = 1.5 mm for milling a groove with a radius of curvature, for example, 1.5 mm, for example, provided that the cutting insert 10 with a radius of curvature was used on the same housing 38 of the disk mill 34 R (i-1) = 1 mm and a thickness S (i-1) = 4.5 mm, providing a groove size of the same width.

The thickness Si of the cutting insert 10, which provides the size B of the milled groove, when used on the same housing 38, is determined from the expression 1. In this case, we obtain Si = 4.522 mm. Thus, the thickness of the cutting insert 10 has changed by a value of 0.022 mm, which can be technologically obtained by grinding the workpiece of the cutting insert in question on the lower base surface 14.

Next, we consider the use of cutting inserts 10 with the same rounding radius Ri = 1.5 mm, for example, provided that on the same housing 38 of the disk mill 34, a cutting insert 10 with a rounding radius R (i + i) = 2 mm and thickness S ( i + 1) = 4.543 mm, providing a groove size of the same width. From expression 1 we get the same result Si = 4.522 mm.

Consider another example, the use of cutting inserts 10 with a radius of curvature Ri = 2 mm, for example, provided that on the same housing 38 of the disk mill 34, a cutting plate 10 with a radius of curvature R (i-1) = 1 mm and a thickness S (i + 1) = 4.5 mm, providing a groove size of the same width. From expression 1 we obtain Si = 4.543 mm.

Thus, we have obtained a disk mill for machining grooves with different radial curves in products from hard-to-work materials with a set of cutting inserts that can be used on its same body for milling dimensional grooves with different angular radii of curvature, which makes it possible to increase the technological capabilities of the cutting tool .

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 spirit and scope of the invention set forth in the claims below.

Claims (14)

1. Disk milling cutter for processing grooves with different radial curves in products made of hard-to-work materials, comprising a housing with sockets and a set of cutting inserts installed in the housing sockets on one or the other of its sides, each of which is made with a central hole, upper working and lower base surfaces between which the side surfaces are located with the lateral base surfaces, the main cutting edges formed at the intersection of the side surfaces, auxiliary cutting edges and formed at the intersection of the upper working surface with the side surfaces, and the angular cutting edges with radial curves, characterized in that the cutting inserts of the set are made with a radius of curvature of the corner cutting edges in the range of 0.5-4 mm and their corresponding thicknesses, ensuring the width of the milled groove selected from the conditions: Si = S (i ± 1) + [(Ri-R (i ± 1)] × cosα × sinβ, where Si is the thickness of the i - cutting insert, providing the corresponding groove width; S (i ± 1) is the thickness of the next and previous cutting plates, respectively; Ri is the radius of curvature of the corner cutting edge i - cutting insert; R (i ± 1) is the radius of curvature of the corner cutting edge, respectively, of the next and previous thickness of the cutting insert; α is the angle between the tangent to the radial curvature at the place of its transition to the auxiliary cutting edge, which ensures the formation of the side wall of the milled groove, and the line of location of the centers of curvature of the corner cutting edge of the insert; β is the undercut angle of the cutting insert installed in the cutter body. 2. The cutter according to claim 1, characterized in that the cutting inserts on the upper working surface have a cross-shaped lowering with rays directed towards the side base surfaces, and angular protrusions located near the angular cutting edges, and a wear-resistant coating is applied to the working surfaces. 3. The milling cutter according to claim 1, characterized in that the cutting inserts are made with main and auxiliary cutting edges arranged pairwise mirror symmetrically with respect to the symmetry axes of the cutting inserts. 4. The mill according to claim 1, characterized in that on the auxiliary cutting edges of the cutting inserts are made stripping cutting edges, 5. The cutter according to claim 1, characterized in that the cutting inserts are made with a thickness in the range of 3.3-3.7 mm and a radius of curvature of the corner cutting edges in the range of 1-2 mm. 6. The cutter according to claim 1, characterized in that the cutting inserts are made with a thickness in the range of 4.1-4.5 mm and a radius of curvature of the corner cutting edges in the range of 1-2.5 mm. 7. The cutter according to claim 1, characterized in that the cutting inserts are made with a thickness in the range of 5.2-7.4 mm and a radius of curvature of the corner cutting edges in the range of 1-3 mm.

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