DE19906554C1 - Cutting plate for milling tool has cutting edge and two polygonal bores to position plate in tool carrier - Google Patents

Abstract

The cutting plate (1) for a milling tool has a cutting edge and two bores (5,6) for fastening and positioning the plate in the tool carrier. The fixing bores have a polygonal cross section. A long edge of the polygonal section is parallel to the tool axis. Claims include tool assembly

Description

The invention relates to a cutting insert for a cutting Machining tool, especially a milling tool, with min at least one cutting edge and at least two towards each other perforations spaced apart from the tool axis for positioning and / or fastening the cutting plate in the tool carrier body.

From DE 196 28 428 A1 a cutting plate is known, which with is provided with two precision recesses with which they on The projections provided for the tool carrier body are placed can. The precision recesses are created by in the Raw breakthroughs a foreign material unit that this precision has recesses, used and ver sticks. The manufacture of this insert is quite on agile.

DE 36 29 157 A1 discloses a cutting plate which is equipped with a circular and an elongated breakthrough. In the Breakthroughs engage locking pins of a clamping element, to support the positioning of the insert. To the Accuracy of the holes and their location becomes a high requirement tion so that exact positioning is possible.  

DE 76 02 409 U1 discloses a mounting bracket for a Cutting tool, in which the cutting insert has a pin is positively secured in the tool carrier body. To position Nation is in the tool carrier and correspond to it on Knives provided a seat.

The invention has for its object a cutting insert like this train that they are easily positioned and blocked can.

To solve the problem, a generic is distinguished Cutting plate characterized in that the openings in the profile polygo nal trained and the profiles are rotated to each other. If If the polygons are formed regularly, they must face each other be rotated by half a division.

The polygonal design of the breakthroughs Cutting insert clearly in its axial and radial position in the Tool support body positioned in that two cylindrical Insert the pins into the openings with play. By diff ben the cutting plate, for example in the direction of the centrifugal force te, the positioning then takes place by creating the profile the cylindrical pins. The cylindrical pins can be a be in one piece with the tool support body, they can but can also be formed by dowel pins or dowel screws.

The opening is preferably one with a long side of it Profiles running parallel to the tool axis and the other Breakthrough with a tip of its profile to the tool axis arranged pointing.

If the openings in the profile are essentially triangular are formed and the two profiles of the openings other are rotated by 60 °, the positioning is further ver simple. By moving the insert in preferably The direction of action of the centrifugal forces is one cylinder pin on two Sides of the triangular opening and the other on one  Side of the triangular opening. The mode of action ent then speaks a fixed and a floating bearing.

A plurality of openings can also be provided, from which only two have a polygonal profile when the clamping Evenly force the cutting plate (screw clamping forces) to be shared. The two outer ones are then preferred Breakthroughs designed as polygons. The rest of the breakthroughs the run with play to the clamping screw to the unique Position not to be influenced.

The corners of the polygon profile are preferably rounded to Avoid notch stresses. To a defined system to the To enable triangle sides, the corner radius of the triangles must be be made smaller than the radius of the cylinder pins. The The position of the cylinder pins in the tool carrier body determines the Location of the insert.

The insert is preferably made of hard metal and in particular theirs preferably produced by sintering, the poly gonal breakthroughs unprocessed, especially not ground stay.

The fact that the positioning inside the insert takes place, the insert can be cut on all sides become. The main cutting edge can be straight or profiled be det, with different within a cutting insert Profiles are possible.

The accuracy of the cutting profile can by the Invention proper training can be significantly increased by cutting plate is used for grinding in a device at which the insert can be positioned in the same way as in the tool carrier. The accuracy of the breakthroughs are then no longer have to make any special demands because the Cutting plate ground according to its installation position becomes.  

A processing tool, in particular a milling tool draws is characterized in that it with a cutting insert described above te is provided. For positioning the insert in the factory Stuff are preferably two able to pass through Fractures with corresponding cylindrical pins with a polygonal profile provided, the diameter of which is smaller than the inner circle of the Polygons.

The attachment of the insert in the processing tool can via fitting screws, which makes positioning and Tensioning takes place simultaneously or via dowel pins that are connected to the Interact polygon profile, and a jaw. The Posi tion then takes place via the dowel pins and tensioning the cheeks.

If the insert is attached using a support plate, only the support plate according to the cutting profile per be filleted. The tool support body can be used universally bar.

To grind the insert, it is also used in a pre Positioned and tensioned, as you then in the loading work tool is positioned and clamped. That is called The insert is pulled radially outwards until it matches the Breakthroughs on the two cylinder pins. Through this Measure will be the relocation of the insert - that in operation due to the influence of centrifugal force - thus anticipated and taken into account when grinding the cutting edge. Thus late no longer change the tool's circle diameter and consequently there are no inaccuracies when editing of the workpieces.

With the help of a drawing, embodiments of the inven be explained in more detail below. It shows:

Fig. 1 - the schematic view of an inventive cutting insert;

Fig. 2 - the side view of the insert according to arrow II of FIG. 1;

Fig. 3 - the enlarged sectional view according to arrow III of Fig. 1;

Fig. 4 - a cutting plate designed as an indexable insert;

Fig. 5 - the side view of the insert according to arrow V of Fig. 4;

FIG. 6a-6b - a machining tool in partial view with attached via fitting bolts cutting plate;

Fig. 7 to 7b - a processing tool in partial representation with positioned over dowel pins and clamping jaws ge clamped insert;

Fig. 8 - a cutting insert with a plurality of breakthroughs in a representation analogous to Fig. 1;

Fig. 9 - the side view of the insert according to arrow IX of Fig. 8;

. Fig. 10 - the enlarged detail view according to arrow X in FIG. 8

Fig. 1 to 3 according to the invention show the formation of a cutting plate 1. On a parallel to the tool axis W duri fenden axis 13 , two triangular openings 2 , 3 are introduced. The triangular profile 4 of the opening 2 is rotated by 60 ° relative to the profile 4 of the opening 3 . As the figures show, the tip of the opening 2 points radially outwards and the tip of the opening 3 radially inwards. The corners of the profile 4 are rounded. If the openings 2 , 3 have a different polygonal profile, care must be taken to ensure that they are twisted so that in relation to the installation position in the tool, one opening 2 radially inside a straight surface and the other opening 3 forms a corner . The axis 13 does not necessarily have to run parallel to the tool axis W ver.

The insert 1 can be designed as an insert with all-round cutting 7 , 8 , 8 ', 9 and, as shown in FIG. 4, with different profiles of the cutting edges.

For positioning the cutting plate 1 , cylindrical pins 5 , 6 are provided, which can be designed either as dowel screws 11 (FIGS . 6 to 6b) or dowel pins 12 ( FIGS. 7 to 7b).

The diameter D of the cylindrical pins 5 , 6 is smaller than the inner circle (incircle) which can be drawn in the triangular profile 4 . With this configuration, the cutting insert 1 can be moved relative to the pins 5 , 6 . The radius r of the rounded corners is smaller than the radius D / 2 of the cylindrical pins 5 , 6 . To position the cutting plate 1 , it is preferably pulled radially outward. The profile 4 of the breakthrough 2 at a point A on the pin 5 and the profile 4 of the breakthrough 3 at two points B, C on the pin 6 . The positioning of the insert 1 corresponds to a fixed bearing (B, C) and a floating bearing (A). After this positioning, the insert 1 can be clamped in the tool carrier body 10 .

As Fig. 6a to 6b shows, the positioning and the clamping NEN of the insert 1 can be done simultaneously by using pass screws 11 . The fit of the fitting screws 11 then has the diameter D ( Fig. 3).

It is also possible to position the insert 1 via dowel pins 12 ( FIG. 7) and to carry out the clamping by means of a Spannbac ken 14 , which is wedge-shaped and is pulled to the outside by ra dial.

In particular, if fitting screws 11 are to be used, a plurality of openings 2 , 3 , 23 can be provided in the cutting plate 1 '( FIG. 8) which can lie on an axis 13 and of which only the two outer 2nd , 3 have a polygo nales profile 4 . The other openings 23 are designed with play to the clamping screw then used.

The insert blank, including the polygon openings, can be sintered. The insert 1 only has to be ground on the two broad surfaces 15 , 16 and the at least one cutting edge 7 . The stop surfaces in the openings 2 , 3 can be unprocessed.

For grinding the insert 1 , this is positioned and clamped in the same way in a device (not shown here), as it is then positioned and clamped in the processing tool. Regardless of the exact location of the breakthroughs 2 , 3 , the cutting tip 1 is then directly grinded accordingly to its later seat in the processing tool, which means that only little requirement is placed on the accuracy of the profile 4 of the breakthroughs 2 , 3 , which not only increases the manufacturing costs lowers, but also significantly simplifies the replacement of a cutting plate 1 .

Within specified limits, the insert 1 can be resharpened on the surface or in the profile. The position of the cylindrical pins 5 , 6 determines the position of the insert 1 in the tool support body 10 and thus also the flight circle diameter.

Reference list

1

Insert

1

'' Insert

2nd

breakthrough

3rd

breakthrough

4th

profile

5

Cones

6

Cones

7

Cutting edge

8th

Cutting edge

8th

'Cutting edge

9

Cutting edge

10th

Tool carrier body

11

Fitting screw

12th

Dowel pin

13

axis

14

Jaws

15

Wide area

16

Wide area

17th

Support plate

23

breakthrough
AApplication point
BApplication point
CApplication point
D diameter
D / 2 radius
rRadius
WWool axis

Claims (11)

1. Cutting plate ( 1 ) for a machining tool, in particular a milling tool, with at least one cutting edge ( 7 ) and at least two spaced-apart openings ( 2 , 3 ) for positioning and / or fastening the cutting plate ( 1 ) in the tool carrier body ( 10 ) characterized in that the openings ( 2 , 3 ) in the profile ( 4 ) polygonal and the profiles ( 4 ) are mutually ver. 2. Cutting insert according to claim 1, characterized in that the one opening ( 2 ) with a longitudinal side of its profile ( 4 ) parallel to the tool axis W and the other opening ( 3 ) with a tip of its profile ( 4 ) to the tool axis W facing is. 3. Cutting insert according to claim 1, characterized in that the openings ( 2 , 3 ) in the profile ( 4 ) are essentially three corner-shaped, and that the profiles ( 4 ) are rotated to each other by at least 60 °. 4. Cutting insert according to one of claims 1 to 3, characterized in that a plurality of openings ( 2 , 3 , 23 ) is provided, of which only two ( 2 , 3 ) have a polygonal profile ( 4 ). 5. Cutting insert according to one of the preceding claims, characterized in that the openings ( 2 , 3 ) unprocessed tet, in particular are not ground. 6. Cutting insert according to one of claims 1 to 3, characterized in that the corners of the polygonal profile ( 4 ) are rounded abge. 7. Cutting insert according to one or more of the preceding claims, characterized in that cutting edges ( 7 , 8 , 8 ', 9 ) are provided on all four sides. 8. machining tool, in particular milling tool, characterized marked by a cutting plate ( 1 ) according to one or more of claims 1 to 7. 9. Processing tool according to claim 8, characterized in that for positioning the cutting plate ( 1 ) in the tool holder ( 10 ) two in position to the openings ( 2 , 3 ) with polygonal profile ( 4 ) corresponding cylinder pins ( 5 , 6 ; 11 , 12 ) are provided or can be provided, the diameter (D) of which is smaller than the drawable inner circle (incircle) within the polygon. 10. Processing tool according to claim 8 or 9, wherein the cutting plate ( 1 ) via a support plate ( 17 ) in the tool support body ( 10 ) is fixed, characterized in that only the support plate ( 17 ) of the cutting edge ( 7 ) of the cutting plate ( 1 ) is profiled accordingly. 11. Processing tool according to claim 8, characterized in that the radius (r) of the rounded corners of the profile ( 4 ) is smaller than the radius D / 2 of the cylindrical pins ( 5 , 6 ; 11 , 12 ).