DE9407575U1 - Drilling tool - Google Patents

Description

Description

The invention relates to a tool for drilling and associated indexable inserts.

Drilling tools with detachably attached cutting plates in various designs are known. Such tools with two cutting plates are shown in DE-OS 26 10 292 and EP-Al - 0 289 651. In these tools, the area between the center of the hole and the outside diameter of the hole is divided between the cutting plates. Therefore, such a tool can be described as "single-edged" because the effective cutting areas of the cutting plates can be viewed as a single cutting edge that works with one revolution of the tool.

0 In contrast, another known tool (EP 0 172 148 A2) has two cutting edges, each of which covers the same area when drilling. This can be described as a "two-cutter" because each of the two cutting edges is fully effective during one rotation of the tool. However, this tool does not have any cutting plates that can be attached detachably, but has a head with cutting elements soldered into them.

From DE 3 0 3 7 097 Al, a double-edged 0 drilling tool with two removable indexable inserts offset by 180° is also known, which have aligned or parallel offset main cutting edges, which together

Leave a core area of 0.2-2.5 mm diameter free from cutting.

State-of-the-art tools are usually provided with a central lubrication and coolant hole, which extends to a feed that cuts across the hole in front of the tool holder. If necessary, the hole is provided with two openings on the drill tip, which have their outlet behind the two cutting edges.

The invention is based on the problem of creating a drilling tool of the type specified that works as a genuine two-cutter and nevertheless allows the use of cutting plates that can be exchanged in the usual way. The invention also aims to optimize the other tool parts compared to the state of the art. Other problems related to all of this, which the invention deals with, arise from the respective explanation of the solutions shown in claims 1, 6 and the further developments according to the subclaims. 20

The invention provides that the cutting edges are formed by two detachably attached cutting plates, in particular a triple indexable cutting plate, which have the following features:

- the cutting plates are triangular in their basic shape,

each main cutting edge ends in a corner area which has a rounded section and an adjoining straight edge which is shorter in relation to the main cutting edge, 0 - the corner angle between the respective main cutting edge and the shorter straight edge is 90° or greater.

The cutting edges of both indexable inserts that are effective during drilling each cut across the entire radius of a hole, i.e. together they cut across the entire diameter of the hole. This is possible because the inner corner areas of the cutting edges extend to the center of the tool or slightly beyond, so that the main cutting edges and secondary cutting edges are engaged at the same time.

The setting angle, measured as the inclination of the main cutting edges radially outwards from the drill center, is advantageously in the range of 3° to 20°, preferably around 5° to 10°. The best drilling results were achieved on the workpiece at these angles.

The cutting plates can be manufactured in the specified shape from the outset. Because these are simple shapes, it is also advantageous to start with standard plates or standardized plates, which can then be modified without great effort 0 by grinding or other suitable processing so that the described shape is obtained. The preferred shape has a longer main cutting edge and a shorter secondary cutting edge on each of the three cutting edges, which are connected by a rounding covering an angle of approximately 12 0° at minimum and 179° at maximum, which also represents the drill tip. Angles in the range of 135 - 175° are preferred. The shape of the indexable insert is overall asymmetrical, due to the secondary cutting edge being approximately 5% to 80%, preferably 2 0% to 40% 0 shorter than the main cutting edge.

The drilling tool according to the invention is characterized by a

A number of significant advantages, in particular it can be used to create high-precision holes of great depth at high feed rates. The cutting plates, each of which is fastened by a screw or a corresponding element, can be exchanged quickly and easily. The uniformity of the cutting plates and their symmetrical arrangement means that the forces are evenly distributed during drilling. The tool has good drilling behavior and, thanks to its self-centering, allows relatively large drilling depths. The triangular basic shape of the cutting plates makes it possible to achieve an overlap in the center and at the same time the least possible weakening of the core. The cutting plates do not have sensitive sharp corners, but are characterized by stable corner areas which, due to the selected setting angle, are also less sensitive to the reaction forces on the cutting plate than with conventional tools. Furthermore, the shape of the cutting plates with flattened corners also results in favorable drilling areas where the cutting speed is not zero. This also allows the chip to be bent and thus achieves advantageous chip breaking behavior.

The position of the cutting edges relative to an axial longitudinal center plane of the drilling tool can be selected according to the circumstances. In a design that has proven itself in practice, the cutting edges are slightly set back with respect to this plane by a dimension that corresponds to the maximum tolerance in the manufacture of the workpiece body, the cutting plate and its fastening in order to ensure that the cutting plates do not collide in the overlap area in the center of the drill.

The drilling tool can form a rigid unit. In another design, the tool can be radially adjusted to a certain extent. This can be done in particular by means of an adjusting element, as is known per se. The size of the cutting plates is such that a drilling diameter range of, for example, 22-24 mm or 27-29 mm can be covered with one size when using different tool bodies or a variable fastening. The range limits can be specified by the min. and max. degree of overlap of the cutting edges in the center of the drill.

The drilling tool is advantageously secured in the work spindle with a special clamping device. The accuracy of the hole to be made with the tool increases if it is possible, according to the invention, to avoid even a minimal amount of chattering, despite the higher feed rate on the tool with two cutting edges. Practical tests have shown that multiple line contact of the 0 fastening shaft in the work spindle is correspondingly successful, with optimum clamping in the work spindle being achieved by clamping elements lying orthogonal to the axial longitudinal center plane L. Instead of line contact, surface contact would be optimal, but theoretically this is hardly achievable, unless by Herz ^&lgr; surface pressure.

Further details, features and advantages of the invention emerge from the following explanation of 0 embodiments, from the associated drawings and from the claims. They show:

Fig. 1 a drilling tool according to the invention in

• · &igr;

· ■

overall view;
Fig. 2 the front part of the drilling tool in larger

Scale;

Fig. 3 is a front view of Fig. 2 and Fig. 4 is an even larger view of the cutting plates

and their arrangement;

Fig. 5,6 a second form of a tool body; Fig. 7 a second embodiment of a cutting plate.

In the following description, similar parts are provided with the same reference numerals.

The tool body 1 of the drilling tool shown has an elongated shaft 2 which merges into a flange-like part 3. This is followed by a fastening part 4 which can be inserted into a corresponding receptacle in the work spindle of a machine tool. Of course, the fastening part can also be designed differently, for example as a cone. The shaft 2 is provided with spiral grooves 5 for chip removal, of which only one outlet is indicated in Fig. 1. The diameter-length ratio of the shaft 2 can be 1:3 and more, preferably 1:4 or more.

At the front end of the shaft 2, on opposite sides thereof, a recess 6 is provided as a seat for an indexable insert 7 with a triangular basic shape. The cutting inserts are each releasably fastened in their seat on the shaft 2 by means of a screw 8 or in another suitable manner.

0 Each cutting plate 7 has three cutting edges with straight main cutting edges 11, each of which ends on one side in a corner area designated overall with the number 10.

This has a rounding 12 and a shorter straight edge 13 in relation to the main cutting edge. The latter merges with a slight rounding into the next main cutting edge 11, at the end of which there is then a corner area 10 with a rounding 12 and a short straight edge 13. The same applies to the third cutting edge. This cyclical sequence of main cutting edge, rounding and short edge results in the outline of the cutting plates 7, as is particularly illustrated in Figures 2 and 4. The sequence is of course reversed: main cutting edge, short edge, rounding, main cutting edge, etc. The short edges 13 can serve as secondary cutting edges and have a corresponding clearance angle. In Figure 3, the letter D indicates the external dimension of the cutting plate arrangement and thus the bore diameter.

Both cutting plates 7 are arranged on the shaft 2 in such a way that the main cutting edge 11 used in each case runs at an acute angle, the setting angle k, to a plane Q perpendicular to the central axis M of the drilling tool, with the points S protruding furthest in the feed direction being on the inside, i.e. towards the central axis M. These are the points at which the main cutting edges 11 merge into the short edges 13, as shown in Fig.

4 can be clearly seen. This means that the drilling tool first starts on the workpiece when working, which results in a favorable drilling behavior and high stability when drilling. By choosing such an adjustment angle k, i.e. a backward inclination of the radially outward 0 cutting areas relative to the feed direction or drill tip, it is achieved that the resulting reaction forces on the cutting plate in the direction of the drill axis

M. This prevents a possible elasticity of the screw 8 or the fastening of the cutting plates 7 from leading to an increase in the drilling diameter D due to radial offset of the cutting plates 7 outwards.

The points S are at a certain distance from the central axis M, so that the cutting speed here has a value that differs from zero. In the feed direction, the points S are expediently at the same height, if necessary with a small tolerance.

The angle a between the main cutting edge 11 and the short edge 13 of two adjacent cutting edges is suitably about 90°. However, it can also be larger, in particular up to 10° larger.

In the center area, the cutting plates 7 overlap with parts of their corner areas 10, in particular essentially with the rounded parts 12, as can be seen in Figures 3 and 4. This also results in the least possible weakening of the core of the drilling tool.

The position of the cutting edges of the cutting plates 7 with respect to an axial longitudinal center plane L of the drilling tool can be selected in a way that best meets the respective requirements. In an advantageous embodiment, the cutting edges are set back by a small amount with respect to the plane L. This is in particular in the order of 0.1 mm.

The cutting plate 7 can be given the shape explained and shown during its manufacture. The invention

but also offers the possibility of starting from standardized or standardized triangular plates and giving them the modified shape through appropriate, low-cost processing, such as grinding. 5

In Fig. 2, one of the two cutting plates 7 is indicated by a dash-dotted line at the letter E, indicating that the cutting plate may originally have had sharp corners which were then machined off.

The number 9 designates a longitudinal bore in the drilling tool, which can continue to the front side with one or two openings and/or to the side at the front end and through which lubricant and/or coolant can be fed to the work site.

Preferably, the tool body 21 according to Fig. 5 contains two bores 19 in the shaft 22 running parallel from the front side to the flange part 23 or fastening part 24, which receive a coolant supply from a common bore 20.

This measure allows the chip groove 25 on the drill tip to be guided close to the drill axis M for better chip removal. The body 21 can be fitted with two triple indexable inserts inserted in the groove 26, as shown in the figure.

The drilling tool has a special clamping device, comprising the groove 1.7 and the centering hole 29 in the mounting shaft 24 as well as the threaded hole 18 in the work spindle 14 of a drilling machine (not shown). A clamping screw 16 with a complementary thread can be screwed into the threaded hole 18 until its tip 27 reaches the bottom of the centering hole 29. If tightened further

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the clamping screw 16, the cross-section of the fastening shaft 24, which is weakened by the groove 17, is deformed; represented by the gap 28 in Fig. 6. As a result, the fastening shaft 24, which is several 1/100 mm smaller, rests with its outer circumference opposite the clamping screw 16 with multiple line contact on the inner surface of the clamping bore 15.

Fig. 7 shows a second specific embodiment of a cutting plate ^7λ with a mounting hole in the center, which is designed as an indexable cutting plate with the main cutting edges 11 and the secondary cutting edges 13, which are larger than in Fig. 4, and can be attached to the tool body 1 or 21. The curves 12 and corner areas 10 with the angles a are shaped similarly to the plate 7, which is shown here at a scale of approximately 10:1. The largest plate size is determined by the circle D1 around the curves 12. The incircle D3 describes the distance between the main cutting edges 11 and at the same time approximately the limit up to which a corner area 10 of an adjacent plate ^7X can cover this plate when they are attached to a tool body 1 or 21. D2 describes the circumference of the tips S between the two straight cutting edges of the three cutting edges. DE designates the distance of a main cutting edge 11 and NE that of a secondary cutting edge 13 to the opposite curve 12.

All features mentioned in the above description or shown in the drawings are to be considered as falling within the scope of the invention, either individually or in combination, as far as the known state of the art allows.

Claims (10)

Protection claims 1. Tool for drilling, in particular in solid material, with a tool body and two cutting edges offset by approximately 18 0° in the circumferential direction of two detachably fastened cutting plates (7.7 ^V ), in particular indexable cutting plates, with cutting edges whose straight main cutting edge (11) each run radially outwards and backwards to the feed direction at an acute setting angle (k) and which both machine at least approximately the same surface during drilling, wherein the cutting edges with inner corner regions (10) or parts (12) thereof extend to the tool center (M) or beyond. 2. Tool according to claim 1, characterized in that the setting angle (k) is in the range of approximately 3° to 20°. 3. Tool according to one of claims 1 or 2, characterized in that the cutting edges are slightly set back with respect to an axial longitudinal center plane (L) of the tool. 4. Tool according to one of the preceding claims, characterized in that identical cutting plates (7, 7 ^V ) for different drilling diameters (D) 0 have different overlaps of their inner corner regions (10). 5. Tool, in particular according to one of the preceding claims, with a shaft to be received in a clamping bore of a machine tool spindle, characterized by a partially thin-walled tool shaft (24) which can be elastically deformed by means of a clamping screw (16) to such an extent that, in the clamped state, it has a surface contact or multiple line contact with the slightly larger clamping bore (15).
10 6. Cutting plate (7, 7') which can be releasably attached, in particular for a tool according to one of the preceding claims, which has the following features: - it is triangular in its basic shape and has three cutting edges, each of which has a main cutting edge (11) which merges into a corner area (10) which has a rounded (12) and a subsequent one in Ratio to main cutting edge (11) shorter straight edge (13), and a corner angle (a) between the respective main cutting edge (11) and the shorter straight edge (13) 90° or greater. 25 7. Cutting plate according to claim 6, characterized in that the main cutting edge (11) and the shorter edge (13) of a cutting edge designed as a secondary cutting edge enclose an angle of 135 - 175°. 8. Cutting plate according to claim 6 or 7, characterized in that the secondary cutting edge (13) has at least 5%, preferably 20 - 40%, shorter than the main cutting edge (11). 9. Cutting plate according to one of claims 6 to 8, characterized in that the distance (DE) of a rounding (12) to the main cutting edge (11) of an opposite
Cutting edge: greater than the distance (NE) to its
secondary cutting edge (13). 10. Cutting insert for a tool according to one of the preceding claims, characterized in that
They have a modified standard cutting plate with three
Main cutting edges (11).