Drilling tool

A drilling tool comprising a tool holder that extends along a central axis and comprises a first cutting insert receptacle having a first abutment surface oriented parallel to the central axis. The drilling tool further comprises a first cutting insert that is fixed in the first cutting insert receptacle and abuts with one of its sides against the first abutment surface, wherein an axial portion of the first cutting insert projects axially beyond an end face end of the tool holder, and wherein the first cutting insert comprises in the axial portion a first main cutting edge that is inclined with respect to a first imaginary plane, which is oriented orthogonally to the central axis and arranged at the end face end of the tool holder, so that a radially outer end of the first main cutting edge is spaced a larger distance from the first imaginary plane than a radially inner end of the first main cutting edge and the first main cutting edge does not intersect the first imaginary plane, and wherein the first main cutting edge touches or intersects a second imaginary plane that is spanned by the central axis and oriented orthogonally to the first abutment surface.

BACKGROUND

This disclosure relates to a drilling tool.

The herein presented drilling tool is particularly suitable for machining sintered cemented carbide or ceramics. However, the use of the drilling tool is not limited to the machining of workpieces made of such materials, although this is the preferred application.

Sintered cemented carbide has a very high hardness. In addition to its use as a cutting material, sintered cemented carbide is often used in forming technology as a punch, hammer or as a wear part. The machining of such components made of sintered cemented carbide is traditionally mainly done by grinding and eroding. Milling tools are also known whose cutting edges are made of cemented carbide coated with a diamond layer. However, drills suitable for machining sintered cemented carbide are hard to find.

The production of through holes or blind holes in workpieces made of sintered cemented carbide often proves to be extremely complicated in practice due to the very high hardness of this material. Especially when a thread is to be cut in such holes/bores, the use of tools with very precise and at the same time very stable cutting edges of extremely high hardness is absolutely necessary. This is virtually impossible with the previously known eroding processes. Only with diamond-coated cemented carbide milling tool has this been possible so far. However, the service life of such diamond-coated cemented carbide milling tools is very short, so that the use of such milling tools has proven to be cost-intensive.

Drilling of sintered cemented carbide with conventional drills has not been possible up to now, especially for the following reasons: In addition to the lack of strength and stability of the previously known drilling tools, the extreme heat development during the machining of sintered cemented carbide is a main obstacle. In addition, when using conventional drilling tools, too much pressure would be built up in the center of the drill, as the cutting speed of the drill is typically zero here, because the cutting process starts from the center or tip of the drill, around which the drill rotates, and proceeds from the inside outwards. For the machining of sintered cemented carbide by drilling, drilling tools with specially adapted cutting edge geometries would therefore be required.

SUMMARY

It is tan object to provide a drilling tool that overcomes the problems mentioned above and is particularly suitable for machining sintered cemented carbide and ceramics.

According to a first aspect, a drilling tool is provided, which comprises:a tool holder that extends along a central axis and comprises a first cutting insert receptacle and a second cutting insert receptacle, wherein the first cutting insert receptacle comprises a first abutment surface oriented parallel to the central axis, and wherein the second cutting insert receptacle comprises a second abutment surface oriented parallel to the central axis,a first cutting insert that is made of CVD thick film diamond, is connected to the first cutting insert receptacle in a firmly bonded manner, and abuts with one of its sides against the first abutment surface, anda second cutting insert that is made of CVD thick film diamond, is connected to the second cutting insert receptacle in a firmly bonded manner, and abuts with one of its sides against the second abutment surface,wherein an axial portion of the first cutting insert projects axially beyond an end face end of the tool holder, and wherein the first cutting insert comprises in the axial portion a first main cutting edge that is inclined with respect to a first imaginary plane, which is oriented orthogonally to the central axis and arranged at the end face end of the tool holder,wherein a radially outer end of the first main cutting edge is spaced a larger distance from the first imaginary plane than a radially inner end of the first main cutting edge,wherein the first main cutting edge does not intersect the first imaginary plane, andwherein the first main cutting edge touches or intersects a second imaginary plane that is spanned by the central axis and oriented orthogonally to the first abutment surface.

According to a second aspect, a drilling tool is provided, which comprises:a tool holder that extends along a central axis and comprises a first cutting insert receptacle and a second cutting insert receptacle, wherein the first cutting insert receptacle comprises a first abutment surface oriented parallel to the central axis, and wherein the second cutting insert receptacle comprises a second abutment surface oriented parallel to the central axis,a first cutting insert that is fixed in the first cutting insert receptacle and abuts with one of its sides against the first abutment surface, anda second cutting insert that is fixed in the second cutting insert receptacle and abuts with one of its sides against the second abutment surface,wherein an axial portion of the first cutting insert projects axially beyond an end face end of the tool holder, and wherein the first cutting insert comprises in the axial portion a first main cutting edge that is inclined with respect to a first imaginary plane, which is oriented orthogonally to the central axis and arranged at the end face end of the tool holder,wherein a radially outer end of the first main cutting edge is spaced a larger distance from the first imaginary plane than a radially inner end of the first main cutting edge,wherein the first main cutting edge does not intersect the first imaginary plane,wherein the first main cutting edge touches or intersects a second imaginary plane that is spanned by the central axis and oriented orthogonally to the first abutment surface,wherein a radial portion of the first cutting insert projects beyond an outer circumference of the tool holder, and wherein the first cutting insert comprises in the radial portion a first minor cutting edge that is parallel to the central axis or inclined with respect to the central axis by a maximum of 2°,wherein the first minor cutting edge is connected to the first main cutting edge via a transition element that comprises at least one of a radius and a chamfer, andwherein the first minor cutting edge is inclined at an angle less than 90° with respect to the first main cutting edge.

The presented drilling tool comprises a cutting edge geometry that is specially adapted for machining materials with very high hardness. The cutting edge geometry includes an inclination of the main cutting edge from outside to inside. The radially outer end of the main cutting edge projects in axial direction (i.e. parallel to the central axis) further beyond the end face end of the tool holder than the radially inner end of the main cutting edge.

With presented the drilling tool, the first cut of the workpiece is therefore not from inside to outside, but from outside to inside. The drilling tool does not necessarily have a central drill tip and thus no convex cutting edge geometry of the drill head, as is otherwise usual in most cases, but has a concave cutting edge geometry of the drill head. This considerably reduces the pressure on the center of the drill head. Thus, it is possible to largely negate the cutting speed in the center of the drill (typically zero).

Two imaginary planes are referred to herein, which imaginary planes only serve to describe the geometry and position of the main cutting edge. The first imaginary plane is oriented orthogonally to the central axis and runs through the end face end of the tool holder or touches the end face end of the tool holder. It represents a kind of vertical plane or yz-plane. In relation to this first imaginary plane, the main cutting edge of the cutting insert, which is herein referred to as the first main cutting edge, is inclined in such a way that the radially outer end of the first main cutting edge is spaced a larger distance from the first imaginary plane than a radially inner end of the first main cutting edge. However, the first main cutting edge is entirely on one side of this first imaginary plane, while the tool holder is entirely on the opposite side of this first imaginary plane.

The second imaginary plane describing the geometry and position of the first main cutting edge is spanned by the central axis of the tool holder and is orthogonal to the first abutment surface. The central axis of the tool holder therefore lies in this second imaginary plane. The first main cutting edge touches or intersects this second imaginary plane. The first main cutting edge thus cuts up to the center or beyond the center of the drill head, so that despite the concave cutting edge geometry, machining is also performed in the center of the drill head and no material is left standing in the center of the drill hole.

Due to the cutting edge geometry of the first main cutting edge, machining starts at the radially outer end of the drill head when the drilling tool is placed on a workpiece. This leads to increased stability as well as high axial accuracy and roundness in the bore.

The first cutting insert is preferably made of CVD thick film diamond. By the mentioned geometry and position of the first main cutting edge, it has been possible to use the high wear resistance of the CVD thick film diamond in such a way that the excellent properties of the CVD thick film diamond against friction are utilized and at the same time the properties against breakage are protected. Thus, it is possible to machine very hard materials with geometrically defined cutting edges efficiently and with low stress.

According to a refinement, the first abutment surface is oriented parallel to a radial direction of the tool holder that is orthogonal to the central axis.

The first abutment surface is thus parallel to both the central axis and the radial direction. In other words, the first abutment surface is orthogonal to the first and second imaginary plane. According to this refinement, the power transmission between the tool holder and the first cutting insert is therefore in the circumferential direction, orthogonal to the radial direction and the central axis.

According to another refinement, the first main cutting edge is oriented parallel to the first abutment surface. With respect to the radial direction or the first imaginary plane, the first main cutting edge is preferably inclined at an angle of 0.2° to 3°.

As already mentioned, the first main cutting edge is inclined from radially outside to radially inside, resulting in a concave cutting edge geometry. When machining a workpiece, the cutting pressure, which is initially radially outside, is thus slowly transferred to the first cutting insert from outside to inside along the first main cutting edge, so that the total load of the first main cutting edge is delayed. This stabilizes the cutting pressure and avoids chunking at the first main cutting edge.

According to another refinement, a length of the first main cutting edge is larger than half a diameter of the tool holder.

In this refinement, the first main cutting edge preferably cuts from the very outside to the inside over the center of the drilling tool. In this case, the drilling tool can be configured as a single cutter with only one cutting insert and one main cutting edge, namely the first cutting insert with the first main cutting edge.

In the latter refinement, a radial portion of the first cutting insert preferably projects beyond an outer circumference of the tool holder and the first cutting insert comprises in the radial portion a first minor cutting edge that is parallel to the central axis or inclined with respect to the central axis by a maximum of 2°.

This first minor cutting edge is spaced a larger distance from the central axis than the radially outer end of the first main cutting edge. The first minor cutting edge serves as a kind of support with which the drilling tool is supported on the workpiece on the circumference. Thus, it serves mainly as a guide. At the same time, however, material is also removed at this point. If the first minor cutting edge is slightly inclined with respect to the central axis of the drilling tool, this guarantees better freewheeling, since the first minor cutting edge then for the most part no longer contacts the workpiece to be machined and therefore less friction between the first cutting insert and the workpiece occurs at this point.

According to another refinement, the first minor cutting edge is connected to the first main cutting edge by a radius and/or a chamfer.

The radius and/or the chamfer form the cutting edge corner and thus the point where the first cut of the workpiece begins. The radius and/or the chamfer thus contribute to cutting. It is therefore a kind of corner cutting edge.

According to another refinement, the first minor cutting edge is inclined at an angle of less than 90° with respect to the first main cutting edge.

The angle of <90° already results from the fact that the first main cutting edge, as already mentioned, is inclined inwards at an angle with respect to the radial direction and at the same time the first minor cutting edge is inclined with respect to the central axis.

According to another refinement, the tool holder comprises a second cutting insert receptacle having a second abutment surface oriented parallel to the central axis, and wherein a second cutting insert is fixed in the second cutting insert receptacle, which second cutting insert abuts with one of its sides against the second abutment surface.

The tool can therefore also be configured as a two- or multi-cutter. The second abutment surface, against which the second cutting insert abuts, is preferably arranged parallel offset to the first abutment surface. The offset of the two abutment surfaces is preferably realized in such a way that there is a maximum gap of 6 hundredths between the first main cutting edge of the first cutting insert and the second main cutting edge of the second cutting insert. This cutting edge gap can also be set to 0. However, the two main cutting edges of the two cutting inserts do not overlap each other.

Depending on the number of cutting inserts, the main cutting edges of the different cutting inserts preferably machine different radial segments of the bore. When using two cutting inserts, it is preferred that the first main cutting edge of the first cutting insert machines the bore from the very outside to beyond the center of the bore, whereas the second main cutting edge of the second cutting insert machines only the radially outer area of the bore. Thus, in the radially inner or central area of the bore, only the first cutting insert cuts, whereas in the radially outer area, the bore is machined by both the first and the second cutting insert.

According to a refinement, an axial portion of the second cutting insert projects beyond the end face end of the tool holder and the second cutting insert comprises in the axial portion a second main cutting edge that is inclined with respect to the first imaginary plane in such a way that a radially outer end of the second main cutting edge is spaced a larger distance from the first imaginary plane than a radially inner end of the second main cutting edge and the second main cutting edge does not intersect the first imaginary plane. The second main cutting edge of the second cutting insert is therefore inclined from outside to inside, just like the first main cutting edge of the first cutting insert.

According to another refinement, the first main cutting edge is inclined at a first angle with respect to the first imaginary plane, whereas the second main cutting edge is inclined at a second angle different from the first angle with respect to the first imaginary plane.

Since both main cutting edges are preferably inclined from outside to inside, a concave cutting edge geometry results. In a side view orthogonal to the two abutment surfaces of the cutting inserts, the first and second main cutting edges preferably enclose an angle that is smaller than 180° but larger than 174°. The minimum angle of 174° would result from an inclination of both main cutting edges of 3° with respect to the first imaginary plane.

Preferably, a dimension of the second cutting insert measured in the radial direction, i.e. orthogonal to the central axis, is smaller than a dimension of the first cutting insert measured in the radial direction.

While the first main cutting edge preferably machines the bore from the very outside inwards to beyond the center, the second main cutting edge preferably machines only the radially outer edge of the bore. The second main cutting edge therefore does not extend to the center of the tool holder or even beyond it. In other words, the second main cutting edge does not intersect or touch the second imaginary plane.

However, according to a refinement, it is also possible that the second main cutting edge projects beyond an outer circumference of the tool holder, but the first cutting insert does not. In such a configuration, the radially outer edge of the bore would be machined only by the second cutting insert and the radially inner edge of the bore would be machined only by the first cutting insert.

Regardless of whether only the second cutting insert projects beyond the outer circumference of the tool holder or both cutting inserts project beyond the outer circumference of the tool holder, the second cutting insert has a radial portion that extends beyond an outer circumference of the tool holder, wherein the second cutting insert comprises in the radial portion a second minor cutting edge that is parallel to the central axis or inclined with respect to the central axis by a maximum of 2°.

Similar as the first cutting insert, the second minor cutting edge is connected to the second main cutting edge by a radius and/or a chamfer.

Preferably, the drilling tool is designed neither rotationally-symmetrical nor mirror-symmetrical.

According to a refinement, the cutting inserts are each connected to the tool holder in a firmly bonded manner. This guarantees a stable connection of the cutting inserts with the tool holder.

Preferably, the cutting inserts are soldered to the tool holder. Although a welded connection would also be possible in principle, a soldered connection is advantageous in the present case, since the cutting inserts are preferably made of CVD thick film diamond and the tool holder is preferably made of cemented carbide.

It goes without saying that the features mentioned above and the features to be explained below can be used not only in the combination indicated in each case, but also in other combinations or on their own, without leaving the spirit and scope of the present disclosure.

DESCRIPTION OF PREFERRED EMBODIMENTS

FIG.1shows a perspective view of a first embodiment of the drilling tool. The drilling tool is therein denoted in its entirety with the reference numeral10.

The drilling tool10is preferably designed neither rotationally-symmetrical nor mirror-symmetrical.

The drilling tool10comprises a tool holder12that extends along a central axis14. In the area of its end face end, the tool holder12in the herein shown embodiment comprises two cutting insert receptacles16,18, which are referred to as first cutting insert receptacle16and second cutting insert receptacle18for better differentiation. The two cutting insert receptacles16,18are used to receive two cutting inserts20,22, which are referred to as first cutting insert20and second cutting insert22.

The two cutting inserts20,22are differently sized in the shown embodiment. In addition to their size difference, the two cutting inserts20,22in the present embodiment do also not have exactly the same geometry.

Although the drilling tool10in the shown embodiment is provided with two cutting inserts20,22, it should be noted at this point that only one of the two cutting inserts, namely cutting insert20, would be sufficient for the function of the drilling tool10. The drilling tool10could just as well be provided with more than two cutting inserts without leaving the spirit and scope of the present disclosure.

The cutting insert receptacles16,18, in which the cutting inserts20,22are arranged, are shown in detail inFIGS.4and5, since the cutting inserts20,22are not shown here. Both cutting insert receptacles16,18comprise an abutment surface24and26, respectively, on which the two cutting inserts20,22rest flat (see alsoFIG.3). These two abutment surfaces24,26, which are referred to as first abutment surface24and second abutment surface26, preferably run parallel to the central axis14of the tool holder12. Similarly preferably, the two abutment surfaces24,26run parallel to each other and parallel to a radial direction28of the tool holder12. The radial direction28, which is orthogonal to the central axis14, is simply shown with an arrow inFIG.3.

Each of the two cutting inserts20,22has a side surface that additionally rests on another support surface on the tool holder12. InFIGS.4and5, said support surface on which the first cutting insert20rests is denoted with the reference numeral30. The corresponding support surface of the second cutting insert receptacle18, on which the second cutting insert22is supported, is hidden inFIGS.4and5and not explicitly shown. However, like the support surface30, it runs at an acute angle (angle<90°) to the central axis14of the tool holder12.

The two cutting inserts20,22are connected to the tool holder12, or more precisely to the cutting insert receptacles16,18, preferably in a firmly bonded manner. The two cutting inserts20,22are particularly preferably soldered to the cutting insert receptacles16,18. The cutting inserts20,22are preferably made of CVD thick-film diamond. The tool holder12is preferably made of cemented carbide.

Together with the front part of the tool holder12to which they are attached, the cutting inserts20,22form a drill head32, which is shown in detail inFIGS.2and3in a side view (FIG.2) and in a top view from the front (FIG.3). In the herein shown embodiment, two outlets34of two coolant channels provided in the tool holder12are arranged on this drill head32. These coolant channels can be used to transport cooled air in the area of the drill head32, for example, in order to cool the inserts20,22during the cutting process. Instead of air, of course, any other coolant can also be transported through the coolant channels to the coolant outlets34.

The chips removed from the workpiece are transported via chip grooves36, which extend from the drill head32along the tool holder12to the rear. In the herein shown embodiment, the drilling tool10comprises two such chip grooves36, wherein one of the chip grooves36is assigned to the first cutting insert20and the other one of the two chip grooves36is assigned to the second cutting insert22.

In the first embodiment shown inFIGS.1-3, the two cutting inserts20,22project outwards both in the axial direction (i.e. along the central axis14) over an end face end38of the tool holder12and transversely thereto, in the radial direction28over an outer circumference40of the drill head32.

Each of the two cutting inserts20,22comprises a main cutting edge42,44and a minor cutting edge46,48. The main cutting edges42,44are arranged in the axial portion of the cutting inserts20,22, which projects beyond the end face end38of the tool holder12. The minor cutting edges46,48are arranged in the radial portion that projects over the outer circumference40of the drill head32.

The main cutting edge42of the first cutting insert20is herein referred to as the first main cutting edge42. The main cutting edge44of the second cutting insert22is herein referred to as the second main cutting edge44. Accordingly, the minor cutting edge46of the first cutting insert20is referred to as first minor cutting edge and the minor cutting edge48of the second cutting insert22is referred to as second minor cutting edge48.

The first main cutting edge42is connected to the first minor cutting edge46by a corner cutting edge50, which can be configured as a chamfer and/or a radius. The second main cutting edge44is connected to the second minor cutting edge48by a second corner cutting edge52, which can also be configured as a chamfer and/or a radius. These two corner cutting edges50,52preferably form the portion of the respective cutting insert20,22which has the largest distance from the central axis14of the tool holder12.

If the corner cutting edges50,52are configured as radii, they preferably have a radius in the range of 0.1-1 mm. If the corner cutting edges50,52are configured as chamfers, they are preferably inclined at an angle of 5°-20° relative to the adjacent main cutting edges42,44and have a length in the range of 0.2-1 mm.

To describe the position and geometry of the main and minor cutting edges42,44,46,48, reference is made to two imaginary planes, which only serve for a better description. The two imaginary planes are shown as dashed lines inFIG.2andFIG.4and denoted with reference numerals54,56. The two imaginary planes54,56are two planes that are oriented orthogonally to one another. The imaginary plane54, which is herein referred to as the first imaginary plane54, is oriented orthogonally to the central axis14of the tool holder12and runs through the end face end38of the tool holder12. The imaginary plane56, which is herein referred to as the second imaginary plane56, is oriented orthogonally to it. The central axis14of the tool holder12is arranged in this second imaginary plane56. Both imaginary planes54,56preferably run orthogonally to the two abutment surfaces24,26of the cutting insert receptacles16,18. In other words, the first imaginary plane54forms the radial plane that runs through the end face end38of the tool holder12. The second imaginary plane56, on the other hand, is spanned by the radial direction28and the central axis14.

The first main cutting edge42of the first cutting insert20is inclined with respect to the first imaginary plane54in such a way that a radially outer end58of the first main cutting edge42, which is adjacent to the first corner cutting edge50, has a larger distance from the first imaginary plane54than a radially inner end60of the first main cutting edge42. However, both ends58,60of the first main cutting edge42are located on the same side of the first imaginary plane54, namely on the side of the first imaginary plane54facing away from the tool holder12. The first main cutting edge42does therefore not intersect the first imaginary plane54.

The described arrangement results in an inclination of the main cutting edge42with respect to the first imaginary plane54or with respect to the radial direction28. This inclination is illustrated inFIG.2by the angle α. The angle α is preferably 0.2°-3°. The first main cutting edge42touches or intersects the second imaginary plane56. In other words, the first main cutting edge42extends to the center of the drilling tool10(if it touches the second imaginary plane56) or extends beyond the center of the drilling tool10(if it intersects the second imaginary plane56).

The first minor cutting edge46of the first cutting insert20preferably runs parallel to the central axis14of the tool holder12or is inclined at an angle of maximum 2° with respect to the central axis14of the tool holder12. This angle is denoted as angle β inFIG.2.

The inclination of the first main cutting edge with respect to the radial direction28(angle α) and the optional inclination of the first minor cutting edge46with respect to the central axis14(angle β) results in an angle γ between the first main cutting edge42and the first minor cutting edge46, which is preferably smaller than 90°. This angle γ is particularly preferably in the range of 85° to 89.8°.

The second main cutting edge44of the second cutting insert22is also inclined with respect to the first imaginary plane54. The corresponding inclination angle is denoted as angle δ inFIG.2. Also the inclination of the second main cutting edge44is such that a radially outer end62of the second main cutting edge44is spaced a larger distance from the first imaginary plane54than a radially inner end64of the second main cutting edge44. The second main cutting edge44does not intersect the first imaginary plane54either.

This results in an angle c between the main cutting edges42,44which is less than 180°, but preferably larger than 174°. Preferably, the angle ε is larger than 174°, but less than 179.6°. All together, the main cutting edges42,44result in a concave cutting edge geometry at the axial end face end of the drill head32.

Unlike the first main cutting edge42of the first cutting insert20, the second main cutting edge44of the second cutting insert22does not extend up to the center of the drilling tool10. The second main cutting edge44does therefore not touch or intersect the second imaginary plane56.

In the embodiment shown inFIGS.1-3, the second minor cutting edge48of the second cutting insert22runs parallel to the central axis14of the tool holder12. However, just like the first minor cutting edge46, it can be inclined with respect to the central axis14by a maximum of 2°. Despite the described inclinations of the main and minor cutting edges42,44,46,48by the angles α, β and δ the main and minor cutting edges42,44,46,48preferably run parallel to the two abutment surfaces24,26of the cutting insert receptacles16,18. The main and minor cutting edges42,44,46,48are preferably all configured as straight cutting edges.

When machining a workpiece with the drilling tool10, the corner cutting edges50,52first come into contact with the workpiece due to the described inclination of the main cutting edges42,44. The drill head32therefore supports itself on the workpiece with these two corner cutting edges50,52. Due to the described inclination of the main cutting edges42,44with respect to the radial direction28, the first cut runs from outside to inside. This increases the wear resistance of the cutting inserts20,22enormously, since the cutting pressure is slowly transferred from the outside to the inside of the cutting edge geometry, thus delaying the total load. This stabilizes the cutting pressure so that breakouts at the main cutting edges42,44can be avoided. The design of the cutting inserts20,22as CVD thick-film diamond cutting inserts results in a drilling tool with high-strength cutting edges, which enables a machining of very hard materials such as sintered carbide or ceramics. The pressure on the center of the drilling tool10is considerably reduced by the described inclination of the main cutting edges42,44. Due to the developed cutting edge geometry it is possible to negate to a large extent the cutting speed in the center of the drill, which is typically 0. The support in the corners50,52leads to an increased stability and thus to highest axial accuracy and roundness in the bore. The inclination of the minor cutting edges46,48minimizes the friction on the lateral surface of the bore.

In order to be able to guarantee the high-precision properties of the drilling tool10, it is further preferred that the cutting edge geometry or the cutting edges42,44,46,48are produced by laser processing.

The top view from the front shown inFIG.3further shows the following: the two cutting inserts20,22preferably have different sizes. The first cutting insert20is larger than the second cutting insert22, especially with respect to its radial extension. Preferably, the first cutting insert20has an extension in radial direction28that is larger than half the diameter of the tool holder12. This diameter, which is denoted as diameter D inFIGS.1and3, refers to the diameter of the drill head32. In the rear part, the tool holder12comprises a clamping section66, the diameter of which is preferably larger than the diameter D. Since, as already mentioned, the first main cutting edge42of the first cutting insert20cuts from the very outside to the center or beyond, the first main cutting edge44also has a length that is larger than half the diameter D of the drill head32.

In the top view from the front shown inFIG.3, a distance d1is also drawn, which is between the two main cutting edges42,44. This distance d1should not exceed 6 hundredths. However, the distance d1can also be 0.

FIGS.6and7show a second embodiment of the drilling tool10, in which only the second cutting insert22projects radially outwards beyond the outer circumference40of the tool holder12in the area of the drill head32. In contrast, the first minor cutting edge46of the first cutting insert20is arranged inside the tool holder12without protruding radially outwards beyond the outer circumference40of the tool holder12in the area of the drill head32. However, the inclinations of the main and minor cutting edges42,44,46,48do not differ from the first embodiment. The main difference to the first embodiment is therefore that with the drilling tool10shown inFIGS.6and7, the outer contour of the bore is machined only with the second cutting insert22and the center of the bore is machined with the first cutting insert20only. Between this outer and inner area, the bore is machined with both cutting inserts20,22, as in the first embodiment.

It would also be conceivable to provide more than two cutting inserts, wherein the main cutting edges of each cutting insert machine a radial segment of the bore from outside to inside. However, if the first cutting insert20is configured as shown in the first embodiment inFIGS.1-3, it is sufficient to use only one cutting insert20, since in the first embodiment, the cutting insert20machines the entire contour from the very outside to the center.