DE102014225320B4 - drilling - Google Patents

Abstract

Drilling tool, in particular a metal boring tool, having at least one groove (7) running around an axis (a) of the boring tool (1) and having an end region (9) with at least one end face (27) and at least one main cutting element (25), formed between at least one rake face (21) of the groove (7) and the at least one end face (27), wherein the at least one groove (7) adjacent, in particular adjacent, to the end region (9), in particular to the at least one end face , at least one trough (31), characterized in that the trough (31) is formed by a forming process in the at least one groove (7).

Description

The invention relates to a drilling tool, a production method and an apparatus for producing a drilling tool, in particular a metal drilling tool, having at least one, in particular helical, groove extending around an axis of the drilling tool and having an end region with at least one end face and at least one main cutting element is formed between at least one rake face of the groove and the at least one end face.

State of the art

In the DIN (German Institute for Standardization) 1412A a drilling tool is disclosed having at least one helical groove extending along an axis of the drilling tool and an end region having at least two end faces and at least one cutting edge. Adjacent to the end region, the groove of the drilling tool has a chamfer, which is formed by a grinding process. The disadvantage here is the additional grinding effort.

In the DE 10 2009 036 285 A1 For example, there is disclosed a method of making a rock drill having a shank with a male end and a drill bit. In the insertion end facing away from the end of the shaft a Verbindungsausformung is provided for a positive engagement with the drill head.

The DE 10 2010 018 791 A1 discloses a method of making an elongate tool having a working portion and a male portion, wherein the male portion is adapted to be received in a tool holder and has at least one recess formed as a recess in an outer circumferential surface. For forming the elongated tool, a forming step is provided, which enlarges an elongate blank by extrusion in the region of the insertion section from an outer diameter D1 to an outer diameter D2.

The DE 10 2011 000 882 A1 discloses a drilling or milling tool having a cutting edge for exciting machining of a workpiece and a recess, wherein the recess is disposed within a flute adjacent to the cutting edge and the recesses has at least one wall and a bottom.

Disclosure of the invention

The invention is based on the object with simple production engineering measures a drilling tool for a machine tool, in particular a hand tool, in such a way that an increased throughput in the production of the drilling tool is achieved with improved drilling properties.

The object is achieved with a drilling tool, in particular a metal boring tool, with at least one, in particular helical, groove extending around an axis of the drilling tool and with an end region having at least one end face and at least one main cutting element which is between at least one rake surface of the groove and the at least one end face is trained. The at least one groove has adjacent, in particular adjoining, at least one depression to the front region, in particular to the at least one end surface. According to the invention, the trough is formed by a forming process in the at least one groove.

The invention makes it possible to provide a drilling tool with a depression which minimizes the radial extent of the drilling tool, in addition to which the local strength of the depression is increased by the forming process. As a result, a contact force required for drilling in the drilling operation of the drilling tool on the drilling tool and thus on the workpiece to be machined is reduced. Furthermore, it is prevented by the drilling tool according to the invention that the drilling tool slips when drilling a position to be drilled on the workpiece and thereby a borehole or a Bohrvorschub arises at an unscheduled position.

By the forming process further material of the drilling tool is solidified in the immediate vicinity of the trough, in particular work hardened, so that material parameters or material strengths are increased locally. Accordingly, the trough, not as already described in the prior art, introduced by a grinding process that not least requires an additional manufacturing step, but according to the invention introduced by a forming process in the groove of the drilling tool. A disadvantage of the prior art is accordingly the additional grinding costs, which previously represented an unavoidable additional effort in the production of a drilling tool with a groove and a trough. This grinding effort is eliminated by at least one forming tool a forming device, in particular a rolling device, not only the groove ausformt, but also forms the at least one trough in the groove of the drilling tool in a same or in a subsequent process step. Furthermore, in a single method step with a first portion of the forming tool, in particular the forging disc, a first deformation of the grooves and with a second portion, a second deformation of the Mulde be introduced into the blank or the drilling tool.

The drilling tool according to the invention is formed at least in one piece. The drilling tool is divided into a receiving area and a work area. The receiving area of the drilling tool is intended to be received in a receiving device of a machine tool, in particular a hand tool machine. The working area of the drilling tool is intended to work on workpieces. In this case, the working area has at least one groove, which extends spirally around an axis and opens into an end area. The end region has at least one end face and at least one main cutting element. The main cutting element is at least substantially formed between a rake face of the groove and the at least one end face. The at least one groove of the working area in this case has at least one trough which is adjacent, in particular adjacent, formed to the end region. The trough is formed by a forming process in the at least one groove.

In this context, a "radial extent" is to be understood to mean an extent, in particular a distance, preferably a first contact point, from the axis of the drilling tool, for example, to the at least one depression or the at least one groove. The radial extension of the trough or the groove may be formed as a radius of a supporting cross section of the drilling tool. The load-bearing cross-section is designed for power transmission, in particular torque or torque transmission. The supporting cross-section may be circular, in particular as a circle, preferably as a circular surface, be formed, and extend transversely, in particular orthogonal, to the axis of the drilling tool in a plane. In particular, a radial extent of the supporting cross section is limited by the groove and / or the trough. The radial extension of the supporting cross section may change along the axis of the drilling tool at least in sections, in particular increase or decrease. Alternatively, the radial extent of the supporting cross-section of at least the groove and / or trough along the axis of the drilling tool may remain the same. Thus, the supporting cross section of the drilling tool along the axis of the drilling tool, in particular the working area, form a supporting body, which is at least partially cylindrical or partially frusto-conical. The radial extension of the load-bearing cross-section of the groove may extend up to 40%, in particular up to 30%, preferably up to 20%, preferably up to 15%, particularly preferably up to 10%, relative to the maximum radial extension of the drilling tool. The radial extent of the supporting cross-section of the trough may be up to 30%, in particular up to 20%, preferably up to 10%, preferably up to 8%, particularly preferably up to 5%, in relation to the maximum radial extension of the drilling tool.

In this context, a "forming process" is to be understood as meaning a process in which elastic and / or plastic deformation is achieved by massive deformation, in particular material displacement and / or material accumulation of the workpiece. By a "massive forming" is meant a process such as rolling, drop forging, cold forming, extrusion, forging (free forging), upsetting or roll forming. Here, the workpiece to be deformed by a forming tool, such as by at least one hammer or by at least one disc, in particular a forging disc, a forming device to be deformed. For example, two or more forming tools can be pressed onto the workpiece to be deformed or a blank. Thus, a desired deformation or formation of the groove and / or the trough can be achieved. An arrangement in a tool device of the at least one forming tool, for example, the EP 0 792 705 A2 which describes how a groove of a drilling tool can be produced. However, it is not known how a trough, if it were provided, could be manufactured without additional effort.

In this context, a "forming tool" is to be understood as meaning a tool of a device for producing drilling tools, which is designed to introduce a deformation of the drilling tool to be produced. The at least one forming tool may be formed as a disc. The at least one disc can be designed as a forged disc or as a rolling disk. The disc may also be formed roller-shaped. In particular, the disc may be formed like a circle and thus do not extend completely around a tool axis.

In an alternative embodiment, at least one pin can be formed instead of at least one disk, which provides the necessary forming performance. The pin can press or squeeze a depression into a groove and shape it up to the end region, in particular to the end face.

The dependent claims indicate expedient developments of the drilling tool according to the invention.

It may be expedient that the trough, in particular a main extension of the trough, is formed at least substantially along, in particular parallel to, the axis of the drilling tool. Furthermore, it may be expedient that the trough, in particular a main extension of the trough, is formed at least substantially transversely to the axis of the drilling tool. In particular, the trough, in particular the main extension of the trough, be formed at an angle to the axis of the drilling tool. Preferably, a main extension of the trough can run in a spiral around the axis. Depending on the workpiece to be machined, it may be advantageous to adapt a main extension of the trough of the drilling tool to the material to be processed.

Preferably, the trough may be formed angled to the axis of the drilling tool. As a result, the trough can extend to the forehead area tapering. Particularly preferably, the trough, in particular a trough surface, opposite the groove, in particular a groove surface, angled or radially spaced formed. Preferably, the trough may be angled closer to the axis and / or to the groove and / or radially spaced. Thus, a larger transport volume is formed, which is provided for the transport of drilling dust. Thus, the accumulated drill dust is quickly conveyed out of the well, so that the drilling dust does not accumulate during drilling.

Furthermore, the trough can at least partially adjoin at least one end face. As a result, a shortened cross-cutting element, running transversely to the main cutting element, of the drilling tool can be formed, which reduces the at least one end face in a region adjacent to the axis of the drilling tool, in particular a central region. As a result, the drilling tool can apply an increased contact pressure with the same contact force of the drilling tool to the workpiece to be drilled as a result of the reduced end face.

Likewise, the radial extent of the groove can be designed to be consistent with increasing distance from the end region. In particular, the radial extent of the groove can be formed continuously or stepwise with increasing distance from the end region. Furthermore, the radial extension of the trough with increasing distance from the end region, in particular at least in sections, be designed to be consistent. Preferably, the radial extension of the trough with increasing distance from the end region, in particular at least partially, continuously or stepwise be formed increasingly. It is thereby achieved that the radial extension of the drilling tool, in particular of the transverse cutting element, is minimal at the end region. Hereby, the drilling tool can have a taper at the front area, which is particularly advantageous when machining workpieces. Likewise, an increased stability is achieved in the entire drilling tool, since the trough only adjacent, in particular adjacent, extends to the end region.

Preferably, the minimum radial extent of the depression relative to the minimum radial extent of the groove can be up to 40%, in particular up to 30%, preferably up to 20%, preferably up to 10%, particularly preferably up to 5%. , reduce. In this way, an advantageous endabaugegetreues drilling tool can be produced, which has a minimum radial extent to the end region. As a result, an additional grinding operation or an additional grinding effort to form this advantage can be avoided. Thus, with a low device and manufacturing cost, a drilling tool can be made with a trough having an improved strength characteristic. As can be achieved by solidification of the material with an increasing degree of deformation in near-edge material areas of the trough increased strength of the material.

Furthermore, it is proposed that the trough extend axially with respect to the maximum axial extent of the drilling tool up to 10%, in particular up to 8%, preferably up to 6%, preferably up to 5%. Further, the radial extent of the trough with respect to the maximum radial extent of the drilling tool by up to 50%, in particular up to 40%, preferably up to 30%, preferably up to 20%, particularly preferably up to 10%, extend. As a result, the complexity of the forming process or the rolling process is minimized because the trough is formed only in a region adjacent to the end region, in particular adjacent, and not in the entire groove. As a result, the forming tool can be made simpler. Thus, a forming tool, in particular at least one forging disc, which is provided for forming the groove, form a further deformation in the form of the recess in the groove by a simple control of the device.

In particular, a, in particular axial, main extension of the trough with respect to a transverse extent by up to 500%, in particular by up to 400%, preferably by up to 300%, preferably by up to 200%, more preferably by up to 150%, be formed ,

Preferably, the transverse extent of the trough with respect to the maximum radial Extension of the drilling tool by up to 70%, in particular by up to 55%, preferably by up to 40%, preferably by up to 30%, more preferably by up to 15%, such as 10% or 7%, extend.

Preferably, the maximum axial extent of the trough may be up to 25%, in particular up to 30%, preferably up to 40%, preferably up to 45%, more preferably up to 50%, of the maximum radial extent of the drilling tool extend.

Particularly preferably, the maximum radial extent of the trough with respect to the maximum radial extent of the drilling tool advantageously by up to 70%, in particular by up to 55%, preferably by up to 35%, preferably by up to 20%, particularly preferably up to 10%, such as 8% or 5%.

Further, the maximum axial extent of the trough with respect to the maximum axial extent of the drilling tool by up to 20%, in particular by up to 10%, preferably by up to 8%, preferably by up to 6%, particularly preferably by up to 4% , such as 2% or 1%.

By adjusting the extension of the trough of the drilling tool, the trough can be optimally adapted for different applications.

Furthermore, the minimum radial extent of the depression can be up to 50%, in particular up to 40%, preferably up to 30%, preferably up to 20%, particularly preferably up to 10%, compared to a minimum radial extent of the groove. , such as 8% or 5%, decrease. This ensures that the trough 31 minimizes the radial extent of the cross cutting element 29 and forms a transport volume.

Particularly preferably, the trough, in particular at least substantially, be formed in a transport surface of the groove. This is advantageous because the main cutting element is at least substantially not limited by the trough, so that a homogeneous course of the main cutting element is provided.

Another aspect of the invention relates to a method of manufacturing the drilling tool.

A method for producing a drilling tool and an arrangement of a tool device of the at least one forming tool, for example, the EP 0 792 705 A2 which describes how a groove of a drilling tool can be produced. In an embodiment with two grooves and / or two wells exactly two forming tools can be provided.

Hereinafter, an embodiment of a drilling tool with two grooves, each with a trough will be described. However, the invention should not be limited to this embodiment, but rather be expandable to further embodiments with only one or more grooves.

By virtue of the method, grooves and / or depressions can be formed by means of two opposing forming tools whose tool axes lie in mutually parallel at least substantially parallel tool axis planes. The forming tool has, in particular, an outer area formed as a circumference, which delimits at least substantially the radial extension of the forming tool. The distance of the outer region of two forming tools to one another can thereby determine the load-bearing cross section of the manufactured drilling tool. This is achieved by passing a cylindrical blank having a circular cross section between the forming tools, in particular pulled through it. The forming tools rotate to each other in opposite directions to pass through the blank. The outer region, in particular an outer surface of the outer region, preferably a forming edge of the outer region, of the forming tool is thereby pressed into the blank. Thereby, the groove and / or the trough, in particular in a single Verfahrungsschritt, are formed in the blank.

Furthermore, the tool axes of the forming tools can be angled relative to each other so that grooves can be formed spirally around the axis of the blank. In particular, the tool axes of the forming tools can be arranged to each other in parallel axis planes, but in the axial plane to each other angled tool axes. The tool axes of the forming tools may also be inclined to the axis of the blank or of the drilling tool. Thereby, a helix angle of the groove and / or the trough of the drilling tool can be adjusted.

In order to form supporting cross-sections, in particular grooves and / or depressions, it is possible to arrange the forming tools either in such a way that the forming tools come closer together to reduce the load-bearing cross-section, or to make the forming tools such that between an initial state the forming tools are engaged with the blank until a final state at which the Forming tools disengage, the forming tools have a changing radius. In the latter case, it is important that a state of initial engagement of the forming tool with the blank is the same for each blank. As a result, the forming tool can only be designed to extend in a circle-shaped manner around the tool axis.

The peripheral region, in particular the forming edge, can run in a spiral around the tool axis. In particular, the peripheral region, in particular the peripheral edge, may have an elevation which forms a depression which is opposite to the drilling tool. In this case, the trough may be formed as a recess introduced by the increase of the forming tool in the production.

The elevation may be formed as an accumulation of material on an outer area, in particular a starting area and / or an end area, of the forming tool. The increase can increase steadily or suddenly. The elevation may extend radially and / or axially to the tool axis. In particular, by a suitable design of the elevation, a recess formed as a depression in the groove can be formed, which is introduced into the rake surface and / or the transport surface. It can also be adjusted by how far the trough in the rake face and how far the trough is placed in the transport surface. Likewise, thereby, the axial extent of the trough may be formed only in the transport surface.

Furthermore, the subject of the invention is a device for producing the drilling tool. The device is designed for carrying out a method for producing a drilling tool. The at least one forming tool has at least one increase.

list of figures

Further advantages emerge from the following description of the drawing. In the drawings, embodiments of the invention are shown. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider these features individually and combine them into meaningful further combinations.

• 1 eine perspektivische Ansicht auf eine Handwerkzeugmaschine mit einem Bohrwerkzeug,
• 2 eine Seitenansicht auf ein erstes Ausführungsbeispiel eines erfindungsgemäßen Bohrwerkzeugs,
• 3a - b ein Ausschnitt aus und eine stirnseitige Draufsicht auf das Bohrwerkzeug aus 2,
• 4a - b ein Ausschnitt aus und eine stirnseitige Draufsicht auf das Bohrwerkzeug,
• 5 eine Querschnittsansicht a-a des Bohrwerkzeugs aus 3,
• 6 eine Querschnittsansicht entlang der Achse a einer Ausführungsform eines Bohrwerkzeugs und
• 7 eine Seitenansicht auf das erfinderische Umformwerkzeug.

This shows

• 1 a perspective view of a hand tool with a drilling tool,
• 2 a side view of a first embodiment of a drilling tool according to the invention,
• 3a b shows a detail of and a frontal top view of the drilling tool 2 .
• 4a b is a detail of and a frontal plan view of the drilling tool,
• 5 a cross-sectional view of the drill aa 3 .
• 6 a cross-sectional view along the axis a of an embodiment of a drilling tool and
• 7 a side view of the inventive forming tool.

In the following figures, the same components are provided with the same reference numerals.

The following figures each relate to a drilling tool, in particular a metal drilling tool, in particular for receiving the drilling tool in a receiving device of a machine tool, preferably a hand tool, with a rotary and / or translational working movement on a workpiece to be machined. In this case, a translational feed is introduced into the workpiece by the operator of the power tool applying a force on the power tool, in particular the power tool housing. The drilling tool is suitable for machining, in particular for drilling metals. However, the drilling tool according to the invention is not only designed for drilling metals, but can also be used for machining other materials that appear appropriate to a person skilled in the art, such as wood, plastic or a composite.

1 shows a perspective view of a hand tool 101 with one in the cradle 105 clamped drilling tool 1 , The hand tool machine 101 has a hand tool housing 103 with at least one grip area 109 for grasping with at least one hand of a user. The cradle 105 in this embodiment has three jaws 107 on, of which only two jaws 107 are shown. The jaws 107 clamp the drilling tool 1 radially in the receiving device 105 one.

The side view on the drilling tool 1 according to 2 shows a recording area 3 of the drilling tool 1 for inclusion in a cradle 105 a hand tool 101 is provided and a workspace 5 which is provided for machining a workpiece. The drilling tool 1 is at least substantially cylindrical. The recording area 3 has a circular cross-sectional area. In an alternative embodiment, the cross-sectional area may have a polygonal cross-section. The recording area 3 extends from a chucking end of the drilling tool 1 axially to the work area 5 and adjoins the workspace 5 at. Alternatively or additionally, the receiving area 3 Positive locking means, such as depressions and / or survey (not shown), which, to an improved, in particular positive connection with the holding device 105 the hand tool machine 101 can be provided. Adjacent to the recording area 3 subsequent workspace 5 also has an end portion and two grooves 7 on.

The two grooves 7 are at least substantially formed spiral. The two grooves 7 extend axially about an axis a of the drilling tool 1 around and flow into the forehead area 9 of the workspace 5 of the drilling tool 1 , The two grooves 7 run in the direction of the forehead area 9 transverse to the axis a of the drilling tool 1 , In particular, the, preferably radial, extension of the two grooves can be 7 in the direction of the forehead area 9 at least partially continuously and / or at least partially abruptly decrease. The radial extent of the grooves 7 may also have a radius of a supporting cross section 11 of the drilling tool 1 form, which is formed in a radially extending to the axis a of the drilling tool extending plane. This load-bearing cross-section 11 may be formed in particular circular. Here, the load-bearing cross-section 11 circular, in particular as a circle, with a center around the axis a of the drilling tool 1 be educated. The load-bearing cross-section 11 may have a radius along the axis a with decreasing distance to the forehead area 9 can be formed continuously decreasing. In an alternative embodiment, the radial extent of the at least one groove 9 , in particular of the two grooves 9 at least substantially parallel to the axis a of the drilling tool 1 run.

The two grooves 7 are in the circumferential direction of, in particular two, webs 13 separated. Thus, the webs run 13 parallel to the grooves 7 and are spirally formed. A peripheral area 15 of the bridges 13 limits the radial extent of the drilling tool 1 , The peripheral area 15 of the bridges 13 also has a first peripheral surface 17 characterized by a first radial extent and a first radius, respectively. Furthermore, the bridge 13 a second peripheral surface 19 which is characterized radially with a second radial extent and a second radius, respectively. The second peripheral surface 19 stands to the first peripheral surface 17 radially off. Furthermore, the second peripheral surface 19 smaller than the first peripheral surface 17 , The second peripheral surface 19 limits the radial extent of the second section 5 of the drilling tool 1 , The second peripheral surface 19 is intended to minimize a friction surface and, accordingly, a frictional action which increases when drilling in a wellbore with increasing drilling depth.

One groove each 7 has a groove surface 21 . 23 on that in two groove surfaces 21 . 23 can be divided. A first groove surface 21 is axially through a main cutting edge 25 of the forehead area 9 limited. The first groove surface 21 is as a rake surface 21 the main cutting edge 25 educated. A second groove surface 23 is through an end face 27 of the forehead area 9 limited. The second groove surface 23 is as a transport area 23 educated. The first groove surface 21 and the second groove surface 23 can merge into each other. The first groove surface 21 and the second groove surface 23 can pass through an imaginary line in the at least one groove 9 or the at least one trough 31 be separated from each other, which runs through the, in particular minimal, radial extent of the groove or the trough along the groove or the trough of the drilling tool. The at least one end face 27 is here as an open space 27 the main cutting edge 25 of the forehead area 9 educated.

The forehead area 9 essentially has two end faces 27 on. The two end faces 27 are by a cross cutting element 29 separated from each other. Both faces 27 form between a rake surface 21 the groove 7 a main cutting edge 25 made out as the main cutting element 25 is trained. The main cutting element 25 separates the at least one designed as an open space face 27 from the rake face 21 , The forehead area 9 or the faces 27 limit the axial extent of the drilling tool 1 , in particular the work area 5 , The at least one main cutting element 25 is formed axially projecting, so that the end faces 27 angled to the respective main cutting edges 25 are formed and toward the receiving area 3 run.

Furthermore, in this case has at least one of the grooves 7 adjacent to the forehead area 9 at least one hollow 31 on. The hollow 31 is elongated and extends along the axis a of the work area 5 of the drilling tool 1 , The hollow 31 extends at least substantially parallel to the axis a of the drilling tool 1 , The hollow 31 is in a central area of the drilling tool 1 arranged. The hollow 31 is at least partially in the first groove surface 21 or the chip surface 21 the groove 7 arranged. The hollow 31 is at least partially in the second groove surface 23 or the transport area 23 the groove 7 arranged. In an alternative embodiment, the trough is 31 exclusively in a transport area 23 the groove 7 formed, whereby a correspondingly increased transport volume is generated. In particular, the trough can be up to a peripheral area 15 run. This allows the main cutting edge 25 or the main cutting element 25 homogeneous, in particular straight and / or curved, without passing through the introduced trough 31 to be changed. Thus, this can be done by the main cutting edge 25 machined drill meal can be stored in an increased transport volume before passing through the groove 7 out of the borehole. Likewise, a radial extent or the supporting cross section 11 the at least one groove 7 adjacent to the forehead area 9 downsize axially towards the forehead area. This allows a radial extension of the cross cutting element 29 , in particular a transverse cutting edge 29 , to minimize.

The hollow 31 is formed at least substantially rectangular. One, in particular axial, main extension of the trough 31 is designed opposite to a transverse extension of up to 300%. In this case, the transverse extension can extend transversely, in particular at least substantially orthogonally, to the main extension. The transverse extension of the trough 31 extends opposite the diameter of the drilling tool 1 by up to 40%, such as 30% or 15%. The transverse extension of the trough 31 extends opposite the diameter of the drilling tool 1 by up to 55%, in particular by up to 40%, such as 25% or 20%. The maximum radial extent of the trough 31 extends opposite the maximum radial extent of the drilling tool 1 advantageously up to 30%, such as 25% or 15%.

3a shows a section of the drilling tool 1 with the forehead area 9 and the hollow 31 as already in 2 described. Clearly visible is the trough 31 along the axis a of the drilling tool 1 extends and in a central region to the axis a of the drilling tool 1 is provided. Likewise, the trained as an open space face 9 to see in particular the hollow 31 empties.

3b shows a frontal plan view of the drilling tool 1 out 2 , Clearly visible are the two end faces 27 of the forehead area 9 and across the main cutting elements 25 extending transverse cutting elements 29 that the two end faces 27 separate each other. Likewise, the two opposing grooves 7 to see each other, in particular symmetrical. The two at least substantially rectilinear main cutting elements 25 or main cutting edges 25 that at least essentially by the respective rake face 21 the groove 7 and the respective as open space 27 trained face 27 of the forehead area 9 are formed. Furthermore, each is a trough 31 shown, each in a groove 7 is formed and the extension of the cross cutting element 25 limited. In an alternative embodiment, at least one groove 9 also several hollows 31 exhibit. In an alternative embodiment, the forehead area 9 even without the cross cutting element 25 be educated. The hollows 31 extend substantially axially to the axis a of the drilling tool 1 , The hollows 31 thus reduce the front surfaces 27 of the forehead area 9 ,

Furthermore, the 3b the load-bearing cross-section 11 out 1 to take in this embodiment, circular about the axis a of the drilling tool 1 is trained. Here is the load-bearing cross-section 11 two opposing grooves 7 educated. The radial extent of the supporting cross section 11 is in the feed direction of the drilling tool 1 through the hollows 31 reduced.

4a shows a section of the drilling tool 1 , The workspace 5 is at least essentially analogous to the work area 5 of the 2 educated. In contrast to the first embodiment, the trough 31 of the second embodiment at least substantially in the transport surface 23 educated. The hollow 31 can only be used in the transport area 23 be educated. The radial extent of the trough 31 can be formed at least substantially larger than the axial extension trough. The hollow 31 limited thereby the web 13 , in particular the peripheral surface 17 . 19 of the footbridge 13 ,

4b shows a frontal plan view of the drilling tool 1 out 4a , The forehead area 9 is at least substantially analogous to the forehead area 9 of the 2 educated. As already in 4a shown is the trough 31 at least essentially in the transport area 23 trained and extends to the jetty 13 , in particular to the peripheral surface 17 . 19 of the footbridge 13 ,

5 shows a cross-sectional view aa 3a and additionally two forming tools 71 , in particular two rolls 71 , preferably Schmiederollen, each of the grooves 7 forming, in particular rolling or forging. You can see the circular load-bearing cross-section 11 whose center is the axis a of the drilling tool 1 is. The two forming tools 71 engage in the workpiece so that the workpiece or the blank deformed, in particular solid deformed, is. The wedge-shaped forming tools 71 can a groove 7 form their groove surfaces 21 . 23 , in particular the first groove surface 21 and the second groove surface 23 are formed at an angle α in a range of 40 ° to 155 °, in particular from 45 ° to 150 °, preferably from 50 ° to 145 °, preferably from 55 ° to 140 °, to each other. The first groove surface 21 and the second groove surface 23 may be connected to each other under a radius of up to 0.5 mm, in particular up to 1 mm, preferably up to 1.5 mm, preferably up to 2 mm, particularly preferably up to 2.5 mm.

6 shows a cross section along the axis a of the drilling tool 1 out 2 , You can see a projection of the supporting cross section 11 of the recording area 3 of the drilling tool 1 , It can be seen above all that the minimum radial extent of the at least one groove 7 or the supporting cross section 11 to the forehead area 9 steadily rejuvenated. The groove 7 is in the 6 not visible, but as a projection of a radial to the supporting cross-section 11 running area shown.

In 7 is a cross-sectional view of the forming tool 71 shown. The forming tool 71 extends along a circular section and axially to a tool axis b of the forming tool 71 , The forming tool 71 is formed at least substantially hollow cylindrical. In an alternative embodiment, the forming tool 71 be at least substantially cylindrical. The forming tool 71 has an outdoor area 73 and one outside 73 opposite interior area 75 on. The outdoor area 73 can be designed as an outer surface. The interior 75 may be formed as an inner surface. The forming tool is in the circumferential direction 77 . 78 through side surfaces 79 limited.

Parallel to the tool axis b can in the forming tool 71 holes 81 be introduced, which are provided to the forming tool 71 to connect with a carrier (not shown).

The outdoor area 73 of the forming tool 71 has a forming edge 83 on. The forming edge 83 is intended a groove 7 and / or a trough 31 in a blank or a drilling tool 71 to shape. The forming edge 83 runs at least substantially helically around the tool axis b. The radial extension of the forming edge 83 to the tool axis b can in the circumferential direction 77 . 78 increase. In particular, the forming edge 83 of the outdoor area 73 be formed such that the radial extent in the circumferential direction 77 . 78 from a first position of the forming tool to a second position of the forming tool 71 elevated. In particular, the radial extension of the Umformkante runs 83 for example, from a position I via a position II and a position III to a position IV continuously increasing. In an alternative embodiment, the radial extent of the forming edge 83 from a position I to a position IV constant or abruptly increase or decrease. The forming edge is preferred 83 with an increase 85 provided, for example, at the position V is provided. The increase 85 may be provided to the drilling tool 1 one to increase 85 form a contrary depression. The recess in the drilling tool is formed as a recess in a groove of the drilling tool.

The general method of the deforming method, in particular the profile rolling, of drilling tools 1 is already well known to a person skilled in the art and will therefore not be described in detail. For possible construction of a device is on the EP 0 792 705 A2 directed.

Claims (12)

Drilling tool, in particular a metal boring tool, having at least one groove (7) running around an axis (a) of the boring tool (1) and having an end region (9) with at least one end face (27) and at least one main cutting element (25), formed between at least one rake face (21) of the groove (7) and the at least one end face (27), wherein the at least one groove (7) adjacent, in particular adjacent, to the end region (9), in particular to the at least one end face , at least one trough (31), characterized in that the trough (31) is formed by a forming process in the at least one groove (7). Drilling tool after Claim 1 , characterized in that the trough (31), in particular a main extension of the trough (31), at least substantially along, in particular parallel to, the axis (a) of the drilling tool (1) is formed. Drilling tool according to one of the preceding claims, characterized in that the trough (31), in particular the main extension of the trough (31), angled to the axis (a) of the drilling tool (1) is formed. Drilling tool according to one of the preceding claims, characterized in that the trough (31) at least partially adjacent to at least one end face (27). Drilling tool according to one of the preceding claims, characterized in that the radial extent of the groove (7) with increasing distance from the end region (9) is formed continuously increasing or continuously or stepwise. Drilling tool according to one of the preceding claims, characterized in that the minimum radial extent of the trough (31) with increasing distance from the end region (9) is formed continuously and / or continuously or stepwise increasingly. Drilling tool according to one of the preceding claims, characterized in that the minimum radial extension of the trough (31) relative to the minimum radial extent of the groove (7) by up to 40%, in particular by up to 30%, preferably by up to 20% , preferably by up to 10%, more preferably by up to 5%, reduced. Drilling tool according to one of the preceding claims, characterized in that the trough (31) axially opposite the maximum axial extent of the drilling tool (1) of up to 10%, in particular up to 8%, preferably up to 6%, preferably up to 5 %, extends. Drilling tool according to one of the preceding claims, characterized in that the radial extent of the trough (31) up to 50%, in particular up to 40%, preferably up to 30%, preferably up to 20%, particularly preferably up to 10%, of maximum radial extent of the drilling tool (1) corresponds. Drilling tool according to one of the preceding claims, characterized in that the trough (31), in particular at least substantially, in a transport surface (23) of the groove (7) is formed. Method for producing a drilling tool (1) according to one of the preceding claims, characterized in that the trough (31) is formed by a deforming method in the at least one groove (7). Apparatus for carrying out a method according to Claim 11 , characterized in that at least one forming tool has an elevation (85).

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