METHOD FOR PRODUCING A CUTTING HEAD, AND CUTTING HEAD

Abstract

A method for producing a cutting head is specified. The latter is manufactured from a blank, which in turn is manufactured by means of extrusion. During extrusion, a number of coolant channels as well as a number of flutes are formed, wherein the coolant channels and the flutes are in each case formed helically during extrusion. After extrusion, the flutes have a pitch that is adjusted by grinding the flutes to a finished dimension. The method is particularly material-saving. A corresponding cutting head is moreover specified.

Claims

1. A method of producing a cutting head that is manufactured from a blank comprising: extruding the blank, wherein a number of coolant channels as well as a number of flutes are formed during the extrusion, wherein the coolant channels and the flutes are each formed helically during extrusion, and wherein, after extruding, the flutes have a pitch that is adjusted by grinding the flutes to a finished dimension.

2. The method according to claim 1, wherein the flutes have an angle of twist (D2) that is adjusted after extrusion by changing the pitch.

3. The method according to claim 1, wherein during extrusion, an endless blank is produced from which the blank is parted off.

4. The method according to claim 3, wherein the blank is parted off from the endless blank without any sacrificial allowance.

5. The method according to claim 1, wherein the flutes are formed in an outer region that surrounds a core region, and that the coolant channels are formed in the core region.

6. The method according to claim 1, wherein the blank is extruded via an extrusion nozzle with a circular aperture into which a shaping projection protrudes for each of the flutes.

7. The method according to claim 1, wherein the blank is sintered after extrusion.

8. The method according to claim 1, wherein the blank is reworked after extrusion by grinding a number of cutting edges into the blank.

9. A cutting head which is produced by a method according to claim 1.

10. The cutting head according to claim 9, wherein the cutting head is formed of hard metal.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0026] Exemplary embodiments of the invention are explained in greater detail below with reference to the figures. Shown schematically in each case are:

[0027] FIG. 1 a method for producing a cutting head,

[0028] FIG. 2A a cutting head in a front view,

[0029] FIG. 2B the cutting head of FIG. 2A in a side view,

[0030] FIG. 3A a blank in a perspective view,

[0031] FIG. 3B the blank of FIG. 3A in a front view,

[0032] FIG. 4 the extrusion in the method of FIG. 1,

[0033] FIG. 5A an extrusion nozzle in a front view,

[0034] FIG. 5B an alternative extrusion nozzle in a front view,

[0035] FIG. 6 a variant of the blank in a front view.

DETAILED DESCRIPTION

[0036] FIG. 1 shows the sequence of a method according to the invention for producing a cutting head 2 for a cutting tool not shown in more detail. An exemplary cutting head 2 produced by means of the method is shown in FIG. 2A, 2B. The cutting head 2 is in this case designed as a cutting insert or even as a drill bit for a drill. The cutting head 2 shown is manufactured from tungsten carbide and also formed in one piece, i.e., it consists in the present case only of tungsten carbide. The cutting head 2 in FIG. 2A, 2B has a diameter D of 25 mm and a length L of 30 mm.

[0037] The cutting head 2 is manufactured from a blank 4, which is produced in a first step S1 by means of extrusion, i.e., the blank 4 is formed from an extruded material. An exemplary blank 4 is shown in FIG. 3A, 3B. During the extrusion, a number of coolant channels 6, in this case two coolant channels 6, is formed. These coolant channels extend longitudinally within the blank 4. The coolant channels 6 are, for example, formed by means of nylon threads, which serve as placeholders during extrusion. A number of flutes 8, in this case two flutes 8, is moreover formed during extrusion. In contrast to the coolant channels 6, which run inside the blank 4, the flutes 8 are formed as recesses on the outside of the blank 4. The formation of coolant channels 6 takes place in a first substep U1 of the first step S1. The formation of flutes 8 takes place in a second substep U2 of the first step S1. The two substeps U1, U2 in FIG. 1 take place simultaneously. The coolant channels 6 and the flutes 8 are accordingly respectively formed during extrusion, i.e., in the same first step S1. The flutes 8 are thus not first created by subsequent machining of a blank without flutes but are already preformed during manufacturing of the blank 4. This results in a significant material saving.

[0038] The coolant channels 6 and the flutes 8 are moreover in each case formed helically during extrusion; they thus in each case follow a helical course about a longitudinal axis R of the blank 4. With respect to the longitudinal axis R, the coolant channels 6 have a first angle of twist D1 and the flutes 8 have a second angle of twist D2. In the flutes 8, the angle of twist D2 is also called the flute angle. The angles of twist D1, D2 result from a respective pitch for the coolant channels 6 and the flutes 8. In this case, the pitch of the coolant channels 6 is equal to the pitch of the flutes 8 in consequence of the production. During extrusion, a direction of rotation is imprinted onto the extruded material so that the coolant channels 6 and the flutes 8 are automatically produced helically. The angles of twist D1, D2 are not necessarily identical depending on the relative position of the coolant channels 6 and the flutes 8, namely not when they extend at different distances in relation to the longitudinal axis R of the blank 4. The coolant channels 6 and the flutes 8 in the present case are however separated from the longitudinal axis R in the radial direction at about the same distance so that the angles of twist D1, D2 are approximately equal.

[0039] After extrusion in the first step S1, the blank 4 is sintered in a second step S2 so that the material of which the blank 4 consists hardens. During sintering, the material is hardened and the blank 4 generally shrinks so that the diameter D and the length L are correspondingly reduced. The essential shape, i.e., the course of the flutes 8 and the coolant channels 6 are however basically maintained in the process.

[0040] After sintering, the blank 4 is reworked in a third step S3 and the cutting head 2 is produced in the final shape, e.g., as in FIG. 2A, 2B. During reworking in the third step S3, a number of cutting edges 10 are ground into the blank 4. These cutting edges in the cutting head 2 serve to machine a workpiece. The blank 4 for the cutting head 2 in FIG. 2A, 2B was moreover also reworked such that a coupling element 12 is formed in order to connect the cutting head 2 to a base body not shown. The coupling element is visible in particular in FIG. 2B and comprises a pin 14 and a collar 16 for mounting in the manner of a bayonet lock. The cutting edges 10 are formed on the front end of the cutting head 2; the coupling element 12 is formed on the rear end. The coolant channels 6 serve to supply coolant or lubricant and extend through the entire cutting head 2. The flutes 8 serve to transport chips away and also extend across the entire cutting head 2. In the exemplary embodiment shown, the number of coolant channels 6 corresponds to the number of flutes 8.

[0041] The flutes 8 in the exemplary embodiment shown are already formed with full depth in the first step S1 so that a reworking of the flutes for further deepening in particular in step S3 is omitted. In a variant not shown, the flutes 8 are however not formed with full depth and then brought into a final shape within the scope of reworking in the third step S3.

[0042] In FIG. 4, the first step S1, i.e., the extrusion of the blank 4, is shown in more detail. In the process, an endless blank 20 is produced by means of an extrusion system 18, which endless blank extends in the longitudinal direction R and off which endless blank the blank 4 is then parted. The blank 4 can accordingly be produced with any length L. The coolant channels 6 are marked by helical dashed lines. It can be seen clearly that the angle of twist D1 of the coolant channels 6 corresponds to the angle of twist D2 of the flutes 8 in the exemplary embodiment shown.

[0043] The material for the blank 4 is extruded through an extrusion nozzle 22. Behind the extrusion nozzle 22, a portion, i.e., a longitudinal section 24 of the extruded material, i.e., of the endless blank 20, is parted off, separated or cut off, as blank 4. Extrusion is then continued in order to produce another blank 4. In the exemplary embodiment shown, the blank 4 is accordingly produced as one of several blanks 4, which are parted off one after the other from the endless blank 20. In a variant, blanks 4 are parted off with different lengths L.

[0044] The extrusion nozzle 22 imprints a twist onto the material as already mentioned above so that the coolant channels 6 and the flutes 8 are formed helically, i.e., already exist in a helical shape in the endless blank 20. For this purpose, the extrusion nozzle 22 comprises an appropriate aperture 26. Exemplary extrusion nozzles 22 are shown in FIG. 5A, 5B. The aperture 26 of the extrusion nozzle 22 in FIG. 5A comprises a number of projections 28 for forming the flutes 8 as well as a profiling therebetween with a plurality of teeth 30 for generating the twist, i.e., a rotational movement. The shape of a projection 28 corresponds to the cross-section of a corresponding flute 8. On the other hand, the aperture 26 of the extrusion nozzle 22 in FIG. 5B is formed without profile, i.e., does not have any profile or any teeth 30, but is instead circular, except for the projections 28 for the flutes 8. In other words, the aperture 26 consists of a circle K, from the circumference of which projections 28 protrude inwardly. The rotational movement during extrusion is in this case only generated by the projections 28.

[0045] In the method shown, the flutes 8 are already formed during the initial shaping of the blank 4 so that an allowance for the purposes of holding the blank during reworking can be dispensed with and is also dispensed with. The blank 4 is manufactured directly in the actually sufficient length L. In other words, the blank 4 is parted off from the endless blank 20 without any sacrificial allowance and precisely in the length L that the finished cutting head 2 is to have. A shrinking within the scope of sintering in the second step S2 is, where applicable, taken into consideration in the process.

[0046] In order to adapt the angle of twist D2 of the flutes 8, the second angle of twist D2, i.e., the flute angle, is adjusted, in the present case even changed by regrinding the flutes 8.

[0047] This takes place, e.g., during reworking in the third step S3. Since the cutting head 2 only has a short length L, i.e., in particular a length of less than 10 mm, there is also no risk of exposing the coolant channels 6 when the angle of twist D2 of the flutes 8 is adapted. In a variant not shown, the flutes are only formed in an outer region 32 of the blank 4. The flutes 8 have a certain depth and thereby define a core region 34, which is surrounded by the outer region 32. No flutes 8 are accordingly formed in the core region 34. In FIG. 6, a corresponding variant of the blank 4 is shown. It can be seen clearly in FIG. 6 how the outer region 32 is formed to be annular and concentric in relation to the circular core region 34. In the variant mentioned and not shown, the coolant channels 6 are then formed in the core region 34, whereby the now internal coolant channels 6 are no longer affected by a change of the angle of twist D2 of the flutes 8.