CUTTER HEAD FOR CUTTING MATERIALS, AND CUTTER THEREFOR

Abstract

A cutter includes a cutting edge, a rear, a cutting surface, a foot and a longitudinal axis, as well as a transverse axis, wherein a stop surface is provided on the rear pointing towards the cutting edge. The stop surface extends in the direction of the transverse axis and is provided at an angle (alpha) of between 92° and 112° in relation to the longitudinal axis. In addition, the cutter is suitable for use in a cutter head having a carrier body, in which at least one radially outwardly open recess is provided for receiving a cutter and a clamping jaw which can be actuated by a clamping screw, and by means of which the cutter can be clamped in a fixed position in the recess. The recess has a stop with a stop surface that is directed radially inwards, and the cutter can be introduced into the recess against the force of at least one elastic element. The cutter can be applied, in a radially outward direction, by its stop surface to the stop surface that is directed radially inwards, by an elastic element.

Claims

1. A cutter head for a subtractive processing of materials, in particular timber materials, plastics, light-metal materials, and/or composite materials therefrom, comprising a holder body in which at least one clearance that is open in a radially outward manner for receiving a cutter and clamping jaw that is activatable by way of a tensioning screw and by means of which the cutter is fixedly clampable in the clearance are provided, wherein the clearance has a detent having a radially inwardly directed detent face and the cutter is insertable into the clearance, counter to the force of at least one elastic element, wherein the cutter has a radially outwardly directed detent face which in relation to a longitudinal axis runs at an angle of 92° to 112°, and the cutter by way of the detent face thereof is placeable by the elastic element in a radially outward direction against the radially inwardly directed detent face.

2. The cutter head as claimed in claim 1, wherein the angle is 92° to 110°, in particular 95°±2°, preferably exactly 95°.

3. The cutter head as claimed in claim 1, wherein the cutter is provided with a groove which interacts with at least one protrusion that is provided on the clamping jaw.

4. The cutter head as claimed in claim 1, wherein the detent is configured on a protrusion and/or a groove wall.

5. The cutter head as claimed in claim 1, wherein the detent face is a wall of a groove that is disposed in the cutter, or is formed on a shoulder that is provided on the cutter.

6. The cutter head as claimed in claim 4, further comprising at least one radially outwardly directed protrusion on which the detent face is configured is provided on a shoulder that is provided on the cutter.

7. The cutter head as claimed in claim 1, wherein the elastic element is attached to the clamping jaw.

8. The cutter head as claimed in claim 1, wherein the elastic element is connected to the tensioning screw, by a disk that is placed onto the tensioning screw.

9. A cutter for use in a cutter head as claimed in claim 1, further comprising a blade, a spine, a chip surface, a base, and a longitudinal axis and a transverse axis, and wherein the detent face is on the spine that points in the direction of the blade, and which extends in the direction of the transverse axis, and in relation to the longitudinal axis runs at an angle (α) of 92° to 112°.

10. The cutter as claimed in claim 9, wherein the angle is 92° to 110°, in particular 95°±2°, preferably exactly 95°.

11. The cutter as claimed in claim 9, wherein the detent face is configured on a shoulder that projects from the spine.

12. The cutter as claimed in claim 9, wherein the detent face is a wall of a groove that in the spine runs in the direction of the transverse axis and that is proximal to the base.

13. The cutter as claimed in claim 10, wherein the detent face is disposed on at least one protrusion that is disposed on a shoulder that is provided on the cutter and points in the direction of the blade.

14. The cutter as claimed in claim 9, further comprising a slot that emanates from the base and runs in the direction of the blade and that is open toward the spine and the chip surface.

15. The cutter as claimed in claim 9, further comprising a first groove that runs in the direction of the transverse axis and in relation to a groove that is provided in the spine is offset in the longitudinal direction is provided in the chip surface, wherein a spacing (a) of the first groove from the base is smaller than the spacing (b) of the detent face from the base.

16. The cutter as claimed in claim 9, wherein the blade is configured on a plate which is connected to a blade holder, the plate being composed of a material that is different from that of the blade holder.

17. The cutter as claimed in claim 9, wherein the former is composed of a sintered material.

18. The cutter as claimed in claim 17, wherein the spine is configured so as to be untreated post sintering.

19. The cutter as claimed in claim 11, wherein the detent face is configured so as to be spherical and untreated post sintering.

Description

[0026] In the drawing:

[0027] FIG. 1 shows a perspective exploded part-illustration of the cutter head;

[0028] FIG. 2 shows an enlarged fragment of FIG. 1;

[0029] FIG. 3 shows the view according to the viewpoint arrow III as per FIG. 2;

[0030] FIG. 4 shows perspective part-illustrations of the tool;

[0031] FIG. 5 shows an enlarged part-section according to the section line V-V in FIG. 4;

[0032] FIG. 6 shows an enlarged part-section according to the section line VI-VI in FIG. 4;

[0033] FIG. 7 shows a plan view of the clamping jaw;

[0034] FIG. 8 shows a section through the clamping jaw along the section line VIII-VIII in FIG. 7;

[0035] FIG. 9 shows a first perspective view of the clamping jaw;

[0036] FIG. 10 shows a second perspective view of the clamping jaw;

[0037] FIG. 11 shows a first embodiment of a cutter in a perspective illustration;

[0038] FIG. 12 shows the cutter as per FIG. 11 in another perspective;

[0039] FIG. 13 shows a side view of the cutter as per FIG. 11;

[0040] FIG. 14 shows a second embodiment of a cutter in a perspective illustration;

[0041] FIG. 15 shows the side view of the cutter as per FIG. 14;

[0042] FIG. 16 shows a third embodiment of a cutter in a perspective illustration;

[0043] FIG. 17 shows the cutter as per FIG. 16 in another perspective;

[0044] FIG. 18 shows a fourth embodiment of a cutter in a perspective illustration;

[0045] FIG. 19 shows the cutter as per FIG. 18 in another perspective;

[0046] FIG. 20 shows a further embodiment of a cutter;

[0047] FIG. 21 shows a further embodiment of a cutter;

[0048] FIG. 22 shows a further embodiment of a cutter;

[0049] FIG. 23 shows a further embodiment of a cutter;

[0050] FIG. 24 shows the side view of the cutter as per FIG. 23;

[0051] FIG. 25 shows the further embodiment of a cutter;

[0052] FIG. 26 shows the further embodiment of a cutter;

[0053] FIG. 27 shows a further embodiment of a cutter.

[0054] FIGS. 1 to 5 let the construction of the cutter head by way of which in particular timber materials, plastics, or light-metal materials or composite materials, respectively, can be subtractively processed.

[0055] Said cutter head is composed of the holder body 1 in which a plurality of clearances 2 that are mutually spaced apart in a regular manner and are open in a radially outward manner are provided. In each case one cutter 10 is clamped in the clearances 2 by means of a clamping jaw 4 and a tensioning screw 3 having a washer 50 onto which an elastic disk 24 is placed. A groove 9 that runs in an axial direction A (transverse axis Q) is incorporated in the clearance 2, the radially outward wall of said groove 9 forming a detent 5 which interacts with a detent face 15 that is provided on the cutter 10. The clamping jaw 4 on the radially inward end thereof has a base 40 which sits in an undercut 8 that is incorporated in the clearance 2. The contour of the undercut 8 is adapted to the contour of the base 40. The circumferential contour of the clamping jaw 4 corresponds substantially to the profile of the cutter 10, so as to prevent a secure support of the cutter 10 during operation and any breaking away of the blade 14.

[0056] A threaded bore 41 into which the tensioning screw 3 can be screwed, and two obliquely running bores 42, 43 into each of which one elastic element 20 can be plug-fitted are provided in the clamping jaw 4. A protrusion 44 that runs in the axial direction A and interacts with a groove 19 that runs in the axial direction A in the chip surface 11 of the cutter 10 is provided on that side of the clamping jaw 40 that faces the groove 9. The groove 19 has the function of an assembly groove. Said groove 19 does not accept any retaining forces. In order for the cutter 10 to be axially positioned, a clearance 101 that emanates from the base 13 on the lower side of said cutter 10 is provided, said clearance 101 being able to be placed onto a positioning pin 26 that can be inserted into a bore 25 that is incorporated in the radial wall of the groove 9. A clearance 30 is provided in the cutter 10 to facilitate assembly when the latter is being inserted. An activation tool for the tensioning mechanism (Torx screwdriver) can be introduced axially into the clearance 30 so as to push the clamping jaw 4 radially inward, counter to the spring force of the elastic elements 20, in the case of a loosely placed cutter 10. The cutter herein by way of the groove 19 is entrained by the form fit and by way of the detent face 15 latches to the detent 5 (cf. FIGS. 7 to 10).

[0057] The cutter 10 on the spine 12 thereof that is opposite the chip surface 11 has a detent face 15 which interacts with the detent 5 that has a radially inwardly directed detent face, is configured in the clearance 2 in the holder body 1 and is provided on the upper wall of the groove 9 that runs in the clearance, or on a protrusion 6, respectively (FIGS. 2, 3). The detent face 15 can be configured on a shoulder 17 (cf. FIG. 13) or on the wall, facing the base 13, of a groove 16 that runs in the axial direction A (transverse axis Q) (cf. FIGS. 14 and 15). The detent face 15 can also be configured on protrusions 18 which are provided either on the shoulder 17 (cf. FIGS. 17 and 19) or in the lower wall of the groove 16. As is shown in FIG. 15, the thickness d of the base 13 of the cutter 10 is greater than the thickness c of the remaining cutter 10 such that the detent face 15 is configured both on the wall of the groove 16 as well as on a shoulder. A slot 100 that extends from the base 13 in the direction of the blade 14 (radial direction) and, as is shown in FIGS. 20 to 22, can have a variable profile, can be introduced so as to be directly adjacent to the clearance 101 that is provided for the axial alignment of the cutter 10, in order to be able to set an elasticity in the axial direction A in the cutter 10. The slot 100 protrudes across the full width of the cutter 10, that is to say that the former extends from the chip surface 11 to the spine 12.

[0058] The spacing a from that wall of the groove 19 that is proximal to the blade 14 to the base is smaller than the spacing b of the detent face 15 from the base 13. In principle, it is advantageous for the grooves 19 and not to run in the same plane because this would weaken the cross section of the cutter 10 to an extent that there can be a risk of breakage. If and when the groove 19 is disposed above the groove 16, the groove 19 lies so tightly on the cutting edge that the profile depth of the cutter 10 would be restricted. The detent face 15 in relation to the longitudinal axis L is inclined at an angle α of 90° to 110°. The angle α is preferably 95°. Elastic elements 23 which protrude beyond the face of the base 13 can be inserted into the base 13 (cf. FIGS. 25 and 26). As is shown in FIGS. 23 and 24, the cutter 10 can be configured as a composite part. To this end, a plate 10a on which the blade 14 is configured is inserted into the blade holder 10b and is fixedly connected, for example soldered/brazed or adhesively bonded, to the latter. The plate 10a is composed of a material of higher quality than that of the blade holder 10b. The cutter otherwise is configured as has been described above.

[0059] In order for the cutter 10 to be assembled and clamped, the latter is initially placed on the clamping jaw 4, by way of the clearance 101 of said cutter 10 is positioned in the axial direction A in relation to the positioning pin 26, and by way of the groove 19 is placed or brought to bear, respectively, on the protrusion 44 that is configured on the clamping jaw 4 (assembly groove). The base 13 of the cutter 10 herein bears on the elastic elements 20 that are plug-fitted in the bores 42, 43 and are composed of an elastomer. The elements 20 which can also be compression springs have a diameter of approximately 2 mm. The cutter 10 and the clamping jaw 4 by way of the groove 19 and the protrusion 44 are interconnected in a form-fitting manner such that the cutter 10 is conjointly pulled if and when the clamping jaw is pushed radially inward. In the case of the clamping jaw 4 being pivoted about the base 40 thereof, the detent face 15 on the cutter 10 and the detent 5 in the clearance 2 are brought into superimposition. The two elastic elements 20 which are plug-fitted in the bores 42, 43 are supported in the holder body 1 such that the clamping jaw 4 is pre-positioned conjointly with the cutter 10. It is also conceivable for only a single elastic element 20 to be used.

[0060] The elastic disk 14 that is composed of an elastomer and is plug-fitted onto the tensioning screw 3 is biased in a radially inward manner in the case of a movement of the cutter 10. If and when the clamping jaw 4 is detressed (let go), the elastic element 24 pushes the cutter 10 radially outward until the detent face 15 comes into contact with the detent 5, the cutter 10 on account thereof being positioned in a radially outward manner. The clamping jaw 4 is further pivoted by driving the tensioning screw 3 into the threaded bore 41 and fixedly clamps the cutter 3 in the clearance 2. Elastic elements 23 which are plug-fitted in the base 13 of the cutter 10 can also be used instead of the elastic elements 20 which are inserted into the bores 42, 43 in the clamping jaw 4 (FIGS. 25, 26).

[0061] The detent face 15 in the case of the embodiment of a cutter 10 that is illustrated in FIG. 27 and is preferably composed of a sintered material is embodied as a protrusion and does not run continuously but is subdivided into two regions to the left and the right of the clearance 101. The detent faces 15 and the spine in one preferred embodiment are untreated post sintering. In order to ensure that defined detent regions exist on the detent face 15, the two regions of the detent face 15 are configured so as to be slightly convex (spherical).

LIST OF REFERENCE SIGNS

[0062] 1 Blade holder [0063] 2 Clearance [0064] 3 Tensioning screw [0065] 4 Clamping jaws [0066] 5 Detent [0067] 6 Protrusion [0068] 8 Undercut [0069] 9 Groove [0070] 10 Cutter [0071] 10a Plate [0072] 10b Blade holder [0073] 11 Chip surface [0074] 12 Spine [0075] 13 Base [0076] 14 Blade [0077] 15 Detent face [0078] 16 Groove [0079] 17 Shoulder [0080] 18 Protrusion [0081] 19 Groove [0082] 20 Elastic element/elastomer element [0083] 23 Elastic element/elastomer element [0084] 24 Elastic element/elastomer element [0085] 25 Bore [0086] 26 Positioning pin [0087] 30 Clearance [0088] 40 Base [0089] 41 Threaded bore [0090] 42 Bore [0091] 43 Bore [0092] 44 Bore [0093] 50 Washer [0094] 100 Slot [0095] 101 Clearance [0096] A Axial direction [0097] a Spacing [0098] b spacing [0099] c Thickness [0100] d Thickness [0101] L Longitudinal axis [0102] Q Transverse axis