EP0266447A1 - Rotating cutter, especially for a plastic granulator - Google Patents

Abstract

1. A rotary cutting tool, more particularly for the continuous granulation of plastics, having a cylindrical tool body (1, 100) formed with a number of longitudinal grooves (2) uniformly distributed in the peripheral direction, each of which contains a releasably inserted, strip-like cutting element (6, 6a, 6b) and a clamping element (7) of wedge shaped cross-section which is disposed in the space, tapering in wedge shape in the direction of the periphery of the tool body (1), between a bearing surface (12) of the cutting element and the side wall (13) of the longitudinal groove opposite said bearing surface and has in cross-section a matching wedge shape tapering in the same direction and is pressed radially outwards by clamping means (16; 17; 18; 22) borne in the zone of the bottom (15) of the longitudinal groove into the space tapering in wedge shape, so that the cutting element is clamped via a clamping surface (11) remote from the clamping element against a seating surface (5) in the zone of the longitudinal groove, characterized in that that part of the cutting element which extends into the longitudinal groove in the tool body or in a member (35) connected thereto and is bounded by the clamping and bearing surfaces (11, 12) has a substantially wedge shaped cross-section tapering in the direction of the periphery of the tool body (1, 100) and having a maximum width smaller than the opening width of the longitudinal groove, and the tool body or the member (35) connected thereto has a bearing surface (14, 140) for the cutting element which determines the radial position of the cutting element.

Description

The invention relates to a rotary cutting tool, in particular for strand pelletizing of plastics, with a cylindrical tool body, which has a number of longitudinally evenly distributed longitudinal grooves, each of which contains a detachable strip-like cutting element and a clamping element which is wedge-shaped in cross section and which in the space between one Support surface of the cutting element and the opposite side wall of the longitudinal groove is arranged and through which the cutting element is braced with a clamping surface opposite the clamping element against a seat in the region of the longitudinal groove.

In a cutting tool of this type known from US-C-4360 168, two strip-like cutting elements are arranged in the lateral recesses of the two side walls of a longitudinal groove, which are clamped by an intermediate wedge, which is penetrated by a clamping screw penetrating it in the direction of the bottom of the longitudinal groove is too moved. The cutting elements are narrow strips on the sides with parallel flanks, which are not supported radially outwards. It is therefore necessary to apply relatively large clamping forces from the wedge-shaped clamping element, which widens towards the circumference of the tool body, in order to ensure that the clamping elements are held securely by friction against the action of the centrifugal forces acting on them. In addition, an exchange of damaged or worn cutting elements is relatively cumbersome because a considerable number of clamping screws have to be loosened over the length of the cutting tool, with the fact that the countersunk holes in the clamping elements containing the clamping screw heads are covered by their own cover elements and, based on experience, are not It can be excluded that the wedge-shaped clamping elements are stuck in the longitudinal grooves after loosening the clamping screws and only have to be loosened with difficulty.

In another rotary cutting tool (DE-A2- 22 08 687), which is designed in the form of a knife shaft for woodworking machines and is therefore not suitable or intended for strand pelletizing of plastics, the narrow, strip-like, laterally parallel-flanking knives are rectangular in cross-section Longitudinal grooves of the knife shaft body stretched. For this purpose, as seen in the direction of rotation of the knife shaft, wedge-shaped clamping elements are arranged in the longitudinal grooves behind the knives, a movable intermediate holder being held in the knife shaft body in a form-fitting manner for transmitting the clamping force applied by the clamping element being provided between a knife and such a clamping element. The against compression springs the bottom of the longitudinal groove supported clamping elements are tapered in cross section to the circumference of the knife shaft body, so that they are pulled outwards under the influence of the centrifugal forces acting on them during operation and thus increase the clamping force for the knives. However, the narrow knives are also held in a positive manner in the radial direction without support even with this measuring shaft, the intermediate holder arranged in each longitudinal groove of the knife shaft body meaning additional effort.

The object of the invention, in contrast, is to provide a concentric cutting tool, in particular for strand pelletizing of plastics, which is distinguished by a particularly simple construction, allows easy and convenient replacement of the cutting elements from the circumferential side of the tool body and, moreover, above all a flawless, ensures secure holding of the cutting tools.

To achieve this object, the cutting tool mentioned at the outset is characterized in that the support surface of the cutting element and the opposite longitudinal groove side wall delimit a space which tapers in the direction of the circumference of the tool body and the clamping element has a corresponding wedge shape which tapers in the same direction and by means of clamping means supported in the area of the longitudinal groove bottom, radially outward into the wedge-shaped tapering space is pressed in and that the clamping element is supported radially in the region of the seat on the tool body or a part connected to it.

Since the wedge-shaped clamping element is clamped directly between the support surface of the cutting element and the opposite longitudinal groove side wall, there is no need for any intermediate holders or elements, so that the cutting element holder is of a very simple construction. The radial support of the cutting elements towards the outside ensures that the centrifugal forces acting on it during operation are reliably absorbed, so that there is always a correct and correct clamping of the cutting elements in the longitudinal grooves. Finally, the assembly and replacement of the cutting elements from the circumferential side of the tool body are effortless: it is sufficient to use a suitable device to press the wedge-shaped clamping element radially inwards against the action of the clamping means or after loosening them in the respective longitudinal groove, with which the clamping element gets rid of its radial support and can be removed freely from the longitudinal groove. The new cutting element only needs to be inserted in the correct position, whereupon the clamping element is made effective, which is pressed radially outwards by its clamping means into the wedge-shaped space between the supporting surface of the cutting element and the opposite longitudinal groove side wall and thus the clamping of the radially supported cutting element on the Tool body guaranteed. The centrifugal forces that then occur during operation cannot affect anyone Release the tension of the cutting elements; at most, they reinforce the clamping forces exerted by the clamping elements.

It is useful if the seat is arranged with its track forming a secant to form a circle representing the outline of the tool body, so that, on the one hand, there are favorable cutting conditions for the cutting elements, and, on the other hand, the radially directed centrifugal forces acting thereon are perpendicular to that Have seat surface acting component that increases the pressure of the clamping surface of the cutting elements on the seat surface. Suitable selection of the position of the plane containing the seat surface with respect to the axis of rotation of the tool body can achieve practically any desired clamping and supporting forces. The support surface and the opposite longitudinal groove side wall can enclose a self-locking acute angle with one another, as a result of which the securing of the holder is further increased.

The seat is advantageously formed in or next to a recess of the tool body that extends laterally from the longitudinal groove, the bottom of which has an abutment for the cutting element. This ensures with simple means that after insertion all cutting elements run with their cutting edges on a common flight circle. To achieve this system, for example, the bottom of the recess or areas of the tool body circumference can be designed as a contact surface for the cutting element, but embodiments are also conceivable in which adjustable adjusting elements are arranged in the bottom of the longitudinal groove allow to tune the system in particular radially to the respective cutting element.

The clamping means pressing the clamping elements radially outwards can have spring means, which in turn can expediently have at least one corrugated spring or at least one spring element made of an elastomeric material. This spring element can be an elongated spring body which is inserted lengthways into the longitudinal groove, but embodiments are also conceivable in which the spring element is a spring pin which is arranged upright on the longitudinal groove base. Alternatively, the spring element can also be at least one spring piston which acts against a gas cushion and acts in the manner of a gas spring.

At least the part of each cutting element that projects into the longitudinal groove and is delimited by the clamping and supporting surface advantageously has a substantially wedge-shaped cross-sectional shape that tapers towards the circumference of the tool body. The clamping and supporting surface can in turn have an acute angle of such a size that on the surfaces of the tool body and the clamping element interacting with them, i. the seat and the support surface, a self-locking effect occurs.

In a preferred embodiment, the two-legged cutting element is essentially L-shaped in cross-section, at least one of its legs having the wedge-shaped cross-sectional shape. The clamping surface is expediently on the inside of the associated leg arranged. In order to increase the material utilization, the cutting element designed as an indexable cutting element can have two legs of the same design, each of which carries a cutting edge.

The tool body can be solid, at least in the outer peripheral regions, so that the longitudinal grooves are machined directly into the material of the tool body. In order to save material and weight, however, it may be expedient, in particular in the case of cutting tools for greater outputs, if the longitudinal grooves are each formed in elongate cutting element carriers which are connected to the tool body or are arranged to form parts thereof.

With a greater axial length of the cutting tool, it is advantageous if the tool body consists of a number of coaxial, annular, axially braced sections and equipped with cutting elements, the cutting elements of which are butt-jointed at the parting joints of the sections, so that the axial length of the cutting tool result in continuous cutting edges. In order to enable the replacement of individual defective cutting elements from the outer peripheral side of individual sections of this tool body, the arrangement is such that adjacent sections on the facing end faces are rotatably connected to one another by fitting elements and spring parts acting in the axial direction are inserted between adjacent sections . This configuration ensures that after releasing the axial tensioning of the individual sections, the spring elements arranged between them automatically push the sections at the joints apart to such an extent that the individual cutting elements of the sections are separated from one another at the end and after the wedge-shaped clamping elements have been pressed down in the one already described Can be removed from the associated longitudinal grooves of the respective section. With axially braced sections of the tool body, this is not readily possible because the cutting elements are also axially braced against one another on the end face.

The tensioning means can also have at least one tensioning screw coupled to the tensioning element and / or the tool body or a part connected to it, which presses the tensioning element radially outward into the wedge-shaped tapering space. Such tensioning screws can be present in addition to the spring means already mentioned, but embodiments are also conceivable in which the tensioning means are only formed by such tensioning screws.

Particularly simple structural conditions are obtained when each clamping screw is inserted into a bore of the clamping element that opens to the circumference of the tool body and is supported against the bottom of the longitudinal groove. However, embodiments are also possible in which the clamping screw, arranged in corresponding recesses or bores in the tool body, press against the respective clamping element from below or are inserted into the tool body or its parts, accessible from the side.

Depending on the circumstances of the respective cutting tool, it can finally be advantageous if the support surface of the cutting element with the adjacent longitudinal groove side wall is arranged substantially flush or only slightly protruding beyond the latter into the groove interior.

Exemplary embodiments of the subject matter of the invention are shown in the drawing. Show it
1 shows a concentric cutting tool according to the invention, in cross section, in detail and in a schematic representation, illustrating four different embodiments of the spring means assigned to the clamping elements, FIG. 2 shows a concentric cutting tool according to the invention, in cross section, in detail and in a schematic representation, FIG. 3 shows the arrangement according to FIG. 2, illustrating another embodiment of the cutting elements in a corresponding illustration, FIG. 4 shows a multi-part tool body of a rotary cutting tool according to the invention, cut along the line IV-IV of FIG. 5 5, the tool body according to FIG. 4, in a side view, FIG. 6 a cutting element carrier for use in the tool body according to FIG. 5, in a perspective representation and on a different scale, FIG. 7 an from me 4.5, a circular cutting tool assembled according to FIG. 4, according to the invention, in a top view, partially cut open and in a schematic representation, FIG. 8 shows two sections of a rotating cutting tool according to the invention, in a perspective schematic representation, and Figures 9,10 a circular cutting tool according to the invention, in cross section, in detail and in a schematic representation, illustrating a modified embodiment of the cutting elements and a clamping element of the arrangement according to Figure 9, in a side view.

The rotary cutting tool shown in FIGS. 1-3 in detail has a solid, essentially sleeve-shaped or circular tool body 1, as is shown in principle in FIG. This tool body 1 is intended - in particular together with other axially connecting, identical tool bodies 1 - to be arranged in a rotationally fixed manner on a shaft which at the end carries shaft journals with which the tool can be rotatably supported in corresponding bearings. The cutting tool is used in particular for strand pelletizing of plastics and is excellently suitable for processing plastics which are difficult to granulate, for example those with admixtures of mineral fibers and the like.

The essentially cylindrical tool body 1 is formed on its circumference with a number of evenly distributed longitudinal grooves 2, which extend over the entire axial length of the tool body 1. The longitudinal grooves 2 form a small angle of approximately 2 ° with the axis of rotation of the tool body 1, as is shown somewhat enlarged in FIG. 7 at 3.

A recess 4 extends laterally from each of the longitudinal grooves 2, which opens towards the periphery of the tool body 1 and whose side surface forms a seat surface 5 for a cutting element 6, 6a or 6b, which together with a clamping element 7 which is wedge-shaped in cross section, in the longitudinal groove 2 is housed.

The strip-like cutting elements 6, 6a, 6b preferably consist of hard metal, stellite or ceramic; they can be constructed in one or more parts, in which case cutting bars made of hard metal or the like are applied, for example soldered, to a corresponding carrier. The cutting elements 6, 6a, 6b are basically arranged in the tool body 1 in such a way that their effective cutting edges 8 run on a common flight circle.

In the embodiment according to FIG. 1, each of the cutting elements 6 is essentially L-shaped in cross section. It is therefore two-legged; his two legs are labeled 9 and 10. The two legs 9, 10 are each essentially wedge-shaped in cross-section, the leg 10 lying in the longitudinal groove 2 having a wedge shape tapering towards the peripheral surface of the tool body 1. It is delimited on one side by a clamping surface 11 resting on the seat surface 5 and on the opposite side by a support surface 12, on which the wedge-shaped clamping element 7 acts, which in turn counteracts that of the support surface 12 lying side surface 13 of the longitudinal groove 2 is supported. With its leg 10, the cutting element 6 also lies on the base surface 14 of the associated recess 4, which thus forms a stop surface for the cutting element 6.

The space delimited by the support surface 12 of each cutting element 6 and the opposite longitudinal groove side wall 13 is tapered towards the circumference of the tool body 1. The corresponding wedge-shaped clamping element 7, which tapers in the same direction, is pressed into this space by spring means which are arranged between the underside of the clamping element 7 and the bottom 15 of the longitudinal groove 2.

Of these spring means, four different embodiments are illustrated in FIG. 1, which can be used alternatively:

In the longitudinal groove 2 shown on the left, the spring means are formed by at least one spring element made of an elastomeric material in the form of an elongated, cylindrical spring body 16, which is inserted lengthways into the longitudinal groove 2.

A corrugated or leaf spring 17 is inserted as a spring element in the longitudinal groove 2 adjoining on the right, while at least one spring piston 18 is arranged in the longitudinal groove 2 following on the right as a spring means projects with a cylindrical piston neck 19 into a gas-filled cylinder space 20 formed in the tool body 1, which is sealed against the piston neck via a corresponding sealing wall 21. The spring piston 18 thus acting against a gas cushion is thus fundamentally similar to a gas spring.

In the longitudinal groove illustrated on the far right, the spring means are formed by spring pins 22 made of elastomeric material, which are inserted upright into corresponding bores 23 in the groove base 15.

The recesses 4 receiving the legs 10 of the cutting elements 6 are arranged in the tool body 1 in such a way that each seat surface 5 is formed with its trace a secant to form a circle representing the outline of the tool body 1 Centrifugal forces therefore have a component which is at right angles on the seat 5 and which strives to press the leg 10 against the seat 5 with the clamping surface 11. The cutting elements 6 are supported radially on the tool body 1 by the inclined seating surfaces 5 and the cooperating, likewise inclined clamping surfaces 11.

The support surface 12 and the opposite longitudinal groove side wall 13 of each longitudinal groove enclose an acute angle, which results in a self-locking effect for the wedge-shaped clamping element 7, the size of which depends in individual cases on the material pairing that applies to the superimposed surfaces. Similarly, the clamping and support surface 11 and 12 of each cutting element 6 limit an acute angle of such a size that there is also a self-locking effect.

As can be seen from FIG. 1, the clamping surface 11 of the cutting elements 6, which are essentially L-shaped in cross section, is arranged on the inner side of the associated leg 10. The L-shaped cross-sectional shape of the cutting elements 6 brings with it the advantage of high stability of the cutting elements, while at the same time the region of the circumference of the tool body 1 which adjoins the cutting edge 8 in the cutting direction and which is, according to experience, particularly highly stressed, by the outer surface of the leg 9 of the respective made of hard metal, etc. existing cutting element is formed and is therefore particularly resistant. In the cutting direction in front of the cutting edges 8, flutes 24 are finally formed in the circumferential surface of the tool body 1 in the usual manner.

The embodiment illustrated in FIG. 2 differs from that according to FIG. 1 in that the cutting elements 6a are designed as so-called indexable cutting elements. The two legs 9, 10 the strip-like cutting elements 6a, which otherwise correspond essentially to the cutting elements 6, are both designed identically; each of them carries a cutting edge 8.

Each of the recesses 4 is designed with its seat 5 and its bottom surface 14 to match the shape of the two legs 9, 10, but the contact surface 14a is arranged next to the longitudinal groove 2 on the circumference of the tool body 1. The same parts are therefore provided with the same reference numerals, so that a repeated discussion is unnecessary.

Finally, in the embodiment according to FIG. 3, the strip-shaped cutting elements 6b are formed in one leg with an essentially wedge-shaped cross-sectional shape, the surfaces 11, 12 which laterally delimit the wedge shape being tapered radially outward.

1.2 but the wedge-shaped clamping element 7 is arranged on the side of the leg 10 of the cutting element 6 or 6a facing away from the cutting edge 8, in the embodiment according to FIG. 3 the arrangement is such that the Clamping element 7 on the clamping surface 11 of the cutting element 6b containing the cutting edge 8, ie attacks on its front.

To replace one of the cutting elements 6, 6a, 6b in the tool body 1, it is sufficient to use a suitable device to press the clamping element 7 from the circumference of the tool body 1 radially inward against the action of the spring means to such an extent that the leg 10 or the cutting element 6b is released and can be removed from the longitudinal groove 2 unhindered and replaced by a new cutting element. This new cutting element can be made to measure outside the tool body 1. When the clamping element 7 is depressed, it is simply pushed into the recess 5 until it stands on the stop surface 14. Then the clamping element 7 is released, which is pressed by the spring means into the wedge-shaped space between the surfaces 12, 13, whereby the cutting element 6, 6a, 6b is clamped with its clamping surface 11 against the seat surface 5 of the tool body 1. The centrifugal forces that occur during operation endeavor to pull the tensioning element 7 outwards, whereby the tension of the cutting elements 6, 6a, 6b is further increased. Because of the inclined position of the seat surfaces 5, which deviates from the radial direction, the cutting elements are, at the same time, as already explained, supported radially outward in a form-fitting manner.

In the modified embodiment of the new cutting tool shown in FIGS. 4-7, the tool body is designed in the manner of a so-called rotor 100. The rotor 100 consists of a number of annular disks 30 which are clamped axially to one another by means of clamping bolts 31 in the manner shown in FIGS. 4 and 7. The arrangement is such that between the two outside Ring washers 30 spacer sleeves 32 are arranged, through which the clamping screws 31 run, which are screwed into corresponding threaded bores 32 of a centrally arranged hub disk 33, on which two further ring washers 30 rest on the end face. The rotor 100 is covered on both end faces by cover caps 34 and, moreover, is placed on a shaft (not shown) in a rotationally fixed manner.

The ring disks 30 are provided on their circumference with open-edge grooves 200 which are aligned with one another over the axial length of the rotor 100. Rail-shaped or strip-shaped cutting element carriers 35, as are illustrated in detail in FIG. 6, are inserted into the grooves 200 of adjacent annular disks 30.

Each of the cutting element supports 35 has two end flanges 36 which are substantially rectangular in cross section and which have holes 37 for fastening screws 38 which are screwed into corresponding threaded holes 39 on the bottom of the grooves 200 and are adapted to the shape of the grooves 200. In the area between the end flanges 36, each cutting element carrier 35 is chamfered at 40 to ensure that the granulate produced can pass freely.

The cutting element carriers 35 are each designed with a continuous longitudinal groove 2 that is in the area between the end flanges 36 has the cross-sectional shape shown in FIGS. 1-3. In it, the respective cutting element 6 (or 6a or 6b) is clamped by a wedge-shaped clamping element 7 in the manner shown in FIGS. 1 and 3.

The cutting element carriers 35 arranged on adjacent pairs of annular disks 30 are arranged with their cutting elements 6 butt-abutting, so that continuous cutting edges 8 result over the length of the rotor 100, which include the small angle 3 (FIG. 7) with the rotor axis of rotation 41.

Taper dowel pins 42 (FIG. 4) ensure an exact angular alignment of the ring disks 30 relative to one another.

In the embodiment schematically illustrated in FIG. 8, the cutting tool consists of several coaxial sections, each of which is formed by a tool body 1, as has already been explained with reference to FIGS. 1-3. These tool bodies 1 are non-rotatably mounted on a common shaft (not shown in FIG. 8) and axially clamped thereon, for example by a threaded ring. Between adjacent sections, each formed by a tool body 1, axially parallel, cylindrical locating pins 44 and locating holes 45 associated therewith are arranged in the region of the end faces facing one another. Between Dowel pins 44 are provided in corresponding bores 46 compression springs 47, which strive to axially press the tool body 1 apart.

If a cutting element 6 of one of the tool bodies 1 has to be exchanged in a cutting tool consisting of such sections, the axial bracing of the sections is released, with the result that the compression springs 47 can axially push apart the tool body 1 forming the sections to such an extent that the cutting elements thereof Sections come free from each other on the end face and can be released and exchanged in the manner already described by depressing the tensioning elements 7.

Of course, the idea of facilitating the exchange of the individual cutting elements 6 in this way is not only applicable to solid tool bodies 1; it can also be transferred to the rotor 100 according to FIG. 7, in which case spring elements corresponding to the compression springs 47 are to be arranged between the annular disks 30 which are not connected to one another by cutting element carriers 5.

Finally, the radial support of the cutting elements 6, 6a, 6b on the tool body 1 or the cutting element carrier 35 can also take place in a form-fitting manner by means of an extension 50 of the cutting element, as is indicated schematically in FIG. 1.

In the embodiment shown in FIGS. 9, 10, the cutting element 6, which is essentially L-shaped in cross section, is designed essentially as in FIG. 1. The same parts are also designated here with the same reference numerals and are not further explained in detail.

The recess 4 is so deep in the circumferential direction of the tool body 1 that the leg 10 of the cutting element 6 tapering in a wedge-shaped manner toward the circumferential surface of the tool body 1 is received essentially entirely in the recess 4. Its support surface 12 projects only slightly beyond the adjacent longitudinal groove side wall into the interior of the longitudinal groove 2. With a corresponding design of the tensioning element 7 with a laterally projecting shoulder resting on the support surface 12, it could also be aligned with the adjacent longitudinal groove side wall. In the exemplary embodiment shown, the wedge-shaped clamping element 7 has two bores 52 arranged at a distance, which open to the circumference of the tool body 1 and each of which receives a clamping screw 51. The clamping screw 51 is screwed into a threaded bore 53 in the bottom of the bore 52 and is supported against the bottom 15 of the longitudinal groove 2. Spring elements can be arranged between the tensioning screws 51, as explained in detail with reference to FIG. 1, but it is also possible to dispense with these spring elements in certain applications.

In order to replace such a cutting element 6, the clamping screws 51 provided with a hexagon socket are loosened through the bore 52 from the circumference of the tool body, so that the clamping element 7 can be pushed downwards in the longitudinal groove 2. Thus, it comes free from the support surface 12 of the cutting element 6 because of its wedge-shaped shape, to the extent that the cutting element 6 with its wedge-shaped leg 10 can be removed from the recess 4 towards the circumference of the tool body. After the insertion of a new cutting element 6, only the clamping screws 51 need to be tightened, which, on the longitudinal groove bottom 15, press the clamping element 7 radially outward via their thread and thus clamp the cutting element 6.

If additional spring means 16, 17, 18, 22 are present, these first take on the task of pushing the tensioning element 7 radially outward into the tensioning position, the tensioning screws 51, which are then tightened, still further increasing the tensioning action and thus one result in additional security.

Claims (21)

1.Rotary cutting tool, in particular for strand pelletizing of plastics, with a cylindrical tool body which has a number of longitudinally evenly distributed longitudinal grooves, each of which contains a releasably inserted, strip-like cutting element and a clamping element which is wedge-shaped in cross section and which is located in the space between a support surface of the cutting element and the side wall of the longitudinal groove opposite this and through which the cutting element is braced with a clamping surface opposite the clamping element against a seat surface in the region of the longitudinal groove, characterized in that by the support surface (12) of the cutting element (6, 6a, 6b ) and the opposite longitudinal groove side wall (13) is limited to the circumference of the tool body (1) tapered space and the clamping element (7) has a corresponding wedge shape tapering in the same direction and through in the area of the longitudinal groove base (15) supported clamping means (16; 17; 18; 22) is pressed radially outwards into the wedge-shaped tapered space and that the clamping element (7) is supported radially in the region of the seat surface (5) on the tool body (1) or a part (35) connected to it. 2. Cutting tool according to claim 1, characterized in that the seat (5) is arranged with its track forming a secant to form the outline of the tool body (1) forming a circle. 3. Cutting tool according to claim 1 or 2, characterized in that the support surface (12) and the opposite longitudinal groove side wall (13) enclose a self-locking resulting acute angle with each other. 4. Cutting tool according to one of the preceding claims, characterized in that the seat surface (5) in or next to a laterally from the longitudinal groove (2) outgoing recess (4) of the tool body (1) or a part (34) connected thereto is formed whose bottom (14) has a system for the cutting element (6, 6a, 6b). 5. Cutting tool according to claim 4 or 5, characterized in that the recess (4) or the tool body (1) has a contact surface for the cutting element (6, 6a, 6b). 6. Cutting tool according to one of the preceding claims, characterized in that the clamping means have spring means (16, 17, 18, 22). 7. Cutting tool according to one of the preceding claims, characterized in that the spring means have at least one corrugated spring (17). 8. Cutting tool according to claim 6, characterized in that the spring means have at least one spring element (16; 22) consisting of an elastomeric material. 9. Cutting tool according to claim 8, characterized in that the spring element is an elongated spring body (16), which is inserted lengthways into the longitudinal groove (2). 10. Cutting tool according to claim 8, characterized in that the spring element is a spring pin (22) which is arranged upright on the longitudinal groove bottom (15). 11. Cutting tool according to claim 8, characterized in that the spring element is a spring piston (18) acting against a gas cushion. 12. Cutting tool according to one of the preceding claims, characterized in that at least the part of the cutting element (6, 6a, 6b) projecting into the longitudinal groove (2) and delimited by the clamping and supporting surface (11, 12) has a substantially wedge-shaped, has a cross-sectional shape tapering towards the circumference of the tool body (1; 100). 13. Cutting tool according to claim 12, characterized in that the clamping and the support surface (11, 12) one in cooperation with the associated surfaces of the tool body (1) or a part connected to this (35) and the clamping element (7) one Includes self-locking resulting acute angle. 14. Cutting tool according to claim 12, characterized in that the two-legged cutting element (6, 6a) is designed in cross section essentially L-shaped and at least one of its legs (10) has the wedge-shaped tapering cross-sectional shape. 15. Cutting tool according to claim 14, characterized in that the clamping surface (11) is arranged on the inner side of the associated leg (10). 16. Cutting tool according to claim 12 or 14, characterized in that the cutting element designed as an indexable cutting element (6a) has two identically shaped legs (9, 10), each of which carries a cutting edge (8). 17. Cutting tool according to one of the preceding claims, characterized in that the longitudinal grooves (2) are each formed in elongated cutting element carriers (35) which are connected to the tool body (1, 100) or arranged to form parts thereof. 18. Cutting tool according to one of the preceding claims, characterized in that it consists of a number of coaxial, annular, axially braced and with cutting elements (6, 6a, 6b) equipped sections (1), the cutting elements (6, 6a, 6b) at the parting lines of the sections are arranged so as to abut one another in such a way that adjacent sections (1) are connected to one another in a rotationally fixed manner on the mutually facing end faces by fitting elements (44, 45) and spring parts (47) are inserted between adjacent sections (1) in the axial direction. 19. Cutting tool according to one of the preceding claims, characterized in that the clamping means at least one with the clamping element (7) and / or the tool body (1) or a clamping screw (51) coupled to this part. 20. Cutting tool according to claim 19, characterized in that each clamping screw (51) is inserted into a bore (52) of the clamping element (7) which opens to the circumference of the tool body and is supported against the bottom of the longitudinal groove (7). 21. Cutting tool according to one of the preceding claims, characterized in that the support surface (12) of the cutting element (6, 6a, 6b) with the adjacent longitudinal groove side wall is substantially aligned or only slightly projecting over this in the groove interior.

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