DE3521799A1 - Machine-tool spindle and matching tool holder - Google Patents

Abstract

A machine-tool spindle (1) serving to alternately accommodate tool holders (13) with different shanks (8, 16) has in its spindle head (1a) a frustoconical location bore (3) for accommodating a steep-taper shank of a first tool holder. The spindle head (1a) is provided with an end face (4) surrounding the frustoconical location bore (3). Directly adjoining this end face, a mating bore (8) is provided whose diameter (D) is slightly larger than the theoretical diameter of the frustoconical location bore (3) in the plane of the end face (4). The axial length of the mating bore (8) is only about 10-15% of the theoretical diameter. The mating bore (8) serves to accommodate a cylindrical mating extension (15) of the second tool holder (13). <IMAGE>

Description

The invention relates to a machine tool spindle and matching tool holder with different sheep which can be used alternately in the spindle head, which has a truncated cone-shaped receiving bore for receiving me of a steep taper shank of a first tool holder, an end face surrounding the receiving bore and Area of the frusto-conical receiving bore a cylin Drical fitting hole for receiving a cylindrical passer has set on the shaft of a second tool holder, that at one end of the pass with a con to this centric flange and at the other end of the fitting approach with a with the flange on the end face Engage play in the frustoconical mounting hole the truncated cone is provided, one in the spindle Tension rod is provided, which in the to the mounting hole a collet or a thread wears, each with one at the free end of each Provided pull stud or thread together works.

Such a machine tool spindle became the occasion a VDMA conference on April 26, 1985 in Frankfurt published (documents from VALENITE-MODCO GmbH, D-6920 Sinsheim / Elsenz, "VAL clamping unit for flexible Production").

Such a known machine tool spindle is used for optional mounting of a tool holder with conventional chem steep taper shank (DIN 2080 or 69871) or one new like tool holder, which is then attached to a flange has a cylindrical fitting pin. Tool holder with Steep taper shafts usually also have a flange, often with a circumferential trapezoidal groove to attack the changing arm of an automatic tool changer  is determined. For tool holders with steep taper shanks however, the flange is usually not on the forehead surface of the spindle. The tool holder is supported rather only with its steep taper in from the truncated cone-shaped receiving bore of the spindle. If now through this frusto-conical receiving hole Arrangement of the cylindrical fitting hole on about half their length is removed, then a large part of the Contact surface between the steep taper shank and the taper truncated bore. Which anyway regarding the power transmission with today's requirements one Fixed connection between tool holder and spindle is thereby adversely affected even more. Also is the centering effect between steep taper shank and frustoconical mounting hole in today's Insufficient accuracy requirements. However, becomes a Tool holder with a cylindrical fit in the spindle better centering is used between tool holder and machine tool spindle is enough, but the support of this tool neck ters across the spindle axis is no longer as good as the cylindrical fitting bore only at a greater distance starts from the spindle face. Furthermore, points the well-known tool holder with a cylindrical fitting shoulder two diametrically opposed clamping pieces, which in Slidably mounted to the spindle axis in the radial direction are. There is between the inner ends of these clamping pieces an axially movable wedge is provided which with a pull stud protruding from the truncated cone connected is. The collet grips the pull stud which is slidably mounted in the machine tool spindle tension rod. By their axial displacement the clamping pieces are extended in the radial direction, at the outer ends provided inclined surfaces in bevelled, worked into the wall of the fitting bore Intervene. This will put the flange on  pressed against the end face of the spindle. A disadvantage of that This facility is the fact that none is special high repeatability when changing tools holder is reached. This is due to the fact that despite very tight tolerances between the fitting approach and the fitting bore still some play between the two Parts must be available. Since the two clamping pieces on radially opposite sides of the fitting approach will drive counteract the approach to the pass directions use approximately equal reaction forces. Depending on the friction between the slant the fitting pin will be flat opposite the fitting hole orient so that it is either in the area of one Clamping piece or in the area of the opposite Clamping piece rests on the fitting bore. However, it can also happen that the passport approach any intermediate takes position between the two extreme positions. This affects the exchange tolerance and thus the re-entry fetching accuracy when changing the same again Tool holder or various tool holder entirely essential.

The invention has for its object a tool machine spindle and matching tool holder different shafts of the type mentioned in the introduction to improve in that when using a tool holder with steep taper shank the connection between the sem and the machine tool spindle as little as possible is impaired and when using a tool holder optimal cross-support with a cylindrical extension is achieved with high centering accuracy. Beyond that the repetition accuracy when replacing should also the tool holder can be improved.  

This object is achieved according to the invention in that the fitting hole is directly on the forehead area adjacent and its diameter slightly larger is the truncated cone as the theoretical diameter shaped receiving hole in the plane of the end face and that the axial length of the fitting bore is only about 10-15% of the theoretical diameter.

Since the fitting bore is only a relatively short axial Has length, goes through the fitting hole only ratio moderately little of the frustoconical bore lost. When using a tool holder with steep Taper shank is therefore despite the cylindrical fitting bore a relatively large investment area between the Steep taper shank and the frustoconical receptacle bore available so that the connection between steep taper shank and machine tool spindle through the cylin drische fitting bore is hardly affected. The arrangement the fitting hole immediately adjacent to the forehead The surface of the machine tool spindle has when using Tool holders with a cylindrical fitting approach have the advantage that the cross support of the tool holder in immediate real neighborhood of the face. Across The transverse forces acting on the spindle axis are thus optimally reduced Transfer tool holder to the spindle and vice versa. This is particularly the case with tool holders with a cylindrical one Fit approach important because of this tool holder the wide support of their flange on the face the machine tool spindle for transferring high bear workers are particularly suitable. Furthermore it is also possible to adjust the tolerance between the cylindri passport approach and the cylindrical fitting bore particularly keep tight because of the small axial length of both Divide them very little in the axial direction must be shifted from one another.  

A particularly advantageous embodiment of the invention is that in the truncated cone in the area of the pass approach a clamping piece in a radial guide ver is slidable by means of one at its inner end attacking, with the axially displaceable in the truncated cone Pull bolt connected wedge surface is radially movable and at its free outer end with a pressure surface is provided on a provided on the spindle Counter surface is pressed.

The use of only one clamping piece has the advantage that when extending and pressing the clamping piece to the Counter surface on the cylindrical fitting approach a reaction force is exerted on the the clamping piece diametrically opposite side to the fitting hole Plant brings. The tool holder comes with it each change process automatically in a clearly defined Always on the same side of the fitting hole. Here due to very low exchange tolerances with a high repeatability achieved.

Further advantageous embodiments of the invention are characterized in the remaining subclaims.

The invention is in the following, based on in the drawing tion illustrated embodiments explained in more detail. It shows:

Fig. 1 shows a first embodiment, partially cut in the longitudinal,

Fig. 1a details of the location a of Fig. 1 on a larger scale

Fig. 2 shows a second embodiment, partially in longitudinal section;

Fig. 3 is a partial section along the line III-III of Fig. 2,

Fig. 4, the machine tool spindle according to the invention with inserted conventional taper shank,

Fig. 5 u. 6 two further exemplary embodiments in longitudinal section.

The machine tool spindle 1 is rotatably mounted in the headstock 2 . On its spindle head 1 a , the machine tool spindle 1 has a truncated cone-shaped receiving bore 3 which is designed in accordance with DIN 2079 or the corresponding ISO standard. The receiving bore 3 is surrounded by a flat, annular end face 4 that runs perpendicular to the spindle axis A. In a central bore of the spindle 1, a tension rod is also mounted axially displaceably 5, which is at its front end in the Be 3 reaching the frusto-conical receiving bore a collet 6 bears and against the force of not represent recorded disc springs to the spindle head 1 a toward axially ver slidably ( Figs. 2 and 4).

As shown in Fig. 1, the clamping rod 5 a instead of the collet 6 could also have a thread 7 and be rotatably mounted in the spindle 1 .

Immediately adjacent to the end face 4 a , the spindle head 1 a has a cylindrical fitting bore 8 in the region of the receiving bore 3 . The diameter D of this fitting bore is only slightly larger by about 1 mm than the theoretical diameter d 1 , which the truncated cone-shaped receiving bore 3 would have in the plane of the end face 4 . This theoretical diameter d 1 is specified in DIN 2079 and is, for example, for spindle head size No. 50 / 69.95 mm. Details regarding this theoretical diameter d 1 and the diameter D of the fitting bore 8 are shown in Fig. 1a. The Paßboh tion 8 is relatively short out in the axial direction, its axial length L , measured from the end face 4 , should be about 10-15%, preferably about 12%, of the theoretical diameter d 1 . The diameter D of the fitting bore 8 is made with a tolerance of + 0.002- + 0.005 mm.

In the machine tool spindle 1, a first tool holder 9, which at its free end 9 a a non Darge notified any tool, beisielsweise head a drilling, a boring tool, a milling cutter, a reamer od. Like. Can bear, with its taper shank 10, which is designed in accordance with DIN 2080 or 69871, can be inserted into the frustoconical receiving bore 3 . At the rear, free end of the steep taper shank 10 , a pull stud 11 according to DIN 69872 can be arranged, on which the collet 5 engages. Under the action of the disc springs, the steep taper shank 10 is drawn into the spindle 1 and pressed against the frustoconical receiving bore 3 . The flange 9 a , with the trapezoidal groove for a gripper of an automatic tool changer 12 , is located at a distance from the end face 4 , since it is not possible for manufacturing reasons to manufacture the machine tool spindle 1 or the most diverse tool shafts that both the steep taper shank 10 abut the receiving bore 3 and the flange 9 b on the end face 4 .

In Fig. 1, a second tool shaft 13 is shown, at the free end 13 a in turn a tool, not shown, is arranged. The tool holder 13 also has a flange 13 b .

The tool holder 13 has a cylindrical fitting shoulder 15 immediately adjacent to the flange 13 b , which should fit into the fitting bore 8 with the smallest possible radial tolerances. The diameter of the fitting shoulder 15 is made with a tolerance of approximately -0.003 mm. The axial length of the fitting shoulder 15 , measured from the annular surface 13 c of the flange 13 b , is slightly shorter by about 0.5 mm than the axial length of the fitting bore 8 , so that it is certain that the tool holder 13 is always with its annular surface 13 c fits snugly against the end face 4 of the spindle head 1 a , without the fitting shoulder 15 being seated at the bottom of the fitting bore 8 .

At the fitting approach 15 is a truncated cone 16 , but which is dimensioned such that between the outer surface of the truncated cone 16 and the truncated cone-shaped receiving bore 3 is some play when the annular surface 13 c abuts the end face 4 . At the free end 16 a of the truncated cone, in turn, similar to FIG. 4, a pulling bolt interacting with a collet can be seen, or, as shown in FIG. 1, an internal thread 17 into which the clamping rod 5 a its external thread 7 can be screwed. In this case, the tension rod 5 a is only rotatable, but not axially displaceably mounted in the spindle 1 , and the tool holder 13 is drawn into the spindle head 1 a under the action of the interlocking thread 7 , 17 . The tool holder 13 is precisely centered with respect to the spindle 1 by means of the fitting shoulder 15 which engages in the fitting bore 8 . In addition, the flange 13 b with its ring surface 13 is pressed against the end face 4 . Since the cone 16 bluntly engages in the receiving bore 3 , the ring surface 13 c is pressed against the end face 4 with the full clamping force of the tension rod 5 a or the thread 7 , 17th Lateral forces acting on the tool holder 13 are transmitted in the immediate vicinity of the end face 4 via the fitting shoulder 15 and the fitting hole 8 on the spindle. To transfer the torque element can also be arranged on the spindle head 1 a with the usual slave blocks according to DIN 2079, which engage two diametrically opposed driver grooves 18 in the flange 13 b .

When the tool holder 13 is introduced into the spindle head 1 , the truncated cone 16 initially serves as a rough guide. The truncated cone 16 in the frustoconical receiving bore 3 causes a pre-centering of the tool holder. However, since there is a step between the cylindrical Paßan set 15 and the largest diameter of the truncated cone 16 , it is expedient to provide a chamfer 19 between the end face 6 and the cylindrical fitting bore 8, which chamfer can extend, for example, at 45 ° relative to the spindle axis A. The radial extent of this chamfer must be at least as large as half the diameter difference between the fitting shoulder 15 and the largest diameter of the truncated cone 16 in the region of the fitting shoulder 15 . The chamfer 19 has a centering effect on the fitting shoulder 15 and facilitates its insertion into the fitting bore 8 . Instead of the chamfer 19 on the spindle head 1 a , a correspondingly large chamfer could also be provided at the transition between the fitting shoulder 15 and the truncated cone 16 . It would also be conceivable to provide a chamfer 19 both on the spindle head and a chamfer on the cylindrical fitting shoulder 15 , in which case the radial dimensions of the two chamfers together would have to be somewhat larger than half the difference in diameter between the fitting shoulder 15 and the largest diameter of the truncated cone 16 .

The force of the plate springs acting on the tension rod 5 is fixed in existing machine tools and cannot be increased arbitrarily for spatial reasons. For this reason and above all, in order to increase the repeat accuracy with multiple tool changes, ie to keep the change tolerance as low as possible, the clamping device shown in FIG. 2 is expediently provided. In this clamping device is a truncated cone 16, a cylindrical clamping piece 20 in a serving as Füh tion transverse bore 21 is radially displaceable. The clamping piece 20 has at its outer end a truncated cone 20 a or an inclined surface to the spindle axis A de inclined surface. The clamping piece 20 also has a longitudinal slot 22 , which ends in a wedge surface 23 extending obliquely to the spindle axis A. In an axial bore 24 of the truncated cone 16 , a wedge 25 is axially displaceable. The wedge 25 is supported with its back 25 a in the axial bore 24 . the wedge 25 is firmly connected to the pull stud 26 . A compression spring 27 presses on a cylindrical collar 28 provided between the pull stud 26 and the wedge 25 and thus tries to press the wedge in the direction of the fitting shoulder 15 . Furthermore, the wedge 25 has an elongated hole 29 which extends parallel to the wedge surface 25 b . A cross pin 30 fastened in the tensioning piece 20 engages in this slot 29 with play. A screw 31 is screwed radially into the spindle head 1 a and has a truncated cone-shaped recess 32 . The tip angle of this frustoconical recess 32 and the frustoconical end 20 a of the clamping piece 20 are the same size. The axis A 1 of the clamping piece 20 is arranged at a distance a 1 from the annular surface 13 c , which is somewhat smaller than the distance a 2 of the axis A 2 of the screw 31 from the end face 4 . The embodiment of the tool holder 13 shown in Fig. 2 'with respect to the flange 13 b, the Paßansatzes 15 and the Kegelstum PFEs 16, as well as other parts corresponds to the embodiment shown in FIG. 1, and therefore the same reference numerals have been used for entspre sponding parts and the above description is to be applied accordingly.

As long as the tool holder 13 'is not clamped in the spindle 1 , the wedge 25 under the action of the spring 27 is pressed forward in the direction of the fitting shoulder 15 ge. About the slot 29 and the cross pin 30 , the clamping piece 20 is held with its frustoconical end 20 a within the truncated cone 16 . If the pull stud 26 is gripped by the collet 6 and pulled through it in direction B , then the wedge 25 also moves in the direction B , its wedge surface 25 b sliding along the wedge surface 23 of the clamping piece 20 and pushing it radially outward . Here, the frustoconical end 20 a bears against the frustoconical recess 32 . Due to the axial Ver set of the axes A 1 and A 2 , the annular surface 13 c is pressed against the end face 4 . The wedge surfaces 23 and 25 b or the surfaces of the truncated cones 20 a and 32 cause an increase in the clamping force generated by the plate springs acting on the tension rod 5 . However, it is also important that a reaction force R in the radial direction results from the abutment of the frustoconical end 20 a on the frustoconical recess 32 , which always gives the fitting shoulder 15 at a point diametrically opposite the screw 31 in the same direction to the fitting bore 8 presses. As a result, the desired high repeatability is achieved with small change tolerances. The clamping piece 20 has been shown in FIG. 2 for the sake of clarity at a distance from the fitting shoulder 15 . However, it should be arranged as close as possible to the fitting shoulder 15 in order to avoid possible tipping forces which could arise from the one-sided radial extension of the clamping piece 20 . If the clamping piece 20 is brought closer to the fitting shoulder 15 , the axial length of the truncated cone 16 can also be shortened.

Instead of the trapezoidal groove 12 shown in FIG. 4, another engagement surface for the arm of an automatic tool changer can be provided on the flange of the respective tool holder 13 , 13 'according to FIGS . 1 and 2. This is preferably a radial thread 14 for a grip of the clamping screw of a prism-shaped gripper, as shown in FIGS. 1 and 2 of the European patent application, publication no. 0 125 529.

In FIGS. 5 and 6 are two further execution of the invention examples shown, which differs from that shown in Fig. 2 and 3 embodiment in Wesent union by the design of the clamping pieces and the cooperating with the clamping piece parts. The design of the tool holder shown in FIGS . 5 and 6 13 '' with respect to the flange 13 b of the fitting shoulder 15 and the truncated cone 16 and other parts, corresponds to the embodiment shown in Fig. 1, which is why the same reference signs for the corresponding parts were used and the above description is to be applied accordingly.

In the embodiment shown in FIG. 5, a cylindrical clamping piece 40 is guided radially displaceably in a transverse bore 41 in the truncated cone 16 . The clamping piece 40 has at its inner end a wedge surface 42 which includes an angle α of 45 ° with the spindle axis A, for example. The pull bolt 26 , which is axially displaceable in the truncated cone 16, has a recess 43 with a wedge surface 44 which is inclined at the same angle with respect to the spindle axis and interacts with the wedge surface 42 . So that the clamping piece 40 cannot inadvertently emerge from the transverse bore 41 when the tool holder 13 '' is outside the spindle 1 , the clamping piece is provided with an elongated hole 45 into which a cross pin 46 fastened in the truncated cone 16 engages.

On the spindle 1 , a counter surface 47 cooperating with the clamping piece 40 is provided. This counter surface 47 forms the part of a recess which was created by means of an end mill 48 , which is shown in broken lines in FIG. 5. The axis C of the end mill 48 is inclined at an acute angle with respect to the spindle axis A , so that the mating surface 47 generated by the end mill is inclined at an acute angle β with respect to the spindle axis A. The angle β should be at least 45 °, preferably about 60 °. At the outer end of the pressure piece 40 , a pressure surface 49 inclined at the same angle β is arranged, this pressure surface 47 having a curvature which corresponds to the curvature of the counter surface 47 and thus the radius of the end mill 48 .

If the pulling bolt 26 is moved in direction B by means of a pull rod, not shown, acting on it via a collet or preferably a thread, then the clamping piece 40 moves under the action of the wedge surfaces 42 , 44 in the radial direction. Its pressure surface 49 is pressed against the counter surface 47 , a force 5 component being generated in the radial and in the axial direction. The axial force component increases the pressure of the annular surface 13 c on the end face 4 of the spindle 1 . The radial force component generates a reaction force R in the radial direction, which always presses the fitting shoulder 15 at the location diametrically opposite the clamping piece 40 in the same direction on the fitting bore 8 . As a result, the desired high repeatability is achieved with low exchange tolerances. It is important here at that the transverse bore 41 still partially extends into the cylindrical fitting shoulder 15 , so that the pressure surface 49 acts in the area of the cylindrical Paßan set 15 on the counter surface 47 . As a result, who avoided the tilting forces that could arise from the one-sided extension of the clamping piece 40 .

The tool holder 13 'shown in Fig. 6''is formed in a similar manner as the previous embodiment, which is why the same reference numerals have been used again for parts of the same function. The cylindrical clamping piece 50 is in a radial Querboh tion 51 of the tapered shaft 16 slidably, the transverse bore 51 also extends into the area of the fitting shoulder 15 . On the pull stud 26 , a wedge surface 52 is provided which cooperates with a corresponding wedge surface 54 at the inner end of the clamping piece 50 . The angle α 1 , which the wedge surfaces enclose with the spindle axis A , should be as large as possible, so that only a limited radial clamping of tool holder 13 '' with the spindle 1 is achieved by the clamping piece 50 . However, self-locking on the wedge surfaces 52 , 54 must not occur. The clamping piece 50 is hollow and has in its interior a screw 53 which is screwed into the pull stud 26 . Furthermore, a return spring 55 is provided, which exerts a radially inward restoring force on the clamping piece 50 . At the radially outer end of the clamping piece 50 , a pressure surface 59 is provided which interacts with the fitting bore 8 . For this reason, the pressure surface 59 is curved in the circumferential direction of the fitting shoulder 15 in a radius which corresponds to that of the fitting bore 8 .

If a force in direction B is exerted on the pull stud 26 by means of the pull rod (not shown), the clamping piece 50 is extended in the radial direction by means of the wedge surfaces 52 , 54 and its pressure surface 59 is pressed against the fitting bore 8 . This creates a radial force R , which always presses the fitting shoulder 15 at the point radially opposite the clamping piece 50 in the same direction to the fitting bore 8 . This ensures repeatability. As soon as the pressure surface 59 bears against the fitting bore 8 , the mutual movement of pull stud 26 and clamping piece 50 is blocked. The force acting on the pull rod 26 in the axial direction B of the pull rod then presses the annular surface 13 c of the tool holder 13 '' on the end face 4 of the spindle 1 .

The tool holder or its flange should suitably be large enough that the flange extends over the entire end face 4 of the spindle and rests on the entire end face 4 . Partial coverage would gradually lead to deformation of the spindle face. However, it can also happen that tool holders are to be connected to the spindle, the flange of which is designed in accordance with DIN 69871 and has a trapezoidal groove so that the tool in question can be detected by a conventional tool changer. In this case, the flange of the most common steep taper No. 50 has a diameter of 97.5 mm. So that such tools with this flange diameter leave no markings by their outer edge, it is advisable to provide a ring groove 60 in the area of this outer edge in the end face 4 . This ring groove 60 is arranged at a diameter of 97.5 mm and extends from this diameter in each case by approximately 1 mm radially outwards and inwards, so that the ring groove has a total width of approximately 2 mm. As a result, the outer edge of a flange with an outer diameter of 97.5 mm lies in the area of the ring groove 60 and deformations of the end face 4 in this area are thus avoided.

Claims (15)

1. Machine tool spindle and matching tool holder, with different shafts that can be used alternately in the spindle head, which has a frustoconical mounting hole for receiving a steep taper shank of a first tool holder, an end face surrounding the mounting hole and in the area of the frustoconical mounting hole, a cylindrical fitting hole for mounting a cylindri's fitting approach on the shaft of a second tool holder, which is provided at one end of the fitting approach with a concentric to this flange and at the other end of the fitting approach with an engaging the flange on the end face with play in the frustoconical receiving bore conical frustum, characterized in that the fitting bore ( 8 ) immediately adjoins the end face ( 4 ) and its diameter ( D) is slightly larger than the theoretical diameter ( d 1 ) of the truncated cone-shaped receiving bore ( 3 ) in the plane d he end face ( 4 ) and that the axial length (L) of the fitting bore ( 8 ) is only about 10-15% of the theoretical diameter ( d 1 ). 2. Machine tool spindle according to claim 1, characterized in that the diameter (D) of the fitting bore ( 8 ) is approximately 1 mm larger than the theoretical diameter ( d 1 ). 3. Machine tool spindle according to claim 1, characterized in that the axial length (L) of the fitting bore ( 8 ) carries about 12% of the theoretical diameter ( d 1 ) be. 4. Machine tool spindle according to claim 1, characterized in that between the end face ( 4 ) and the cylindrical fitting bore ( 8 ) a diameter difference between the fitting shoulder ( 15 ) and truncated cone ( 16 ) bridging chamfer ( 19 ) is provided. 5. Machine tool spindle according to claim 1, characterized in that a bevel bridging the diameter difference between the two parts is provided between the taper shank ( 16 ) and the fitting shoulder ( 15 ). 6. Machine tool spindle according to claim 1, characterized in that in the truncated cone ( 16 ) in the region of the fitting shoulder ( 15 ) a clamping piece ( 20 , 40 , 50 ) in a radial guide ( 21 , 41 , 51 ) is displaceable by one engaging at its inner end, with the in the truncated cone ( 16 ) axially displaceable tightening bolt ( 26 ) connected wedge surface ( 25 a , 42 , 52 ) is radially movable and at its free outer end with a pressure surface ( 20 a , 49 , 59 ) is provided, which can be pressed onto a counter surface ( 32 , 47 , 8 ) provided on the spindle ( 1 ). 7. Machine tool spindle according to claim 6, characterized in that the clamping piece ( 20 , 40 , 50 ) is formed cylin drically and is guided in a transverse bore ( 21 , 41 , 51 ) in the truncated cone ( 16 ). 8. Machine tool spindle according to claim 7, characterized in that the transverse bore ( 21 , 41 , 51 ) partially extends into the cylindrical fitting shoulder ( 15 ). 9. Machine tool spindle according to claim 8, characterized in that the fitting bore ( 8 ) forms the counter surface and the pressure surface ( 59 ) has a radius which corresponds to that of the fitting bore ( 8 ). 10. Machine tool spindle according to claim 6, characterized in that the pressure surface ( 49 ) and the counter surface ( 47 ) are inclined at the same acute angle (β) to the spindle axis (A) . 11. Machine tool spindle according to claim 10, characterized in that the counter surface ( 47 ) is generated by means of an end mill ( 48 ) whose axis (C) is inclined relative to the spindle axis (A) . 12. Machine tool spindle according to claim 6, characterized in that the pressure surface is a truncated cone ( 20 a) and the counter surface is formed by a truncated cone-shaped recess ( 32 ) in a screw ( 31 ) screwed into the spindle ( 1 ). 13. Machine tool spindle according to claim 6 and 7, characterized in that the clamping piece ( 20 a ) extends substantially over the entire cross-section of the truncated cone ( 16 ) and has a longitudinal slot ( 22 ) extending over part of its length, in which the wedge ( 25 ) engages. 14. Machine tool spindle according to claim 6, characterized in that the clamping piece ( 50 ) is hollow and in the interior of the clamping piece ( 50 ) in the pull stud ( 26 ) screwed screw ( 53 ) and a return spring ( 55 ) are arranged, which exerts a radially inward restoring force on the clamping piece ( 50 ). 15. Machine tool spindle according to claim 1, characterized in that an annular groove ( 60 ) with about 2 mm width is provided in the end face ( 4 ) of the spindle at a diameter of 97.5 mm.