DE3930787A1 - Lathe tool turret with traversing milling unit - avoids need for third machine axis by providing unit with cross-traverse - Google Patents

Abstract

Seen in plan view, the milling unit (7) fits into one of the tooling bores (6) pitched round the indexing tool turret plate of an NC lathe. The milling unit is driven through the tooling bore by a clutched drive located in the turret housing (3). The milling spindle and drive are able to traverse a distance of about 20 mm in the direction y, thus allowing milling across the work axis. The cross-traverse drive (46) is fitted into the adjacent tooling bore and is again driven through the bore. USE/ADVANTAGE - The complication and expense of an additional positioning axis on the machine is avoided by providing a traverse movement on the milling unit. System can readily be fitted to existing machines.

Description

The invention relates to a device for cutting lifting processing, especially milling equipment, for the tool turret of machine tools, their Tool turret with a step around a turret axis wise switchable and in their respective work position lockable tool disc with a number of axially parallel mounting holes is used to hold the tool shafts holders are set up, at least one work tool holder one in one on a holding shaft seated housing rotatably mounted tool spindle has that with a through the receiving shaft ver running first drive shaft is bound, which in a receiving bore of the Tool disc inserted over the shank  first coupling means with a first drive source can be coupled in the area of the tool disk.

For tool turrets, such as those on lathes It is known to find use (VDI-Zeitung 125 (1983) No. 22, pages M107 to 111), tool holder to use with rotating tools, whose by the standard drive shaft extending drive shaft in a corresponding mounting hole of the tool disc inserted shaft with a drive source is coupled in the area of the tool disc. With such also referred to as drilling or milling heads It is tool holders for powered tools possible, on the lathe also drilling and milling to perform work. The tool spindle of this Drilling or milling heads are often quite right at an angle to the axis of the receiving shaft, it being there are also embodiments in which the axis of the Tool spindle with respect to the axis of the holding shank can be swiveled so that inclined bores or To be able to produce surfaces.

Lathes are included in their normal version a cross support that has a relative Adjustment movement between that in the main spindle of the headstock clamped workpiece and the in Working position of the tool revolvers in the Z direction (coaxial or axis parallel to the axis of the main spindle) and in the X direction (in a plane perpendicular to the Axis of the main spindle). For machining operations that additionally an adjustment of the work in the direction of the Y axis (perpendicular to the z and x axes) are complex  Special constructions or additional devices the lathe necessary to allow the whole tool turret including his factory tool disk along the Y axis.

In contrast, the object of the invention is a To point the way that allows, especially at such machine tools, e.g. lathes, where an adjustment movement between the Re volverkopf and the main spindle axis of rotation only is provided in the z and x directions additional adjustment of the tool in the enable y-axis without doing anything special constructions of the machine tool or certain order of the tool turret would be required.

To solve this problem is the ge named device according to the invention thereby characterized records that in the tool holder the tool spindle with a housing part supporting it across the associated receiving shaft in a cross extending to the axis of this receiving shaft Direction is mounted so that it is a adjuster carrying a second receiving shaft unit with a movably mounted actuator points that geared with one by the second Shank extending, the actuator one Adjustment movement giving second drive shaft which is connected to one of the recording bore of the tool holder adjacent receptacle bore inserted second shank over second coupling means with a second drive source can be coupled in the area of the tool disk,  and that the actuator of the adjusting unit with the housing part supporting the tool spindle the tool holder is coupled.

With this device, the adjustment movement of the tool in the Y axis in the range of Tool holder, i.e. of the drilling or milling head itself, misplaced so that any conventional tool machine in a simple way if necessary can be retrofitted that only in two mounting holes assigned to neighboring stations the tool disk the tool holder mentioned and the adjustment unit coupled with this in each case be inserted with their receptacles. Any what major changes to the machine or the tool turret are not required. It it suffices to use the tool turret in the area of the Tool disc a second drive source see that with the drive shaft of the adjustment unit can be coupled. The associated extension of the usually already existing tool turret through a second driven tool station, those for the adjustment task in the driven Tool or for special tools can be used can be done easily.

In a preferred embodiment, the two between the two drive shafts and their drives swell arranged coupling means different trained so that on the second drive shaft seated coupling elements not with the on holes of the tool disk of a normal Tool turret assigned coupling means for the first drive shaft of the tool spindle in Intervention can come. The adjustment unit can  thus in the through its mounting hole in the Tool disc specific tool work center to be ordered; it can with appropriate Design itself as a carrier for a tool be trained or provided with such, by, for example, pre-boring on it see is. In this case it goes through the opening Tool station occupied by the adjustment unit not on the tool disc for machining lost. For the rest, the space requirement of the Ver setting unit on the tool disk small; he does not need that of a normal tool holder exceed, with the result that the occupancy the other tool stations through the new one direction is not disabled.

Between the second drive shaft of the adjuster unit and its drive source is convenient one to a predetermined, maximum transferable Torque-adjustable overload slip clutch on ordered, their driving and driving coupling parts Feeler can be assigned to the presence be and / or lack of synchronism between give electrical signals to these parts. The overload slip clutch responds when the Ver actuator blocked or its actuator in a End position moves. It is advantageous if that Actuator whose actuating movement in at least one Adjustment direction limiting slings assigned are.

To determine an exactly reproducible Re reference or zero point for the adjustment of the To facilitate the tool spindle in the Y axis it is advantageous if at least the second drive shaft  releasable locking means are assigned by which the drive shaft can be locked in a rotationally fixed manner. This locking means can by the second Coupling means designed to be automatically controllable be such that when the second drive is uncoupled source the actuator of the adjustment unit in a fixed position is fixed.

It is expedient to carry the shank of the part of the tool holder and the adjustment unit mechanically connected so that the whole Facility forms a structural unit, which as such mounted on the tool disc of the tool turret or can be removed from this. It did turned out to be advantageous if that's the inclusion shank supporting part of the tool holder and the ver actuator are adjustably connected to each other, especially such that the part is parallel pivoting to the second receiving shaft axis is pivotable. This adjustable connection between the tool holder and the adjustment unit allows a precise when assembling the device Fine adjustment of the tool to the center of the axis Tool disc and at the same time the compensation of any existing in the mounting holes of the tool disc Tolerances.

The second coupling means of the drive shaft of the Adjustment unit can finally be one in the too Appropriate mounting hole inserted second mounting have shaft-controllable actuating device, which the approach to a reference or zero point for the adjustment in the Y-axis is much easier.  

The facility can also advantageously be a tax have unit with the feelers of the he mentioned overload slip clutch and the actuation direction of the second coupling means is connected and the sensing means and / or the actuator can be controlled according to program or sequence control. It may also be appropriate that the second Coupling means are also assigned to sensing means, which are connected to the control unit and which input and / or output coupling elements Coupling agents are assigned.

In the drawing is an example of execution of the counter state of the invention. Show it:

Fig. 1 a tool turret with a device according to the invention, in a schematic plan view in the assignment to a bear beitenen workpiece,

Fig. 2 shows the device according to Fig. 1, view in a side,

Fig. 3 shows the tool holder of the device according to Fig. 2, taken along the line III-III of Fig. 4, in a side view;

Fig. 4 shows the device of FIG. 2 taken along the line IV-IV of FIG. 5, in a side view;

Fig. 5 shows the device of FIG. 2, in a view from the front, partially cut away, and

Fig. 6, the drive device for the second drive shaft of the device of FIG. 2, in axial section, in a side view and in a schematic representation, and in section.

The turret 1 is shown only schematically in Fig. 1, a to the non Darge cross support featured on one illustrated only with its headstock 2 lathe to set casing 3, on whose end face a planar tool disc is rotatably schrittschaltbar about a turret axis 5 4. The associated storage devices of the tool disk 4 and their stepping drive are known; they are arranged in the housing 3 and are not illustrated.

The tool disk 4 is formed in the conventional manner with a number of continuous cylindrical receiving holes 6 , which lie with their axes at equal intervals on a common pitch circle. The axially parallel mounting holes form individual tool stations, in which so-called tool holders or heads are each inserted with a cylindrical mounting shaft into the corresponding mounting hole 6 .

For example, from Fig. 4 it can be seen that a tool holder 7 designed as a milling or drilling head is arranged in one of these tool stations and has a flange-like base plate 8 , which is connected to a cylindrical receiving shaft 9 , which in the associated receiving bore 6 of the tool disc 4 inserted and clamped in position by means of clamping means (not shown). These clamping means engage in a manner known per se on a toothing 10 of the receiving shaft 9 . On the base plate 8 , a housing part 12 is mounted at right angles to the axis of the receiving shaft 9, indicated at 13 , via a longitudinal guide 11 , as can be seen in particular from FIGS. 2 and 3. On the housing part 12 , a spindle housing 14 is fixed, in which a tool spindle 15 in tapered roller bearings 16 , 17 is rotatably mounted. The factory tool spindle 15 is provided at the end with a for receiving a milling or drilling tool 0 ( Fig. 2, 5) collet 18 .

The longitudinal guide 11 is designed as a pretensioned swallow tail guide. It has an opening formed in the housing part 12 dovetail groove 19, is supported in the region of the housing part 12 via a guide bar 20 surface against a corresponding guide 19 on the base plate. 8 The guide bar 20 opposite two further straight guide surfaces 21 , 22 are formed on the base plate 8 , against which guide pieces 23 , 24 are pressed resiliently, which are aligned at right angles to one another in a screwed at 25 end face to the housing part 12 guide housing 26 are gela. The length of the longitudinal guide 11 is such that the housing part 12 and thus the tool spindle 15 with respect to the receiving shaft 9 and thus the tool disk 4 can perform a linear movement of about 20 mm.

Through the hollow shank 9, a first drive shaft 27 extends, which is mounted in a needle bearing 28 and a deep groove ball bearing 29 rotatably and endsei tig a rotationally fixed manner translated clutch member supports 30, the inner half of the mounting hole 6 is inserted shank. 9 The coupling element 30 is provided on its end face with coupling claws 31 , which form parts of the first coupling means and are designed to interact with corresponding coupling claws of a machine-side coupling element which is connected to a drive source, for example an electric motor, which is in the area of the tool disk 4 arranged and is not shown in detail.

On the opposite side the coupling element 30 the first drive shaft 27 carries a dip actuating drive gear 300, which by means of a coaxial cone 310 and a clamping screw 32 in rotation with the first drive shaft 27 is connected. Axially parallel to the lying in the housing part 12 input drive gear 300 is in the housing part 12, a bevel gear 33 at 34, mounted for rotation 35 which meshes with a second bevel gear 36 in engagement, which in a rotationally fixed to the tool spindle mounted 15 and drives them. The bevel gear 33 is connected in a rotationally fixed manner to a shaft journal 37 , onto which a drive gear 38, which is also arranged in the housing part 12 , is wedged, which is coupled via an intermediate gear 39 ( FIGS. 4, 5) to form a spur gear with the input gear 300 .

The intermediate gear 39 is rotatably mounted in the manner shown in FIG. 4 by means of roller bearings (not shown in more detail) on an intermediate axis 40 which is supported on both sides on rockers 41 , 42 , which in turn are at the other end via roller bearings 43 and 44 ( FIG. 4, 3) are mounted on the input gear 300 or the drive gear 38 .

In this way, the intermediate gear 39 is movably mounted on the planetary tracks of the input gear 300 and the drive gear 38 so that it housing part 12 and thus the tool spindle 15 with respect to the base plate 8 Achsver occurring between the axis 13 of the input gear 38 when the first gear Ge is displaced 30 and the axis 45 ( Fig. 3, 5) of the drive toothed wheel 38 can compensate.

For example, Fig. 4 shows that in which the receiving shaft 9 of the described tool holder 7 receiving receiving hole 6 adjacent receiving hole 6 of the tool disk 4 of the receiving shaft 9 a of an adjusting unit 46 is inserted, which thus occupies the adjacent tool station.

The adjustment unit 46 has a housing 47 which is rigidly connected to the receiving shaft 9 a and in which a spindle drive 48 is arranged. The spindle drive 48 consists of a in the Ge housing 47 at 49, 50 rotatably mounted spindle nut 51 ( Fig. 4), which interacts with a thread rolling spindle 52 , the axis of which is arranged transversely to the axis 53 of the receiving shaft 9 . With the threaded nut 51 , a bevel gear 54 is rotatably connected, the pinion 55 can be set in rotation by a second drive shaft 56 , which is rotatably supported via roller bearings 58 , 59 in a corresponding bore of the receiving shaft 9 a.

The threaded screw 52 forms an actuator which allows the tool spindle 15 to displace the tool holder 7 in the longitudinal guide. 11

For this purpose, the thread rolling spindle 52 is pinned at the end to a coupling part 60 ( FIG. 4) which engages in a corresponding recess 61 of the first housing part 12 of the tool holder 7 and is held in a form-fitting manner in this manner in a rotationally fixed manner. The coupling part 60 sits on a threaded pin 62 , which is screwed into a corresponding threaded bore of the ball screw 52 and allows the effective length of the threaded roller screw 52 to be fine-tuned in accordance with the spacing of the adjacent bore 6 .

Upon rotation of the second drive shaft 56 , the ball screw 52 undergoes a longitudinal adjustment movement in the axial direction, which is transmitted via the coupling element 60 to the first housing part 12 of the tool carrier 7 , which is thus adjusted in its longitudinal guide 11 with respect to the tool disc 4 accordingly.

On the side facing away from the coupling member 60, the ball screw 51 supports a stop plate 63 which delimits at a the displacement of the ball screw 52 in this direction, 64 may come into contact with the casing 47 rigidly connected to the stop surface.

With the second drive shaft 56 which is in the receiving bore 6 setztem shank is on the bevel pinion 55 side facing away from a bearing bush 65, a clutch member 66 rotationally fixed to wearing arranged at the end clutch claws 67, 9 a bore within the recording are 6 and parts form second coupling means. The clutch claws 67 lie on a pitch circle which runs within the pitch circle assigned to the clutch claws 31 of the first clutch means for driving the first drive shaft 27 , as is indicated in FIG. 4. The first and second coupling means are thus designed differently, the two th coupling means for the second drive shaft 56 being inside and coaxial with the first coupling means, so that the drive of the second drive shaft 56 takes place coaxially to the receiving bore 6 .

As can be seen in particular from FIGS. 4 and 6, the second coupling means on the machine side, ie behind the tool disk 4 , have a second coupling element 68 which can be positively coupled to the coupling claws 67 of the second drive shaft 56 via a corresponding claw toothing on the end face. The second coupling element 68 is via needle bearings 69 bush in one of an otherwise not shown in wall portion 70 of the turret housing 3 (Fig. 1) flanged bearing rotatably supported 71 that simultaneously carries a toothed drive pulley 73 which in its at 72 via roller bearings is rotatably mounted. At the drive pulley 73 is via a coupling piece 74 which engages in a spline 75 of the two-th coupling element 68 , rotatably connected to this. At the same time, the second coupling element 68 is axially displaceably mounted in the bearing bush 71 , the arrangement being such that a compression spring 76 strives to hold the second coupling element 68 with the claw coupling elements 67 of the second drive shaft 56 in engagement.

To disengage the second coupling element 68 , a hydraulic cylinder 77 is used , which at 78 is positively coupled to the second coupling element 68 only in one axial direction by means of a corresponding coupling device, such that when a pressure medium connection 79 of the hydraulic cylinder 77 is acted upon appropriately, this presses the second coupling element 68 , based on Fig. 6, against the action of the compression spring 76 to the right, so that the positive coupling between the toothed drive pulley 73 and the second drive shaft 56 disengages.

In the first drive member 66 of the second drive shaft 56 are in the position shown in Fig. 4 way locking means for the drive shaft 56 arranged, having a bore in a respective radial 80 of the first coupling element 66 radially displaceable clamping piece 81 which extends at one end to a in a corresponding axial bore of the first coupling element 66 axially displaceably supported actuating wedge 82 is supported, through which it can be jammed at the other end against the inner wall of an associated, the coupling element 66 receiving axial bore of the receiving shaft 9 a with non-rotatable locking of the second drive shaft 56 . The actuating wedge 82 is axially biased in the clamping direction by a compression spring 83 , which in the case of the second coupling element 68 ( FIG. 6) uncoupled second drive shaft 56 via the actuating wedge 82 and the clamping piece 81 locks the drive shaft 56 in a rotationally fixed manner.

The spring characteristic of the compression spring 83 is matched to that of the compression spring 76 in such a way that when clutch claws 67 are engaged, an end face on the second coupling element 68 arranged pressure plate 84 holds the actuating wedge 82 in an inactive position, so that the second drive shaft 56 is free is rotatable.

A shaft 88 which is rotatably mounted in the turret housing 3 ( FIG. 1) at 87 is coupled to the drive toothed belt pulley 73 via a toothed belt 85 ( FIG. 6) and a toothed belt pulley 86 and in turn is driven by an electric motor 90 via an overload slip clutch 89 can. The overload slip clutch 89 has two coupling parts 92 and 93 , each of which is connected in a rotationally fixed manner to the shaft 88 or the motor shaft stub 91 ; it is set to a predetermined, maximum transmissible torque. The rotational movement of the driving and the driving clutch parts 93 and 92 is sensed by assigned sensors or sensors 94 , 95 , which supply electrical signals to an electrical control unit 96 , which indicate whether:

• a) the two clutch parts 92 , 93 run synchronously, ie the slip clutch 89 does not respond,
• b) the two clutch parts 92 , 93 have a relative rotation against each other, ie the slip clutch 89 slips, and
• c) the coupling part 92 stands still, ie the ball rolling spindle 52 ( FIG. 4) is blocked or has run against the end stop surface 64 .

In a similar manner, the axial position of the second coupling element 68 and thus the coupling or uncoupling of the second drive shaft 56 is reported via corresponding signals from the control unit 96 , which in turn can also control the hydraulic cylinder 77 , via two sensors or sensors 97 , 98 .

The device described allows a reference or reference point (zero point) for the longitudinal adjustment of the tool spindle 15 in its straight guide 11 to be controlled in a particularly simple manner:
After switching on the machine, the tool spindle 15 is switched to its working position by a corresponding incremental movement of the tool disk 4 , in which the straight guide 11 is generally oriented such that the tool accommodated in the tool spindle 15 by the adjusting unit 46 in the Y -Direction is radially adjustable.

The reference point of the adjustment axis is then approached and saved with a subroutine for the reference point. The control of this adjustment axis takes place indirectly, ie with value acquisition on the drive motor 90 , because no electrical information can be removed from the tool holder 7 itself, which is movable. The thread rolling spindle 52 is driven with its thrust washer 63 against the stop 64 , whereupon with the help of the overload slip clutch 89 the mechanical end position of the adjusting unit 46 is folded with the zero marker of the incremental encoder on the drive motor 90 .

As soon as the tool disk is locked in the tool turret when the tool spindle 15 is in the working position, the control unit 96 is activated. The drive motor 90 is switched on in the predetermined direction of rotation at a predetermined speed. As soon as this is achieved, the control unit 96 causes the hydraulic cylinder 77 to be vented, so that the compression spring 76 couples the second drive shaft 56 to the drive motor 90 via the two coupling elements 66 , 68 .

After starting the pressure plate 63 on the stop surface 64 and thus reaching the mechanical end position, the sensors 94 , 95 give corresponding signals to the control unit 76 , which reduces the speed of the drive motor 90 . The zero marker is now activated. In addition, the speed / position control loop of the control unit 96 is activated. The hydraulic cylinder 77 is then actuated, which pulls the second coupling element 68 back and thus disengages the second coupling means, which is confirmed by the sensors 97 , 98 .

The control unit 96 is now free for further programming according to the intended workflow.

In normal operation, sensors 94 , 95 monitor the drive of adjustment unit 46 . A Festge determined slipping of the overload slip clutch 89 leads as a fault to the machine or at least the drive motor 90th

The switching drive of the turret itself is naturally also electrically locked with the control unit 96 ; he may only shift when the second clutch means are switched off.

In order to finally ensure that - regardless of any tolerances of the receiving bores 6 or the tool disk 4 - the tool spindle 15 is exactly centered with its axis in the working position, a fine adjustment device is provided.

For this purpose, the base plate 8 of the tool carrier 7 with the housing 47 of the adjusting unit 46 is pivotally connected to a pivotable axis 100 parallel to the axes 13 , 53 of the two receiving holes 6 , as can be seen in particular from FIGS. 4 and 5 is. The housing 47 carries a laterally arranged extension 101 , which is connected to the first housing part 12 of the tool carrier 7 via a bearing pin 100 . Two bearing parts 103 arranged on both sides of the bearing extension 101 on the first housing part 12 interact with two coaxial set screws 104 , which are screwed into corresponding threaded bores of the bearing extension 101 and, by correspondingly different tightening, cause a slight pivoting of the housing part 12 (and the base plate 8 ). allow relative to the housing 47 about the pivot axis 100 . A interacting with clamping slides not shown clamping bolt 105 finally allows the United adjusting unit 46 and the tool holder 7 rigidly locked to each other in the respectively set position.

Since the housing 47 of the adjustment unit 46 is aligned centrally to the axis 53 of the receiving bore 6 , it would be readily possible to additionally design the housing 47 as a tool carrier, for example as a boring bar holder, in order to also accommodate the tool position occupied by the adjustment unit 46 at the If necessary, use tool disk 4 for machining.

Claims (14)

1. Device for machining, in particular special milling device, for the tool turret of machine tools, the tool turret of which is provided with a tool disk that can be gradually switched around a turret axis and can be locked in its respective working position with a number of axially parallel receiving bores that are used to receive the receiving shafts of tools Holders are set up, wherein at least one tool holder has a tool spindle rotatably mounted in a housing seated on a receiving shaft, which is geared to a first drive shaft running through the receiving shaft, which with inserted into a receiving bore of the tool disk receiving shaft via first coupling means a first drive source can be coupled in the area of the tool disk, characterized in that in the tool holder ( 7 ) the tool spindle ( 15 ) with a housing part ( 12 ) supporting it Compared to the associated receiving shaft ( 9 ) in a direction transverse to the axis ( 13 ) of this receiving shaft ( 9 ) direction is mounted displaceably that it has a second shaft ( 9 a) carrying adjustment unit ( 46 ) with a movably mounted actuator ( 52 ), which is operatively connected to a second drive shaft ( 56 ) which extends through the second receiving shaft ( 9 a) and which provides the adjusting element ( 52 ) with an adjusting movement and which is drilled into one of the receiving bores ( 6 ) of the tool holder ( 4th ) adjacent mounting hole ( 6 ) inserted second mounting shaft ( 9 a) via second coupling means ( 66 , 67 , 68 ) with a second drive source ( 90 ) in the area of the tool disc ( 4 ) can be coupled, and that the actuator ( 52 ) of the adjusting unit ( 46 ) is coupled to the housing part ( 12 ) of the tool holder ( 7 ) which supports the tool spindle ( 15 ). 2. Device according to claim 1, characterized in that the coupling means ( 30 , 31 ; 66 , 67 ) arranged between the two drive shafts ( 27 , 56 ) and their drive sources are designed differently. 3. Device according to claim 1 or 2, characterized in that between the second drive shaft ( 56 ) and its drive source ( 90 ) is arranged on a predetermined, maximum transferable torque overload clutch ( 89 ). 4. Device according to claim 3, characterized in that the driving and driving clutch parts ( 93 , 92 ) of the overload slip clutch are arranged sensing means ( 94 , 95 ), which indicate the presence and / or absence of the synchronous state between these parts to electrical signals submit. 5. Device according to one of the preceding claims, characterized in that at least the second drive shaft ( 56 ) releasable locking means ( 81 , 82 ) are assigned, by which the drive shaft can be locked in rotation. 6. Device according to claim 5, characterized in that the locking means ( 81 , 82 ) by the two th coupling means ( 66 , 67 , 68 ) are automatically designed to be controllable. 7. Device according to one of claims 4 to 6, characterized in that the actuator ( 52 ) whose actuating movement in at least one adjustment direction limit de stop means ( 63 , 64 ) are assigned. 8. Device according to one of the preceding claims, characterized in that a receiving shaft ( 9 ) supporting part ( 8 ) of the tool holder ( 7 ) and the adjusting unit ( 46 ) are mechanically connected to each other. 9. Device according to claim 8, characterized in that the part ( 8 ) and the adjusting unit ( 46 ) are adjustably connected to one another. 10. The device according to claim 9, characterized in that the part ( 8 ) with the adjusting unit ( 46 ) about a parallel to the second receiving shaft ( 9 a) extending pivot axis ( 100 ) is pivotally connected. 11. Device according to one of the preceding claims, characterized in that the second coupling means ( 66 , 67 , 68 ) in a in the associated on receiving bore ( 6 ) inserted second receiving shaft ( 9 a) controllable actuating device ( 77 ). 12. Device according to claims 4 and 11, characterized in that it has a control unit ( 96 ) with the sensing means ( 94 , 95 ) of the overload slip clutch ( 89 ) and the actuating device ( 77 ) of the second coupling means is connected and through which the sensing means ( 94 , 95 ) and / or the actuating device ( 77 ) can be controlled in accordance with the program or in sequence. 13. The device according to claim 12, characterized in that the second coupling means are associated with their input and / or output coupling elements ( 66 , 68 ) assigned sensing means ( 97 , 98 ) which are connected to the control unit ( 96 ). 14. Device according to one of the preceding claims, characterized in that the adjusting unit ( 46 ) is designed as a tool carrier or is connected to such.