WO2003106105A1 - Device and method for fixing a tool - Google Patents

Abstract

The invention relates to a method for fixing a tool (10) in a chuck (14), according to which the tool (10) is introduced into said chuck (14) in a vertical direction and after reaching an axial desired position (54) is fixed in the latter (14). According to the invention, a value that characterises the length (Z₁) of the tool (10) in an axial direction (16) is determined prior to the introduction of the tool (10) into the chuck (14) by a measurement and said value is used to set a positioning device (20) for positioning the tool (10) in the desired position (54).

Description

Device and method for fastening a tool

State of the art

The invention is based on a device for fastening a tool according to the preamble of claim 1 and a method for fastening a tool according to the preamble of claim 8.

Devices and methods for fastening a tool, in particular a shank tool in a tool chuck, are known, in which the tool is inserted into the tool chuck and fixed in the tool chuck when an axial desired position is reached. From DE 100 15 322 AI a method is known in which the tool is inserted into a first chuck and is positioned there by a movement of a positioning stop. The movement of the positioning stop is then transferred to a second positioning stop in a second chuck, and the tool is fixed there in the desired position. Such a method requires two tool chucks, which is expensive.

BESTATIGUNGSKOPIE The invention has for its object to provide an inexpensive device and an inexpensive method with which a tool in a tool chuck can be quickly and exactly positioned and attached. The object directed to the device is achieved according to the invention by a device with the features of claim 1. Further refinements result from subclaims 2 to 7.

Advantages of the invention

The invention is based on a device for fastening a tool in a tool chuck with a positioning device for vertical positioning of the tool in a desired position in the tool chuck.

It is proposed that the device be a measuring device with a means for determining a length of the tool in the axial direction, one separate from the tool chuck

Includes receiving area for receiving the tool and a measuring stop that is immovable relative to the receiving area. An immovable measuring stop is inexpensive to manufacture. With the determined length of the tool, the positioning device can be brought into the desired position in a simple manner.

The measuring device advantageously comprises at least two receiving ranges, each with a measuring stop. Several tools can be measured one after the other, which means that when using several tools, a short can be achieved. In addition, with a different design of the receiving area, several different tools can be measured without having to replace adapters.

A further advantage is achieved if the recording area can be moved, in particular pivoted, from a waiting position into a measuring position. A camera and with it a light source or a bright background do not have to be moved to several or all of the recording areas, which would mean technical effort. Here, the measuring position is such a position at which a tool held in the recording area can be focused by a camera device. A position outside a measuring position is called a waiting position.

A simple movement of the recording area in front of a camera can be achieved if the recording area is arranged in a rotatable turret.

An additional advantage can be achieved in that a tool fastened in the tool chuck can be rotated by rotating the turret. With the aid of the rotation of the tool, focusing of a camera on a tool element, for example a cutting edge, can be facilitated or made possible. A rotating mechanism is necessary for this. By combining this rotary mechanism with a rotary mechanism of the revolver, components and costs can be saved. By placing the measuring stop in a defined position relative to the tool chuck, a high degree of accuracy in the positioning of the tool in the chuck can be achieved, since only a reference point or coordinate zero point is necessary for length measurement and positioning. In addition, a separate position calibration of a separately arranged measuring stop is not necessary, since the position calibration of the measuring stop can be achieved with the position calibration of a positioning stop.

The defined position of the measuring stop relative to the tool chuck can be achieved particularly easily if the measuring stop is part of a spindle into which the tool chuck can be inserted.

It is also proposed that the device comprise a means for determining a length of the tool in the axial direction with respect to the shaft end. As a result, the positioning device can be set before the tool is inserted into the tool chuck, so that the tool can be automatically moved into its desired position when it is inserted into the tool chuck. An additional unit for determining the target position of the tool in the tool chuck before fixation can thus advantageously be avoided. A quick, simple and inexpensive device for exact positioning of the tool in the tool chuck can be reached.

If the positioning device comprises a tool magazine with at least one tool holding area and the means is provided for determining the length of at least one tool To determine the tool receiving area located tool, removing the tool from the tool magazine for length determination can advantageously be avoided and work steps can be saved. If the tool magazine has a plurality of tool receiving areas with tools, the lengths of all the tools in the tool magazine can be determined one after the other in a particularly advantageous manner and workflows can thus be rationalized.

If the device has a data processing system which is provided in the tool magazine for storing and for outputting the determined length of at least one tool, in particular at least two tools, the length of the tool can be determined in advance and can be called up when the tool is inserted into the tool chuck. If it is possible to uniquely assign the specific length to the tool using a code on the tool, a process for positioning the tool can be automated. Furthermore, the lengths of several tools located in the tool magazine can be stored in the data processing system, called up at the same time and compared with one another via a data output. In the data processing system, other tool data can also be stored and called up, which the person skilled in the art considers useful, e.g. Geometry data, cutting edge lengths, etc.

In a further embodiment of the invention, it is proposed that the positioning device has at least one measuring stop for positioning the tool in the tool holding area and one positioning stop for positioning the tool in the tool chuck. It is a structurally simple device for determining the length and for determining the target position can be reached by the measuring stop having a defined position and the positioning stop having a defined starting position from which the positioning stop is moved into the positioning position, the tool being able to be brought into contact with the stops.

The measuring stop and the positioning stop advantageously each have a stop surface which is shaped identically to one another. The length of the tool and / or the target position in the tool chuck are structurally simple and clearly reproducible with respect to the respective stops. The stops can be attached in the respective receiving areas in the tool magazine and / or on other parts of the positioning device. Tolerances in determining the length and / or in the target position can thus be kept small. The abutment surfaces can each be spherical, flat or in another manner that appears useful to the person skilled in the art. If the stop surface is formed by an outer surface of a hardened steel ball, precise positioning of the tool in the respective receiving area can be achieved in a structurally simple manner.

If the positioning device has a controllable positioning element, the positioning device can be structurally adjusted so that the tool comes into contact with the positioning element when it reaches its desired position. The control can be done manually or automatically. If the control is automatic, a process for reaching the target position can be automated. It is also proposed that the means be provided to carry out a contactless measurement and to determine the length therefrom. A simple and exact measurement can be carried out, in which damage between the tool and the medium can be reliably avoided. Furthermore, the target position can be checked in a structurally simple manner after the tool has been fastened in the tool chuck.

According to the invention, the object directed to the method is achieved by a method having the features of patent claim 8. Advantageous refinements result from subclaims 9 to 16.

The invention is based on a method for fastening a tool in a tool chuck, in which the

Tool is inserted into the tool chuck in the vertical direction and is fixed in the tool chuck after reaching an axial desired position.

It is proposed that, before the tool is inserted into the tool chuck, a value characterizing the length of the tool in the axial direction is determined by a measurement and a positioning device for positioning the tool in the desired position is set with the value. The positioning device can already before

Insertion of the tool into the tool chuck can be set so that the tool can be moved into its desired position when it is inserted into the tool chuck and comes into contact with at least part of the positioning device when the desired position is reached. Determining the target position of the tool in the tool chuck before fixation can thus can be avoided with advantage. As a result, a quick, simple and inexpensive method for exact positioning of the tool in the tool chuck can be achieved with only one movable positioning device. Due to the vertical insertion of the tool into the tool chuck, the tool is pressed onto the positioning device by its own weight and does not have to be pressed onto the positioning device by an operator. As a result, high positioning accuracy can be achieved since the tool has the same pressure, namely its

Weight pressure, is pressed both on a measuring stop and on a positioning stop. In addition, this pressure is always the same when several fixing processes are carried out in succession, as a result of which good positioning reproducibility can be achieved.

The method can be carried out particularly simply and inexpensively by carrying out the measurement, the tool being introduced into a receiving area of a measuring device and brought into contact with a measuring stop which is immovable relative to the receiving area, and the position of a measuring point which characterizes the tool is determined with respect to the measuring stop.

A value characterizing the length of a first tool is advantageously determined and a value characterizing the length of a second tool is determined before the first tool is fixed in the tool chuck. Several tools can be measured "on stock", so that a later positioning process, in particular with several positioning devices, can be carried out quickly. A successively more and more accurate positioning of the tool with several consecutive positions can be achieved if after fixing the tool in the target position the actual position of the tool is measured and a difference between the target position and the actual position is saved and is used as a correction value in a later positioning process. If the actual position is, for example, 50 .mu.m too deep, this value is taken into account as a correction value for the next positioning. This positioning can therefore be more precise. A repeatability of 15 μm can be achieved in this way.

A high repeatability can also be achieved if the later positioning process takes place after removing the tool and reinserting the tool into the tool chuck. This is the case, for example, when the tool is used again later. The correction value is then expediently in mechanical connection with the tool, for example in a chip on the

Tool, saved. It can thus be read out and assigned in a later positioning process with little effort.

To separate the tool from the tool chuck, for example after the use of the tool has ended, the tool must be removed from the chuck. If the tool is broken, the stump remaining in the chuck may not be long enough to be able to grasp it from the chuck. In addition, a tool can be hot due to a shrinking process, so that it can be is taken out with a gripper. It can happen that the tool shank does not protrude far enough from the tool chuck to be sufficiently tangible. By loosening the fixation of the tool in the tool chuck and then ejecting the tool from the tool chuck with the help of the positioning device, the tool shank can be lifted out of the tool chuck to such an extent that it can be gripped by a gripper. In the following, ejection is understood to mean lifting the tool in the chuck, the distance of the lifting being irrelevant. The tool can be lifted out of the chuck in whole or in part.

A positioning stop is expediently moved toward the tool before the fixation is released. This can prevent the tool from falling onto the stop over a long distance when it is loosened and from being displaced or impaired in an undesired manner. The positioning stop is moved directly to the tool or only in the vicinity by moving it.

An unwanted adjustment of the positioning stop can also be prevented by bringing it together with the tool before ejecting it and, if a predetermined contact pressure of the tool against the positioning stop is exceeded, an ejection process is interrupted. If the tool is jammed in the tool chuck, damage to the positioning device can also be prevented. Merging takes place by moving the positioning stop towards the tool or vice versa, for example by the tool falling onto the stop. It is further proposed that pressing the tool onto a positioning stop is processed into a release signal for an ejection process. The ejection process can be effectively prevented before the fixation is released. For example, if the tool falls down, the tool is released in the chuck and hits the positioning stop. This impact can be registered, for example by a sensor, and the ejection can begin. Pressing occurs when the tool lies on or falls down on the stop.

In the case of a tool chuck in particular, the receiving opening of which is widened by the supply of heat, the positioning device can be adjusted before the heating, so that when the tool chuck is heated or the receiving opening is widened, the weight of the tool can simply slide into the tool chuck until it reaches the positioning device comes into contact and the target position is reached. The tool can be inserted quickly into the tool chuck, and long keeping warm or maintaining a temperature of the tool chuck can advantageously be avoided. This can reduce the risk of a possible structural change in the tool chuck.

The measurement is advantageously carried out by bringing the tool into contact with a measuring stop and determining the position of a measuring point that characterizes the tool with respect to the measuring stop. The length of the tool can be easily determined by design using the measuring has a position defined in a coordinate system and the length between the measuring point and the measuring stop is determined. If the measuring stop is integrated in a receiving area of a tool holder, the length of the tool can already be determined while the tool is in the tool holder. Removing the tool from the tool holder for the purpose of measurement can thus advantageously be avoided. The tool holder can be formed by a tool holder that is separate from the positioning device.

If the tool is held in a tool magazine that has tool holding areas for at least two tools while the measurement is being carried out, the length of the tools located in the holding areas can advantageously be determined in one work step. The tool receiving areas can have different diameters, one diameter being assigned to a certain diameter of the receiving opening of the corresponding tool chuck. A determination of the length of the respective tool suitable for the tool chuck immediately before and / or during insertion into the tool chuck can thus advantageously be avoided and a flowing and fast workflow can be achieved.

It is also conceivable that several tool holder openings have the same diameter. The tool in the tool chuck can be exchanged after use with one of the already measured tools from the tool magazine, the tool from the tool magazine using the positioning device in its target position in the factory. Stuff is positionable. Movements can be improved and the time for changing the tool can thus advantageously be reduced.

If the tool magazine can be combined with a magazine for tool chucks, the tools located in the tool holder areas and their determined lengths can be assigned to appropriate tool chucks using suitable codes. When a specific tool chuck is selected, the positioning device can be set accordingly and the tool corresponding to the tool chuck can be used in its desired position in the tool chuck. The tool chuck or the tool can be inserted manually and / or automatically. If the insertion is automatic, the operator can position the tool quickly and independently in its target position in the tool chuck.

In a further embodiment of the invention, it is proposed that the measurement be carried out without contact. The position of the measuring point characterizing the tool can be determined simply, quickly and precisely, in particular with a measuring device having optics, wherein damage through contacts between the tool and the measuring device can be avoided. However, other points and / or positions that the person skilled in the art considers useful, such as in particular a reference point on the tool chuck, a check of the target position after being fixed in the tool chuck, etc. can also be determined by means of the measuring device without contact risk of injury to an operator from measuring points Tool cutting, which would be present with a manual determination, can advantageously be avoided.

The target position of the tool in the tool chuck is advantageously defined with respect to a reference point, as a result of which the target position can always be checked. Once the reference point has been defined on the tool chuck, the target position of the tool in the tool chuck can easily be checked in a cutting machine.

In a further embodiment of the invention, it is proposed that the tool in the tool chuck be brought into contact with at least one positioning element when the desired position is reached. A simple positioning can be achieved in which the weight of the tool when it is inserted into the tool chuck can slide into the tool receiving area until the desired position is reached.

If the positioning element for positioning the tool is at least partially moved in the tool chuck in the axial direction, the positioning device can be set in a structurally simple and exact manner. The positioning device forms a stop for the tool, and the tool always comes into contact with the positioning element set in the axial direction in the desired position.

It is also proposed that the tool chuck be heated to receive the tool and cooled to fix the tool in the desired position, in particular by a cooling device. The tool can be thermally clamped precisely and evenly in its target position. A change The set position by mechanical clamping elements can advantageously be avoided.

drawing

Further advantages result from the following description of the drawing. In the drawing, an embodiment of the invention is shown. The drawing, the description and the claims contain numerous features in combination.

The person skilled in the art will expediently also consider the features individually and combine them into useful further combinations.

Show it:

Fig. 1 is a schematic representation of a setting and

Measuring device with a positioning device, FIG. 2 a tool magazine from above and FIG. 3 an enlarged sectional view of the positioning device from FIG. 1.

Description of the embodiment

1 shows a device designed as a setting and measuring device 48 for fastening a tool 10, 12 in a tool chuck 14 with a positioning device 20 for positioning the tool 10 in a desired position 54 (FIG. 2). The setting and measuring device 48 comprises a means 40 for acquiring tool parameters and a heating device 62 for thermally deforming tool chucks 14. The target position 54 here is the position of a tool 10 positioned in the tool chuck 14 to a prescribed length dimension Z _s .

The setting and measuring device 48 has a data processing system 42 with a screen 50 as a data output unit. With the data processing system 42, measured values, e.g. a certain length Zi of tools 10, 12 can be stored and called up. Arranged in a central region of the setting and measuring device 48 is a measuring slide 52 which can be moved in the axial direction 16 and opposite to the axial direction 16 and is mounted on linear axes (not shown in more detail). The linear axes are protected in a housing 56. The means 40 for determining a length Zi of the tool 10 in the axial direction 16 with respect to a shaft end 18 is mounted on the measuring slide 52 (FIG. 2). The means 40 has a CCD camera device (not shown in more detail) with which, in addition to the determination of the length Zi, parameters of the tools 10, 12 can also be detected in transmitted light and in incident light. The means 40 is connected to the data processing system 42 via lines, not shown. The positioning device 20 is arranged after the housing 56 of the linear axes.

The setting and measuring device 48 also comprises a tool magazine 28 which is formed by a tool turret which can be rotated about the axial direction 16. The tool magazine 28 has a plurality of receiving areas 30 for receiving tools 10, 12 with different diameters (FIG. 2). The receiving areas 30, the diameters of which can be freely selected, are located in a radially outer area of the tool magazine 28. assigns. Each receiving area 30 has an identically shaped measuring stop 22 with a stop surface 44. The measurement stops 22 are all immovable relative to the associated receiving areas 30.

Each receiving area 30 can be pivoted from a waiting position into a measuring position by rotating the tool turret. In this case, a tool 10 held in the receiving area 30 can be focused by the camera device, whereas a tool 12 cannot be focused in a waiting position.

In a radially inner area, the tool magazine 28 has a receiving area 60 for a tool chuck 14. The receiving area 60 is arranged centrally in the tool magazine 28. When the tool magazine 28 rotates about the axial direction 16, a tool fixed in the tool chuck 16 is also rotated about its axial direction 16. The tool magazine 28 is designed as a high-precision spindle, in the receiving area 60 of which the tool chuck can be inserted and fixed for various tool chucks 14. The measuring stops 22 can thus be indirectly attached to the tool chuck 14, so that they can be brought into a defined position relative to the tool chuck 14.

The setting and measuring device 48 also has a heating device 62 which can be moved in the axial direction 16 and counter to the axial direction 16 and has an induction head 64 (FIGS. 1 and 3). The tool chuck 14 located in the receiving area 60 of the tool magazine 28 is heated with the induction head 64. Furthermore, on the setting and measuring device 48 Different cooling adapters 66 are arranged for cooling the tool chuck 14.

To determine the length Zi of at least one of the tools 10, 12, the tool 10 is inserted into one of the receiving areas 30 of the tool magazine 28. Here, the tool 10 is brought into contact with its shank end 18 with a surface 44 of a measuring stop 22, a distance Z ₃ between the stop surface 44 of the measuring stop 22 and a reference point 32 being known.

The reference point 32 is formed by a marking which is attached to an outwardly facing surface of the tool chuck 14. The reference point 32 can be checked contactlessly by means 40 of the setting and measuring device 48. Furthermore, the target position 54 of the tool 10 in the tool chuck 14 is defined via the length dimension Z _s between a measuring point 26 characterizing the tool 10 and the reference point 32.

In a next step, means 40 is used to carry out a contactless measurement, from which the length Zi of the tool 10 located in the tool magazine 28 in the axial direction 16 with respect to the shaft end 18 or a value characterizing the length Z is determined. For this purpose, the position of the measuring point 26 characterizing the tool 10 with respect to the measuring stop 22 is determined. With the position of the measuring point 26 and with the known distance Z _{3 of} the stop surface 44 from the reference point 32, the length Zi of the tool 10 located in the tool magazine 28 can thus be determined in a simple manner. It is also possible to change the lengths rerer or all of the tools 10, 12 located in the tool magazine 28, for example one after the other, before one of the tools 10, 12 is fixed in the tool chuck 14.

A positioning element 34, which can be controlled via an adjusting unit 70 and can be moved in the vertical axial direction 16 and counter to the axial direction 16, has a positioning stop 24 with a stop surface 46. The stops 22 and 24 or their stop surfaces 44 and 46 are shaped identically and formed by steel balls. In a defined starting position 36, the positioning element 34 has a known distance Z ₂ between the stop surface 46 of its positioning stop 24 and the reference point 32.

So that the tool 10 comes into contact with the positioning stop 24 of the positioning device 20 when the desired position 54 is reached, the positioning element 34 is moved via the adjusting unit 70 by an adjusting path Z ₄ in the axial direction 16 into a second position 38 in the tool chuck 14 , The adjustment path Z ₄ results from the distance Z and the prescribed target position 54 of the tool 10 minus the determined length Zi of the tool 10. The positioning device 20 is used to position the tool 10 in the target position 54 by the determined adjustment path Z ₄ for the respective tool 10, and the positioning element 34 forms a stop for the tool 10 when the desired position 54 is reached.

Before, during or after the adjustment path Z _{4 is} determined and the positioning element 34 via the adjustment unit 70 has been positioned, the tool chuck 14 is heated via the induction head 64 of the heating device 62. The receiving area 68 of the tool chuck 14 widens, and the manually or automatically insertable tool 10 slides vertically downward into the receiving area due to its weight

68. In order to avoid getting stuck in the receiving area 68, the tool 10 is pressed into the receiving area 68 via an additional plunger 72. When the target position 54 is reached, the tool 10 comes into contact with the positioning stop 46 of the positioning element 34.

The heating device 62 is removed and the tool chuck 14 is cooled via a corresponding cooling adapter 66. The tool 10 is fixed in its desired position 54 in the tool chuck 14. The correct target position 54 of the tool 10 in the tool chuck 14 is then checked contactlessly by means 40.

To remove the tool 10 - or in the case of a broken tool to remove the tool stump - from the tool chuck 14, the positioning element 34 is moved into a range of a few mm below the shaft end of the tool 10. The tool chuck is then heated in the manner described above, so that the receiving area 68 widens again. Here, the tool falls 10 or

Blunt down onto the positioning element 34. The associated pulse acting on the positioning element 34 is registered by a sensor (not shown) and processed in the data processing system 42 to form a release signal for an ejection process. Triggered by the release signal, the positioning element 34 moves upward. As a result, the positioning element 34 and the tool 10 are brought together, and the positioning element 34 exerts a contact pressure on the tool 10 and pushes the tool 10 out of the tool chuck 14 by a presettable distance. If the tool 10 is jammed, the contact pressure exceeds a predetermined value, the contact pressure being measured by the sensor described above or by another sensor. If this is exceeded, the ejection process is stopped by the data processing system 42 and an error message is output on the screen 50.

18th 06. 03

reference numeral

10 Tool 54 target position

12 tool 56 housing

14 tool chuck 58 circumferential direction

16 axial direction 60 receiving area

18 Shank end 62 heater

20 Positioning device 64 induction head

22 Measuring stop 66 cooling adapter

24 Positioning stop 68 Recording area

26 Measuring point 70 adjustment unit

28 tool magazine 72 plunger

30 Recording area Z _s length dimension

32 Reference point Zx length of the tool

34 positioning element Z ₂ distance

36 Position Z ₃ distance

38 Position Z adjustment path

40 means

42 Data processing system

44 stop surface

46 stop surface

48 Presetting and measuring device

50 screen

52 measuring slides

Claims

18.06.03Ansprüche

1. Device for fastening a tool (10) in one

Tool chuck (14) with a positioning device (20) for the vertical positioning of the tool (10) in a desired position (54) in the tool chuck (14), characterized by a measuring device with a means (40) for determining a length (Zi) of the tool (10) in the axial direction (16), a receiving area (30) separate from the tool chuck for receiving the tool (10) and a measuring stop (22) which is immovable relative to the receiving area (30).

2. The device as claimed in claim 1, so that the measuring device comprises at least two receiving areas (30), each with a measuring stop (22).

3. Device according to claim 1 or 2, so that the recording area (30) can be moved, in particular pivoted, from a waiting position into a measuring position.

4. Device according to one of the preceding claims, characterized in that the receiving area (30) is arranged in a rotatable turret.

5. The device according to claim 4, so that a tool (10) fastened in the tool chuck (14) can be rotated by rotating the turret.

6. Device according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the measuring stop (22) can be brought into a defined position relative to the tool chuck (14).

7. The device as claimed in claim 6, so that the measuring stop is part of a spindle into which the tool chuck (14) can be inserted.

8. A method for fastening a tool (10) in a tool chuck (14), in which the tool (10) is inserted into the tool chuck (14) in the vertical direction and after reaching an axial desired position (54) in the tool chuck (14 ) is fixed, characterized in that, before the tool (10) is inserted into the tool chuck (14), a value characterizing the length (Zi) of the tool (10) in the axial direction (16) is determined by means of a measurement and a positioning device ( 20) for positioning the tool (10) in the desired position (54). Method according to claim 8, characterized in that the measurement is carried out by inserting the tool (10) into a receiving area (30) of a measuring device and bringing it into contact with a measuring stop (22) which is immovable relative to the receiving area (30) and the position of a measuring point (26) characterizing the tool (10) with respect to the measuring stop (22) is determined.

10. The method according to claim 8 or 9, characterized in that a value characterizing the length (Zi) of a first tool (10) is determined and before fixing the first tool in the tool chuck (14) a length (Zi) of a second tool (10 ) characterizing value is determined.

11. The method according to any one of claims 8 to 10, characterized in that after fixation of the tool (10) in the target position (54), the actual position of the tool (10) is measured and a difference between the target position (54 ) and the actual position are saved and used as a correction value in a later positioning process.

12. The method as claimed in claim 11, so that the subsequent positioning process takes place after the tool (10) has been removed and the tool (10) has been reinserted into the tool chuck (14).

13. The method according to any one of claims 8 to 12, so that the fixation of the tool (10) in the tool chuck (14) is released and the tool (10) is then ejected from the tool chuck (14) with the aid of the positioning device (20).

14. The method according to claim 13, so that a positioning stop (24) is moved towards the tool (10) before releasing the fixation.

15. The method according to claim 13 or 14, characterized in that before the ejection a positioning stop (24) and the tool (10) are brought together and an ejection process is aborted when a predetermined contact pressure of the tool (10) on the positioning stop (24) becomes.

6. The method according to any one of claims 13 to 15, that a pressing of the tool (10) on a positioning stop (24) is processed into a release signal for an ejection process.