EP0365976A2 - Profiling machine - Google Patents

Abstract

A rolling mill wherein the frame or frames for pairs of superimposed rolling tools can be lifted off the base by a crane. Each rolling tool carries a first clutch element receiving torque from a separable discrete second clutch element on a support which is adjacent a properly installed frame. The support is mounted on a reciprocable carriage, together with or independently of a drive for the second clutch elements, and can be moved in the axial direction of the tools toward and away from the adjacent frame. The upper second clutch element of the pair of second clutch elements on the support is movable up and down by a fluid-operated motor toward and away from a position of alignment with the corresponding first clutch element. The second clutch elements have pins which enter registering sockets in the adjacent first clutch elements, or vice versa, and the second clutch elements are axially movably mounted in their bearings on the support and are biased toward the respective first clutch elements. The second clutch elements are disengaged from the respective first clutch elements by moving the support away from the adjacent frame. A sensor cooperates with a stop to ensure that each movable second clutch element moves to a position of accurate alignment with the respective first clutch element, and the carriage can be moved toward the frame only when the alignment of the movable second clutch element with the respective first element is completed.

Description

The invention relates to a profiling machine with one or more pairs of forming rollers arranged one behind the other in the feed direction of a workpiece, each of which is mounted in tool stands by means of working shafts, in addition to which a drive with a gear block and between the latter and the ends of the working shafts facing it are pushed together in their length and pulling apart adjustable cardan shafts and couplings are provided as detachable connections between the cardan shafts and the working shafts, a coupling frame or carrier being arranged between the respective tool frame and the associated gear block, on the side facing the gear block the cardan shafts and on the side facing the tool frame the releasable couplings for the working shafts are arranged.

Profiling machines are known and allow the production of profiles with relatively complicated cross sections from strips or sheet metal strips with high accuracy and high speed. When changing from a product to a product with a different cross-section, however, there is a loss of time due to the change of the forming rolls, which must first be disengaged and removed and replaced with new sets of rolls, which must then be engaged again. From DE-OS 22 43 534 and JP-Patent-Abstracts, M-373,1985, Vol. 9 / No.92 a profiling machine of the type mentioned at the outset is known, in which the block containing the forming rollers is exchanged in the longitudinal direction of the drive shafts must be brought out of the coupling position before it can be lifted off and replaced in the reverse order with a new tool set. The working shafts and their scaffolds must therefore first be moved on their substructure until the couplings are released before a tool change can be carried out.

For such cases, aids are known from DE-AS 24 39 017 which are intended to facilitate the replacement of pairs of forming rollers. Above all, the new adjustments and adjustment work that are necessary when replacing such forming rolls are to be avoided. This aid consists in a fixation and support device which can be supported on the machine part, each for a pair of forming rollers, so that the replacement of the individual forming rollers is also time-consuming and difficult. Above all, considerable personnel expenditure is required.

According to DE-OS 25 56 974, a profiling machine was therefore created, in which two superimposed pairs of forming rollers for different profiles are provided to shorten changeover times in a roll stand. As a result, however, the number of profiles of different cross sections that can be produced with this profiling machine is limited to a minimum.

A solution is known from DE-OS 25 56 974, in which turntables, each with a plurality of forming rollers of pairs of forming rollers, are arranged on the stands of the roll stands or on the tool carrier. Although there is a somewhat greater possibility of variation depending on the capacity of these turntables, the number is of the profiles that can be produced continues to be limited. In addition, there are constructive problems with the arrangement of the turntables, which have to be adjusted very precisely in their respective working position in order to eliminate manufacturing inaccuracies from the inevitable play of these turntables.

It is therefore the task of creating a profiling machine of the type mentioned at the outset, in which individual or all forming roller pairs can be exchanged quickly and fully automatically, as required, in order to limit the downtime of the profiling machine to a minimum and still produce profiles of different cross sections in succession to be able to.

The solution to this problem is that the coupling frame or the coupling carrier, together with the coupling half facing it, can be moved or displaced transversely to the feed direction of the workpiece and transversely to the working direction of the forming rollers from the tool frame and the coupling half facing this, that at least the bearing of the upper one PTO shaft on the coupling frame or carrier is mechanically adjustable in height and a sensor, sensor, switching element or the like on it or on the tool frame. is provided for automatic and automatic adjustment to the respective height of the counter-coupling half of the associated working shaft and that the displacement drive for the coupling frame is controlled in such a way that the displacement movement for engaging or its last section only after the height adjustment of the coupling half of the coupling frame or carrier the coupling half of the tool frame is done.

These measures and features make it possible to detach a tool frame with the interchangeable pairs of forming rollers from its drive without having to move it yourself. Instead, the coupling frame or a coupling carrier with the Corresponding coupling half is moved away from the tool frame and, after the shaping rollers have been replaced, the coupling is carried out by a reverse movement. The height of the coupling halves is previously adjusted to each other fully automatically before the sliding movement of the coupling frame or the like. takes place in the working position or is ended. The complete roller tool, which can consist of one or more pairs of forming rollers arranged one behind the other, can be quickly and fully automatically changed in one or more tool stands arranged one behind the other in as short a time unit as possible, by exchanging one tool frame after another without, without to have to be postponed beforehand so that unproductive downtimes that occur during the changeover are reduced to a minimum.

For a structurally simple solution and at the same time precise mode of operation, it is advantageous if the gear block and the coupling frame or the like. are fastened to a common gear carrier, which is mechanically adjustable by means of a drive in guides, for example sliding guides, transversely to the feed direction of the workpiece, in particular at right angles to the feed direction. As a result, the distance between the gear block and clutch remains unchanged and it is only necessary to compensate for the changing altitude, especially of the upper clutch on the coupling frame or carrier, by means of the cardan shafts located between the gear block and coupling frame. A single drive is sufficient for the transverse displacement. For example, the like can be used to move the gear block with the coupling frame. a motor-driven spindle can be provided, which also makes it possible to first carry out a first part of the displacement path when engaging, before then adjusting the height of those located in the coupling frame or on the coupling carrier Chen coupling half on a possibly by the tool change located at a different height coupling half on the forming rollers, after which the final displacement movement of the gear block and the coupling frame or the like. is feasible in the working position. This shifting movement of the gear block can therefore take place in two steps.

A modified embodiment in which the movable masses are reduced may consist in the fact that the gear block and the coupling frame or the like. are each attached to their own support or bearing and only the coupling frame or the like. or the like, the coupling frame. load-bearing beams by means of a drive, e.g. a motor-driven spindle, preferably in guides, is mechanically adjustable transversely to the feed direction of the workpiece. This is possible without any problems because the length of the cardan shafts can be adjusted in a known manner by pulling them apart and pushing them together, which also favors the height adjustment of the individual couplings.

A particularly expedient, the fully automatic adjustment of the height of the coupling halves facilitating embodiment of the invention can consist in that as a sensor or sensor on the coupling frame or the like. or, if appropriate, an arm, preferably oriented parallel to the axis of the coupling shaft, is provided on the tool frame, which fixes the coupling half in its coupling position to the counter-coupling half at the end of the height adjustment with a counter stop. It can thus be effected in a purely mechanical way by means of a stop arm and a counterstop that the height adjustment of the one coupling half is ended at the right moment, namely when the coupling halves have arrived in the same position for engaging.

An advantageous embodiment can consist in that the counter stop for the arm is one of the coupling halves. For example, the stop arm coupling frame or the like. attached, the coupling half located on the tool frame can be its counter-stop.

A working cylinder, in particular a pneumatic cylinder, or a servomotor can be provided as the drive for the height adjustment of the coupling. Such drive means can namely be stopped by a mechanical stop even when they are still under pressure or current, so that no great control effort and the like is required for the automatic alignment of the two coupling halves to one another in their coupling position.

It should also be mentioned that both the upper and the lower bearing of the drive shafts on the coupling frame or the like. can be mechanically adjustable in height so that the couplings for a pair of forming rollers can be adapted to the working shafts.

One of the coupling halves, in particular that of the sliding coupling frame or the like. worn coupling half, in turn - or the like - compared to the coupling frame. - Be axially displaceable against a restoring force. This applies in particular to couplings whose halves interlock positively. If the two halves do not yet fit into each other when engaging, because they are offset in the direction of rotation, one half of the coupling can initially dodge. It is then sufficient to briefly start the drive in order to bring the matching parts, for example coupling pins and coupling perforations or the like, into alignment, so that the restoring force then ends the engagement movement of the displaceable coupling half.

The restoring force for the preferably on the coupling frame or the like. located coupling halves can be generated by compression springs and both coupling halves located on the coupling frame can be axially displaceable against spring force.

The fully automatic tool change and in particular also the fully automatic re-coupling can be promoted and improved in that sensors are provided for monitoring the coupling process, which block the drive until the end of the coupling process. This ensures that the drive of the profiling machine and the forming rollers can only start again when all the couplings are really engaged and ready for operation. Further embodiments of the invention are the subject of claims 11 and 12.

Combining one or more of the features and measures described above results in a profiling machine of the type mentioned at the outset, in which one or more forming rolls can be exchanged fully automatically, care also being taken to ensure that the coupling movement required in each case can take place fully automatically. Nevertheless, the entire construction is simple and therefore comparatively inexpensive.

• Fig. 1 einen Querschnitt einer Profiliermaschine mit ei­ner Ansicht auf ein Umformrollen-Paar, dessen Werk­zeuggerüst, ein in axialer Richtung der Arbeits­wellen daneben angeordnetes Kupplungsgerüst und den zugehörigen Getriebeblock,
• Fig. 2 in vergrößertem Maßstab und teilweise im Längs­schnitt gehalten vor allem das Kupplungsgerüst mit den Kupplungen für die Arbeitswellen der Umform­rollen auf der einen Seite und den Gelenkwellen als Verbindung zu dem Getriebeblock auf der ande­ren Seite, sowie
• Fig. 3 in schematisierter Darstellung eine abgewandelte Pro­filiermaschine, bei welcher nur das Kupplungsgerüst in axialer Richtung der Arbeitswellen verschiebbar ist.

The invention is described in more detail below with its details that are essential to it, using the drawing. It shows in a partially schematic representation:

• 1 shows a cross section of a profiling machine with a view of a pair of forming rollers, its tool frame, a coupling frame arranged next to it in the axial direction of the working shafts, and the associated gear block,
• Fig. 2 on an enlarged scale and partially in longitudinal section mainly held the coupling frame with the couplings for the working shafts of the forming rollers on one side and the cardan shafts as a connection to the gear block on the other, as well
• Fig. 3 shows a schematic representation of a modified profiling machine, in which only the coupling frame is displaceable in the axial direction of the working shafts.

A profiling machine, designated as a whole by 1, has, in a known manner, either one or several pairs of forming rollers 2 in the feed direction of a workpiece, which are formed in a known manner from matching forming rollers 3 and 4, the outer contours of which in their working area are to be formed on them Generate cross-section of the workpiece. These forming roller pairs 2 are with Working shafts 5 are each mounted in a tool frame 6, which is constructed on a tool carrier 8 which is detachably fastened to the profiling machine 1 or its underframe 7, a lifting device (not shown in more detail) for lifting and exchanging these tool frames 6 being provided. In the exemplary embodiment, the tool carriers 8 are centered on the machine base frame 7 by means of centering bolts 9, which fit corresponding perforations. However, other positioning and / or centering devices could also be provided.

In the exemplary embodiment, the tool frame 6 consists of a lower bearing housing 10, columns 11 embedded therein on both sides and upper bearing housings 12 and a yoke 13, each of which carries an adjusting screw 13a which determines the position of the respective upper bearing housing 12. The bearing housings 10 and 12 contain the bearings for the working shafts 5 of the lower and upper forming rollers 4 and 3. The distance between the lower and upper working shaft 5 and thus the position of the upper bearing housing 12 is determined by the diameter of the upper forming roller 3 and is different from pair of forming rollers to pair of forming rollers.

The working shafts 5 also carry counter-coupling halves 14 of couplings 15 at their ends facing away from the forming rollers 3 and 4.

In addition to the tool stands 6 there is a drive with a gear block 16 and between this and the ends of the working shafts 5 facing it, drive shafts 17 and the couplings 15 for releasing the drive connection of the forming rollers 3 and 4 for their replacement can be seen.

A coupling frame 18 is provided between the respective tool frame 6 and the associated gear block 3, on the side facing the gear block 3 the articulated shafts 17 and on the side facing the tool frame 6 the releasable couplings 15 for the working shafts 5 are arranged. Instead of the coupling frame 18, a different type of coupling carrier or holder could also be provided. The gear block 3 can now be moved together with the coupling frame 18 transversely to the direction of advance of the workpiece and transversely to the working direction of the forming rollers 3 and 4 to release the couplings 15 away from the tool frame 6 in the direction a of the double arrow Pf 1.

The height of the mounting of the upper propeller shaft 17 on the coupling frame 18 can be adjusted mechanically, so that the coupling half 19 of the coupling 15 assigned to it can also be adjusted in height. In the exemplary embodiment, a sensor to be described in more detail for automatic and automatic adjustment to the respective height of the mating coupling or coupling half 14 of the associated working shaft 5 is provided on the coupling frame 18. The shift drive for the gear block 16 with the coupling frame 18 is now controlled such that the shifting movement or its last section in direction b of the double arrow Pf 1 for coupling takes place only after the height adjustment of the coupling on the coupling frame. With a sufficiently long sensor, either the height adjustment and then the complete displacement movement of the gear block 16 could take place.

In the exemplary embodiment, however, it is provided that the drive group consisting of gear block 16 and coupling frame 18 is shifted in the direction b of the double arrow Pf 1 to the point b1, where the shifting movement is interrupted and the upper bearing housing 18a of the clutch gear scaffold 18 is adjusted in its altitude until this vertical adjustment movement is limited and ended by the sensor to be described in more detail. If the coupling halves 19 and 14 are at the same height, the drive group can be shifted further from b1 to b in order to end the engagement of the coupling.

The gear block 16 and the coupling frame 18 are fastened on a common gear carrier 20, which is mechanically adjustable by means of a drive, in the exemplary embodiment of a motor-driven spindle 21, in or on guides 22 transversely to the feed direction of the workpiece. The drive motor 23 for the spindle 21 can be seen in FIG. 1.

As a sensor or sensor for adjusting the height of the upper coupling and its coupling half 19 located on the coupling frame 18, an arm 25 oriented parallel to the axis of the coupling shaft 24 is provided in the exemplary embodiment on the coupling frame 18, but could also be reversed on the tool frame 6, and which, together with a counterstop, ends the height adjustment of the two coupling halves in their coupling position.

It can be clearly seen in FIGS. 1 and 2 that the height adjustment of the coupling half 19 means the corresponding height adjustment of this arm 25 until it comes to rest on its counter-stop, in the exemplary embodiment of the coupling half 14. This represents a very simple height adjustment of the two coupling halves 14 and 19 to one another, which can nevertheless take place fully automatically.

A preferably pneumatic working cylinder 26 is provided for height adjustment of the upper coupling half 19, but this could also be accomplished by a servomotor.

In Fig. 2 it can be seen that the one coupling half, in the exemplary embodiment the coupling half 14 located on the working shaft 5, perforations 27 and the other coupling half coming into operative connection therewith, in this case the coupling half 19 having coupling pins 28 fitting into these perforations 27, which taper somewhat at the end to simplify the coupling process. Nevertheless, it could happen that the holes 27 and the coupling pins 28 are offset against one another in the direction of rotation when engaging in such a way that the coupling process does not initially take place. It is therefore provided that one of the coupling halves, in this case the coupling half 19 carried by the coupling frame 18, is axially displaceable against a restoring force, the restoring force for the axially adjustable coupling half 19 each being generated in the exemplary embodiment by a compression spring 29. In Fig. 2 it can be seen that both coupling halves 19 of the coupling frame 18 can dodge axially against the force of such a compression spring 29 if the coupling pins 28 do not meet in the holes 27 when performing the coupling movement, this case in the drawing on the lower Coupling is shown.

In this case, sensors (not shown in more detail) can be provided for monitoring the engagement process, which block the drive for the transmission block 16 until the coupling process has ended. If the pins 28 are somewhat offset relative to the perforations 27, the drive can be briefly rotated until the pins can enter the perforations.

The changing of the forming roller pairs can therefore take place fully automatically in this profiling machine 1 in the following way:

The drive group comprising the transmission block 16 and the coupling frame 18 located on the transmission carrier 20 is moved in the direction a by means of the spindle 21 driven by the motor 23 on the guides 22 according to the double arrow Pf 1. As a result, the coupling pins 28 are pulled out of the perforations 27 in the coupling halves 14 so that the tool carrier 8 carrying the tool frame 6 can be lifted off by means of a lifting device. This lifting device can be provided with access to a tool magazine in which the complete tool frame 6 with tool carrier 8 can be stored. The same lifting device can take another complete tool from the same tool magazine and place it on the base of the profiling machine 1, the positioning and centering being carried out by the centering bolts 9.

Thereafter, the upper coupling halves 19 or coupling shafts 24 are moved vertically downward via their bearing housings by means of working cylinders 26 until the upper bearing housing 18a rests on the lower bearing housing 18b.

For coupling together, the gear carrier 20 now moves with the gear block 16 and the coupling frame 18 in the horizontal direction according to the double arrow Pf 1 in direction b. Due to the different diameters of the forming rollers 3 and 4 from the forming roller pair to the forming roller pair, the position of the upper working shaft 5 and thus the upper coupling half 14 also changes with each exchanged forming roller pair. So that the pins 28 of the coupling half 19 can be inserted into the holes 27 of the coupling half 14, the height of these coupling halves 14 and 19 must be adapted to one another. This is done by interrupting the infeed of the gear carrier 20 in direction b at b1, that is to say after part of the distance, and then lifting the upper bearing housing 18a of the coupling frame 18 upwards by means of the cylinder 26.

This stroke movement is automatically and automatically limited by the adjusting arm 25. If this arm 25 is in contact with the coupling half 14 serving as a counterstop, the position is reached in which the pins 28 of the coupling half 19 can be moved into the holes 27 in the coupling half 14, which is caused by a further displacement of the drive group in the direction of the double arrow Pf 1 from b1 to b.

In the manner already described, the respective coupling half 19 can dodge axially in the axial direction against the force of the spring 29 if the pins 28 do not exactly meet the perforations 27. With a slight rotational movement of the coupling halves 19, the pins can be brought into line with the perforations and then inserted by the springs. This completes the tool change process fully automatically and very quickly and machine 1 is ready for production again.

A profiling machine 1 with one or more pairs of forming rollers 2 arranged one behind the other in the direction of feed of a workpiece, which are parted in tool stands 6, has between a gear block 16 and the ends of the working shafts 5 of the shaping rollers 3 and 4 facing them 17 and couplings 15 for Loosen the drive connection of the forming rollers 3 and 4 if they are to be replaced. A coupling frame 18 is provided between the respective tool frame 6 and the associated gear block 3, on the side facing the gear block 3 the articulated shafts 17 and on the side facing the tool frame 6 the releasable couplings 15 for the working shafts 5 are arranged. The gear block 3 can together with the coupling frame 18 transversely to the direction of advance of the workpiece and transversely to the working direction of the forming rollers 3 and 4 for releasing the couplings 15 be moved away from the tool frame 6. The mounting of at least the upper propeller shaft 17 can be adjusted mechanically in height on the coupling frame 18 and either on the coupling frame 18 or on the tool frame 6 there is a sensor or the like. Switching element for automatic and automatic adjustment to the respective height of the counter clutch 14 is provided. The displacement drive for the gear block 16 with the coupling frame 18 is controlled in such a way that the displacement movement or its last section for coupling only takes place after the height adjustment of the coupling halves on the coupling frame. It should also be mentioned that instead of the arm 25 which can be displaced from the bottom upwards against the counter-stop, in the exemplary embodiment the coupling half 14, the latter could also be reversely adjustable downward from an upper starting position of the bearing housing 18a.

In both cases, the arm 25 is attached to the height-adjustable bearing housing 18a and the counter-stop is arranged in its adjustment path. If it is on the roll stand, the coupling half 19 can come to rest against the arm 25 when the adjustment takes place from a lower or upper starting position if the height positions of the coupling halves match.

3 shows a somewhat modified embodiment of a profiling machine 1, in which all the essential parts and their functions correspond and which are therefore marked accordingly in the drawing, but are no longer described in detail. - claims -

In contrast to the embodiment according to FIGS. 1 and 2, however, it is provided in this embodiment according to FIG. 3 that the gear block 16 and the coupling frame 18 are each fastened on their own carrier or bearing 20a and 20b and only the coupling frame 18 or the carrier 20b carrying the coupling frame 18 can be adjusted by means of a drive, in the exemplary embodiment of a motor-driven spindle 30 in guides 31 transverse to the direction of advance of the workpiece and in the axial direction of extension of the working shafts 5. Since the drive shafts 17 are infinitely and automatically adjustable in length by pushing or pulling them apart and can also be adapted to different heights of the couplings, this adjustment movement of the coupling frame 18 is also possible without any problems regardless of the gear block 16.

Finally, it should also be mentioned that in both exemplary embodiments, both the upper bearing 18a and the lower bearing 18b of the drive shafts 17 on the coupling frame 18 can be mechanically adjustable in height in order to be able to adjust both couplings 15 to different height positions of working shafts 5. The height of the lower bearing 18b can be adjusted in the same way as that of the upper one.

Claims (12)

1. Profiling machine (1) with one or more pairs of forming rollers (2) arranged one behind the other in the feed direction of a workpiece, each of which is mounted in tool frames (6) by means of working shafts (5), next to which a drive with a gear block (16) and between this and the ends of the working shafts (5) facing it, the length of the articulated shafts (17) and couplings (15) which can be adjusted by pushing and pulling them apart are provided as detachable connections between the articulated shafts (17) and the working shafts (5), between the respective Tool frame (6) and the associated gear block (3) a coupling frame (18) or carrier is arranged, on the side facing the gear block (3) the cardan shafts (17) and on the side facing the tool frame (6) the releasable couplings ( 15) for the working shafts (5), characterized in that the coupling frame (18) or the coupling carrier together with d he facing the coupling half (19) transversely to the feed direction of the workpiece and transversely to the working direction of the forming rollers (3, 4) from the tool frame (6) and the counter-coupling half (14) facing this or is displaceable that at least the mounting of the upper propeller shaft (17) on the coupling frame (18) or carrier is mechanically adjustable in height and on it or on the tool frame (6) a sensor, sensor, switching element or the like. for automatic and automatic adjustment to the respective height of the counter-coupling half (14) of the associated working shaft (5) is provided and that the displacement drive (21, 23; 30) is controlled in such a way that the displacement movement for engaging or its last section only after the height adjustment of the coupling half (19) of the coupling frame (18) or carrier to the counter-coupling half (14) of the tool frame (6). 2. Profiling machine according to claim 1, characterized in that the gear block (16) and the coupling frame (18) or the like. are attached to a common gear support (20) which is driven by a drive, e.g. with a motor-driven spindle (21), preferably in guides (22), is mechanically adjustable transversely to the direction of advance of the workpiece. 3. Profiling machine according to claim 1, characterized in that the gear block (16) and the coupling frame (18) or the like. Each are attached to their own carrier (20a, 20b) or bearing and only the coupling frame (18) or the like. or the coupling frame (18) or the like. load-bearing beams (20b) by means of a drive, e.g. a motor-driven spindle (30), preferably in guides (31), is mechanically adjustable transversely to the feed direction of the workpiece. 4. Profiling machine according to one of claims 1 to 3, characterized in that as a sensor or sensor on the coupling frame (18) or on the tool frame (6) a preferably parallel to the axis of the coupling shaft (24) Oriented arm (25) is provided, which fixes the coupling half (19) in the coupling position to the counter-coupling half (14) at the end of the height adjustment with a counter stop. 5. Profiling machine according to one of claims 1 to 4, characterized in that the counter-stop for the arm (25) is one of the coupling halves (14). 6. Profiling machine according to one of claims 1 to 5, characterized in that both the upper and the lower bearing of the propeller shafts (17) on the coupling frame (18) or the like. are mechanically adjustable in height. 7. Profiling machine according to one of claims 1 to 6, characterized in that a working cylinder (26), in particular a pneumatic cylinder, or a servomotor is provided as the drive for the height adjustment of the coupling (15) or its bearing housing (18a, 18b). 8. Profiling machine according to one of claims 1 to 7, characterized in that one of the coupling halves, in particular that of the sliding coupling frame (18) or the like. worn coupling half (19), in turn - or the like opposite the coupling frame. - Is axially displaceable against a restoring force. 9. Profiling machine according to one of claims 1 to 8, characterized in that the restoring force for the like or preferably on the coupling frame. located coupling halves is generated by compression springs and both on the coupling frame or the like. located coupling halves are axially displaceable against spring force. 10. Profiling machine according to one of claims 1 to 9, characterized in that sensors are provided for monitoring the coupling process, which block the drive until the end of the coupling process. 11. Profiling machine according to one of claims 1 to 10, characterized in that the arm (25) or the like. Sensor is attached to the height-adjustable bearing housing (18a) and protrudes approximately horizontally against the rolling stand and the counter-stop is arranged in its adjustment path. 12. Profiling machine according to one of claims 1 to 11, characterized in that the upper bearing housing (18a) with the upper coupling half (19) relative to the other bearing housing (18b) is displaceable and that the bearing housing (18a) in the starting position, preferably on the other lower bearing housing (18b).

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