EP0083741A1 - Method and apparatus for making a corrugated structure - Google Patents

Abstract

1. A process for the continuous production of a corrugated member comprising a backing web (3) and a top web (2) which is arranged in a corrugated configuration on the backing web (3), wherein the top web is connected at connecting locations in the region of the depressions which extend transversely with respect to the direction of the web, by the backing web (3) being moved cyclically forwards relative to a shaping station (1) and the top web (2) which is to be connected to the backing web (3) being supplied from a feed means, and by the top web being deformed at the shaping station (1) by means of first and second pressing means (4, 5), over a deforming element (6) disposed between the two webs, and being pressed against the backing web (3) at the connecting locations, characterized in that at the shaping station (1), during a rest phase, a deforming element (6) is inserted laterally between the backing web (3) and the top web (2), that the first pressing means (4) which is downstream of the deforming element (6) in the direction of advance movement is lowered and then the second pressing means (5) which is upstream of the deforming element (6) in the direction of advance movement is lowered, in which operation the top web (2) is deformed and connected to the backing web (3), that the first pressing means (4) is raised and the deforming element (6) is withdrawn laterally, and that then the second pressing means (5) is raised and the backing web (3) is moved on by an advance step, and then the operation at the station begins afresh.

Description

Methods and devices for producing shaft parts are generally known and customary. Such as. German patent 494 407 or Swiss patent 263 453 show an upper web, in particular made of stiff paper or cardboard, is formed into waves and then connected to a carrier web. The top web can be shaped as desired and according to the shape of the goods to be packaged. The connection between the top and bottom web is made by an adhesive that is applied to the carrier web immediately before the top web is applied. Such shaft parts are usually produced by continuously deforming the top web. Adhesive is then applied and the carrier web is pressed against the continuously or discontinuously preformed top web and, together with it, is wound up on rollers to dry the adhesive under tension.

The known methods have various disadvantages, which are in particular that the waveform of a shaft part cannot be changed and that a continuous production process is not possible. In particular, the separation into individual process steps, namely shaping the top web, then bringing the top web together with the backing web, the separate introduction of adhesive, drying and subsequent cutting to the desired length make it impossible to produce efficiently.

The object of the invention is to avoid the disadvantages of the known, in particular to create a method and an apparatus for producing a shaft part, in which the method steps are simplified and minimized, the manufacturing process is shortened overall and shaft parts of any surface configuration can nevertheless be produced.

According to the invention, this object is primarily achieved by a method which is characterized in that the carrier web is moved forward step by step relative to a forming station and that the top web connected to the carrier web is fed by a feed device that after each feed step the top web is both pressed against at least one deformation element introduced between the carrier web and top web and also against the carrier web and deformed and at the same time connected to the latter, and that the step length of a feed step is dimensioned such that it corresponds at least to the distance from two successive connection points.

According to the invention, the deformation process of the top web coincides with the pressing and connecting of the top web with the carrier web, which shortens the process. The step-by-step conveying of the carrier web and the simultaneous, continuous pulling off of the top web from a feed device allow both the length of the feed steps and thus the width of the individual sections of a shaft part to be varied in an optimally simple manner and at the same time ensure that the top web is carried out without any special measures in the length required for the feed step and the configuration of the shaft part.

The method according to the invention can be implemented in a particularly simple manner in that firstly both the deformation element and also a first pressure device lying behind the deformation element in the feed direction are shifted into their working position, in which the deformation element is located between the carrier web and the top web and the first pressure device presses the top web against the carrier web, and then a second one lying in the feed direction in front of the deformation element Pressing device is pressed against the upper web in such a way that it is stretched or folded over the deformation element and pressed against the carrier web, and in each case is connected to the carrier web in at least a portion of the pressing region of the deformation elements.

This ensures in particular that only the length of the feed steps has to be set in order to set and / or adjust a specific configuration of the shaft part as a function of the deformation element and / or the pressure devices. The top web automatically adapts to the length of the feed steps, the configuration of the deformation element and the pressure devices due to the course of the deformation process and can be easily removed from a roll. Advantageously, the deformation element is first introduced between the top web and the carrier web and, at the same time, the first pressure device is pressed against the top web and the deformation element. This ensures crease-free deformation and in particular also allows the upper web to be deformed in accordance with the surface configuration of the deformation element and pressure devices.

The cycle can be further shortened if each connection point between the top web and the carrier web is acted upon by both the first pressure device and the second pressure device, and if the connection between the top web and the bottom web takes place during the pressing of both pressure devices. This enables, for example, the provisional connection of the upper web and carrier web in the area of the first line printing device and the subsequent permanent connection in the area of the second pressure device. Since the connection process is particularly time-consuming both when using adhesive or other drying or heat-curing or, in the general way, physically or chemically activatable connection media, as well as with welding processes or similar measures, the time required for each pressing or connection process can be shortened in many cases. In addition, this ensures according to the invention that more time is available for the pressing and connecting process under the first pressing device, since the first pressing device is pressed against the upper web in front of the second pressing device.

The connection of top web and backing web can be carried out very advantageously according to the invention if a heat-activatable medium is used to produce the connection and if the backing web and / or top web are heated in the area of the pressing devices during the pressing process. Such media, such as thermoplastic adhesives and The like can either be applied to the carrier web and / or top web during the advance, or are already located on at least one of the webs. To connect the top web and carrier web, all that is required is heating in the region of at least one pressure device takes place in the area of both pressure devices, it is evident that with the first pressure device a general heating of the adhesive and a provisional connection can be achieved, while in the area of the second pressure device the complete plastification and permanent The fifth connection is made.

Of course, the invention can, however, also be implemented using hot applied connection media or heat drying media. Stamped connections, other folded connections or positive connections and connections with mechanical connecting elements can also be used. Different wave forms can be produced in the simplest way on one and the same shaft part by the invention if the feed step length of a feed step is changed compared to a previous feed step. The adaptation of the upper part or the upper track to the changed configuration takes place automatically.

Shaft parts with different waveforms can also be produced if the surface configuration of the deformation element is changed in at least one deformation step compared to the shape during a previous deformation step. This can e.g. thereby achieve that multi-part deformation elements are used, or that different deformation elements are provided, which can be introduced alternately between the top web and the carrier web.

If a deformation of the top web is to be achieved laterally on the deformation element or on the deformation element, this can be achieved particularly simply by pressing the pressure device laterally against the deformation element and / or onto the deformation element. In this way, practically any surface configurations of the top web can be produced.

It is particularly advantageous if the top web is provided with waves or deformations of different heights and / or surface configurations in the transverse direction. This allows the use of the shaft part for packaging parts of different shapes.

The invention can be implemented in a particularly simple manner by means of a device which is characterized in that a shaping station with a shaping table is provided, on which the carrier web can be transported step by step in the longitudinal direction by means of a feed arrangement, that a feed device for the top web is arranged above the carrier web is that at least one deformation element is provided, which is arranged laterally to the shafts to be generated such that it can be inserted between the upper web and the carrier web to form a shaft section and after the shaping can be pulled out of the closed shaft section again, that in addition at least two pressure devices having molding device above the top track, and is arranged to be pressed against the top track and deformation table, and that at least one drive and sequence control device is provided for the cyclical advancement of the feed arrangement and for the cyclical shifting of the deformation element and the pressing device into the deformation position.

The laterally insertable deformation elements can be changed in an optimally simple manner to produce different shaft part configurations. Because the molding device with the pressing devices lies above the deformation element, the shaping can be carried out on or above the deformation element and the pressing or connecting process of the top web and carrier web can be achieved. The cyclical control of the pressure devices, the feed arrangement and the deformation element means no difficulties for the person skilled in the art. The sequence control can be implemented mechanically or electronically and also hydraulically or pneumatically in a manner known per se.

The adjustment of the molding station can be accomplished particularly easily if the feed device has a drive device with an arrangement for the stepless adjustment of the feed path of the feed device. In this way, the feed path of a feed step can be adapted as desired to the configuration of the deformation element.

The practical implementation of the invention is particularly simple if the feed device has a holding device for holding the carrier web during the feed movement. On In this way, the feed device can carry out a simple lifting movement with a front and a rear detent position, the helte device for holding and transporting the carrier web being engaged only during the feed movement, but disengaging in the front detent position, so that the reverse stroke is empty he follows.

Coupling gears with at least two locking positions are particularly suitable for driving the feed device, as they are e.g. in the doctoral thesis ETH (Eidgenössische Technische Hochschule Zürich) No. 6698 by Guntram Merhar. The latching positions can limit the forward and backward stroke, respectively, and allow the upper web to be deformed and the upper web and carrier web to be connected at the forming station.

Both the stroke setting and the formation of sufficient locking positions can be achieved particularly advantageously if a six-link coupling gear with two locking positions is used.

The control and adjustment of the feed device can also be designed according to the invention in a particularly finely adjustable and adjustable manner if the drive device has a stepper motor drive with an adjustable pulse number and / or pulse length. The use of the stepper motor has the great advantage that, in a manner known per se, both the feed speed and the feed stroke and the duration of the detent positions can be regulated practically indefinitely.

Shaft parts with a different configuration in the transverse direction can be produced particularly easily if at least one of the pressure devices is divided into at least two differently shaped sections and / or at least one of the pressure devices is divided into two approximately adjacent pressure elements with different shapes, and if the deformation element correspondingly in the transverse direction in at least is divided into two differently shaped sections. In this way it is possible, for example, to produce shaft parts in which the waves taper or widen in the transverse direction or which are divided into sections which rise or fall in stages. The adaptability to different wave forms can be further improved if two deformation elements that can be inserted from both sides between the upper web and the carrier web are provided. This also increases the cycle speed, since in this case the deformation elements only have to be inserted half way from both sides.

The invention can be very particularly advantageous and simple by using flat webs, i.e. Realize a carrier web and at least one top web if at least one of the webs has at least in sections and at least in the surface area a medium that can be activated by supplying heat for connecting the webs. This means that there is no need to apply any adhesive in the area of the forming station, which increases the cycle speed and reduces the susceptibility to failure of the forming station. The use of a thermoplastic adhesive, e.g. can be applied in strips to the carrier web. However, the use of a thermoplastic coating, which e.g. can be applied as a protective layer on the carrier web and which at the same time creates the connection between the carrier and top web due to its thermoplastic properties. Particularly good material properties with the simplest processability result if at least one web consists entirely of a thermoplastic plastic material that softens when heat is added and can be connected to the other web. In this way, the application of adhesive becomes superfluous and, in addition, a suitable shaft selection can be used to produce a moisture-resistant, elegant shaft part. Of course, the carrier web and / or the top web can also be cut to the length required for the finished shaft part before or after the shaping process.

• Figur 1 den schematischen Ablauf eines erfindungsgemässen Verfahrens,
• Figur 2 die schematische Darstellung von Verformungselement und Andruckeinrichtungen auf einer Formstation mit den Merkmalen der Erfindung,
• Figur 3 die schematische Darstellung einer Formstation quer zur Bahnrichtung,
• Figur 4 die Formstation gemäss Figur 3 längs zur Bahnrichtung,
• Figur 5 die schematische Darstellung einer Vorschubanordnung gemäss Figur 3,
• Figuren
• 6 bis 11 verschiedene Ausführungsformen von Andruckeinrichtungen und Verformungselementen jeweils während des Verformungs- und Andruckvorgangs,
• Figur 12 die schematische Darstellung einer Formstation mit Heizanordnung,
• Figur 13 eine mit thermoplastischem Material beschichtete Trägerbahn in Verbindung mit einer Oberbahn in vergrössertem Massstab,
• Figur 14 eine aus thermoplastischem Material bestehende Oberbahn in Verbindung mit einer Trägerbahn in vergrössertem Massstab,
• Figur 15 die Seitenansicht eines Wellenteils, das mit unterschiedlichen Vorschubschritten hergestellt ist, und
• Figur 16 die schematische Darstellung des Herstellungsverfahrens eines Wellenteils mit zwei verschiedenen Oberbahnen.

Obviously, the inventive content and the technical progress of the subject of the application are guaranteed not only by the new and inventive individual features but in particular also by combining and sub-combining the features used. The invention is explained below in exemplary embodiments with reference to the drawings. Show it:

• FIG. 1 shows the schematic sequence of a method according to the invention,
• FIG. 2 shows the schematic representation of the deformation element and pressure devices on a molding station with the features of the invention,
• FIG. 3 shows the schematic representation of a forming station transverse to the web direction,
• FIG. 4 the forming station according to FIG. 3 along the web direction,
• FIG. 5 shows the schematic representation of a feed arrangement according to FIG. 3,
• characters
• 6 to 11 different embodiments of pressure devices and deformation elements in each case during the deformation and pressure process,
• FIG. 12 shows the schematic representation of a molding station with a heating arrangement,
• FIG. 13 shows a carrier web coated with thermoplastic material in connection with an upper web on an enlarged scale,
• FIG. 14 an upper web made of thermoplastic material in connection with a carrier web on an enlarged scale,
• Figure 15 is a side view of a shaft part, which is made with different feed steps, and
• Figure 16 is a schematic representation of the manufacturing process of a shaft part with two different top webs.

According to FIG. 1, an upper web 2 is connected to a carrier web 3 on a forming station 1. The individual process steps I to VI run as follows: During step I, a first pressure device 4 and a second pressure device 5 are in their working position, in which they press the top web 2 against the carrier web 3 and at the same time bring about the connection of the two webs . An adhesive (not shown) is applied to the carrier web 3, which establishes the connection during the pressing process. A deformation element 6 is located in its working position between the first pressure device 4 and the second pressure device 5 in such a way that the upper web 2 is stretched over the deformation element 6 in a wave-like manner. A lateral stamp 7 presses against the upper web 2 and the second pressing device 5 and thereby causes the upper web 2 to be folded cleanly over the deformation element 6.

Method step II shows how first the first pressure device 4 is brought out of engagement with the upper web 2 and then the deformation element 6 is laterally withdrawn from the closed shaft section.

Method step III shows how the stamp 7 is then also withdrawn, the second pressure device 5 is brought out of engagement with the upper web 2 and at the same time the carrier web 3 by one step, i.e. is promoted to the right in the drawing.

Method step IV shows how the deformation element 6 is then shifted again between the carrier web 3 and the top web 2, and then the first pressing device 4 is pressed into the shaft section in which the second pressing device 5 was located in the previous working step. This double use of a pressure device at the same connection point ensures that, on the one hand, the top web 2 is pressed and held firmly against the carrier web 3, so that during the subsequent intervention of the second pressure device 5 during the method steps V and VI, the top web 2 is held and via the Deformation element 6 can be tensioned without loosening an already established connection of top web 2 and carrier web 3. In addition, the double pressure causes an improved connection of the carrier web 3 and the top web 2.

Method step V shows how the top web 2 is stretched over the deformation element 6 and thereby deformed.

Method step VI shows, analogous to method step I, the pressing and connecting of top web 2 and carrier web 3 by the second pressing device 5. Obviously, the top web 2 is automatically retightened while the carrier web 3 is being advanced, without any special conveying having to take place. The upper web 3 can be pulled off a roll in a manner known per se, the material being able to be guided in loops or over dancer rolls and the like in a manner known per se to avoid jerky tensile stresses during the feed.

Figure 2 shows the two pressure devices 4 and 5 on an enlarged scale. The side bevel shown in the drawing allows unimpeded supply of the upper web 2 past the second pressure device 5.

According to FIGS. 3 and 4, the pressure devices 4 and 5 are fastened to two hydraulic press arrangements 10, 11 by means of push rods 8, which in turn are arranged on a frame 9. The molding station 1 lies vertically under the pressure devices 4 and 5 and has a deformation table 12 which is provided with a heating arrangement 13 in the region of the deformation element 6. A motor 14 is provided for laterally displacing the deformation element 6.

In addition, a feed device 15 with a drive device 16 and a gripper 17 is provided on the forming station 1 in order to convey the carrier web 3 (not shown in FIGS. 3 and 4) step by step according to FIG. 1 on the forming station 1. To control the drive device 16, the motor 14 and the press assemblies 10 and 11 in the cycle of the process steps according to FIG. 1, a sequence control device 18 is provided which, via control lines 19, issues the corresponding control commands in the order of the process steps according to FIG. 1. Sequence control devices of this type for controlling press arrangements, e.g. About appropriate valves or motors via appropriate switching devices are generally known and do not require further explanation here.

As can be seen from FIGS. 4 and 5, the feed device is driven by means of a step motor drive which has a pulse generator 21 and a stepper motor 22. The pulse duration and the pulse frequency of the pulse generator 21 are adjustable in a manner known per se, so that both the stroke speed and the stroke length can be adjusted during a feed step of the grippers 17. As a result, depending on the shape and configuration of the shaft part to be produced, the feed of the carrier web 3 can be adjusted and adapted as desired. As shown schematically in FIG. 5, the grippers 17 are pivoted against the carrier web 3 during the forward stroke, so that they grip it and convey it forward. In the reverse stroke, however, the grippers 17 are removed from the carrier web 3 lifted off so that they are retracted empty during the reverse stroke. The gripper 17 is pivoted by a magnet arrangement, not shown. Accordingly, during the reverse stroke, the carrier web 3 remains in the feed position last reached, the process sequence according to FIG. 1 taking place.

Figure 6 shows two pressure devices 4 and 5 and a deformation element 6 for producing a shaft part with a modified configuration. It is evident that the upper web 2 is not only stretched over the deformation element 6, but is pressed against it by the pressure devices 4 and 5. In this way, the shape shown can be achieved without difficulty.

FIG. 7 shows an arrangement with three pressure devices 4, 4a and 5. In the process sequence, the first pressure device 4 is first brought into its engaged position. This is followed by the additional pressure device 4a, which presses the top web 2 against the deformation element 6. This ensures that the desired formation of edges 23 is achieved and at the same time prevents the upper web from wrinkling, as could be the case if the second pressure device 5 were lowered in front of the additional pressure device 4a. Otherwise, the deformation in the exemplary embodiment according to FIG. 7 proceeds analogously to the process sequence shown in FIG. 1.

FIG. 8 shows a modified embodiment in which the additional pressure device 4a is mechanically connected to the pressure device 5. Nevertheless, the same sequence as in the embodiment according to FIG. 7 also takes place in the embodiment according to FIG. 8. This means that first the first pressure device 4 engages, and then during the downward movement the additional pressure device 4a is pressed against the upper web 2 or the deformation element 6 becomes and that only then does the second pressure device 5 engage. This is brought about by the fact that the additional pressure device 4a is mounted in a longitudinally displaceable manner on the second pressure device 5 and is pressed into a lower position by a spring 24, so that the additional pressure device 4a in this deep position first onto the upper web 2 or the deformation element 6 presses and then during the further lowering of the second pressure device 5 against the force of the spring 24 is displaced relative to the second pressure device 5.

FIG. 9 shows a modified exemplary embodiment, in which the deformation element 6 is provided with a lateral recess 25 in order to achieve a corresponding configuration of the shaft part. In the yerforming process, the first pressure device 4 is first pressed against the upper web 2 or the deformation element 6. The second pressure device 5 is then lowered and laterally displaced by the stamp 7 and pressed into the depression 25 of the deformation element 6. Obviously, with the arrangement shown, any side surface configurations of the shaft part can be shaped in the simplest way.

In the exemplary embodiment according to FIGS. 10 and 11, a shaft part with shaft sections of different heights is produced. For this purpose, the deformation element 6 is subdivided and has an upper section 6a. FIG. 10 shows a pressing process in which only the lower part of the deformation element 6 is engaged and a lower section of the shaft part is formed accordingly. In contrast, in the deformation step according to FIG. 11, the upper section 6a of the deformation element 6 is also inserted between the upper web 2 and the carrier web 3, so that a higher shaft part is produced. Of course, the introduction of the deformation element 6 with or without the upper section 6a can be controlled in any order by appropriately designing the sequence control device 18 (FIG. 4).

FIG. 12 shows a carrier web 3 which is provided with two strips 26 of a thermoplastic adhesive. The carrier web 3 is heated in the area of the heating arrangement 13, which is designed as an electrical resistance heater, so that the adhesive strips 26 are softened and activated. In this way, the connection between the carrier web and the top web can be achieved by simple pressing by means of the pressure devices 4 and 5. It is particularly advantageous that the heating arrangement 13 is located in the area of both pressure devices 4 and 5, so that the heating of the carrier web 3 in the area of the first pressure device can take place for a relatively short period of time, which leads to a provisional connection of the upper web 2 and carrier web 3 is sufficient. If, in the subsequent process step (FIG. 1), the still heated carrier web 3 is then transported further in such a way that the shaft section located under the second pressing device 5 during the first step passes under the first pressing device 4, the still heated connection point of the upper web 2 and carrier web 3 becomes again pressed together, which then ensures a permanent connection.

FIG. 13 shows a carrier web 3 which is provided with a continuous coating 27 made of thermoplastic material. The coating 27 serves on the one hand to protect the surface of the carrier web 3, which thereby becomes insensitive to water and moisture. At the same time, however, softening in the area of the connection point with the upper web 2 is achieved by heating by means of the heating arrangement 13 and permanent connection is made possible by pressing on by means of the pressure devices 4 and 5.

FIG. 14 shows an exemplary embodiment in which the top web 2 consists entirely of thermoplastic material. Here, too, the connection to the carrier web 3 is achieved by softening in the area of the heating arrangement 13 or the pressure devices 4 and 5.

This represents a particularly simple and advantageous embodiment of a shaft part. On the one hand, there is no need to apply adhesive strips 26, and on the other hand the top web 2 becomes absolutely water-insensitive, which can be desirable in certain applications.

FIG. 15 shows an exemplary embodiment of a shaft part, in which the feed steps of successive sections of the cell part are increased in a ratio of 1: 2 by appropriate control of the feed device 15. The shaft part can thus be optimally adapted to the needs of the parts to be packaged.

FIG. 16 shows an exemplary embodiment in which two top webs 2a and 2b are arranged on a carrier web 3. The configuration formed by the top web 2a corresponds to the exemplary embodiment according to FIG. 6, and the deformation element 6c and a first pair of pressure devices 4, 5 (not shown) are designed as shown there. In contrast, the configuration formed by the upper web 2b corresponds to the shaft part according to FIG. 1 and the deformation element 6d and a second pair of pressure devices 4, 5 (not shown) are designed accordingly. In other words, for the production of the shaft part according to FIG. 16, both two deformation elements 6c and 6d, which can be inserted from opposite sides, and two adjacent pairs of pressure devices 4, 5 are provided for carrying out the deformation process. Shaft parts in the form shown, i.e. With two different surface configurations, it is of course also possible to manufacture the deformation elements 6 and the pressure devices 4, 5 in such a way that a continuous top web 2 can be used. This depends entirely on the desired shape.

Claims (33)

1. A method for producing a corrugated part consisting of a carrier web and a top web arranged in a wave shape on the latter, the top web being connected to the carrier web at connection points in the region of the recesses running transversely to the web direction, characterized in that the carrier web is stepped relative to a forming station is moved forward and that the top web to be connected to the carrier web is fed by a feed device that after each feed step the top web is pressed both against at least one deformation element introduced between the carrier web and the top web and against the carrier web and thereby deformed and at the same time connected to the latter , and that the step length of a feed step is dimensioned such that it corresponds at least to the distance from two successive connection points. 2. The method according to claim 1, characterized in that both the deformation element and also a first pressure device located behind the deformation element in the feed direction are shifted into their working position, in which the deformation element is between the carrier web and the top web, and wherein the first pressure device Upper web presses against the carrier web, and then a second pressure device lying in front of the deforming element in the advancing direction is pressed against the upper web in such a way that it is stretched or folded over the deforming element and pressed against this and / or the carrier web and in each case in at least one section of the pressure area, at least one of the pressure devices is connected to the carrier web. 3. The method according to claim 2, characterized in that first the deformation element is introduced between the top web and carrier web and the first pressure device is pressed against the top web, which is pressed against the carrier web, and then the second pressure device is pressed against top web and carrier web becomes. 4. The method according to claim 3, characterized in that each connection point between the top web and carrier web is acted upon by both the first pressure device and the second pressure device, and that the connection of the top web and bottom web takes place during the pressing of both pressure devices. 5. The method according to any one of the preceding claims using a heat-activatable medium for connecting the top web and carrier web, characterized in that the carrier web and / or top web are heated in the region of at least one pressing device during the pressing process. 6. The method according to any one of the preceding claims, characterized in that the feed step length is changed compared to a previous feed step to generate different wave forms on a shaft part. 7. The method according to any one of the preceding claims, characterized in that, in order to generate different waveforms on a shaft part, the surface configuration of the deformation element is changed in at least one yerforming step compared to the shape during a previous deformation step. 8. The method according to any one of the preceding claims, characterized in that the top web is pressed laterally against the deformation element by at least one of the pressure devices. 9. The method according to any one of the preceding claims, characterized in that the top web is provided in the transverse direction with waves or deformations of different heights and / or surface configurations. 10. The method according to any one of the preceding claims, characterized in that a carrier web is fed two adjacent top webs and connected to the latter on the forming station. 11. Device for producing a corrugated part consisting of a carrier web and a top web arranged in a wave shape on the latter, the top web being connected to the carrier web in the region of the depressions running transversely to the web direction, in particular for carrying out the method according to claims 1 to 10, thereby ge - Indicates that a forming station with a deformation table is provided, on which the carrier web can be transported step by step in the longitudinal direction by means of a feed arrangement, that a feed device for the upper web is arranged above the carrier web, that at least one deformation element is provided, which is to the side and to the generating shafts is arranged so that it can be inserted between the upper web and the carrier web to form a shaft section and after the molding can be pulled out again from the closed shaft section such that it also has at least two pressure devices Shaping device is arranged above the upper web, and can be pressed against the upper web and the deformation table, and that furthermore at least one drive and sequence control device for the cyclical advancement of the feed line Order as well as for the cyclical shifting of the deformation element and the pressing device into the deformation position is provided. 12. The device according to claim 11, characterized in that two pressure devices are provided, of which the first pressure device is arranged behind the deformation element and the second in front of the deformation element, the first pressure device being able to be pressed against the upper web in front of the second. 13. The apparatus according to claim 12, characterized in that at least two deformation elements are provided, which can be inserted individually and / or together for the deformation process between the upper web and the carrier web. 14. Device according to one of claims 11 to 13, characterized in that the feed device has a drive device with an arrangement for adjusting the feed path of the feed device. 15. The apparatus according to claim 11 or 14, characterized in that the feed device has a holding device for holding the carrier web during the feed movement. 16. The apparatus according to claim 14, characterized in that the drive device has a coupling gear with at least two locking positions, each of which limits the forward and the reverse stroke, and that the holding device can be controlled such that it for holding and conveying the Carrier web is engaged with the carrier web during the forward stroke and out of engagement with the carrier web during the reverse stroke. 17. The apparatus according to claim 16, characterized in that the coupling gear is a six-link coupling gear with two locking positions. 18. The apparatus according to claim 14, characterized in that the stroke of the coupling gear is adjustable. 19. The apparatus of claim 14 and 15, characterized in that the drive device has a stepper motor drive with an adjustable number of pulses and / or pulse length. 20. Device according to one of claims 11 to 19, characterized in that the pressure device and / or the deformation table is provided with a heating arrangement. 21. Device according to one of claims 11 to 20, characterized in that at least one of the pressing devices for pressing the top web against the deformation element is arranged above it. 22. The apparatus according to claim 21, characterized in that the pressing device protrudes laterally beyond the deformation element in such a way that the upper web can be pressed both against the deformation element and against the deformation table. 23. Device according to one of claims 11 to 22, characterized in that at least one of the pressing devices is provided with an arrangement for lateral pressing against the deformation element. 24. The device according to claim 23, characterized in that a pressure stamp is provided for laterally displacing and pressing the pressing device against the deformation element. 25. Device according to one of claims 11 to 24, characterized in that at least one of the pressing devices for producing shaft parts with a different surface configuration in the transverse direction is divided into at least two differently shaped sections and / or that at least one of the pressing devices is roughly divided into two pressure elements lying next to one another are subdivided into different shapes, and that the deformation element is also subdivided in the transverse direction into at least two sections. 26. Device according to one of claims 11 to 25, characterized in that two deformation elements that can be inserted from both sides between the upper web and the carrier web are provided. 27. Use of flat webs, i.e. at least one carrier web and at least one top web for producing a shaft part, at least one of which webs is precoated at least in sections and at least in the surface area with a physically and / or chemically activatable medium for connecting the webs. 28. Use according to claim 27, characterized in that the medium is a thermoplastic adhesive which can be softened by the application of heat and which produces the connection after cooling. 29. Use according to claim 28, characterized in that the medium is designed as a thermoplastic coating on the carrier and / or top web. 30. Use according to claim 27, characterized in that at least one web consists entirely of a thermoplastic plastic material which softens when heat is added and can be connected to the other web. 31. Use according to claim 27, characterized in that the medium consists of an adhesive which can be activated by pressure. 32. Use according to claim 27, characterized in that the medium consists of a connection medium which can be activated by radiation. 33. Use according to claim 27, characterized in that the top web and carrier web are coated with two different connection media which can be activated on contact.

Images