EP0116014A1 - Method and machine for manufacturing a corrugated part - Google Patents

Abstract

To manufacture a corrugated part (1), an upper web (3) which is oblique with respect to a carrier web (2), is fed cyclically to a forming station (4). The deformation of the upper web (3), or the production of the individual corrugations, is effected by means of vertically displaceable pressure devices (6, 7) and a laterally displaceable deformation element (5). A yoke (9) permits the angle of incidence of the upper web (3) relative to the carrier web (2) to be changed in accordance with the relative position of the pressure devices (6, 7) or the deformation element (5). This ensures a gentle deformation even at high cycle speeds and prevents damage to the upper web. <IMAGE>

Description

The invention relates to a method for producing a shaft part and a device for carrying out the method according to the preamble of claims 1 and 4. Such a method and the associated device have already been described in detail in European Patent Application No. 82111389.1. The method makes it possible for the first time to manufacture a large number of different shaft parts on the same device by exchanging the tools or by adjusting the individual work steps, which can be used for packaging purposes, for dividing up space, for decorations etc.

In order to achieve high cycle speeds and to avoid damage to the inclined upper web, it has now been shown that it is expedient to add further setting options to the method. This applies in particular to the entry angle of the top web. It is therefore an object of the invention to provide a method or a device of the type mentioned at the outset in which the deformation of the upper web is carried out as gently as possible and in which damage to the upper web is excluded even at high cycle speeds. This object is achieved according to the method in terms of the method with the features of claim 1 and in terms of the device with the features of claim 4.

By changing the entry angle depending on the relative position of the deformation tools, an optimally gentle deformation of the top web can be achieved. This is particularly the case if the run-in angle of the upper web is increased relative to the carrier web before the deformation element is inserted and is reduced again after the insertion. Obviously, the lateral insertion of the deformation element requires the largest possible entry angle in order to avoid unnecessary friction and tension due to the deformation element. In addition, especially at high clock speeds and with short feeds, i.e. in the case of immediately successive shafts, it can be avoided that the deformation element is retracted, tearing up or otherwise damaging the top web. This risk exists at a relatively acute entry angle if the top web is not absolutely tight. On the other hand, the inlet angle when pressing down the pressure device at the rear in the feed direction, i.e. with the deformation element already inserted, be relatively pointed to ensure a gentle deformation. This is ensured in a particularly simple manner by the variable inlet angle.

The method can be further improved if the carrier web is moved forward together with the top web by means of a vacuum conveyor belt arranged after the forming station. The feed of the carrier web is guaranteed regardless of the configuration of the shaft part. It is therefore not necessary to let the carrier web protrude laterally over the top web in order to operate the feed by means of pinch rollers.

An approximately U-shaped bracket supporting the upper web is particularly advantageously used to change the inlet angle. The upper web glides over the frame with little friction loss, while the legs of the frame can be stored in a suitable place. To reduce the friction, the bracket can be provided with a roller on which the top web rolls.

A structurally particularly simple solution is obtained if the bracket increases the entry angle of the upper web under spring tension. In this way, the bracket is always biased in one direction and can be pivoted back by suitable means to change the inlet angle. It is particularly advantageous if the relative position of the bracket can be controlled via the drive device of the pressure devices and / or the deformation element. In this way, no additional coordination of the bow movement with the movement of the deformation elements is required. The control can be carried out in a simple manner, for example mechanically via a cam disk or other suitable means.

In order to ensure that the shaft part leaves the forming station exactly flat to the top of the vacuum conveyor belt, it is advantageous if a holding-down device is arranged above the shaft part after the forming station. Since, in a relative position in which both pressing devices are pulled up, the upper web exerts a pull on the carrier web, this prevents the shaft part from being able to lift off the surface of the vacuum conveyor belt at the beginning thereof. As a hold-down device, a height-adjustable sliding shoe is advantageously used, which can be adapted to the respective wave height.

• Figur 1 einen Querschnitt durch eine erfindungsgemässe Vorrichtung, und
• Figuren 2 bis 6 die einzelnen Arbeitstakte in stark vereinfachter Darstellung.

An embodiment of the invention is shown in the drawings and will be described in more detail below. Show it:

• 1 shows a cross section through a device according to the invention, and
• Figures 2 to 6, the individual work cycles in a highly simplified representation.

FIG. 1 shows, likewise in a greatly simplified representation, a molding station 4 on which the shaft part 1 is manufactured. The shaft part 1 consists of a in the feed direction A. Carrier web 2 supplied and from a top web 3 deformed on the forming station and glued to the carrier web 2. A front pressure device 6 and a rear pressure device 7 are used to deform the top web, and are moved back and forth in the direction of arrow B approximately at right angles to the carrier web. A deformation element 5 is inserted from the side intermittently and defines the cross-sectional configuration of the individual shafts. The actual deformation of the top web 3 takes place through the rear pressure device 7 between the deformation element 5 and the threshold 11 fixedly mounted above the carrier web 2. The front pressure device 6 serves primarily to hold the already glued top web in front of the deformation element 5. Both pressure devices 6 and 7 press the glued webs against the work table 18. However, the threshold 11 can also be arranged at a certain distance from the rear pressure device 7, so that the threshold only has the function of pressing the carrier web 2 against the work table 18. In such a case, the upper web is deformed in half by the two pressure devices.

In the illustrated relative position of the deformation tools, the deformation element 5 is immediately pushed in while the rear pressure device 7 is still pulled up. In this position, the normal entry angle of the upper web 3, indicated by a dash-dotted line, is increased with the aid of a bracket 9. The bracket 9 is mounted on a bearing 22 and biased by a spring 14. When the rear pressure device 7 is lowered, the run-in angle of the upper web should again be reduced, which is done with the aid of the cam plate 12 in the exemplary embodiment shown. The cam 12 presses the roller 13 back on the bracket 9, so that the inlet angle is reduced.

Immediately after the forming station 4, a vacuum conveyor belt 8 is arranged for the cyclical transport of the carrier web 2. Such conveyor belts, as is known per se, have a vacuum chamber. 16, over which the conveyor belt 8 provided with openings 17 strokes. Due to the pressure difference, the carrier web adheres to the conveyor belt 8 and is moved forward in the direction of arrow A by this. In the exemplary embodiment, the carrier web and the top web are thus transported only by train.

In order to prevent the shaft part 1 from lifting off from the vacuum conveyor belt 8, a slide shoe 10 is arranged immediately after the forming station and is adjusted to the correct height by means of an adjusting screw 15.

A complete work cycle for producing a shaft is shown in FIGS. 2 to 6. As shown in FIG. 2, a first shaft 19 is already finished, while a second shaft 20 is deformed above the deformation element 5 and glued onto the carrier web 2. For this purpose, both pressure devices 6 and 7 are in a lower position. The entry angle <is relatively small.

For the further transport of the carrier web 2, the deformation element which can be moved laterally in the direction of arrow C must be withdrawn from the second shaft 20 which has been formed, as shown in FIG. In addition, both pressure devices 6 and 7 must be pulled up. After further transport by a shaft distance, the deformation element 5 can be inserted again between the upper web 3 and the carrier web 2. For this process, the inlet angle ^{c <is} kept relatively large with the aid of the bracket 9. It can be seen that the deformation element can be inserted at a large inlet angle α without the risk that the upper web will be torn apart by the deformation element if there is a slight sag.

In Figure 4, the deformation element 5 for deforming a third shaft 21 is fully inserted. The front pressure device 6 is already partially lowered, while the rear Pressure device 7 is still pulled up. The inlet angle is still approximately the same size as in the position according to FIG. 3.

When the rear pressure device 7 is lowered, the bracket 9 also pivots back again and thus reduces the entry angle 0 (as shown in FIG. 5). Finally, to form and glue the third shaft 21, both pressure devices 6 and 7 take the ones shown in FIG position shown.

Obviously, the invention is not limited to the illustrated embodiment. In particular, the control of the bracket 9 can be implemented in a variety of ways, e.g. through rods or cams, but also through electrical, pneumatic or hydraulic auxiliary devices. The configuration of the bracket can also be adapted to the specific circumstances. Instead of the bracket, other means of changing the inlet angle could theoretically also be used, e.g. Compressed air nozzles are used.

Claims (10)

1. A method for producing a corrugated part (1) consisting of a carrier web (2) and a top web (3) arranged in a wave shape on the latter, the carrier web being moved forward cyclically relative to a forming station (4) and the top web (3) from a feed device is fed at an angle to the carrier web and the top web at the forming station (4) by means of a deformation element (5) which can be inserted between the carrier web and the top web and by means of two pressure devices (6, 7) which can be pressed onto the top web (3) on both sides of the deformation element (5) deformed or connected to the carrier web, characterized in that with each work cycle the inlet angle (α) of the supplied top web (3) relative to the carrier web (2) depending on the relative position of the pressing devices (6, 7) and / or the deformation element (5) is changed. 2. The method according to claim 1, characterized in that before the insertion of the deformation element (5) the inlet angle (α) of the top web (3) is increased relative to the carrier web (2) and is reduced again after the insertion. 3. The method according to claim 1, characterized in that the carrier web (2) is moved forward together with the top web (3) by means of a vacuum conveyor belt (8) arranged after the forming station (4). 4. Apparatus for producing a corrugated part consisting of a carrier web and a top web arranged in a wave shape on the latter, the carrier web being cyclically movable relative to a forming station and the top web being able to be fed obliquely from a feed device to the carrier web, and the top web using a between the carrier web and the top web insertable deformation element and by means of two pressing devices which can be pressed onto the upper web on both sides of the deformation element or can be connected to the carrier web, characterized in that at the forming station (4) a device for changing the inlet angle (α) of the supplied top web (3) relative to the carrier web (2) depending on the relative position of the pressing devices (6, 7) and / or the deformation element (5). 5. The device according to claim 4, characterized in that the device for changing the entry angle (α) of the upper web is an approximately U-shaped bracket (9) supporting the upper web. 6. The device according to claim 5, characterized in that the bracket (9) is biased by a spring to enlarge the inlet angle. 7. The device according to claim 5, characterized in that the relative position of the bracket (9) via the drive device of the pressing devices (6, 7) and / or the deformation element (5) is controllable. 8. The device in particular according to one of claims 4 to 7, characterized in that after the forming station (4) a vacuum conveyor belt (8) is arranged for the cyclical forward movement of the carrier web (2) with the top web (3). 9. The device in particular according to claim 8, characterized in that a hold-down device is arranged above the shaft part (1) in order to keep the run-out angle of the carrier web (2) with the top web (3) constant after leaving the forming station (4). 10. The device according to claim 9, characterized in that the holding-down device is a height-adjustable sliding shoe (10).

Images