DE10214626A1 - Press tool for the production of molded parts or the like - Google Patents

Abstract

The invention relates to a pressing tool for the manufacture of molded parts or the like. Here, the pressing tool is designed in such a way that it can be made to vibrate at least temporarily during the pressing process by vibrations or other influences.

Description

The invention relates to a pressing tool for the production of molded parts or like.

For example in the production of Moldings using a resin mat, the is manufactured in mat form, this is Raw material of the fiberglass from that individual competent worker by hand cut, weighed and in a predetermined manner on the lower press tool of a press placed. Depending on the position of the resin mat, the Flow direction determined within the mold.

This can be done by hand high accuracy cannot be achieved. The The quality of the individual molded parts is of variable sizes depending on the part even with every single molded part during production can change.

The flow behavior of the resin mat, for example, is great Effects on the quality of the molded part. Here you have to Sizes are taken into account, such as the time of Manufacture of the resin mat, or how dry it is and like. Weight tolerances can also occur because the resin mats are usually weighed by hand. Although it is prescribed how the resin mat in the mold to be inserted is never accurate to the millimeter Alignment of the resin mat possible. All the factors mentioned determine the flow behavior of the resin mat.

As the resin flows, the glass fiber strands begin in the Distribute resin. The resin forms for the Glass fiber strands have a natural resistance. Is the resin mat already dried, the resistance increases additionally. Due to the resistance, the glass fiber braid forms in the Press form a wavy structure, the The higher the resistance, the stronger the wave structure for the fiber optic strands. The wave structure determines the Quality of the molded parts. She is responsible for defects the surfaces and in the edge areas of the individual Moldings.

The invention has for its object the resistance of To lower the resin mat, especially during the flow phase, so that the wave structure is formed smaller and from therefore the mixture of resin and glass optimized.

The object is achieved in that the pressing tool in such a way is formed that it is at least temporarily during the Pressing process due to vibrations or other influences Vibrations can be set.

Due to the vibrations or other influences achieved more even distribution of resin and glass, so that the Wave structure smoothes out. You can also use the Vibrations or other influences that cause vibrations, the existing resistances are reduced or even eliminated become. This has the advantage that the surface of the molded parts becomes harder because fewer pores form. Also the Edges become harder because of the number of breakouts and Deformation decreases significantly, ideally even completely disappear. With a much finer and smaller one Wave structure, fewer waves form on the surface. The Edges are also characterized by a finer respectively medium wave structure affects that less Fraying can be observed there.

Especially with plastic parts for the automotive industry is a paintable surface for many Molded parts absolutely necessary. All the negatives mentioned Influences affect or even exclude one paintable surface of the molded parts. By introducing Vibrations, which achieves a more even distribution the number of molded parts that can be painted Surface area, can be increased significantly.

If the vibrations are properly aligned, that is, the amplitude of the vibrations and the duration of the vibrations are optimally adapted to the materials of the molded parts even pore formation, breakouts, deformations and Fraying in the edge areas completely or at least be completely excluded.

An advantageous development of the invention provides that the vibrations are vibrations with a relatively small amplitude.

This can optimally influence the flowing material become.

In a special embodiment of the invention provided that for molded parts with a resin mat or the like the vibrations during the flow phase of the resin mat or the like are introduced. This has the advantage that in the Phase in which the large wave formation is to be expected at all is excluded by vibration or at least is minimized.

A development of the invention provides that the Vibrations are aligned vertically to the molded part to be pressed.

These vertical vibrations break in the resin mat build-up resistance during the flow phase, since the Glass fiber braid deformed wavy by the resistance. This leads to an interruption in the movement of the Glass fiber braid, which in turn causes the shaft to stretch leads. This smoothes the wave size, and thereby there is a better mixture of resin and glass.

An embodiment of the invention provides that a Vibration plate is provided.

This vibration plate transmits the vibrations or Vibrations on the press and thus on the end to be pressed Molding.

According to the invention it can be provided that the Vibration plate can be placed on a mounting plate.

Here, the vibration plate through the mounting plate held.

The mounting plate can be mounted on the press table.

In a development of the invention it is provided that the Mounting plate at least one guide rail, preferably at least four guide rails, for positioning the Has vibration plate.

The guide rails serve to guide the vibration plate, see above that slipping of the vibration plate during the Vibration is avoided.

It is advantageous according to the invention if everyone Guide bar not detachably connected to the mounting plate, but is preferably welded to it.

This will inadvertently loosen a guide rail and thus slipping or even loosening of the vibration plate locked out.

For a further fastening of the guide rail, it is in accordance with the invention possible that a for each guide rail additional holding collar for fastening the guide bar is provided.

It is advantageous according to the invention if each Retaining collar not detachably connected to the mounting plate, but is preferably welded to it.

For an optimal hold between the sleeve and To ensure guide rail, it is provided according to the invention that not every guide rail with the associated holding collar releasably connected, preferably welded to it.

The invention is not based on the welding of the guide rails and retaining sleeves with the mounting plate and with each other limited. Of course, an unsolvable one Connection between the guide rail and the holding collar and Mounting plate can also be made in a different way.

For optimal positioning of vibratory plates different thickness, is provided according to the invention, that a guide bar is telescopic.

Each corresponding guide rail can be pulled out be brought to the necessary length.

In the pressing tool according to the invention it is provided that the Mounting plate is designed as a hollow cuboid.

To compress the mounting plate during the Avoiding the pressing phase provides for a further development of the invention, that reinforcing elements inside the mounting plate, preferably a grid welded to the mounting plate or the like, is provided.

For example, pressure on the Exercised mounting plate ensures an appropriate grid or the like that a deformation of the mounting plate is excluded.

An embodiment of the invention provides that inside the Mounting plate axis or the like, preferably a Synchronous axis is provided.

The kinetic energy emanates from this axis, which ultimately vibrates the molded part to be pressed.

This axis can according to the invention in different ways and be driven. It is possible that this electromagnetic, pneumatic, hydraulic, mechanical or is also electrically driven. Every other drive is of course also possible.

An embodiment of the invention provides that the Synchronous axis drives a synchronous gear.

The transfer of the energy of the axis over one Synchronous gearbox and, as a result, the introduction of synchronous ones Vibration has the advantage that tilting the Vibration plate, the negative impact on the quality of the molded parts could have been excluded.

According to the invention, the synchronous axis inside the Mounting plate. It can by appropriate Bearings on the sides and, if necessary, in the Be guided and held inside the mounting plate. It should advantageously be centered in the mounting plate run.

It is possible according to the invention that Synchronous gear is designed with two, three or more axes. Through the Number of axes and the respective translation between the Axes can have any differences between the Speed of rotation of the synchronous axis and the last axis of the Synchronous transmission can be achieved.

In the pressing tool according to the invention it is provided that the last axis the movement on a vibration release wheel or transmit a movable bolt or the like becomes.

It is advantageous if each on and / or over the Gear of the synchronous gear arranged in the synchronous axis Anchoring is interlocked with the bearings.

This enables an exactly working synchronous gear Realize and ensure that the gearbox is on everyone Case runs synchronously. The gearbox can be attached to a body or the like can be attached depending on the Conditions can be attached to the mounting plate or Not. Of course, any other usual is also Realization of a gearbox that works without gears, possible.

A possible embodiment of the invention provides that the Shape of the vibration trigger wheel is not circular. In particular, it is provided that the vibration trigger wheel at least predominantly forms an ellipse or is eccentric is trained.

These forms of the vibratory trigger wheel allow that Vibration trigger wheel kinetic energy not continuous, but at intervals on the vibration plate in particular can give up.

So it is according to the invention that the vibration trigger or the movable bolt or the like with the Vibrating plate interacts and vibrates them.

It is advantageous that a on the vibration plate interchangeable impact receiving element is fastened, which the Kinetic energy of the vibration release wheel or Movable bolt or the like picks up and to the Vibrating plate passes.

At the point of contact between the vibration trigger wheel or movable bolt or the like and the vibrating plate signs of wear can inevitably occur. Such signs of wear on the vibrating plate would only be fixable with a greater effort while their Not corrected by the associated unbalance and uneven weight distribution the function of the vibration plate could hinder themselves. A smaller one at the Vibrating plate attachable shock receiving element, however, that the Absorbs blows and thus suffers wear are much easier to replace if the one that has occurred Wear this requires.

Another possible embodiment of the invention provides that the vibration release wheel with a counter wheel preferably larger diameter the vibration plate in Vibrated.

As with a special impact receiving element, this also occurs the greatest wear is not on the vibration plate itself one, but on a smaller, replaceable component. Facing a rigid impact receiving element Counter impeller has the advantage that the wear on the entire Outer tread of the counter wheel is distributed and therefore the The need for an exchange can be greatly delayed can.

According to the invention, it is also possible that the movable Bolts the vibrating plate in vibration using a gearwheel added.

In this embodiment, too, the wear of the Vibration plate itself on a replaceable component that Gear, relocated and there on the entire outer tread, namely all individual teeth, distributed.

The vibration tool that comes from the mounting plate with the Vibration plate exists, is mounted on a press table. Here, the lower press tool on the vibration plate of the tool.

The respective parameter settings of the Press calibrated accordingly, depending on are different from the tool height and the pressing point.

As before, the resin mat is cut, weighed and then placed in the lower press tool. Then the actual pressing process started.

So that clear and powerful vibrations are generated, is according to the invention provided that in the, the mounting plate facing underside of the vibration plate damping agent are provided.

These damping means can be designed differently. For example, it is possible according to the invention that Damping pneumatic damping means, preferably at least one or more air cushions are provided.

Furthermore, it is possible according to the invention that for damping a spring system, preferably made of several disc springs existing, is provided.

A gas pressure or oil pressure system can also be used for damping be provided. A steam pressure system is also conceivable.

When the upper tool is immersed in the lower tool begins the pressing phase of the process. Here, the Press generated such a great pressure that the damping means would not withstand. To crush the Avoiding damping agents during the pressing pressure is according to the Invention provided that at least one on the mounting plate Attachment frame to protect the damping agent during the Press phase is provided.

The pressure of the press is compressed by the top frame.

A development of the invention provides that on Synchronous gear a breakpoint to catch the from the Vibration plate generated pressure is provided.

A further development provides that the breakpoint is so is designed that he in the assembled state of the Mounting plate and the vibration plate parallel to that of the Surface of the vibration plate facing away from the mounting plate is aligned.

An advantageous development of the vibration tool provides doing so that the stop in the support area on the Vibration plate has a rubber coating or the like.

This breakpoint can, for example, depend on the structure of the Gearbox are located and manually adjustable. A Rubber coating or damping with a hard rubber or The same leads to avoidance or reduction of knocking noises. Especially with an elliptical Shaped vibration trigger wheel is a parallel orientation of the Breakpoint to the vibration plate advantageous because the Alignment parallel to the smallest radius of the elliptical Shaped vibration release wheel takes place so that a Overpressure of the wheel is avoided and thus the bearings and axles be spared.

It has proven to be particularly advantageous for resin mats proved if it is provided according to the invention that the Amplitudes of vibrations in the millimeter range, preferably move in the tenth of a millimeter range.

The invention is illustrated below by general Explanations of the behavior of a resin mat and based on the Training of the vibration tool explained in more detail. there demonstrate:

Fig. 1 shows a cross section of a conventional sheet molding compound,

Fig. 2 shows the distribution of glass and resin with a conventional prepreg,

Fig. 3 shows the effect of the wave structure in the conventional prepregs,

Fig. 4 is a mounting plate of the vibratory tool,

Fig. 5, the mounting plate with synchromesh in exploded view,

Fig. 6, the mounting plate with vibration plate and

Fig. 7 is a damping system of the vibration plate.

The figures show the same or equivalent components or components with the same reference numerals characterized.

The invention is based on the production of a molded part using a fiberglass resin mat. Such a resin mat is made by the respective processor This mat is cut, weighed and hand-made predetermined type placed on the lower press tool of a press. By these hand-made works are high Inaccuracies.

The flow behavior of the resin mat has a great influence on the later quality of the molded parts. Among other things, this is the The quality of the resin mat is decisive when it was manufactured and whether it is already dry or not. By the Weighing by hand creates weight tolerances. Even at exact adherence to the insertion regulations arise Deviations in alignment, as this can never be done exactly. The flow behavior of the Resin mat determined.

As the resin flows, the glass fiber strands begin in the Distribute resin. The resin forms for the Glass fiber strands provide a natural resistance. The mat is already dried on, the resistance increases even more. Due to the resistance, the glass fiber braid moves in a waveform, the wave structure increasing Resistance is more pronounced, the quality of the Moldings is affected by this wave structure.

In Fig. 1 the cross section of a resin mat is shown, in which the wave structure can be clearly seen. The resistance created during the flow affects the flow of the glass fiber. As a result of the resistance building up, the glass fiber braid cannot be distributed evenly and the braid is deformed and the waveform arises, as shown in FIG. 1.

Fig. 2 shows that the wave has a minus and a plus area, that is, the plus area of the wave contains an excess of glass and the minus area of the wave is characterized by an excess of resin.

The effects of the wave structure can be seen in FIG. 3. Pores have formed in region ( 2 ) in the minus region of the wave structures, since there is an excess of resin and, accordingly, a lack of glass at the same time. Air can settle there by being enclosed by the resin.

( 4 ) indicates edge breakouts which, in contrast to the pore formation (compare 2), can only appear later. Edge breaks of this type occur in the minus region of the wave structure, since the regions there are too soft and therefore do not have a particularly high impact resistance.

The glass fiber is frayed ( 6 ) in the edge areas as soon as the wave structure builds up above or below the outer edges and presses outwards.

Waves ( 8 ) arise on the surfaces as soon as the plus area of the wave meets heavily dried resin in the surfaces, the plus area of the wave running out there, so to speak, so that there is a shifting over and thus formation of waves.

It should therefore be noted that the conventional Pressing process on the molded parts cracks on the surfaces and in the Shapes, a wave shape on the surface, pore formation due to air pockets, edge breaks at the edges and Fringe formation through fiber exits on surfaces and in Edge area can occur among other things. The above Errors are generally caused by the mixing ratios of the Resin mass in relation to the types of fibers through which Calibration of the presses, through air outlet openings as well as through Insertion techniques.

Molded parts that have the above-mentioned defects thus indicate no paintable surface, like this one in most of the cases required in the automotive industry.

According to the invention, become vertical during the flow phase aligned vibrations introduced because during this Phase of resistance builds up. Due to the vibrations Resistance reduced so that the wave stretches. Due to this is a better, if not an optimal, mix of Reach resin and glass.

The vibrations are introduced using a vibration tool. This vibrating tool essentially consists of the mounting plate ( Fig. 4), the vibrating plate ( Fig. 6, Fig. 7) and a synchronous gear ( Fig. 5) through which the vibrations are caused.

In Fig. 4 the structure of the mounting plate ( 10 ) is explained in more detail. The mounting plate ( 10 ) is a hollow cuboid, which is reinforced on the inside by - not visible - grid mesh, which is firmly welded to the inner outer walls of the mounting plate ( 10 ).

Inside the mounting plate ( 10 ) there is also the synchronous axis ( 12 ) which is guided and held on the sides by corresponding bearings that are also not visible. This synchronous axis ( 12 ) runs centrally in the mounting plate. It forms part of the mechanical vibration drive, which in this case is caused by a synchronous drive driven by an electric motor.

Four guide rails ( 14 ) are provided on the top of the mounting plate ( 10 ), which are welded firmly to the mounting plate.

For further fastening of the guide bars ( 14 ), a holding collar ( 16 ) is provided for each guide bar, which is welded both to the mounting plate ( 10 ) and to each associated guide bar ( 14 ).

The vibrating plate is guided through the guide bars ( 14 ).

Furthermore, top frames ( 18 ) are provided on the top of the mounting plate in the longitudinal direction of the plate, the function of which is described in the description of the pressing phase. The height of each top frame ( 18 ) corresponds to the height of each retaining collar ( 16 ).

In Fig. 5, the mounting plate with the associated synchronous gear is shown. This synchronous gear ( 20 ) ensures the vibrations of the vibration plate, not shown. The synchronous running of the gear is ensured by the synchronous axis ( 12 ) running inside the mounting plate ( 10 ). All gear wheels of the synchronous gear ( 20 ) are toothed at the respective anchorages with the bearings, which ensures synchronous running of the gear. The actual gear ( 20 ) is attached to a structure ( 22 ) which is later firmly attached to the mounting plate ( 10 ).

The vibration release wheel ( 24 ) generates the vibrations due to its special shape. It is elliptical and together with the counter wheel ( 26 ), which has a larger diameter, this wheel ( 24 ) generates the vertical vibrations.

In Fig. 6 the mounting plate with associated vibration plate is shown. This complete vibration tool is mounted on the press table. Here, the lower press tool of the press is attached to the vibration plate of the tool. The parameter settings of the press must be recalibrated, as these are changed by the tool height. Furthermore, the pressure point also changes.

As with the known pressing process, the resin mat is from the respective processor weighed and cut and into the lower press tool placed. After that, the real one Pressing process started.

In Fig. 7, the underside of the vibrating plate (28) is shown. A damping system consisting of eight air cushions ( 30 ) is arranged in it. The air cushions ( 30 ) ensure that clear, powerful vibrations are generated. Since the vibrations are in the tenth of a millimeter range, these air cushions ( 30 ) must generate sufficient back pressure to be able to counter the downward vibrations at the same speed - but upward.

The air cushions ( 30 ) are protected by the attachment frame ( 18 ) during the actual pressing phase, since otherwise the relatively large pressing pressure would destroy these air cushions ( 30 ).

When the press is started, the air cushions ( 30 ) are pressurized. These raise the vibration plate by approximately 1.5 centimeters and press it against a holding contact, not shown, which is located on the structure of the gearbox. The electric motor for the drive is also started at the same time when the press is started. It is infinitely variable.

Once the top tool of the press onto the resin mat that is on the lower tool, meets, the actual begins Flow phase. At this point the vibrations started. The flow phase is approximately one to one and a half Seconds, which is equivalent to around 40 to 60 Vibratory shocks during the flow phase.

When the upper tool is immersed in the lower tool, the pressing phase of the process begins, the press producing such a great pressure on the air cushion ( 30 ) that it would not be able to cope with it. When the vibration plate rests on the support frame ( 18 ), the pressure is compensated by the press and the air cushions ( 30 ) are not destroyed.

The vibration plate ( 28 ) forms the movable element of the vibration tool. The lower press tool of the press is mounted on it. The vibration plate ( 28 ) makes it possible to introduce vibrations into the pressing process in the first place.

The outer dimensions of the vibration plate ( 28 ) correspond to the size of the mounting plate ( 10 ). The double securing of the guide rails ( 14 ) by welding to the mounting plate and the additional retaining sleeves ( 16 ) prevent these guide rails ( 14 ) from bending during the actual pressing phase. This high strength is necessary so that the upper plate cannot be bent so that no fraying can occur.

In Fig. 6 the course of the guide bars ( 14 ) in the vibrating plate ( 28 ) is indicated by dash-dotted lines. The vibration plate ( 28 ) is closed in the upper area above the guide bars ( 14 ) so that no dust can penetrate which could otherwise lead to an output.

In Fig. 6, the shape of the vibration-driving wheel ( 24 ) is also shown enlarged in the form of an ellipse.

The invention is not in the form of a resin mat Glass fiber mat limited. For example, it is also at Carbon fiber mats applicable or also with all others Pressing process in which a wave formation or similar structure by mixing different substances could be caused.

Claims (41)

1. Press tool for the production of molded parts or the like, characterized in that the press tool is designed such that it can be set into vibrations at least temporarily during the pressing process by vibrations or other influences. 2. Press tool according to claim 1, characterized characterized that the vibrations Vibrations with a relatively small amplitude. 3. Press tool according to one of the preceding Claims, characterized in that at Molded parts with a resin mat or like the vibrations during the Flow phase of the resin mat or the like be introduced. 4. Press tool according to one of the preceding claims, characterized in that the vibrations are vertical to the the molded part to be pressed are aligned. 5. Press tool according to one of the preceding claims, characterized in that a vibration plate ( 28 ) is provided. 6. Press tool according to claim 5, characterized in that the vibration plate ( 28 ) on a mounting plate ( 10 ) can be placed. 7. Press tool according to claim 6, characterized in that the mounting plate ( 10 ) has at least one guide bar ( 14 ), preferably at least four guide bars ( 14 ) for the positioning of the vibration plate ( 28 ). 8. Press tool according to claim 7, characterized in that each guide bar ( 14 ) is not releasably connected to the mounting plate ( 10 ), preferably welded to it. 9. Press tool according to claim 7 or 8, characterized in that for each guide bar ( 14 ) an additional holding collar ( 16 ) is provided for fastening the guide bar ( 14 ). 10. Press tool according to claim 9, characterized in that each holding collar ( 16 ) is non-releasably connected to the mounting plate ( 10 ), preferably welded to it. 11. Press tool according to one of claims 7 to 10, characterized in that each guide bar ( 14 ) with the associated holding collar ( 16 ) is not releasably connected, preferably welded to it. 12. Press tool according to one of claims 7 to 11, characterized characterized in that a guide bar telescopic is. 13. Press tool according to one of claims 6 to 12, characterized in that the mounting plate ( 10 ) is designed as a hollow cuboid. 14. Press tool according to claim 13, characterized in that in the interior of the mounting plate ( 10 ) reinforcing elements, preferably a grid or the like welded to the mounting plate ( 10 ), is provided. 15. Press tool according to one of claims 6 to 14, characterized in that in the interior of the mounting plate ( 10 ) an axis ( 12 ) or the like, preferably a synchronous axis ( 12 ), is provided. 16. Press tool according to claim 15, characterized in that the axis can be driven electromagnetically. 17. Press tool according to claim 15, characterized in that the axis can be driven pneumatically. 18. Press tool according to claim 15, characterized in that the axis can be driven hydraulically. 19. Press tool according to claim 15, characterized in that the axis can be driven mechanically. 20. Press tool according to claim 15, characterized in that the axis can be driven electrically. 21. Press tool according to one of claims 15 to 20, characterized in that the synchronous axis ( 12 ) drives a synchronous gear ( 20 ). 22. Press tool according to claim 21, characterized in that the synchronous gear ( 20 ) is biaxial, triaxial or multiaxial. 23. Press tool according to one of claims 20 to 22, characterized in that the movement on the last axis is transmitted to a vibration release wheel ( 24 ) or a movable bolt or the like. 24. Press tool according to one of claims 20 to 23, characterized in that each gear arranged on and / or above the synchronous axis ( 12 ) of the synchronous gear ( 20 ) is toothed in the anchoring with the bearings. 25. Press tool according to claims 23 to 24, characterized in that the shape of the vibration release wheel ( 24 ) is not circular. 26. Press tool according to claim 25, characterized in that the vibration release wheel ( 24 ) at least predominantly forms an ellipse or is eccentric. 27. Press tool according to claims 23 to 26, characterized in that the vibration release wheel ( 24 ) or the movable bolt or the like cooperates with the vibration plate ( 28 ) and vibrates it. 28. Press tool according to claim 27, characterized in that on the vibration plate ( 28 ) an exchangeable impact receiving element can be fastened, which absorbs the kinetic energy of the vibration release wheel ( 24 ) or the movable bolt or the like and passes it on to the vibration plate ( 28 ). 29. Press tool according to claims 23 to 26, characterized in that the vibration release wheel ( 24 ) via a counter-rotating wheel ( 26 ) with a preferably larger diameter sets the vibration plate in vibration. 30. Press tool according to claims 23 to 26, characterized characterized in that the movable pin via a gear Vibrating plate vibrated. 31. Press tool according to one of claims 5 to 30, characterized in that damping means are provided in the underside of the vibrating plate ( 28 ) facing the mounting plate ( 10 ). 32. pressing tool according to claim 31, characterized in that for damping pneumatic damping means ( 30 ), preferably at least one or more air cushions ( 30 ) are provided. 33. pressing tool according to claim 31, characterized in that a spring system for damping, preferably of several Disc springs consisting is provided. 34. pressing tool according to claim 31, characterized in that a gas pressure system is provided for damping. 35. pressing tool according to claim 31, characterized in that an oil pressure system is provided for damping. 36. pressing tool according to claim 31, characterized in that a steam pressure system is provided for damping. 37. pressing tool according to one of claims 31 to 36, characterized in that on the mounting plate ( 10 ) at least one attachment frame ( 18 ) is provided to protect the damping means ( 30 ) during the pressing phase. 38. Press tool according to one of claims 21 to 37, characterized in that a stop point is provided on the synchronous gear ( 20 ) for collecting the pressure generated by the vibration plate. 39. pressing tool according to claim 38, characterized in that the holding point is designed such that it is aligned in the assembled state of the mounting plate ( 10 ) and the vibrating plate ( 28 ) parallel to the surface of the vibrating plate facing away from the mounting plate. 40. pressing tool according to claim 38 or 39, characterized in that the holding point in the support area on the vibration plate ( 28 ) has a rubber coating or the like. 41. pressing tool according to one of the preceding claims, characterized in that the amplitudes of the Vibrations in the millimeter range, preferably in the tenth Millimeter range, move.