HOLDING DEVICE FOR THE SURFACE TREATMENT OF BAR CUTTERS

Abstract

A holding device for fastening bar cutters in order for the cutting edges thereof to be coated, wherein the fastening is configured in such a way that a plurality of bar cutters can be arranged in a row such that the cutting faces and tips thereof have the same orientation, and the holding device includes a screen which at least partially protects the cutting faces from the coating, wherein, with bar cutters arranged in a row in the manner described, the top edge of the screen projects beyond the knife tips in such a way that no knife tips protrude.

Description

The present invention relates to a holding device for the surface treatment of bar cutters. Furthermore, the present invention relates to a holding device for the coating of 2 and 3 side-grinding bar cutters.

STATE OF THE ART

The surfaces of many objects are nowadays treated in order to achieve certain surface properties.

The surfaces of components and tools are nowadays often considerably improved by coatings for specific applications.

In this respect, the choice of the right substrate holder plays a very important role for each surface treatment process. Therefore, appropriate substrate holders are being developed for specific surface treatment processes, taking into account the type of substrate surface to be treated as well as further substrate properties (such as for example substrate shape, dimensions and composition).

Coating is nowadays a commonplace surface treatment for substrates. In this respect, layers with particular properties are deposited on certain substrate surfaces. The coating affords the substrate surfaces enhanced properties that enable the use of these substrates for particular applications or make possible a performance increase of these substrates for a particular application.

For example, in the case of cutting tools, the cutting faces are usually (at least partially) coated with wear protection layers in order to increase the cutting performance of these tools.

Despite such a coating, wear will occur over time when the tools are used. Particularly in the case of bar cutters, the coating is often ground down and the edge of the blade is coated again.

A bar cutter is generally formed from a bar with a square cross-section. However, the cross-section of a bar cutter can be provided with any number of edges, so that it can have for example a pentagonal, hexagonal, octagonal etc. shape.

FIG. 1 shows an example of such a square bar cutter of the 2-side grinding type. It comprises a shaft 120 and a cutting extremity. The cutting extremity comprises a first and a second surface resp. an open surface 103 and a secondary open surface 105, as well as a cutting face. The first and second surfaces converge in a roof-like shape, with the “gable” being designed rounded. The cutting face is a flat front side connecting the first and second surfaces. The cutting face and first surface form a cutting edge 101 by means of which material is to be removed from a blank. The surface 110 is coated and is not subjected to regrinding.

FIG. 4 shows in contrast to FIG. 1 a bar cutter of the 3-side grinding type. This differs by the grinding on the machining face which, in contrast to the 2-side grinding, occurs only in the area of the bar cutter head. This entails that during each subsequent grinding, the cutting face 401, 403, 405, 410 also needs to be subjected to regrinding in order to maintain a constant quality. This is not the case for the 2-side grinding. In the case of 3-side grinding bar cutters, all reground surfaces are then generally coated again for the next use.

In order to reduce the wear of this cutting edge, the latter is coated with a wear protection layer. Despite such a coating, wear will occur over time when the tools are used. Particularly in the case of bar cutters, the coating is often ground down for the edge of the blade to be coated again.

In this connection, the so-called 2 face method (in the context of the present invention also called 2-side grinding method) has been mainly used so far, wherein ultimately only the first and the second surfaces 103, 105 are subjected to re-grinding. However, in previous years, the 3-side grinding method has increasingly established itself, wherein in addition to the first and second surfaces 403, 405 the third surface 410 is also subjected to re-grinding.

In the case of the 2-side grinding method, the coating is left on the cutting face. The result, however, is that, when the process is repeated all too often, the thickness of the coating on the cutting face keeps increasing and for example after the fourth or fifth time spalling occurs, which of course negatively affect the performance of the bar cutter.

In document U.S. Pat. No. 8,703,240, this problem is countered in that the cutting face is masked. The masking occurs in such a manner that only peripheral areas of 1 mm or less of the cutting face remain uncovered. During coating, only these uncoated peripheral areas of the cutting face as well as the first and second surfaces are coated and thus also the cutting face. This is shown in FIG. 2. The uncoated peripheral areas are represented in cross-hatched manner. When the bar cutter is subjected to re-grinding on the first and second surfaces, at least part of the uncovered peripheral areas are removed. When the tool is reconditioned repeatedly (re-grinding and masked coating), there is consequently no excessive layer buildup on the cutting face.

The disadvantage of this method, however, is that for each kind of bar cutter an expensive masking needs to be produced. Furthermore, adjusting the bar cutters relative to the masking must be performed with exceptional accuracy, which makes the process considerably more complicated.

Another solution regarding the problem mentioned above is the 3-face method (in the context of the present invention also called 3-side grinding method), according to which the cutting face is also additionally subjected to grinding. In this case, no layer remains on the bar cutter and the grinding and re-coating can be repeated much more often without damaging spalling occurring. The disadvantage is of course that now one additional surface is subjected to re-grinding. Since the coating is a hard material coating, a removal of the coating is laborious, i.e. grinding an additional surface entails an additional effort.

It would therefore be desirable to have available a holding device and a method on the basis of the 2-face method with which the tool reconditioning can be performed without significant additional effort and for the most varied bar cutter.

For the coating of 3-side grinding bar cutters and 2-side grinding bar cutters various holding variants are used nowadays.

For example, for the coating of 3-side grinding bar cutters a holding device variant is used in which the bar cutters are loaded onto a magnetic plate. In this respect, the shafts of the bar cutters are covered with an additional metal sheet. On such a magnetic plate, only two rows can be loaded and the loading density is thus very low.

For the coating of 2-side grinding bar cutters, for example, a holding device variant is used in which the bar cutters are held in a ring-shaped holder, such that only the side surfaces are coated. The bar cutters in this respect are oriented vertically, as shown in FIG. 5.

The holder solutions available so far are not flexible in terms of the holder cross-section, therefore specific holders are respectively required for different cross-sections.

For the efficient coating of both 2-side and 3-side grinding bar cutters in a same batch, no suitable holding device variants are currently available.

AIM OF THE PRESENT INVENTION

One aim of the present invention is to provide a versatile holding device for the surface coating of bar cutters, with which a plurality of re-conditioning cycles can be performed with the 2-side grinding method without this resulting in an excessive layer buildup on the cutting face.

It is a further aim of the present invention to provide a versatile holding device for the surface coating of bar cutters, with which 2-side and 3-side grinding bar cutters can be coated in the same coating batch and with which the 2-side grinding bar cutters can be coated in such a manner that a plurality of re-conditioning cycles can be performed with the 2-side grinding method without this resulting in an excessive layer buildup on the cutting face.

The aim of the present invention is achieved in that a holding device with open design, as described in claim 1, is provided. Dependent claims relate to advantageous embodiments of the present invention.

The invention is based essentially on the effect of shading. Accordingly, the bar cutters are arranged in a holder and the cutting face is protected from the coating by a screen (hereinafter also called coating shield). This covers the cutting faces completely, i.e. does not follow the profile of the cutting extremities. This is in contrast to the masking known from U.S. Pat. No. 8,703,240. The screen can even extend over the tip of the bar cutter. According to the invention, and in a preferred manner, the screen is however not in contact with the cutting face but at a distance from the latter. This results, during the coating of the bar cutters, in the first and second surfaces being fully exposed to the coating application, whereas the coating application on the cutting face due to the shading effect of the screen still occurs, but to a clearly reduced extent. On the cutting face, a coating is formed whose thickness, starting from the cutting edge, clearly decreases. Surprisingly, it is not only the area of the tip of the bar cutter that is sufficiently coated beyond the edge, but also the area surrounding the edge.

After use and wear of the bar cutter, the first and second surfaces are then subjected to grinding according to the 2-face method. Since only the areas close around the edges of the cutting face are coated and this is removed after the first, second or at the latest third grinding process, this does not result in a multiple layer buildup. According to the invention, it is thus possible to achieve without a complicated and adapted masking device that, after several re-conditioning cycles, a detrimental multiple layer buildup on the cutting face can be avoided.

According to a preferred embodiment of an inventive holding device, an optimal loading can be achieved in that a design with four rows of bar cutters is implemented, as shown in FIGS. 6 and 7. The bar cutters 211a, 211b project on two sides out of the holder in order to allow an optimal coating result. The bar cutters 211a, 211b are held via magnets 201. The flexibility of the holder is achieved via a freely adjustable coating shield 205. This allows 2-side grinding bar cutters 211a and 3-side grinding bar cutters 211b to be coated, bar cutters with a smaller cross-section can also be coated. In this respect, the gaps arising between the bar cutters are closed by a coating shield. The easy adjustability of the coating shield 205 is achieved via the magnets 201 that can for example be provided as magnetic strip and can be placed at the top and at the bottom on the holder.

This holding device according to the present invention is, by comparison with the state of the art, more flexible in terms of the cross-section of bar cutters, since it allows the simple loading of bar cutters with different cross-sections, and thus the efficient coating of bar cutters of different sizes (both with different lengths as well as with different cross-sections) in the same batch. This flexibility is achieved among others by means of the easily adjustable coating shield 205, as mentioned above. Depending on the cross-section of the bar cutter, it can be moved into the desired position in order to achieve an optimal distance between cutting face and coating shield.

It is thus possible to coat in each row another type of bar cutter without having to reconfigure the holder.

Additional flexibility is achieved through the adjustable lateral outer metal sheets 230. This functionality makes it possible to achieve that, if a bar cutter with small cross-section is coated, the lateral outer metal sheet 230 can be displaced inwards. This has the advantage that in a facility with a certain amount of space, the useful areas can be used in an optimal manner and the loading for bar cutters with larger bar cutter length can be increased even when available space is restricted.

Additionally, the use of a holding device according to the present invention makes it possible to achieve an increased quality of the coating of 2-side grinding bar cutters due to the horizontal coating.

Claims

1. Holding device for fastening bar cutters for coating the cutting edges thereof, wherein the fastening is configured in such a way that a plurality of bar cutters can be arranged in rows such that their cutting faces and tips have the same orientation, and the holding device comprises a screen which at least partially protects the cutting faces from the coating, characterized in that with bar cutters arranged in rows in the manner described, the top edge of the screen projects beyond the blade tips in such a way that no blade tips protrude.

2. Holding device according to claim 1, characterized in that for the bar cutters arranged in the manner described, the screen is at a distance from the cutting faces.

3. Holding device according to claim 2, characterized in that the distance is between 1 mm and 10 mm, preferably between 1 mm and 5 mm, and even more preferably is 3 mm.

4. Holding device according to claim 1, characterized in that the screen is adjustable.

5. Holding device according to claim 4, characterized in that the holding device comprises four rows with magnets for fastening bar cutters.

6. Holding device according to claim 5, characterized in that two rows are provided for loading 2-side grinding bar cutters and the other two rows are provided for loading 3-side grinding bar cutters.

7. Holding device according to claim 5, characterized in that the holding device comprises adjustable lateral outer metal sheets.

8. Holding device according to claim 2, characterized in that the distance is between 1 mm and 5 mm.

9. Holding device according to claim 2, characterized in that the distance is 3 mm.