NO131355B - - Google Patents

Description

Facade panel and method for the production of

such a plate.

The invention relates to a facade plate made of tin metal, apart from iron tin and in particular aluminum tin, as well as a method for producing such a plate.

Facade panels of such metal and a smooth surface are previously known. Such plates are produced, for example, from thin inks with a substrate of synthetic material. Plates of this type, however, have the disadvantage that weathering becomes easily visible and gives the plates a

unfavorable appearance.

When such plates, in order to achieve a brightening of the surface, a finely divided, regular surface profile is applied, e.g. in the form of rifles, no improvement is achieved by this, as on the one hand the weathering appears as clearly with a regular, finely divided profile as with a smooth plate, and on the other hand finely divided profiles do not have the intended effect at greater heights, as it may come into consideration when cladding buildings. Machine-processed panels are not considered as facade panels, due to their high price.

The invention makes it possible to overcome the aforementioned disadvantage and consists mainly in that said facade sheet of metal tin,' apart from iron tin and especially aluminum tin, exhibits an embossed surface with irregular, flat weathering, which mainly has a width of at least 10 mm and a depth of 10 - 30%, preferably approx. 2. 5%, of the largest available plate thickness; under which the total area of the depressions is between 20 and 50%, preferably approx. 25% >, of the total plate surface, while the back of the plate is flat.

As the recesses are designed flat with a relatively large width, they will also affect the appearance of the boards when mounted at greater heights,

and by the fact that said recesses are irregularly designed and distributed and occupy a large part of the total slab surface, they brighten the surface of the facade slabs to such an extent that any weathering that occurs will no longer appear disturbing, but bear the stamp of an artistic ageing. The plates according to the invention are exclusively profiled on their visible surface, while the back side of the plates is flat, whereby it is possible to produce the plates' profiling by rolling. The method of the invention for the production of such facade panels mainly consists in cold-rolling a tin blank between a smooth roller and a counter-profile roller with such a distribution and dimensioning of elevations and depressions that in an ideal distribution of the rolled material in longitudinal zones along the rolling directions, and whose width constitutes a fractional part, f .ex. 1/in 0 of the roll width, the average cross-sectional reduction of the rolled stock in all longitudinal zones differs from each other by a maximum of 15%

and preferably no more than 8%; and by ideal distribution of the rolled material in the direction of transverse zones along the discharge side of the rolls, and whose widths form a fraction, e.g. 1/20 of the rolling extent, the average cross-sectional reduction of the rolled stock in all cross-sectional zones differs from one another by no more than 20% and preferably no more than 10%; whereby the average absolute cross-sectional reduction over the entire roll width is calculated to be between 5 and 30%, and preferably amounts to a maximum of 15%.

Production of embossed profiles with large, flat and irregular shape and distribution has not been considered possible until now. However, under the conditions that the cross-sectional reduction in the individual longitudinal zones within the above-mentioned limits takes place to approximately the same extent, in connection with the condition that the absolute total cross-sectional reduction is limited to 30%, preferably 15%? a condition is achieved whereby the elongations produced by the cross-sectional reduction in the different zones are mutually balanced to such an extent that there is no risk of warping of the sheet, or at least the warping that may occur is kept within such limits that they can be balanced by normal straightening rolling. The possibly occurring different cross-sectional reductions within the individual zones as a result of the aforementioned large indentation surfaces do not apply to the plate as a whole, as the individual zones keep each other in equilibrium, unless they are completely offset by material flow. Different cross-sectional reductions in the different cross-sectional zones could cause an unevenness in the material's exit velocity from the rollers, but these variations are, according to the invention, kept within such limits that they do not disturb. It has also been shown to be possible by continuous rolling in this way to produce plates with such extensive indentation surfaces that they determine the optical impression of the plate in question, even when this is mounted at a great height, while at the same time the indentations are so deep that a clear demarcation is formed opposite the elevations. According to the invention, the starting point is an ink thickness of 5 - 8 mm, preferably about 6 mm, and in this case is achieved with an assumed indentation depth of approx. 30% of the largest plate thickness, a depth of these recesses of approximately 2 mm, which will be sufficient to achieve a good contrast.

The lower limit of approximately 5% for the mean absolute cross-sectional reduction has been determined so that the elevations on the surface of the tin can also be designed precisely during roll profiling, whereby the raised places on the plate surface also correspond to the profile prepared on the profiling roll. The depressions on this roller are created freehand, so that the irregularities that arise can also be optically apparent. According to the invention, the entire surface of the profile roll is processed by hand, so that the peculiar irregularity of the tin surface does not only extend to the irregular shape of the recesses and elevations, but also applies to the overall surface condition.

In this way, facade tin is produced which will convey a completely unique optical impression, which gives the impression of a hand processing of the tin surface, despite the fact that the plates are produced by machine production on the basis of a continuous rolling process. Such facade panels with an individual appearance can thus be produced on an economically favorable basis.

The surface of the roller which is provided with the counter profile of the plate is processed according to the invention in a hard or optionally hardened state. This processing can take place in a simple way by grinding, whereby a one-time profiling of the roll under the hands of a sculptor is sufficient to give the total rolled plate material the appearance of an individual processing by said sculptor. An industrial serial production of plates indicating a work of art is thereby possible. By profiling the profile roll in question in a hardened or hardened state, it is avoided that the impression of hand processing is erased by a subsequent hardening. With the method of the invention, it is possible to work in a simple way with roll sizes and roll equipment that are common in conventional sheet metal rolling.

The invention will now be explained in more detail with the help of an embodiment example and with reference to the attached drawings, after which:

Fig. 1 shows a section of the surface of eh facade panel; Fig. 2 shows a cross-section along the line II-I-1 in fig. 1 on an enlarged scale; Fig. 3 °g ^ shows a profiled roller, whereby fig. 3 shows an elevation and fig. a section along the line IV-IV in fig. 3>°g Fig. 5 shows a section of the roller surface at the place indicated by V in fig. 3.

As indicated in fig. 1, the facade panel exhibits recesses 1 of different depth and large, uneven ground surfaces. The intermediate parts 2 of the surface likewise exhibit an uneven surface. As shown in fig. 2, the depth a of such a recess 1 amounts to approximately 25% of the largest plate thickness b, which is present in the surface area 2. As fig. 1 shows, the total surface of the recesses 1 is less than 50% of the plate's total surface and amounts to approximately 25% of this.

The roller shown in fig. 3 °g ^ corresponds to a normal roll of

the kind used for rolling tin. Such a roller has e.g. a diameter of 700 mm and a working width c of 1200 mm. 3 denotes the roll jacket which is provided with profiling, and h indicates the roll pins. In this way, the depressions 1 and elevations 2 that correspond to the counter profile of the plate (fig. 2) are created by hand, whereby depressions 1 on the plate correspond to elevations 5 on the roller, and elevations 2 on the plate correspond to depressions 6 on the roller (fig. 5). The processing of the roller's surface takes place in hard, or hardened state. This has two advantages. On the one hand, the prepared profile is not blurred by a subsequent hardening process, and on the other hand, this way it can be used for otherwise unusable and worn-out rolls in a tin rolling mill, since in fact the roll surface must still be made irregular. The entire surface of the roller is processed below, for example with a grinding wheel, i.e. both in the recess areas 6 and in the raised areas 5.

In fig. 3 ideal length zones are drawn which run in the longitudinal direction of the rolled stock. The width of such a length zone d is one-tenth of the roll width c. The design is made so that the cross-sectional shrinkage of the rolled stock is approximately the same in all these length zones, as the mutual deviation does not amount to more than 15% and preferably no more than 8%. In this way, the stretch of the goods is balanced to a high degree over the entire roller width.

The rolling extent according to fig. h is divided into ideal transverse zones e, which extend across the rolling direction, that is to say in the direction of the discharge side of the rolled material, and whose width corresponds to one twentieth of the rolling circumference. Also with regard to this, the roller profiling is carried out so that the cross-sectional reduction in all these cross-sectional zones 1 is essentially the same, and is not subject to mutual deviations of more than 20%, preferably no more than 10%.

After profiling, the plate is placed between smooth straightening rollers for any necessary straightening.

The smooth straightening roller, which acts on the same side of the plate as the profiling roller, thus comes into contact with the plate only in the raised places, so that a relatively higher surface pressure will occur in these places. In this way, the profiled plate is smoothed out in these places, and due to the straightening roller, a further optical effect will thus arise, which will separate the blank-rolled places from the other rough surface areas.

Claims (7)

1: Facade sheet of metal-tin, except iron-tin and special aluminum-tin, characterized in that it exhibits an embossed surface with irregular flat depressions, which mainly have a width of at least 10 mm and a depth of 10 - 30%, preferably approx. 25%, of the largest available plate thickness; under which the overall plate of the recesses makes up between 20 and 50%, preferably approx. 25%5 of the total plate surface, while the back of the plate is flat. 2. Method for the production of a facade panel as specified in claim 1, characterized in that a tin blank is cold-rolled between a smooth roll and a counter-profile roll with such a distribution and dimensioning of elevations and depressions that, with an ideal distribution of the rolled stock in longitudinal zones along the rolling direction, and whose widths make up a fraction, e.g. 1/10 of the roll width, the average cross-sectional reduction of the rolled stock in all longitudinal zones differs from one another by no more than 15% and preferably no more than 8%; and by ideal distribution of the rolled stock in transverse zones along the discharge side of the rolls, and whose widths form a fraction, e.g. 1/20 of the rolling extent, the average cross-sectional reduction of the rolled stock in all cross-sectional zones differs from one another by no more than 20% and preferably no more than 10%; whereby the average absolute cross-sectional reduction over the entire roll width is calculated to lie between 5 and 30%, and preferably amounts to a maximum of 15%. 3. Method as specified in claim 2, characterized in that the overall surface of the counter profile roll is machined freehand. ^ f. Method as stated in claim 2 or 3, characterized in that it starts from a tin blank with a thickness of between 5 °g and 8 mm, and preferably approximately 6 nm. 5. Procedure as stated in claim 2 - h, characterized by. that the surface of the counter profile roll is machined in hard, or hardened state. 6. Method as specified in claims 2-5? characterized in that the tin rolling is carried out with normal roll sizes and normal roll support. 7. Method as stated in claims 2-6, characterized in that the plate is fed between smooth straightening rollers after profiling.