EP0681072A1 - Metal roofing panel for cleaning and purifying building roofs - Google Patents

Abstract

In connection with the natural humidity, the copper contg. material provides a chemical reaction which kills plants or destroys dirt on the building roofs, and prevents growth on dirt sediments on the roof plate applications. Pref. the outer edge of the plate has a peripheral lead preventing rapid draining of moisture to extend the reaction period as much as possible. In the reaction field there may be offset projections, pressed out from the plate surface, in the path of the drained moisture.

Description

The invention relates to a metal roof panel for cleaning and keeping clean the roofs of buildings, in particular vegetation or environmental pollution, consisting of a metal that reacts in connection with moisture.

Such a device for protecting housing roofs against vegetation, in particular against moss and lichen is known from DE-A-41 30 365. In order to protect the roof covering, copper agents are applied in the visible area of the roof surface in such a way that they come into contact with rainwater and the rainwater flowing off overflows as large an area as possible of the roof covering below the copper agent. The rainwater releases components from the copper agents that counteract vegetation, especially moss and lichen. In this case, the copper means are preferably designed in the form of ridge hoods and arranged along the ridge of the roof so that the moisture that flows away can flow off over the entire roof area. As an alternative, instead of the difficult to manufacture, curved ridge hood, simple strip-shaped copper sheets can be attached in the area of the roof saddle.

The disadvantage here, however, is that in the design as a ridge hood, the production is very complex due to the bending work required to adapt to the ridge hoods. The alternatively provided, strip-shaped copper sheet in the area of the roof saddle is relatively easy to manufacture, in which a copper sheet is unwound from the roll, but only a small effective area of the copper medium then remains between two successive rows of roof panels, so that a corresponding one Effectiveness against vegetal growth on the roof surface, a large number of such rows of copper strips must be inserted. This results in a high cost burden overall.

In addition, such copper strips are difficult to attach, especially when retrofitting existing roofs, since the copper strips have to be inserted between two rows of roof plates, which means that depending on the length of the copper strip used, a larger number of roof plates must be removed.

Accordingly, the object of the invention is to further improve a metal roof panel for cleaning and keeping building roofs effective and manageable.

This object is achieved by a metal roof panel according to the features of claim 1.

By producing the metal roof panel from plate-shaped material by punching, there is the possibility that the metal roof panel can be easily adapted to the shape of the roof tiles used in the roof covering. In particular when using so-called beaver tail roof panels, the curve below can be formed with the punching process, so that compared to a simple copper sheet there is a more visually appealing design and in particular the reaction surface for the draining moisture between two rows of roof panels is fully utilized. Furthermore, there is a simpler assembly of the metal roof panel, since the metal roof panel which matches the outer shape of the roof tile can be inserted in a simple manner between the individual rows of roof tiles. In addition, the production by punching the individual metal roof panel provides the simple possibility of forming a circumferential bead in relation to an inserted, smooth copper sheet on the outer edge of each individual roof panel, which delays the rapid drainage of moisture and thus increases the reaction time between moisture and metal roof panel.

In a particularly advantageous manner, the stamping of the metal roof panel can take place in the half lying in the outflow direction the metal roof panel (reaction surface) knobs are embossed so that the draining moisture must travel as long as possible and at the same time a good distribution of moisture on the roof surface is guaranteed.

In addition, openings, in particular in the form of slots, can be provided at the highest points at the same time as the punching process and the raised (raised) knobs, as a result of which liquid can also react on the underside of the metal roof panel with the metal underside. This results in a doubling of the reaction area, so that a considerable reduction in the number of rows to be covered can be achieved with high effectiveness compared to the known system.

In addition, at the same time as the punching process, a bead support can be embossed on the top of the metal roof panel, which is designed as a support for the roof tile above. The narrow space thus created also provides ventilation for the building roof.

Fig.1

eine Draufsicht auf eine im Biberschwanz-Format ausgebildete Metalldachplatte;

Fig.2

eine vergrößerte Querschnittsdarstellung durch den in Fig. 1 unteren Randbereich der Metallplatte; und

Fig. 3

eine Längsschnittdarstellung zur Verdeutlichung der Einbauposition der Metalldachplatte zwischen zwei Dachziegelreihen

In Fig. 1 ist eine Metalldachplatte in Draufsicht dargestellt, die durch einen umlaufenden Wulst 1 (vgl. auch Fig. 2) in Form einer sogenannten Biberschwanz-Dachplatte ausgebildet ist. Hierzu wird die Metalldachplatte entlang dem umlaufenden Wulst 1 aus plattenförmigen Material, insbesondere Kupferblech ausgestanzt, wobei zugleich im Zuge der Stanzbearbeitung der umlaufende Wulst 1 eingeprägt wird. Zudem wird im Bereich einer mittels Kreuzen gekennzeichneten Reaktionsfläche 2, die in eingesetztem Zustand der Metalldachplatte (vgl. Fig. 3) von der Dachoberfläche nach außen weist, eine Vielzahl von erhaben ausgebildeten Noppen 3 eingeprägt bzw. aus der Reaktionsfläche 2 herausgedrückt In bevorzugter Weise sind hierbei an den höchsten Punkten der aus der Reaktionsfläche 2 herausgedrückten Noppen 3 Öffnungen 4 insbesondere in Form von jeweils um 90° zueinander versetzten Schlitzen 4, 4' vorgesehen. Durch diese Strukturierung der Reaktionsfläche 2 in Form von erhabenen, herausgedrückten Noppen 3 wird der Flüssigkeitsablauf gehemmt, so daß die abfließende Feuchtigkeit (Regenwasser, Schneewasser und dergleichen) einen möglichst langen Weg zwischen und entlang den Noppen 3 Zurücklegen muß und gleichzeitig eine gleichmäßige Verteilung auf der Reaktionsfläche 2 gewährleistet wird. Hierdurch wird insbesondere bei Wind oder Sturmböen erreicht, daß die abfließende Feuchtigkeit mit dem Metall möglichst lange reagiert und damit Kupferionen aus der Metalldachplatte löst, die den Bewuchs auf den Gebäudedächern verhindern und eine reinigende Wirkung auf die Dachfläche ausübt.A preferred exemplary embodiment is explained and described in more detail below with reference to the drawing. Here show:

Fig. 1

a plan view of a metal roof tile formed in beaver tail format;

Fig. 2

an enlarged cross-sectional view through the lower edge region of the metal plate in FIG. 1; and

Fig. 3

a longitudinal sectional view to illustrate the installation position of the metal roof plate between two rows of tiles

In Fig. 1, a metal roof panel is shown in plan view, which is formed by a circumferential bead 1 (see also Fig. 2) in the form of a so-called beaver tail roof panel. For this purpose, the metal roof panel is punched out along the circumferential bead 1 from plate-shaped material, in particular copper sheet, while at the same time the punching process is used to cut the circumferential bead 1 is embossed. In addition, in the area of a reaction area 2 marked by crosses, which in the inserted state of the metal roof panel (see FIG. 3) points outward from the roof surface, a plurality of raised knobs 3 are impressed or pressed out of the reaction area 2 in this case, openings 4 are provided at the highest points of the knobs 3 pressed out of the reaction surface 2, in particular in the form of slots 4, 4 ′, each offset by 90 ° to one another. This structuring of the reaction surface 2 in the form of raised, pressed out knobs 3 inhibits the liquid flow, so that the outflowing moisture (rainwater, snow water and the like) must cover the longest possible path between and along the knobs 3 and at the same time an even distribution on the Reaction area 2 is guaranteed. As a result, in particular in the case of wind or gusts of wind, the flowing moisture reacts with the metal for as long as possible and thus releases copper ions from the metal roof panel, which prevent growth on the roofs of the building and has a cleaning effect on the roof surface.

The slots 4, 4 'provided also ensure that moisture can also pass from the top 6 to the bottom 5 of the metal roof panel and can also react there with the metal surface on the bottom 5 of the reaction surface 2. This results in a doubling of the reaction area, since even in fog or light precipitation due to the capillary action, moisture remains on the underside 5 of the metal roof panel resting on the building roof, and thus the reaction time of moisture and metal roof panel is significantly increased until it continues to flow away.

2 shows the preferred embodiment of the knobs 3 pushed out toward the top 6 with openings 4 slotted during the punching or embossing processing. In Fig. 3 the metal roof plate is shown in the inserted position between two rows of roof tiles 8. As a result, the arrangement of the in the lower half of the Structured reaction surface 2 located on the metal roof plate, as well as the bead 1 surrounding the outer edge, are of further importance the additional bead support 7, which is embossed in the upper half (ie above the reaction field 2 shown in FIG. 1) and on which the overlying beads are located Can support roof tiles 8. A flat intermediate space 9 is thus formed between the circumferential bead 1 and the bead support 7, which results in improved ventilation of the building roofs. These gaps 9, 9 'are only a few millimeters high, so that in connection with the relatively long length of these channels there is adequate protection against wind-driven moisture which is driven by storm gusts along the roof surface. However, a certain amount of moisture blown into the interspaces 9, 9 'is even desirable, since this also makes use of the upper side of the metal roof plate covered by the upper row of roof plates as a reaction surface.

Claims (9)

Metal roof panel for cleaning and keeping building roofs clean, in particular vegetation or environmental protection, consisting of a metal that reacts in connection with moisture,
characterized in that
the metal roof plate is made of plate-shaped material by stamping and has a surface-enlarging reaction surface (2). Metal roof panel according to claim 1,
characterized in that
the metal roof panel is made of a copper-containing material. Metal roof panel according to one of the preceding claims,
characterized in that
the outer edge of the metal roof panel has a circumferential bead (1) which prevents moisture from flowing out. Metal roof panel according to one of the preceding claims,
characterized in that
Openings (4) are provided in the reaction surface (2) exposed from the top (6) to the bottom (5) when the metal roof panel is inserted. Metal roof panel according to one of the preceding claims,
characterized in that
from the exposed reaction surface (2) when the metal roof panel is inserted, knobs (3) are provided which are offset with respect to one another in the direction of moisture drainage. Metal roof panel according to claim 4 and 5,
characterized in that
the openings (4) at the tips of the Reaction surface (2) pressed out knobs (3) are arranged. Metal roof panel according to one of claims 4 to 6,
characterized in that
the openings (4) are designed as slots. Metal roof panel according to one of claims 4 to 7,
characterized in that
the slots (4, 4 ') are offset at right angles to each other. Metal roof panel according to one of the preceding claims,
characterized in that
on its upper side (6) there is a support bead (7) for the roof plate (8) above it to form a ventilation space (9).

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