DE10058855C1 - Ridge element, for building tiled roof, has moisture capture channel at bottom edge of each side surface and capillary sheet defining capillary gap with adjacent side surface - Google Patents

Abstract

The ridge element (2) has a Cu sheet strip bent into a ridge tile shape, with its side surfaces (4) angled downwards, with a bent edge strip (13) at the bottom end of each side surface providing a moisture catchment channel (14), extending in the longitudinal direction. A capillary sheet (15) extends between the moisture catchment channel and the crown (8) of the ridge element, parallel to the side surface, for providing a capillary gap together with the side surface.

Description

The invention relates to a ridge element made of copper to prevent fouling Roofs. Roof tiles with anti-fouling coatings or are known Roof coverings that contain anti-fouling substances as well as sheet metal strips that due to relinquish weathering substances to destroy moss.

DE 298 04 136 U contains, as far as from the drawing and the description with the Claims can be seen, a multi-shell copper ridge with a metallic perforated Ridge hood, which extends in the form of a lightning rod over the entire length of the roof should. There is an absorbent between the ridge hood and the roof ridge cover Anti-fouling material not specified. In this way, the Surface of the copper is enlarged and the effect of the growth inhibition can be improved. The disadvantage is that the formation of ions is not possible in dry weather.

The object of the invention is to design a ridge element made of copper, in which low construction effort and the formation of Fighting moss and vegetation on the roof is quick and sustainable.

According to the invention the object is achieved by a ridge element made of copper, which for Prevent the formation of vegetation on roofs a flat ridge in the form of a ridge hood or bent strips of copper sheet with side surfaces inclined in the drain direction having a ridge crown arranged in the apex region of the side faces and at the eaves-side end section of the side surfaces by sheet metal folding of an edge strip longitudinally extending gutter for moisture is formed, with between the gutter and the ridge crown each parallel to the surface of the side surface moisture-bearing capillary sheet with formation of a capillary gap between the The top of the side surface and the underside of the capillary plate is arranged.  

The combustion of fossil fuels produces sulfur dioxide and nitrogen oxides, which, when reacted with atmospheric oxygen and water, form acids in which the copper ions in Solution go. By keeping the air clean, the ridge is made of copper this way different according to the climatic conditions. To do that with increasing age of lichen and moss infested house roof by natural To purify precipitation, an increased supply of copper ions is required, which Thanks to a moisture-bearing capillary sheet, it is structurally simple and particularly sustainable can be accomplished. Due to the capillary action, moisture from the gutter becomes sucked, which is necessary for the increasing formation of copper ions. This will mossy and dirty roofs thoroughly cleaned. The invention brings about a quick and continuous cleaning of the roof, even with heavily soiled and mossy ones Roofs.

The invention will be described below using an exemplary embodiment with reference to the Drawings are explained in more detail. Advantageous refinements of the invention result from the subclaims.

In detail shows

Fig. 1 shows a building with a first member made of copper,

Fig. 2 is a first member having a first crown provided with beads,

Fig. 3 is a ridge member of Fig. 2 with a front ridge end plate,

Fig. 4 is a first member having a trough-shaped first crown,

Fig. 5 is a ridge element attached directly to the ridge and

Fig. 6 shows a detail X from Fig. 5 in a schematic representation

Fig. 1 is a provided with a roofing building 1 with a sloping roof having an elongated ridge member 2 of copper which with its reaching down over the roof edge lath 3 side faces 4 engages over the ridge-side ends of the roofing plates or tiles 5 and seal against this applied. In the ridge direction, the ridge element 2 can be formed in one part or in several parts, parts of the elements overlapping and the individual elements being sealingly connected to one another by means known per se, which is not explained in detail in the drawing for reasons of clarity. On the roof tiles 5 there are 2 disturbing mosses below the ridge element or the formation of vegetation 6 in the form of lichens.

According to FIG. 2, the first element 2 from a flat in the form of a ridge tile is canted 7 or made curved strips of copper sheet with inclined side faces 4 in the eaves direction. In Fig. 2a the side surfaces are curved. On the ridge side, the ridge element 2 has a ridge crown 8 in the apex area of the side faces 4 , which is formed in the exemplary embodiment by a central bead 9 and by symmetrically arranged edge beads 11 . The edge bead 11 and the center bead 9 form depressions 12 in which moisture from precipitation and dew can be collected. The moisture that builds up in the troughs 12 is used to form copper ions, which runs out on the inclined side surfaces 4 when the troughs 12 are overflowed. On the eaves-side end section of the side surfaces 4 , the ridge element 2 has a collecting channel 14, which extends in the longitudinal direction, for retaining moisture, by sheet metal edging of an edge strip 13 .

Between the gutter 14 and the first crown 8 is in each case parallel to the surface of the side surface 4 a moisture leading Kapillarblech 15 to form a capillary gap 16 is arranged between the upper side of the side surface 4 and the bottom of the Kapillarbleches 15 whose function will be explained hereinafter.

When a capillary is immersed in a liquid, the inner surfaces are completely wetted with moisture, the liquid rising above the liquid level to a height which is dependent on the size of the capillary gaps 16 . If the surfaces of two substances move past each other, these substances are electrically charged in opposite directions by friction at their boundary layers. If one substance has a greater conductivity for electrical energy than the other, the first is charged positively, the second negatively electrically. In this way, the circulation of water, due to the osmotic pressure, is conducted from bottom to top and here by evaporation to the outside. This constant water transport caused by evaporation creates an electric field in the direction of the rising moisture. This electric field acts as a pump. The water in the capillary gap 16 rises the slower, but also the higher the narrower it is. The capillary rising moisture evaporates on the upper edge 17 of the side surface 4 . During the evaporation, salts and sulfates crystallize, which are enriched in the moisture contained in the ridge crown 8 . Since the moisture in the ridge crown 8 evaporates faster than in the gutter 14 due to the sun's radiation, this results in a constant transport of moisture and a significantly higher rate of formation of copper ions. In addition, the electric field can also form ions in a neutral environment.

Thus, the moisture may not drain side the ridge member 2 of Fig. 3 with a front ridge end plate 18 and a rear ridge end plate 19 is provided, which is in Fig. 4 and Fig illustrated in the drawing. 5,. According to Fig. 3a, the Firstendscheiben 18, 19 are formed semi-circular or choice in the form of a ridge tile. 7 The ridge end disks 18 , 19 are designed such that the ridge crown 8 and the collecting channel 14 are each closed on the gable end flush with the edge. The trough 12 formed between the upper edge 17 of the side surface 4 and the ridge end disk can have one or more edge beads 11 running in the direction of the ridge and a center bead 9 , through which the evaporation is accelerated and the surface of the ridge crown 8 is enlarged. In addition, the beads of the ridge crown 8 provide greater stability, which is particularly advantageous for durability and when laying. The ridge crown can also be formed by two opposing capillary plates 15 .

According to FIG. 4 and FIG. 5, the first crown 8 can be provided with a low-profile, of a trough designed shallow depression 12, which is peripherally delimited by the upper edge 17 of the side surface 4. The trough-shaped design of the ridge crown 8 offers advantages when fastening. According to FIG. 2, the first element 2 is disposed in an existing building 1 on the ridge tiles 7, which is fixed to the cover of the last row of tiles on the roof edge lath 3 of the ridge and mortared.

According to FIG. 5, the ridge element 2 can be attached directly to the ridge batten 3 when the building 1 is re-covered, which in turn is held on the rafter rafters 22 with the ridge batten holder 21 . The ridge of sloping roofs previously covered with ridge tiles 7 made of concrete or clay can thus be manufactured much more easily. The previously required mortar embedding, which is placed on the roof tiles 5 or pans, is saved. In this way, the time-consuming work of the ridge cover can be accelerated. Furthermore, considerable amounts of mortar are saved.

So that the overflowing moisture collected in the gutter 14 can be better distributed on the roof tiles 5 , the edge strip 13 of the gutter 14 is provided with serrated recesses 23 on the edge, which is illustrated in FIG. 6. The drip edge with the serrated recesses 23 distributes the copper ions evenly on the roof and keeps the roof surface free of vegetation.

A further improvement of the roof cleaning can be obtained by a moistening device, through which moisture is supplied to the ridge element 2 on certain days or at regular intervals in dry weather. For this purpose, nozzles 24 for the supply of liquid are provided in the front ridge end disk 18 or in the rear ridge end disk 19 , which are connected to a line 26 leading to a conveying device 25 . Alternatively, according to FIG. 4, a floor socket 27 can be arranged in the floor area of the trough 12 or a socket in the area of a bead or in the area of the ridge crown 8 if the line 26 is to be laid in the interior area of the roof.

According to Fig. 1, the line 26 may be arranged in the outer area of the building 1, wherein with the conduit 26, a reservoir 28 for liquid. Downstream of the storage container 28 is a conveyor device 25 which can be controlled by means of a timer 29.

The timer 29, which is controlled according to the preselection, is connected to the electrical drive of the conveyor device 25 , so that the delivery of liquid is switched off after a specified follow-up time. When a preselected point in time has been reached, the run-on time is started and the conveyor device 25 is switched on until the amount of moisture required for cleaning to completely wet the roof is reached. Instead of a conveyor 25 , the line 26 can also be provided with a water connection, for example to a drinking water line.

To increase the cleaning effect, the liquid can also be enriched with anti-fouling or moss-killing substances. Instead of or together with moss-killing substances, substances for the formation of copper ions can be added to the liquid in the storage container 28 . In this way, perfect cleaning of the roof tiles 5 can be made possible regardless of the weather conditions and depending on the moss infestation.

Claims (8)

1.Ridge element made of copper to prevent the formation of vegetation on roofs from a flat strip of copper sheet, bent or bent in the form of a ridge hood, with side surfaces inclined in the direction of the drain and a ridge crown arranged on the ridge side in the apex area of the side surfaces, characterized in that on the eaves-side end section of the side surfaces ( 4) a longitudinally extending catch channel (14) is formed for moisture by Blechaufkanten an edge strip (13), wherein between the collecting channel (14) and the ridge crown (8) each parallel to the surface of the side surface (4) a moisture leading Kapillarblech (15 ) is arranged to form a capillary gap ( 16 ) between the top of the side surface ( 4 ) and the bottom of the capillary sheet ( 15 ). 2. ridge element according to claim 1, characterized in that the ridge crown ( 8 ) has one or more troughs running in the direction of the ridge ( 12 ) or center beads ( 9 ) and edge beads ( 11 ). 3. ridge element according to claim 1 to 2, characterized in that the ridge element ( 2 ) with a front ridge end plate ( 18 ) and a rear ridge end plate ( 19 ) and the trough ( 12 ) in the ridge crown ( 8 ) and the collecting channel ( 14 ) is closed on the gable end with the ridge end washers ( 18 , 19 ) flush with the edge. 4. ridge element according to claim 1 to 3, characterized in that the front ridge end plate ( 18 ) and / or the rear ridge end plate ( 19 ) with a nozzle ( 24 ) for the supply of liquid with a to a conveyor ( 25 ) leading line ( 26 ) and is provided with a reservoir ( 28 ) for liquid or a water connection for a supply line on the line ( 26 ). 5. ridge element according to claim 1 to 3, characterized in that the connecting piece ( 24 ) in the bottom region of a trough ( 12 ) or in the region of a bead or in the region of the ridge crown ( 8 ) is arranged. 6. ridge element according to claim 1 to 5, characterized in that the collecting channel ( 14 ) is provided on the edge with a drip edge with serrated recesses ( 23 ). 7. ridge element according to claim 1 to 6, characterized in that the liquid in the reservoir ( 28 ) is enriched with ion-forming and / or antifouling and / or moss-killing substances. 8. ridge element according to claim 1 to 7, characterized in that the conveyor ( 25 ) is controlled by means of a timer (29).