DE102009048501A1 - Roof covering module for attaching photovoltaic solar panel on saddle roof of building, has flow guiding unit designed as barrier element that upwardly projects from base of hollow space section - Google Patents

Abstract

The module (1) has a plastic housing including an upper side retaining region that is arranged for retaining a solar collector (3). A hollow space section is defined at an inner side of front sided ventilation openings (6) and provided with a flow guiding unit (7). The flow guiding unit is designed as a barrier element that upwardly projects from a base of the hollow space section. Through holes end at the hollow space section. A lower side water drainage region is formed with a drainage opening, which is rearwardly opened at the flow guiding unit.

Description

The invention relates to a roof covering module with front-side ventilation openings, with at least one lower-side water drainage area and with at least one upper-side receiving area for a solar collector, with at least one cavity section adjoining the ventilation openings on the inside, which has at least one flow-guiding means.

Such roofing module is from the EP 1 201 842 A1 known. The roof covering module has a roof tile-like housing, which is provided on the upper side with a receiving area for a photovoltaic solar panel. The front of the housing has two ventilation openings. In a bottom of the housing drainage channels are provided in which downwardly open water drainage areas are provided. The bottom of the housing has a small receiving space, are housed in the control and wiring elements for the solar panel.

The object of the invention is to provide a roof covering module of the type mentioned, which allows a roof-mounted state good cooling of the solar collector.

This object is achieved for a roof covering module of the type mentioned above in that at least one flow guide is designed as a barrier element projecting upwards from a bottom of the cavity section. The invention is based on the recognition that, in the roof-mounted state of the roof covering module, water is pushed upwards along the roof surface during rain and strong wind. The at least one barrier member prevents water entering through the front air vents from flooding the void portion. As a result, a significantly improved ventilation of the solar collector, in particular a photovoltaic solar panel is achieved. This allows a good cooling of the solar panel and consequently a good efficiency.

In an embodiment of the invention, the barrier element extends over a portion of the height and / or the width of the cavity portion. This ensures that the barrier element does not perform a complete partitioning of the cavity section, so that the ventilation of the cavity section remains ensured despite the at least one barrier element.

In a further embodiment of the invention, rear ventilation openings are provided, which open into the cavity section. Together with the front ventilation openings, the rear ventilation openings create the conditions for a good ventilation flow within the cavity section. Preferably, the rear vents are provided with smaller cross-sections than the front vents. Together with the at least one barrier element is thus prevented that water can completely penetrate into the cavity or corresponding cavity sections and this can flood. As a result, water is at least largely prevented from reaching the rear-side ventilation openings.

In a further embodiment of the invention, the water drainage area has at least one drainage opening, which is open in the roof-mounted state to flow guide elements of an underlying tile. This ensures a defined flow of water for the corresponding water.

In a further embodiment of the invention, a barrier wall adjacent to the front ventilation openings is provided as the barrier element, which delimits a flow channel discharging laterally toward the water drainage area. The height of the Querwalles is less than a height of the cavity. Preferably, a plurality of spaced parallel spaced successive transverse walls are provided, which may have a different or an identical height to each other.

In a further embodiment of the invention, at least one curved Stausteg is provided in the cavity as a barrier element, which is arranged at a distance behind the at least one transverse wall. Preferably, a plurality of spaced relative to the front ventilation openings at a distance from each other, curved Staustege are provided. The curvature is designed in such a way that, in the roof-mounted state, a discharge of water to the side is ensured.

In a further embodiment of the invention, the Stausteg arcuate, in particular circular arc, curved. The curvature is designed convexly such that lateral edge regions of the Stößges lie in a roof-mounted state below a vertex of the Stausteges.

In a further embodiment of the invention, the arcuate curvature is mirror-symmetrical to a vertical central longitudinal plane of the cavity portion of the roof covering element. This ensures a uniform discharge of incoming water to both sides of the cavity. A bottom or a side wall of the cavity is preferably arranged inclined to the at least one water drainage region, so that the incoming water, the to the Barrier elements is stopped, inevitably flows on the floor of the cavity in the direction of the water drainage areas.

In a further embodiment of the invention, a housing of the roof covering module is double-shell made of plastic, in particular in a twinsheet method. This is a particularly inexpensive and lightweight to manufacture embodiment. An upper shell and a lower shell of the housing are sealed at their edges.

In a further embodiment of the invention, the receiving area of the housing for receiving at least one photovoltaic solar panel is formed, which is closed to the cavity and has room sections for a laying of electrical wiring or wiring. The fact that the receiving area is closed to the cavity, and the entire electrical wiring and wiring is laid in corresponding space portions of the receiving area, corrosion of the wiring or cabling is prevented by passing into the cavity water.

Further advantages and features of the invention will become apparent from the claims and from the following description of a preferred embodiment of the invention, which is illustrated by the drawings.

1 shows a perspective view of an embodiment of a roof covering module according to the invention in a roof-mounted state between upper roof tiles,

2 a plan view of the arrangement according to 1 .

3 in perspective, the cut arrangement after 2 along the section line IV-IV in 2 .

4 a sectional view of the arrangement according to 2 along the section line IV-IV in 2 .

5 an enlarged section of the sectional view after 4 .

6 a sectional view of the arrangement according to 2 along the section line VI-VI in 2 .

7 an enlarged section of the sectional view after 6 .

8th a side view of the arrangement according to the 1 and 2 .

9 in a cutaway view along the section line XI-XI in 8th the arrangement after 8th in a plan view and

10 a perspective view of the arrangement according to the 1 and 2 diagonally from below.

A roof covering module 1 replaces four roof tiles in a roof-mounted condition with a saddle roof of a building or a similarly designed roof with obliquely sloping roof surface 2 a roof tile row. In the embodiment shown in the drawings, a roof assembly is a total of four roof tiles 2 an overlying tile row and four roof tiles 2 an underlying row of tiles with interposed Dachbedeckungsmodul 1 intended. The Dack Cover Module 1 in width, horizontally, it corresponds to the width of four roof tiles 2 , A length of the roof covering module 1 - Seen in a rooftop from bottom to top - corresponds to a length of a single tile 2 , This is the roof covering module 1 flush with a roof covering. The roof covering module 1 has in unspecified manner upper and lower connecting portions, which are at corresponding upper and lower connecting portions of the roof tiles 2 adapted to the roof covering module 1 flush between the above and below rows of roof tiles 2 embed. The roof covering module 1 shows how to use the 3 to 8th can be seen, a housing G, which is made of plastic. Preferably, the housing G is double-shelled in a twinsheet process. The housing G comprises a cavity 8th , which is divided into several, each extending over a roof tile width cavity sections. Each cavity section has on a front side 4 the roof covering module 1 several front air vents 6 on, which are open to the respective cavity portion within the housing G out. The cavity sections are designed identical to one another.

As based on the 3 to 5 and 10 is recognizable, the housing G for each of the cavity sections opposite to the front ventilation openings 6 rear vents 11 on.

The housing G has in the region of its top a receiving area for a photovoltaic solar panel 3 which is embedded in the receiving area and firmly connected to it.

Inside the cavity 8th There are several barrier elements in each cavity section 9a to 9d . 10 provided in the respective Cavity section between the front ventilation openings 6 and the rear vents 11 are arranged. All barrier elements 9a to 9d . 10 serve through the front vents 6 especially in a storm to squeeze in water and to lateral water drainage areas 7 the tile 2 derive. The barrier elements 9a to 9d . 10 therefore have a bulkhead function for the water. In addition, these barrier elements have a water supply or discharge function. All barrier elements 9a to 9d . 10 extend substantially transverse to a longitudinal extent of the housing G, between the front ventilation openings 6 and the rear vents 11 is defined. The longitudinal direction thus extends in a roof-mounted state obliquely from bottom to top. The barrier elements 9a to 9d and 10 are therefore substantially in the direction of the roof width and thus extends substantially along corresponding roof horizontal. The barrier elements 9a to 9d represent transverse walls, which are staggered in the longitudinal direction of the housing G arranged one behind the other. The first crosswall 9a is directly behind the front ventilation openings 6 arranged within the corresponding cavity portion. Rear closes at this first crosswall 9a a second crosswall 9b also in the transverse direction and thus parallel to the first transverse wall 9a extends. This crosswall 9b simultaneously forms a front boundary of a transverse channel, the back by the third transverse wall 9c is limited. Between the third crosswall 9c and the last crosswall 9d a second transverse channel is provided, with both transverse channels to the side in a water drainage area 13 of the housing G open. The water drainage area 13 has a downwardly open water drainage opening 13a on, in the roof mounted state in alignment above a water drainage area 7 of the respective underlying tile 2 is positioned. Each cavity portion of the cavity within the housing G is thus a separate water drainage area 13 with appropriate water drainage opening 13a assigned.

Each cavity section also has in its to the rear vents 11 guided area three traffic jams 10 on, which are arranged at regular intervals one behind the other. All three traffic jams 10 are circular arc shaped and - as well as the transverse walls 9a to 9d - integrally formed from a bottom of the housing G upwards. The traffic jam 10 are mirror-symmetrical to a vertical central longitudinal plane of each cavity portion to the side and curved forward, so that this for from the front ventilation openings 6 from entering water serve as concave barriers. For water, the first Stausteg 10 has overcome, serves the second Stausteg 10 as a concave barrier. At the same time forms a back of the first Stausteges 10 a convex water conduction or diversion function to the side. A floor of the area in which the dues 10 are arranged is just designed. One to the front vents 6 directed boundary wall of the respective cavity portion is in roof-mounted state, in particular with reference to the 9 can be seen, obliquely to the side and inclined down to a corresponding drainage to the - in plan view - each right drainage area 13 to reach the corresponding cavity section. The between the transverse walls 9a to 9d provided transverse channels preferably have at least a slight slope in the direction of the respective water drainage area 13 each cavity section. This ensures that the whole, through the front vents 6 incoming water to the respective water drainage areas 13 discharged and therefore passed to the underlying tiles.

In the illustrated embodiment, the housing G of the roofing module 1 a total of four cavity sections, which replace a total of four tiles within a roof covering. In other embodiments of the invention roofing modules are provided with lesser or greater pitch. This means that in each case the width of the roofing module corresponds to n times the width of a corresponding roof tile. Within the roof covering module, the housing accordingly has an n-fold number of cavity sections with associated water drainage areas and water drainage openings.

As based on the 3 to 5 is clearly visible, the barrier elements are only over a portion of the height of the cavity 8th extends upwards. This means that water entering from the front can overcome the corresponding barrier elements of the row depending on the water pressure. The barrier elements have bulkhead functions and, moreover, direct the incoming water to the side and into the corresponding water drainage area 13 from.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 1201842 A1 [0002]

Claims (10)

Roof covering module with front ventilation openings ( 6 ), with at least one bottom water drainage area ( 13 . 13a ) and with at least one upper-side receiving area for a solar collector ( 3 ), with the ventilation openings ( 6 ) at least one cavity section adjoins the inside, which has at least one flow-guiding means, characterized in that at least one flow-guiding means is arranged as from a bottom of the cavity section ( 8th ) upwardly projecting barrier element ( 9a to 9d . 10 ) is designed. Roof covering module according to claim 1, characterized in that the at least one barrier element ( 9a to 9d . 10 ) over a portion of the height and / or the width of the cavity portion ( 8th ). Roof covering module according to claim 1 or 2, characterized in that rear ventilation openings ( 11 ) are provided, which in the cavity section ( 8th ). Roofing module according to claim 1, characterized in that the water drainage area ( 13 ) at least one drain opening ( 13a ), which in the roof-mounted state to flow guide elements ( 7 ) of an underlying tile ( 2 ) is open. Roof covering module according to at least one of the preceding claims, characterized in that as barrier element at least one of the front ventilation openings ( 6 ) adjacent crosswall ( 9a to 9d ) is provided, one side to the water drainage area ( 13 ) Leaking flow channel limited. Roof covering module according to at least one of the preceding claims, characterized in that in the cavity section ( 8th ) as a barrier element at least one curved Stausteg ( 10 ) provided at a distance behind the at least one transverse wall ( 9a to 9d ) is arranged. Roof covering module according to claim 6, characterized in that the Stausteg ( 10 ) arcuate, in particular circular arc, is curved. Roof covering module according to claim 7, characterized in that the arcuate curvature mirror-symmetrical to a vertical central longitudinal plane of the cavity portion ( 8th ) of the roof covering module runs. Roof covering module according to claim 1, characterized in that a housing (G) of the roof covering module is made of two shells made of plastic, in particular in a twinsheet method. Roof covering module according to claim 1, characterized in that the receiving region of the housing (G) for receiving at least one photovoltaic solar panel ( 3 ) which is closed to the cavity and has space portions for laying electrical wiring or cabling.

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