DE202008017560U1 - Mounting system for flat roof solar systems (photovoltaic and solar thermal) - Google Patents

Abstract

Solar module carrier (1) made of polystyrene or another plastic with a slope of 30 degrees for mounting solar modules (photovoltaic and solar thermal) on flat roofs. The shape of the module carrier is desk-shaped. It is characterized in that a made of a hard weather-resistant polystyrene foam solid body (2), whose bottom surface substantially corresponds to the size of the solar module (1) and facing south ( 2 ) is glued to the roof skin. The solar modules are embedded in the polystyrene block, so that it is flush with the upper edge of the module carrier. The side view essentially results in an irregular triangle. The length of the Ankathete corresponds to the length or width dimension of the solar module to be used. The length of the counter-catheter results from the angle of the inclination of 30 degrees.

Description

The utility model relates to a technically constructive form of a mounting system for solar modules ( 1 ) (Photovoltaic and solar thermie).

in view of endeavoring to supply energy to renewable energy sources Switching is the use of solar systems, such as photovoltaics and Solar-Thermie, an efficient alternative.

by virtue of The small amount of space available in built-up areas is an establishment of solar systems associated with difficulties.

The largest unused Space is available in built-up areas on buildings with flat roofs too Find.

at existing flat roofs It is usually difficult to use photovoltaic and solar thermal systems too install, as these are not included in the original building design Were considered and a subsequent installation to static Limits are encountered.

The novelty of the technically constructive form is characterized in that by the use of lightweight materials, eg. As polystyrene, it comes to minimizing the load transfer on flat roofs and thereby solar modules ( 1 ) can be mounted on flat roofs of buildings whose statics do not allow mounting according to the existing mounting systems. By using plastics such as polystyrene, the additional effect of thermal insulation comes into play. These materials are already used for roof insulation.

The polystyrene block ( 2 ) can be customized for solar modules ( 1 ) are made of different sizes. These are finally finished in the polystyrene block ( 2 ) and, if necessary, can be mounted by means of a holding frame or retaining strips. The block has south ( 2 ) aligned an optimal inclination of 30 degrees. This is also the requirement for optimum utilization of the solar energy of all solar and photovoltaic module manufacturers for monocrystalline photovoltaic modules for Germany. The polystyrene block can be made with different angles of inclination. When using thin-film modules, the tilt angle can be reduced to 5 degrees. If necessary, behind the inserted modules ( 1 ) incorporated a ventilation zone. This mounting block ( 2 ) is secured by a suitable adhesive, which ensures the necessary wind load safety, on the roof of a flat roof. Alternatively, or as an additional attachment to increased wind loads, the polystyrene block may be replaced by one of connection and attachment profiles ( 3 ), on / in the polystyrene foam block ( 2 ), which is pushed through the block, with the upper edge of the building ( 4 ), facing south ( 2 ), firmly connected and anchored ( 5 ) become. This profile is mounted in a mounting system on the outer wall of the building ( 2 . 3 ). The polystyrene block ( 2 ) is thus firmly connected to the building and withstands wind and storm. In the polystyrene block is for reinforcement in the area where the connection and fastening profile ( 3 ) is pushed through, a plastic sleeve ( 13 ) incorporated.

The shape of the polystyrene blocks ( 2 ) offers little attack surface for wind forces. If required, the shape determination of the polystyrene block can be used to modify the aerodynamic behavior. The weight will in most cases correspond to the specifications of the statics of the respective installation site.

The shape of the module carrier is desk-shaped. It is characterized in that a solid body consisting of a hard weather-resistant polystyrene foam ( 2 ) whose bottom surface is substantially the size of the solar module ( 1 ) and faces south ( 2 ) is glued to the roof skin. The solar modules are embedded in the polystyrene block, so that it is flush with the upper edge of the module carrier or mounted by means of a holding frame or retaining strips surface on the polystyrene foam block. The side view essentially results in an irregular triangle. The length of the Ankathete corresponds to the length or width dimension of the solar module to be used. The length of the counter-catheter results from the angle of the inclination of 30 degrees. When reducing the inclination, the length of the counter-catheter decreases.

Of the Utility model application drawings are attached to the existing designs Reference is made.

In the drawings show:

1 a single mounting block with inserted solar module and connection and fastening profile;

2 juxtaposed assembly blocks with inserted solar module and connecting and fastening profile, which are attached to the outer wall of a flat roof and aligned to the south;

3 Cross section of assembly blocks lined up with inserted solar module as well as connection and fixing profile, which freitra are attached to the outer wall of a flat roof;

4 Mounting block for solar module made of single elements in polystyrene;

5 Representation of a connection with dovetail profile;

6 Mounting block for holding several solar modules.

Claims (9)

Solar module carrier ( 1 ) made of polystyrene or another plastic with a slope of 30 degrees for mounting solar modules (photovoltaic and solar thermal) on rooftops. The shape of the module carrier is desk-shaped. It is characterized in that a solid body consisting of a hard weather-resistant polystyrene foam ( 2 ) whose bottom surface is substantially the size of the solar module ( 1 ) and faces south ( 2 ) is glued to the roof skin. The solar modules are embedded in the polystyrene block, so that it is flush with the upper edge of the module carrier. The side view essentially results in an irregular triangle. The length of the Ankathete corresponds to the length or width dimension of the solar module to be used. The length of the counter-catheter results from the angle of the inclination of 30 degrees. Solar module carrier ( 1 ) according to claim 1, characterized in that the solar modules are mounted by means of a holding frame or retaining strips on the surface of the polystyrene foam block. Solar module carrier ( 1 ) according to claim 1 or 2, characterized in that the polystyrene foam block ( 2 ) is manufactured with a need-based angle below 30 degrees. Solar module carrier ( 1 ) according to claim 1 to 3, characterized in that the polystyrene foam block in individual parts ( 6 . 7 . 8th . 9 . 10 ), which are glued or otherwise joined together. Solar module carrier ( 1 ) according to claim 1 to 4, characterized in that the polystyrene foam block ( 12 ) is manufactured in a size such that it has more than one solar module ( 1 ). Solar module carrier ( 1 ) according to claim 1 to 5, characterized in that the polystyrene foam block ( 2 ) are changed in color by means of protective coatings. Solar module carrier ( 1 ) according to claim 1 to 6, characterized in that on the counter-catheter of the polystyrene foam block ( 2 ) with an aerodynamic deflector or on the sides of the polystyrene foam block ( 2 ) adapted end pieces are attached. Solar module carrier ( 1 ) according to claim 1 to 7, characterized in that in the polystyrene foam block ( 2 ) a ventilation zone is incorporated. Solar module carrier ( 1 ) according to claim 1 to 8, characterized in that polystyrene foam block ( 2 ) is surrounded with a hard or soft weather-resistant casing and applied to the roof.