DE202011108662U1 - solar system - Google Patents

Abstract

Solar system for obtaining energy from solar radiation, comprising: - at least one solar converter (1) for converting radiant energy into thermal energy or electrical energy, - a support frame (150, 250) for attachment to a base, and - the solar converter (1) a solar transducer frame (3) for attachment to the support frame, and - the support frame comprises at least one receiving area (151, 251) for receiving the solar transducer frame (3), wherein in the receiving area (151, 251) and / or on the solar converter frame (3) a sliding film (4, 154, 254) is disposed so as to be at least partially disposed between the support frame and the solar conversion frame (3) to reduce frictional resistance between the solar conversion frame (3) and the support frame.

Description

The present invention relates to a solar system with a solar converter for the production of energy from solar radiation, and such a solar converter.

Solar systems generally include a solar converter for converting radiant energy into thermal energy or electrical energy and a support frame for mounting the solar converter. Under such a solar system, for example, a solar thermal system or a photovoltaic system understood. In this case, a solar thermal system comprises at least one solar converter, for example in the form of a solar collector and a photovoltaic system at least one solar converter, for example in the form of a photovoltaic module. Such solar converters are usually bordered by a solar converter frame, which is attached to a support frame. The solar converter frame and the support frame are usually made of aluminum or consist of it.

Such solar converters have different connection options, which are arranged either frontally or laterally. In lateral arrangements, a solar converter is pushed over the support frame to another solar converter during assembly of several solar converters. The solar converter is at least partially with its solar converter frame on the support frame. Due to the high coefficient of friction between aluminum and aluminum, the postponement of the solar converter on the support frame has proved problematic and also causes an unpleasant crunching noise.

The invention is thus based on the object to remedy or reduce at least one of the above-mentioned problems, in particular an improved assembly is to be made possible. At least an alternative solution should be proposed.

According to the invention, a solar system for recovering energy from solar radiation is thus proposed according to claim 1. Such a solar system comprises at least one solar converter for converting radiant energy into thermal energy or electrical energy and a support frame for attachment to a base. The solar converter includes a solar transducer frame for attachment to the support frame, and the support frame includes at least one receiving portion for receiving the solar converter frame of the solar converter. In this case, in the receiving area and / or on the solar converter frame a sliding film is arranged so that it is at least partially disposed between the support frame and the solar converter frame to reduce a frictional resistance between the solar converter frame and the support frame.

In the following, a solar collector, here also referred to as a solar collector, in particular a flat collector or an in-roof collector, or a photovoltaic module, also referred to here as a solar module or a composite of a plurality of solar cells, is understood as such a solar converter. The solar collector converts solar radiation into heat, preferably for heating or for heating water. The photovoltaic module converts the sun's rays into electrical energy, preferably for feeding into the power grid or for own energy consumption. Such solar converters have a solar converter frame, which encloses the individual components such as absorbers and thermal insulation in the flat collector or individual solar cells in the photovoltaic module. In this case, the solar converter frame is preferably designed in a trough or profile construction and / or made of aluminum.

The solar converter frame is attached to the support frame. The support frame is attached to a base. Under this base is preferably understood to be a roof or a mounted on the ground frame. The support frame has a receiving area, in which the solar converter frame is at least partially inserted or inserted. Such a receiving area is formed, for example, by a support surface and a contact surface, which are approximately perpendicular to each other. Babel is the solar converter frame at least partially on the support surface and / or at least partially on the contact surface. Alternatively, the receiving area is essentially formed by a support surface, a contact surface and a guide surface. In this case, the guide surface and the support surface are interconnected, preferably over the contact surface, and have a distance from each other, so that they clasp or embrace a part of the solar converter frame. The distance is so great that it corresponds approximately to the part of the solar converter frame, which is pushed into the receiving area. In order to improve the lubricity in the installation of the solar converter on the support frame, a sliding film is arranged, which is at least partially attached in particular to the solar converter frame and / or to the receiving area of the support frame. Preferably, the sliding film between the contact surfaces of the solar converter frame and the support frame is arranged. By attaching a sliding foil, the coefficient of friction, ie the ratio of the friction force to the normal force, of the resting surfaces is reduced, so that pushing on is simplified.

Preferably, the support frame has at least one support frame profile in the form of an extruded profile and the receiving area or a part thereof. Such an extruded profile is optimized in the ratio of weight to stability, in which it has a plurality of cavities. Preferably, these cavities are used as cable channels and / or mounting channels. This extruded profile forms the receiving area, which can be formed in a simple, known and efficient manner.

In a further embodiment, the support frame profile is formed of a solid material.

In a further embodiment, the support frame profile of a hollow body, for example, a canted profile is formed. In a preferred embodiment of the invention, the support frame profile consists of several individual parts that are screwed together, welded, riveted or otherwise connected to each other.

Preferably, the support frame profile is formed in the form of a curved profile. It is advantageous to provide two support frame profiles, which are arranged substantially parallel to each other, so that the solar converter frame is inserted on two sides of the support frame to be held on these two sides.

In a preferred embodiment, the sliding film is made of polyethylene or is formed from it. Such a sliding film is also referred to as a sliding belt and is preferably formed only from a polyethylene layer. Alternatively, the slip band is formed of multiple layers, forming at least one layer of polyethylene. Such a sliding film is abrasion resistant, durable and / or has a very good self-lubrication behavior. Preferably, the sliding film is self-adhesive and / or has a very low lubricity. The coefficient of friction for aluminum on aluminum in a dry state with sliding friction is for example 1.04 and for example for friction 1.05. The friction coefficient using a sliding film is preferably in a range of 0.1 to 0.8.

In a further preferred embodiment, the sliding film is adhered to the solar converter frame and / or support frame at least partially. Babel the film is preferably adhered to the solar converter frame and / or support frame prior to assembly, so that the solar converter frame and / or the support frame are prepared for installation and the sliding film when sliding the solar converter frame on the support frame remains in place and for a low friction between provides the contact surfaces.

Furthermore, the present invention includes a solar converter for converting radiant energy into thermal energy or electrical energy. The solar converter includes a solar transducer frame for attachment to a support frame to be attached to a base, wherein the support frame includes at least one receiving area for receiving the solar conversion frame. Babel is arranged in the receiving area and / or on the solar converter frame a sliding film so that it is at least partially disposed between the solar converter frame and the support frame when the solar converter is mounted on the support frame.

In addition, the invention proposes the use of a sliding film for installing a solar converter described above on a support frame. Babel is used in particular a transparent polyethylene film and attached to the solar converter and / or support frame so that it is at least partially disposed between the solar converter frame and the support frame, namely between the contact surfaces of the two frames to the sliding during assembly, in particular during Sliding the solar converter frame on the support frame, to facilitate.

• – Anordnen einer Gleitfolie zumindest teilweise zwischen dem Solarwandlerrahmen und dem Tragrahmen, insbesondere an dem Solarwandlerrahmen und/oder dem Tragrahmen, und
• – Aufschieben des Solarwandlers auf den Tragrahmen,

so dass die Gleitfolie beim Aufschieben zumindest teilweise zwischen dem Solarwandlerrahmen und dem Tragrahmen angeordnet ist, insbesondere zwischen einer Kontaktfläche des Solarwandlerrahmens und des Tragrahmens.Furthermore, an installation method for attaching a solar converter described above is proposed on a support frame according to the invention. Babel includes the procedure:

• - Arranging a sliding film at least partially between the solar converter frame and the support frame, in particular on the solar converter frame and / or the support frame, and
• - Sliding the solar converter on the support frame,

so that the sliding film is arranged at least partially between the solar converter frame and the support frame when sliding, in particular between a contact surface of the solar converter frame and the support frame.

In this case, the sliding film is preferably arranged by adhering to the solar converter frame and / or the support frame. Alternatively, the sliding film, in particular directly before pushing, loosely placed on the support frame.

The invention will now be explained by way of example with reference to exemplary embodiments with reference to the accompanying figures.

1 shows an embodiment of a flat collector in a perspective view from above;

1a shows the flat plate of the 1 in a perspective view from below;

2 shows an embodiment of an extruded profile in a perspective view;

2a shows the detail of an embodiment of the flat plate of the 1 together with the extruded profile of 2 ;

2 B shows the detail of an embodiment of the flat plate of the 1 together with the extruded profile of 2 ;

3 shows a further embodiment of an extruded profile in a perspective view;

3a shows the detail of an embodiment of the flat plate of the 2a together with the extruded profile of 3 ;

3b shows the detail of an embodiment of the flat plate of the 1 together with the extruded profile of 3 ,

The figures contain partially simplified, schematic representations. In part, identical reference numerals are used for the same but possibly not identical elements.

1 shows an embodiment of a solar converter according to the invention in the embodiment of a flat collector 1 in a perspective view from above. There is a surface 2 of the flat collector 1 to recognize which of a flat collector frame 3 is enclosed. The flat collector frame 3 consists of a lower area 20 , a middle area 30 and an upper area 40 , In this case, the lower area 20 a lateral contact surface 7 and the middle area a side surface 6 on. The lateral contact surface 7 stands out. At the lateral contact surface 7 is a self-adhesive sliding foil 4 made of polyethylene.

Further shows 1 one on the side surface 6 arranged connection 5 , The connection 5 in particular serves a connection for the exchange of liquid to further flat plate collectors or to a central unit such as a hot water tank. The connection is carried out, for example plugged or screwed.

1a shows the flat collector 1 of the 1 in a perspective view from below. It is a bottom surface 8th of the flat collector 1 to recognize which of the flat collector frame 3 is enclosed. The flat collector frame 3 consists of the lower area 20 with the lateral contact surface 7 and a lower contact surface 14 , the middle area 30 with the side surface 6 and the upper area 40 or is formed from it. Furthermore, the on the side surface 6 arranged connection 5 and the at the lateral contact surface 7 attached sliding foil 4 to recognize.

2 shows an embodiment of a support frame profile in the form of an extruded profile 150 in a perspective view. The extruded profile 150 has a recording area 151 for receiving a solar converter frame of a solar collector or a photovoltaic module. In this case, the receiving area 151 a support surface 152 and a contact surface 153 on, which are perpendicular to each other, or is formed thereby. On the contact surface 153 and the bearing surface 152 is in each case a sliding foil 154 appropriate. Furthermore, the extruded profile 150 cavities 155 which are used, for example, as cable ducts and whose walls stabilize the extruded profile 150 serve. In addition, two cavities, each with a longitudinal opening 157 for supplying fasteners such as screws provided.

Such an extruded profile 150 is to be provided as part of a support frame, which is mounted depending on the application, for example on a roof or the ground. In this case, a support frame preferably consists of at least two extruded profiles or has at least two extruded profiles. Alternatively, such a support frame can also be constructed of curved profiles.

2a shows the extruded profile 150 of the 2 together with a flat plate collector 1 similar to the 1 in a section in the intended installation arrangement. The extruded profile 150 has cavities 155 , two cavities, each with a longitudinal opening 157 as well as the recording area 151 with the support surface 152 and the contact surface 153 on. It is on the support surface 152 and the contact surface 153 each a sliding foil 154 appropriate.

In the reception area 151 is the flat collector 1 added. This is the flat collector 1 with a section around the flat collector frame 3 circumferential lateral contact surface 7 at the contact surface 153 at and with the lower contact surface 14 at least partially on the support surface 152 on. The sliding foil 154 is between the bearing surface 152 and the lower contact surface 14 as well as between the contact surface 153 and the lateral contact surface 7 arranged. In contrast to 1 has the flat collector 1 no sliding film on.

The flat collector 1 has a surface 2 , a thermal insulation 9 , an absorber 10 , several pipes 11 and a flat collector frame 3 on, which encloses the aforementioned components. Due to the sunlight, the air is below the surface 1 heated and the absorber 10 heated. The absorber 10 absorbs the heat and passes it through the pipes 11 to one through the pipes 11 flowing liquid on.

2 B shows an embodiment of the extruded profile 150 of the 2 together with the flat plate of the 1 , In contrast to 2 is not a sliding foil on the support surface 152 and the contact surface 153 appropriate. For simplified assembly is a sliding film 4 at the the flat collector 1 circumferential lateral contact surface 7 appropriate.

3 shows a further embodiment of a support frame profile in the form of an extruded profile 250 in a perspective view. In this case, the extruded profile 250 a recording area 251 for receiving a frame of a solar collector or a photovoltaic module. The recording area 251 is essentially a support surface 252 , a contact surface 253 and a guide surface 256 educated. Here are the support surface 252 and the guide surface 256 arranged parallel with a distance from each other and through the contact surface 253 connected with each other. The distance of the support surface 251 to the guide surface 256 is preferably so large that the frame of a solar collector or a Photovotaikmoduls can be at least partially pushed into it.

On the respective the receiving area 251 forming surfaces is a sliding film 254 appropriate. There are also cavities 255 of the extruded profile 250 shown.

3a shows an embodiment of the extruded profile 250 of the 3 together with the flat collector 1 of the 2a , Part of the flat collector frame 3 is the circumferential lateral contact surface 7 as well as the lower contact surface 14 , The lateral contact surface 7 is partly due to the contact surface 253 of the recording area 251 of the extruded profile 250 at. The lower contact surface 14 is partially on the support surface 252 on. The bearing surface 252 and the guide surface 256 are arranged to each other so that they form a distance to each other, in which the flat collector frame 3 Takes place. The resulting distance together with the contact surface 253 make up the reception area 251 , To easily move the flat collector 1 within the reception area 251 or a slight insertion into the receiving area 251 to enable is at the respective the receiving area 251 forming surfaces a sliding film 254 appropriate.

3b shows an embodiment of the flat collector 1 of the 1 together with the extruded profile 250 of the 3 , Here is the flat collector 1 in the recording area 251 of the extruded profile 250 inserted. To facilitate the insertion is on to the flat collector frame 3 around running lateral contact surface 7 a sliding foil 4 appropriate. The the reception area 251 forming surfaces are contrary to 3 provided with no sliding foil.

Claims (6)

Solar system for the production of energy from solar radiation, comprising: - at least one solar converter ( 1 ) for converting radiant energy into thermal energy or electrical energy, - a supporting frame ( 150 . 250 ) for fixing to a base, and - the solar converter ( 1 ) comprises a solar converter frame ( 3 ) for attachment to the support frame, and - the support frame comprises at least one receiving area ( 151 . 251 ) for receiving the solar converter frame ( 3 ), wherein in the receiving area ( 151 . 251 ) and / or on the solar converter frame ( 3 ) a sliding foil ( 4 . 154 . 254 ) is arranged so that it at least partially between the support frame and the solar converter frame ( 3 ) is arranged to a frictional resistance between the solar converter frame ( 3 ) and the support frame. Solar installation according to claim 1, characterized in that the support frame has at least one support frame profile, in the form of an extruded profile ( 150 . 250 ) and has the receiving area or a part thereof. Solar installation according to one of claims 1 or 2, characterized in that the sliding film ( 4 . 154 . 254 ) is made of polyethylene or is formed. Solar installation according to one of the preceding claims, characterized in that the sliding film ( 4 . 154 . 254 ) to the solar converter frame ( 3 ) and / or the support frame is glued. Solar converter ( 1 ) for converting radiant energy into thermal energy or electrical energy, comprising: - a solar conversion frame ( 3 ) for attachment to a support frame to be attached to a base, the support frame comprising at least one receiving area ( 151 . 251 ) for receiving the solar converter frame ( 3 ), wherein in the receiving area ( 151 . 251 ) and / or on the solar converter frame ( 3 ) a sliding foil ( 4 . 154 . 254 ) is arranged so that it at least partially between the support frame and the solar converter frame ( 3 ) is arranged to a frictional resistance between the solar converter frame ( 3 ) and the support frame. Use of a sliding foil ( 4 . 154 . 254 ) for installing a solar converter according to claim 5 on a support frame.

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