DE102013211167A1 - Solar module frame with a stabilizing rail, solar module with a solar module frame with a stabilizing rail and connection unit for a solar module frame - Google Patents

Abstract

The present invention relates to a solar module frame with a stabilizing rail, the stabilizing rail being designed to accommodate a connection unit, in particular in a cavity of the stabilizing rail. The invention further relates to a solar module with at least one solar cell, in particular designed as a divided cell, and the solar module frame according to the invention. The invention also relates to a connection unit for a solar module frame.

Description

State of the art

The present invention relates to a solar module frame with a stabilizing rail and a solar module with a solar module frame and a stabilizing rail. Furthermore, the invention relates to a connection unit for a solar module frame with a stabilizing rail.

The EP 2 448 009 A1 describes a solar module with one or more solar cells and a frame of the solar module. Also described is a stabilizer bar which connects two separate sides of the frame at the rear, the stabilizer bar having a cavity.

Disclosure of the invention

Advantages of the invention

The solar module frame according to the invention with a stabilizing rail with the features of the independent claim has the advantage that the solar module frame can be constructed very compact. The solar module frame can be constructed particularly compact, since a connection unit can be accommodated by a stabilizing rail of the solar module frame and thus can be integrated into the solar module frame. Additional space for the connection unit is not needed. The solar module frame with the features of the independent claim is further particularly versatile, since the terminal unit can accommodate and carry a high weight, since the terminal unit transmits a weight directly to the stabilizing rail and to the frame.

The measures listed in the dependent claims advantageous refinements and improvements are possible.

In an advantageous development, the connection unit is received by the stabilizing rail in such a way that heat arising in the connection unit is dissipated substantially via the stabilizing rail. A connection unit accommodated in this way is particularly durable, since heat arising in the connection unit can be dissipated particularly efficiently by the stabilization rail.

Also advantageous is at least one electronic component, in particular a bypass element for solar cells and / or an electronic component for yield monitoring and / or an electronic component for safety shutdown and / or a module inverter, a part of the connection unit. Such a trained solar module frame allows the production of a particularly compact and durable solar module, since electronic components of the solar module are housed stable and protected in the stabilizer rail.

Advantageously, a solar module is equipped with the solar module frame according to the invention. In particular, at least one of the solar cells of the solar module is advantageously designed as a divided cell, in particular as a half cell. Such a solar module is particularly compact and durable, since electronic components of the solar module can be taken stable and protected by the stabilizer rail.

In an advantageous embodiment of the solar module, a first number of first solar cells and a second number of the first different second solar cells are part of the solar module, the stabilizing rail being arranged between the first solar cells and the second solar cells. Such a solar module is particularly durable, as derived via the stabilizer rail heat can be dissipated between solar cells and is not delivered to the solar cell. An aging of the solar cells by heat given off is thus avoided.

In a further advantageous embodiment of the solar module, a first part of the first number of first solar cells is connected in series and a second part of the second number of second solar cells connected in series and the first part connected in series or in parallel with the second part. In this development, the solar module is particularly good and versatile, since a required current and / or a required voltage can be generated particularly well.

Further advantageously, the solar cells of the first and / or the second part are connected and arranged in a row such that a first solar cell of the row and a last solar cell of the row are arranged directly next to the stabilizing rail. Such a solar module is particularly easy manufacturable, since electronic components between the first solar cell of the series and the last solar cell of the series can be particularly well in the stabilizer rail, in particular in the connection unit, recorded.

A solar module, in which the bypass element is connected between the first solar cell of the series and the last solar cell of the series, has the advantage that such a solar module is particularly durable, since the bypass element protects the solar cell when the solar cell is shaded, and in particular during a recording of the bypass element in the connection unit in the stabilizing rail a particularly good heat dissipation is ensured.

Furthermore, at least one solar cell is advantageously designed as a solar cell which is photosensitive on both sides. Such a solar module is particularly efficient because light, which falls from both sides of the solar cell, can be used to generate electricity. In particular, in the case of an arrangement of the stabilizing rail between the first solar cells and the second solar cells, the rear side of the solar cell, which is photosensitive on both sides, is advantageously not shadowed by the stabilizing rail.

A connection unit for a solar module frame according to the invention, wherein the connection unit has a shape of a cuboid having a first, a second and a third edge length, wherein the first edge length to the second edge length and / or to the third edge length has a ratio of at least 10, is particularly can be used well with the solar module frame according to the invention. A connection unit with the dimensions described is particularly easy to integrate into the stabilizing rail of the solar module frame.

Further advantages will become apparent from the following description of embodiments with reference to the figures.

Brief description of the drawings

Embodiments of the invention are illustrated in the drawings and explained in more detail in the following description.

Show it:

1 a solar module with solar cell and solar module frame in exploded view

2 a solar module frame with a stabilizing rail and a connection unit

3 a section of the solar module frame with a section of the stabilizing rail, a connection unit and electronic components of the connection unit

4 a schematic representation of the solar module with a first number of first solar cells and a second number of the first different second solar cells in pure circuit

5 a schematic representation of the solar module with a first number of first solar numbers and a second number of the first different second solar cells in parallel

6 a schematic representation of the solar module with the first number of first solar cells and the second number of the first different second solar cells in another circuit.

Embodiments of the invention

The present invention relates to a solar module frame with a stabilizing rail, wherein the stabilizing rail is adapted to receive a connection unit, in particular in a cavity of the stabilizing rail. The invention further relates to a solar module with at least one solar cell, in particular a split cell, and the solar module frame according to the invention. Furthermore, the invention relates to a connection unit for a solar module frame.

1 shows a solar module 1 with a solar cell and with a solar module frame 3 in an exploded view. The solar module 1 has a solar module frame 3 as well as a solar cell 2 on. The solar module frame 3 is from a first frame rail 4 , a second frame rail 5 , a third frame rail 6 and a fourth frame rail 7 educated. The frame rails of the solar module frame 3 are drawn for a better clarity in an exploded view. The solar cell 2 is through the first frame rail 4 , second frame rail 5 , third frame rail 6 and fourth frame rail 7 edged. The frame rails are connected together in assembled form at their corners and take on one side of the solar cell. The solar module is thus formed from the solar cell 2 and the solar module frame 3 ,

2 shows a solar module frame 3 with a stabilizing rail 20 and a connection unit 21 , The in 2 illustrated solar module frame 3 has the first frame rail 4 , the second frame rail 5 , the third frame rail 6 and the fourth frame rail 7 on. Furthermore, the solar module frame 3 a stabilizer rail 20 with a cavity 22 and a connection unit 21 on. In the illustrated embodiment, the stabilizer bar connects 20 the opposing second frame rail 5 with the first frame rail 4 , In an alternative embodiment, the stabilizer bar connects 20 the fourth frame rail 7 with the third frame rail 6 , Alternatively or additionally, the frame rail may be opposite corners of the solar module frame 3 connect with each other. The stabilizer rail 20 has in the illustrated embodiment on one side of the cavity 22 on. The cavity 22 the stabilization rail 20 is formed in the preferred embodiment by an edge of the stabilizing rail on the Top and bottom of the stabilizer rail. In the illustrated embodiment, the terminal unit 21 in the cavity 22 added. The connection unit 21 is fixed to the stabilizer rail 20 connectable. In the illustrated embodiment, the terminal unit 21 positive locking with the stabilizing rail 20 connected. The connection unit 21 has at its top and / or on its underside one or more fastening webs 8th on, with the fastening webs 8th in correspondingly shaped omissions in the stabilizer rail 20 to grab. The connection unit 21 is thus form-fitting with the stabilizing rail 20 connected and in the cavity 22 added. The connection unit 21 is received by the stabilizing rail, that in the connection unit 21 resulting heat can be dissipated substantially via the stabilizing rail. For example, the connection unit 21 with the stabilizing rail 20 the largest possible contact surface, in particular on its upper side and / or on its underside and / or on a lateral surface. A heat-conducting paste at the contact surfaces between the connection unit can be particularly advantageous 21 with the stabilizing rail 20 be applied so that heat from the connection unit 21 particularly efficient on the stabilizer rail 20 can be delivered. In the illustrated preferred embodiment, the stabilizer rail engages 20 such in the frame rails of the solar module frame 3 and is the connection unit 21 such with the stabilizer rail 20 connected to a weight of the connection unit 21 of more than 500g, especially more than 1kg through the solar module frame 3 can be worn. In the illustrated embodiment, a particularly high stability is achieved by an intervention of the stabilizing rail 20 in the frame rails of the solar module frame 3 achieved, as well as by the cohesive connection of the connection unit 21 with the stabilizing rail 20 ,

3 shows a section of the solar module frame 3 with a cutout of the stabilizer rail 20 , a connection unit 21 and electronic components 30 the connection unit. In 3 shown is a section of the solar module frame 3 and a section of the stabilizing rail 20 , Also shown is the connection unit 21 and the cavity 22 the stabilization rail 20 , 3 also shows a first edge length 50 , a second edge length 51 and a third edge length 52 the connection unit 21 , Also shown are at least one electronic component 30 ,

In the illustrated embodiment, the electronic component is 30 as a bypass element for solar cells and / or as an electronic component for yield monitoring and / or as an electronic component for safety shutdown and / or as a module inverter. In addition to the electronic component 30 can add more electronic components in the connection unit 21 be housed. The other electronic components can be designed as various electronic components, for example as a bypass element for solar cells or as electronic components for yield monitoring or as electronic components for safety shutdown or as a module inverter. In particular, the electronic component 30 Part of the connection unit 21 and integrated into it. In the illustrated embodiment, the terminal unit 21 firmly in the cavity 22 the stabilization rail 20 edged. A stable connection between the stabilizing rail 20 and the connection unit 21 is ensured by the fastening web 8th the connection unit 21 the one in the omission 9 the stabilization rail 20 intervenes. In the illustrated embodiment, two fastening webs 8th and two omissions 9 intended. In an alternative embodiment, in addition to the illustrated fastening webs, further fastening webs and / or omissions may be provided on a lower side and / or on a rear side of the connecting unit and the stabilizing rail. Through the fixed enclosure of the connection unit 21 in the cavity 22 the stabilization rail 20 This results in a large-area contact between the connection unit 21 and the stabilizer rail 20 , The large-area contact results at the bottom of the connection unit and at the back of the connection unit and at the top of the connection unit. Over the large-area contacts is an optimal heat exchange between the connection unit 21 and the stabilizer rail 20 guaranteed. Heat in the electronic component 30 or arises in further electronic components in the connection unit, can be derived in a particularly advantageous and efficient manner via the connection unit and the stabilization rail. Due to the stable surround of the connection unit 21 in the stabilizer rail 20 and by the stable connection of the stabilizing rail 20 with the solar module frame 3 For example, weights of at least 500 g, in particular of at least 1 kg, can be stably and safely picked up and carried by the connection unit.

4 shows a schematic representation of the solar module 1 with a first number 41 first solar cells 43 and a second number 42 from the first different second solar cells 44 in series. In the schematic representation in 4 shown are a first number 41 first solar cells 43 and a second number 42 from the first different second solar cells 44 , Also shown are a first part 45 the first number 41 from first solar cells 43 and a second part 46 the second number 42 of second solar cells 44 , 4 also shows a first solar cell of the series 47 as well as one last solar cell of the series 48 , The first solar cell of the series 47 is the first solar cell of a series connection of the first part 45 of solar cells. The last solar cell of the series 48 is the last solar cell of a series connection of the first part 45 of solar cells. Also shown is the electrical component 30 , wherein the electrical component 30 as a bypass element 40 is trained. 4 further shows schematically the arrangement of the stabilizing rail 20 in the solar module 1 ,

In the in 4 Illustrated embodiments is the stabilizing rail 20 between the first solar cells 43 and the second solar cells 44 arranged. A first part 45 the first number 41 from the first solar cells 43 is connected in series. In the in 4 illustrated embodiments is still a second part 46 the second number 42 the second solar cell 44 connected in series. The first part 45 is with the second part 46 connected in series. In addition, in the in 4 illustrated embodiment, further solar cells with the first solar cells 43 connected in series. Furthermore, there are additional solar cells with the second solar cells 44 connected in series. In the illustrated embodiment, the first part 45 with the second part 46 connected in series. The bypass element 40 is between the first solar cell of the series 47 and the last solar cell of the series 48 connected. Further bypass elements are connected between the first and last solar cells of a row and in 4 shown. When shading the first part 45 the first number 41 from first solar cells 43 In these solar cells, no electricity or less electricity is produced. Current flow can in this case via the bypass element 40 respectively. In the case of a current flow via the bypass element 40 the bypass element heats up 40 , In the illustrated embodiment, the bypass element 40 in the stabilizer rail 20 accommodated. The solar cells of the first part 45 and the second part 46 are connected and arranged in series such that the first solar cell of the series 47 and the last solar cell of the series 48 right next to the stabilizer rail 20 are arranged. Between the first solar cell of the series 47 and the last row 48 can thus be located in the stabilizing rail, in particular in the connection unit in the stabilizing rail, bypass element with short lines to the first solar cell of the series 47 and the last solar cell of the series 48 get connected. When heating the bypass element 40 The resulting heat can be particularly advantageous and efficient to the stabilizer rail 20 be delivered. In the in 4 illustrated embodiment is the stabilizing rail 20 between the first solar cells 43 and the second solar cells 44 arranged. Above the stabilizer rail 20 there are no solar cells. Heat passing through the bypass element 40 can thus arise over the stabilizing rail 20 are delivered in an upper direction as well as in a lower direction. The heat emitted does not strike the solar cells of the solar module directly, since there are no solar cells above and / or below the stabilizing rail and / or the connecting unit in the stabilizing rail. An aging due to thermal stress of the solar cells is thus avoided. By the series connection of the first part 45 with the second part 46 It is particularly advantageous to achieve a multiplication of the voltage generated by the solar cells. Furthermore advantageous in the in 4 Series connection shown are the positive pole and the negative pole of the series connection on the same side of the solar module.

5 shows a schematic representation of the solar module 1 with a number 41 first solar numbers 43 and a second number 42 from the first different second solar cells 44 in parallel. In the schematic representation of 5 be like in 4 the first number 41 first solar cells 43 and the second number 42 from the first 43 different second solar cells 44 shown. Also shown are the first part 45 and the second part 46 , Also shown are stabilizer rails 20 and the bypass element 40 , In the in 5 illustrated embodiment, the first part 45 and the second part 46 the solar cells connected in parallel. In addition, in the illustrated embodiment, further parts of the first number 41 from first solar cells 43 connected in parallel to other parts of the second number 42 of second solar cells 44 , By the in 5 shown parallel circuit can be produced in a particularly advantageous manner, an increase in the current flow of the current generated by the solar cell.

6 shows a schematic representation of the solar module 1 with the first number 41 first solar cells 43 and the second number 42 from the first different second solar cells 43 in another circuit. In the schematic representation of 6 the same elements are shown as in the previously described 4 and 5 and marked with the same reference numerals. In the in 6 schematically illustrated embodiment, the first part 45 the first number 41 from first solar cells 43 connected in series with the second part 46 the second number 42 of second solar cells 44 , Furthermore, further parts of the first number 41 of solar cells with further parts of the second number 42 connected in series by solar cells.

The individual series circuits of the first number 41 from first solar cells 43 and the second number 42 of second solar cells 44 are connected in series. In a particularly advantageous manner, a multiplication of the increased voltage can thus be achieved. The stabilizer rail 20 with the connection unit, not shown 21 is between the first part 45 the first number 41 of solar cells and the second part 46 the second number 42 arranged by solar cells.

In another embodiment, not shown in the drawing, at least one solar cell of the solar module 1 designed as a double-sided photosensitive solar cell.

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 2448009 A1 [0002]

Claims (10)

Solar module frame ( 3 ) with a stabilizing rail ( 20 ), characterized in that the stabilizing rail ( 20 ), a connection unit ( 21 ), in particular in a cavity ( 22 ) of the stabilization rail ( 20 ). Solar module frame ( 3 ) according to claim 1 or 2, characterized in that the connection unit ( 21 ) in such a way by the stabilization rail ( 20 ), that in the connection unit ( 21 ) resulting heat substantially via the stabilizing rail ( 20 ) is derived. Solar module frame ( 3 ) according to one of the preceding claims, characterized in that at least one electronic component ( 30 ), in particular a bypass element ( 40 ) for solar cells and / or an electronic component for yield monitoring and / or an electronic component for safety shutdown and / or a module inverter, part of the terminal unit ( 21 ) are. Solar module ( 1 ), with at least one, in particular as a divided cell formed, solar cell ( 2 ), characterized by a solar module frame ( 3 ) according to any one of the preceding claims Solar module ( 1 ) according to claim 4, characterized by a first number ( 41 ) first solar cells ( 43 ) and a second number ( 42 ) from the first ( 43 ) of different, second solar cells ( 44 ), wherein the stabilization rail ( 20 ) between the first solar cells ( 43 ) and the second solar cells ( 44 ) is arranged. Solar module ( 1 ) according to claim 4 or 5, characterized in that - a first part ( 45 ) of the first number ( 41 ) of first solar cells ( 43 ) are connected in series and - a second part ( 46 ) of the second number ( 42 ) of second solar cells ( 44 ) are connected in series and - the first part ( 45 ) with the second part ( 46 ) is connected in series or in parallel. Solar module ( 1 ) according to one of claims 4 to 6, characterized in that the solar cells of the first part ( 45 ) and / or the second part ( 46 ) are connected and arranged in a row such that a first solar cell of the row ( 47 ) and one last solar cell of the series ( 48 ) directly next to the stabilization rail ( 20 ) are arranged. Solar module ( 1 ) according to one of claims 4 to 7, characterized in that between the first solar cell of the series ( 47 ) and the last solar cell of the series ( 48 ) the bypass element ( 40 ) is switched. Solar module ( 1 ) according to one of claims 4 to 8, characterized in that at least one solar cell ( 2 ) is designed as a double-sided photosensitive solar cell. Connection unit ( 21 ) for a solar module frame ( 3 ) according to one of the preceding claims, characterized in that the connection unit ( 21 ) a shape of a cuboid with a first ( 50 ), second ( 51 ) and third edge length ( 52 ) wherein the first edge length ( 50 ) to the second ( 51 ) Edge length and / or to the third edge length ( 52 ) has a ratio of at least ten.

Images