SE0802552A1 - Solar panel - Google Patents

Description

U 20 25 30 35 2 concentrated sunlight generated by the reflecting surfaces must not be "oversized" in relation to the surface of the solar panel. At least the primary object of the present invention is realized by means of devices which have obtained the features stated in the following independent claims. Preferred embodiments of the invention are defined in the dependent claims.

Brief Description of the Drawings Hereinafter, preferred embodiments of solar panels according to the present invention will be described with reference to the accompanying drawings, in which: Fig. A shows a known solar panel with series-connected solar cells, the solid frame symbolizing the area of full light intensity incident on the solar panel; Fig. B shows the solar panel according to Fig. A, however, the area with full light intensity is offset relative to the position according to Fig. A; Fig. 1 shows a first embodiment of a solar panel according to the present invention; Fig. 2 shows a wiring diagram for the solar cells that equip the solar panel according to Fig. 1; Fig. 3 shows a second embodiment of a solar panel according to the present invention; Fig. 4 shows a wiring diagram for the solar cells that equip the solar panel according to Fig. 3; Fig. 5 shows a solar panel according to the present invention where an area of full light intensity does not cover the entire solar panel; and Fig. 6 shows a solar panel according to the present invention where an area of full light intensity does not cover the entire solar panel and is offset relative to the position according to Fig. 5.

Detailed Description of Preferred Embodiments of the Invention Figs. A and B show a solar panel comprising series-connected solar cells C, these solar cells C being symbolized by squares with an obliquely upwardly extending provision, see the associated symbol. The solid frame R symbolizes the surface on which the incident light has full intensity.

As can be seen from Figs. A and B, the solid frame R is offset relative to the solar cells C of the solar panel. In Fig. A a vertical displacement is shown while in Fig. B a lateral displacement is shown. In the situation shown in Fig. A, the top row of solar cells will not be completely located inside the frame R, but the frame R passes through the middle of this top row of solar cells. In the situation shown in Fig. B, the leftmost solar cells will not be completely located inside the frame R, but the frame R passes in the middle of the leftmost row of solar cells.

Fig. 1 schematically shows a plan view of a solar panel according to the present invention, the solar panel being equipped both with series-connected first solar cells 1 and with parallel-connected second solar cells 3. As can be seen from the associated symbols, the series-connected solar cells 1 are indicated by squares having an oblique upward right stretching pantry. The other solar cells 3 connected in parallel are symbolized by squares which have an obliquely upwardly extending provision. The first and second solar cells 1 and 3, respectively, have equal areas, ie. the squares are equal in size.

In the embodiment of a solar panel according to the present invention shown in Fig. 1, the second solar cells 3 located along the edge portions of the solar panel are connected in parallel, while the first solar cells 1 located inside these second solar cells 3 are connected in series. Hereinafter, the series-connected solar cells 1 will be called center cells, while the parallel-connected solar cells 3 will be called edge cells.

In Fig. 1 the parallel connection between two edge cells 3 is shown, one of these edge cells 3 being located in an upper row of the solar panel while the other of these edge cells 3 is located in a lower row of the solar panel. The principle according to the invention is that the parallel-connected edge cells 3 must be located in respective opposite rows of edge cells 3, the rows being parallel. This applies to both the edge cells 3 which are located along the horizontal edges of the solar panel and the edge cells 3 which are located along the vertical edges of the solar panel. The reason for this will be explained below.

In Fig. 1, the edge strip which houses the edge cells 3 has the width B1 and between the width B1 of the edge strip and the width B or height H of the solar panel there is the following relationship: O

Fig. 2 shows the coupling arrangement between the center cells 1 and the edge cells 3 of the solar panel according to Fig. 1. edge cell 3 from the top row of the solar panel and an edge cell from a The edge cells 3 connected in parallel in parallel, e.g. a bottom of the solar panel, are interconnected in series, ie. first pair of parallel-connected edge cells 3 is connected in series with a second pair of parallel-connected edge cells 3, the second pair of parallel-connected edge cells 3 being connected in series with a third pair of parallel-connected edge cells 3, etc. The last pair of parallel-connected edge cells 3 is connected in series with the first series-connected center cell 1, in turn is connected in series with the next series-connected center cell 1, etc .. In this context it should be pointed out that the coupling arrangement according to Fig. 2 is also valid for the side edge cells 3 according to Fig. 1. Also in the embodiment of a solar panel shown in Fig. 3 In the present invention, the edge cells 103 located along the edge portions of the solar panel are connected in parallel, while the center cells 101 located inside these edge cells 103 are connected in series. In Fig. 3, the parallel connection between two groups of edge cells 103 is shown, one group of edge cells 103 being located in the top row of the solar panel while the other group of these edge cells 103 is located in the bottom row of the solar panel. The principle according to the invention is that the groups of other solar cells 103 connected in parallel must be located in each 103, edge cells 10 3 as their opposite row of edge-located solar cells, the rows being parallel. This applies both to those located along the horizontal edges of the solar panel and to the edge cells 103 which are located along the vertical edges of the solar panel. The reason for this will be explained below. With regard to the width B1 of the edge strip in relation to the dimensions of the solar panel, reference is made to what has been said above in connection with Fig. 1.

Fig. 4 shows the coupling arrangement between the center cells 101 and the edge cells 103 of the solar panel according to Fig. 3. As can be seen from Fig. 3, the edge cells 103 located at the top are connected in series and the edge cells 103 located at the bottom are also connected in series. Thereby an upper group of edge cells 103 is formed where the edge cells included in the group are connected in series and a group of edge cells 103 located at the bottom where the edge cells 103 included in the group are also connected in series. These two groups of edge cells 103 are connected in parallel, whereby each group of series-connected edge cells 103 can be regarded as a solar cell. Correspondingly, the two rows of edge cells 103 in the height cell H of the solar cell can be connected in series within each row, thereby forming two groups of series-connected edge cells 103 which are located at the outermost direction B of the solar panel. These two groups of edge cells can also be connected in parallel, whereby each group of edge cells can be regarded as a solar cell.

Fig. 4 illustrates how the groups of series-connected edge cells 103 are connected in parallel and how one of these parallel-connected groups is connected in series with a first center cell 101, which in turn is connected in series with the next center cell 101, and so on.

Figs. 5 and 6 show how the special parallel connection of the edge cells 3 as described above works when the surface with full light intensity does not cover all the solar cells on the solar panel.

The surface is symbolized with full light intensity by the solid frame R. Fig. 5 shows two parallel-connected edge cells 3, half of the surface of these two edge cells 3 being located inside the solid frame R. Since these two edge cells 3 are connected in parallel, they can be considered as a solar cell with an area that is the sum of the two half surfaces, ie. a solar cell / edge cell with a surface corresponding to the surface of a center cell 1.

Fig. 6 shows how the frame R is displaced in relation to the position R of the frame according to Fig. 5. In this case only about 20% of the left edge cell 3 is located inside the frame R while about 80% of the right edge cell 3 is located inside the frame R the edge cell 3 is located inside the frame R. Because the edge cells 3 are connected in parallel, the sum of the surfaces of the edge cells 3 which lie inside the frame R can be considered as a solar cell / edge cell with a corresponding surface as a center cell 1.

Since the parallel-connected edge cells 3 have a combined surface corresponding to the surface of the series-connected center cells 1, both the lighting cases shown in Figs. 5 and 6 for the solar panel according to the present invention will cause both the edge cells 3 and the center cells 1 to produce full effect.

In the case that edge cells are connected in series with each other, see Fig. 3 and the wiring diagram according to Fig. 4, the edge cells 103 connected in series in Fig. 3, ie. four at the top together with four at the bottom generate as much energy as four series-connected center cells 101. The total illuminated area of these eight edge cells 103 thus corresponds to the illuminated area of four series-connected center cells 101. When edge cells 103 are connected in series as in Fig. 3 so thus, twice as many edge cells 103 are required to generate the same electrical energy as center cells 101 are required. In the embodiment shown in Fig. 3, it should be pointed out that the lateral edge cells 103 can also be connected in series in a corresponding manner to form groups of series-connected edge cells 103, the groups then being connected in parallel.

Conceivable modifications of the invention In the embodiments described above, it is the outermost rows of solar cells called edge cells 3; 103. However, a series of solar cells along the circumference of the solar panel can constitute so-called depending on the size of the solar cells, more than edge cells. In this context, it should be pointed out that the number of solar cells that equip the solar panel according to the schematically shown embodiments is only an example.

As for the shape in plan view of the solar panel according to the present invention, it can in principle be arbitrary, whereby for exemplary and non-limiting purposes mention may be made of rectangular, circular, oval. When it comes to the width of the edge portions that are equipped with edge cells, the corresponding parameter relation as stated above applies, however, the width B and the height H are replaced by the relevant transverse dimensions of Thus, for a circular shape O, 1D, the current shape. the parameter relation 0 <Bl S where D is the diameter of the circle.

As for the shape in plan view of the solar cells 101, 103 square shape in the above-described embodiments. Within equipping the solar panel, these solar cells have 1, 3; within the scope of the present invention, however, it is conceivable that the solar cells have a shape other than square, whereby for exemplary and non-limiting purposes mention may be made of rectangular, hexagonal and triangular. In this context, it should be mentioned that solar cells on the same solar panel can also have different shapes.

In the embodiments described above, all solar cells included in a solar panel are the same size. Within the scope of the present invention, however, the edge cells may have an area which is larger than the area of the center cells. In this context, it should be pointed out that by the surface of an edge cell is also meant the sum of parts of edge cells according to the view illustrated in Figs. 5 and 6.

Claims (11)

N 15 20 25 30 35 Patent claim Solar panel comprising a number of solar cells (1, 3; 101, 103), circumferentially located edge cells (3; 103) are connected in parallel, and characterized in that along the solar panel located inside the edge cells (3; 101) 103) center cells ( 1; are connected in series. Solar panel according to claim 1, characterized in that the width (B1) of the edge portion of the solar panel which is equipped 103) relates to the following: with parallel connected edge cells (3; width of the solar panel (B) or height (H) 0 <Bl SO, 1B / H. Cknad av Solar panel according to Claim 1 or 2, characterized in that the edge cells (3) are connected in pairs in parallel. Solar panel according to claim 3, characterized in that the edge cells (3) are located in opposite edge portions of the solar panel. Solar panel according to claim 1 or 2, characterized in that the edge cells (103) are connected in series in groups, and that the groups of edge cells (103) are connected in parallel. Solar panel according to claim 5, characterized in that the groups of edge cells (103) are located in opposite edge portions of the solar panel. Solar panel according to one of the preceding claims, characterized in that all solar cells (1, 3; 101, 103) have an equal surface area. Solar concentrator comprising a number of solar panels, each solar panel comprising a number of solar cells (1, 3; 101, 103), circumferentially located edge cells (3; 103) are connected in parallel, and characterized in that along the solar panel that inside the edge cells (3 ; 103) located center cells (1; 101) are connected in series. 10 15 20 Solar concentrator according to claim 8, characterized in that the width (B1) provided with parallel-connected edge cells (3; or height (H) of the edge portion of the solar panel which is 103) relates to the width (B) of the solar panel as follows: 0 <Bl SO, lB / H 10. Solar concentrator according to claim 9, characterized in that the edge cells (3) are connected in pairs in parallel and located in opposite edge portions of the solar panel. 11. ll. Solar concentrator according to claim 9, characterized in that (103) the groups of edge cells (103) are connected in parallel and located that the edge cells are connected in series in groups, in opposite edge portions of the solar panel.