CN114141907A - Sheet distribution method for battery array - Google Patents

Abstract

The invention discloses a method for distributing a cell array, which belongs to the technical field of solar cell arrays for space and comprises the following steps: s1, selecting the type and the number of the solar cells; s2, selecting a first trapezoidal solar cell, and arranging the first trapezoidal solar cell on the inner side of the edge of the substrate; s3, laying a second trapezoidal solar cell on the substrate; s4, arranging an X-1 trapezoidal solar cell matched with the X trapezoidal solar cell on the substrate; s5, selecting the type and the number of the solar cells according to the residual positions of the substrate, repeating S1-S4, and arranging the solar cells at the residual positions of the substrate; s6, arranging the rest series solar cells in the vertical direction according to the number of actually required series solar cells; s7, if a vacant area exists, filling in the vacancy; and S8, arranging a common bypass diode between adjacent batteries, and arranging an upper electrode bus bar and a lower electrode bus bar at the head end and the tail end of the battery string. The polygonal battery piece distributing mode is reasonably distributed and formed, and the polygonal battery piece distributing mode has the characteristic of good adaptability.

Description

Sheet distribution method for battery array

Technical Field

The invention belongs to the technical field of solar cell arrays for space, and particularly relates to a method for distributing sheets of a cell array.

Background

The solar cells are uniformly distributed on the surface of the solar cell array substrate, and the purpose is to convert light energy into electric energy to supply power for the satellite. The solar cells adopted on the current solar cell array for space use are mainly rectangular solar cells with more regular shapes, and the epitaxial wafers of the rectangular solar cells have lower utilization rate and higher production cost. Polygonal solar cells are less used in space solar cell arrays and cannot be well adapted to a rectangular solar cell sheet distribution method. For this case, the following problems may occur if the conventional rectangular solar cell sheet method is used:

in the traditional method, the same type of cells are adopted for sheet distribution, the gaps among the solar cells are large, the sheet distribution rate is low, and each cell needs to be protected by adopting an independent diode. Undoubtedly, the effective sheet distribution area of the whole plate is reduced, the sheet distribution rate is reduced, and the cost of the solar cell is increased.

If the same large-size polygonal solar cell is used for sheet distribution, the gap between the edges of the solar cell spacing plates is larger at the edge of the substrate, and the sheet distribution rate is lower.

The rectangular solar cell is completely symmetrical in shape, and the uniform distribution of a plurality of cells and the sheet distribution on the surface of the substrate have poor adaptability and low sheet distribution rate.

Disclosure of Invention

The invention provides a cell array sheet distribution method for solving the technical problems in the prior art, which is used for improving the adaptability of polygonal solar cell sheet distribution.

The invention aims to provide a sheet distribution method of a battery array, which comprises the following steps:

s1, selecting the type and the number of the solar cells according to the size of the substrate; the solar cell is a trapezoidal solar cell;

s2, selecting a first trapezoidal solar cell according to the structure of the edge of the substrate, and arranging the first trapezoidal solar cell on the inner side of the edge of the substrate, wherein one waist edge of the first trapezoidal solar cell is parallel to the edge of the substrate, and the distance between the waist edge and the edge of the substrate is not less than 2 mm;

s3, arranging a second trapezoidal solar cell matched with the first trapezoidal solar cell on the substrate;

s4, arranging an X-1 trapezoidal solar cell matched with the X trapezoidal solar cell on the substrate; x is a natural number greater than 2; until covering the working area except the forbidden distribution area or the edge of the substrate;

s5, selecting the type and the number of the solar cells according to the residual positions of the substrate, repeating S1-S4, and arranging the solar cells at the residual positions of the substrate;

s6, arranging the rest series solar cells in the vertical direction according to the number of actually required series solar cells;

s7, if a vacant area exists, filling in the vacancy; otherwise, go to S8;

and S8, arranging a common bypass diode between adjacent batteries, and arranging an upper electrode bus bar and a lower electrode bus bar at the head end and the tail end of the battery string.

Preferably, the heights of two adjacent trapezoidal solar cells are equal; splicing surfaces of two adjacent trapezoidal solar cells are parallel; two adjacent trapezoidal solar cells share one diode; the anodes of the two adjacent trapezoidal solar cells are positioned at the same side, and the cathodes of the two adjacent trapezoidal solar cells are positioned at the same side.

Preferably, the trapezoidal solar cell has a right-angled trapezoid structure.

Preferably, the trapezoidal solar cell has a non-right-angled trapezoid structure.

Preferably, the trapezoidal solar cell has an isosceles trapezoid structure.

Preferably, an upper electrode bus bar and a lower electrode bus bar are disposed on two parallel sides of the trapezoidal solar cell.

Preferably, the diode is positioned between the upper electrode bus bar and the cell array, and the diode is positioned between two adjacent trapezoidal solar cells.

The invention has the advantages and positive effects that:

the invention combines the trapezoidal solar cell with the long edge as the upper electrode with the trapezoidal solar cell with the long edge as the lower electrode, thereby solving the problems of larger occupied area and lower sheet distribution rate of the traditional single solar cell. Two adjacent batteries can share one diode, so that the production cost and the weight of the battery piece are reduced;

the invention combines the whole trapezoidal solar cell and the single and half polygonal solar cells, and solves the problems of large vacant area and low sheet distribution rate of the whole polygonal solar cell combination at the corners of the rectangular substrate. Two different sheet distribution modes provide solutions for the residual spaces of the substrates with different sizes;

the invention combines and uses a plurality of half polygonal solar cells, and solves the problem that the vacant positions of the substrates are not enough for placing the whole polygonal solar cells after the overall layout is completed;

the polygonal solar cell cloth piece is reasonable in design idea, and the problem that the polygonal solar cell cloth piece is poor in adaptability can be effectively solved. According to the conditions of the substrates with different sizes, different types of polygonal solar cell combination modes are adopted, so that the distribution rate of the polygonal solar cells can be effectively improved; namely, the invention can improve the sheet distribution adaptability of the solar cell array and improve the sheet distribution rate.

Drawings

FIG. 1 is a schematic structural diagram of a first preferred embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a second preferred embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a third preferred embodiment of the present invention;

FIG. 4 is a schematic structural diagram of a non-right trapezoid solar cell in a preferred embodiment of the invention;

FIG. 5 is a schematic view of a rectangular trapezoidal solar cell according to a preferred embodiment of the present invention;

FIG. 6 is a layout diagram of non-rectangular trapezoid solar cells arranged on the edge of a substrate according to a preferred embodiment of the present invention;

FIG. 7 is a layout diagram of rectangular trapezoid solar cells arranged on the edge of a substrate according to a preferred embodiment of the present invention;

FIG. 8 is a layout diagram of rectangular trapezoid solar cells arranged at the remaining positions of the substrate according to the preferred embodiment of the present invention;

FIG. 9 is a layout diagram of non-rectangular trapezoid solar cells arranged at the remaining positions of the substrate according to the preferred embodiment of the present invention;

FIG. 10 is a block diagram of a tandem solar cell in a preferred embodiment of the present invention;

fig. 11 is a block diagram of a supplement in a preferred embodiment of the present invention.

Detailed Description

In order to further understand the contents, features and effects of the present invention, the following embodiments are illustrated and described in detail with reference to the accompanying drawings:

as shown in fig. 1, the technical solution of the present invention is:

a battery array based on trapezoidal solar cells is formed by splicing M trapezoidal solar cells 3, wherein M is a natural number greater than 1; wherein:

the heights of two adjacent trapezoidal solar cells 3 are equal; splicing surfaces of two adjacent trapezoidal solar cells are parallel; two adjacent trapezoidal solar cells share one diode 1; the anodes 2 of the two adjacent trapezoidal solar cells are positioned at the same side, and the cathodes 4 of the two adjacent trapezoidal solar cells are positioned at the same side. Wherein:

bus bars 5 are arranged on two parallel sides of the trapezoidal solar cell, and the bus bars comprise an upper electrode bus bar and a lower electrode bus bar.

The diode is positioned between the upper electrode bus bar and the battery array, and the diode is positioned between two adjacent trapezoidal solar batteries.

A method of laying out a battery array, comprising:

s1, selecting the type and the number of the solar cells according to the size of the substrate; the solar cell is a trapezoidal solar cell; as shown in fig. 4 and 5; the trapezoidal solar cell can be in a right trapezoid shape, a non-right trapezoid shape or an isosceles trapezoid shape. Preferably a right trapezoid, an isosceles trapezoid;

s2, selecting a first trapezoidal solar cell according to the structure of the edge 6 of the substrate, and arranging the first trapezoidal solar cell on the inner side of the edge of the substrate, wherein one waist edge of the first trapezoidal solar cell is parallel to the edge of the substrate, and the distance between the waist edge and the edge of the substrate is not less than 2 mm;

s3, arranging a second trapezoidal solar cell matched with the first trapezoidal solar cell on the substrate;

s4, arranging an X-1 trapezoidal solar cell matched with the X trapezoidal solar cell on the substrate; x is a natural number greater than 2; until covering the working area except the forbidden arrangement area 7 or the edge of the substrate; as shown in fig. 6 and 7;

s5, selecting the type and the number of the solar cells according to the residual positions of the substrate, repeating S1-S4, and arranging the solar cells at the residual positions of the substrate; the maximum cloth piece rate is realized, as shown in fig. 8 and fig. 9;

s6, arranging the rest series solar cells in the vertical direction according to the number of actually required series solar cells; as shown in fig. 10;

s7, if the vacant areas exist, filling in the vacancy areas by adopting the method shown in the figure 11; otherwise, go to S8;

s8, arranging a common bypass diode between adjacent batteries, and summarizing the upper electrode bus bar and the lower electrode bus bar at the head end and the tail end of the battery string:

(1) the invention provides a novel sheet distribution method, which solves the problems of poor adaptability and low sheet distribution rate of a polygonal battery using a traditional rectangular battery sheet distribution method.

(2) The slice distribution method provided by the invention aims at the polygonal cell, and improves the slice distribution rate of the solar cell array while improving the utilization rate of the epitaxial slice of the polygonal cell.

Aiming at the special-shaped characteristic of the high-efficiency large-size polygonal solar cell, the invention provides a method for combining and using various polygonal cells according to the original conventional solar cell sheet distribution thought, and various polygonal cell sheet distribution modes can be formed through reasonable layout. The solar cell substrate with the shape of the solar cell forbidden distribution region can be effectively suitable for substrates with various sizes commonly used at the present stage, and has the characteristic of good adaptability for the solar cell forbidden distribution regions with various shapes on the substrate.

The above description is only for the preferred embodiment of the present invention, and is not intended to limit the present invention in any way, and all simple modifications, equivalent changes and modifications made to the above embodiment according to the technical spirit of the present invention are within the scope of the technical solution of the present invention.

Claims (7)

1. A method for distributing battery arrays is characterized by comprising the following steps:

s1, selecting the type and the number of the solar cells according to the size of the substrate; the solar cell is a trapezoidal solar cell;

s2, selecting a first trapezoidal solar cell according to the structure of the edge of the substrate, and arranging the first trapezoidal solar cell on the inner side of the edge of the substrate, wherein one waist edge of the first trapezoidal solar cell is parallel to the edge of the substrate, and the distance between the waist edge and the edge of the substrate is not less than 2 mm;

s3, arranging a second trapezoidal solar cell matched with the first trapezoidal solar cell on the substrate;

s4, arranging an X-1 trapezoidal solar cell matched with the X trapezoidal solar cell on the substrate; x is a natural number greater than 2; until covering the working area except the forbidden distribution area or the edge of the substrate;

s5, selecting the type and the number of the solar cells according to the residual positions of the substrate, repeating S1-S4, and arranging the solar cells at the residual positions of the substrate;

s6, arranging the rest series solar cells in the vertical direction according to the number of actually required series solar cells;

s7, if a vacant area exists, filling in the vacancy; otherwise, go to S8;

and S8, arranging a common bypass diode between adjacent batteries, and arranging an upper electrode bus bar and a lower electrode bus bar at the head end and the tail end of the battery string.

2. The method for arranging the solar cells of claim 1, wherein the height of two adjacent trapezoidal solar cells is equal; splicing surfaces of two adjacent trapezoidal solar cells are parallel; two adjacent trapezoidal solar cells share one diode; the anodes of the two adjacent trapezoidal solar cells are positioned at the same side, and the cathodes of the two adjacent trapezoidal solar cells are positioned at the same side.

3. The method of claim 1, wherein the trapezoidal solar cells are rectangular trapezoidal.

4. The method of claim 1, wherein the trapezoidal solar cells are configured as non-right trapezoids.

5. The method for arranging the cell array of claim 2, wherein the trapezoidal solar cell has an isosceles trapezoid structure.

6. The method of laying out a plurality of cell arrays according to claim 1, wherein upper electrode bus bars and lower electrode bus bars are provided on two parallel sides of the trapezoidal solar cell.

7. The method of arranging a plurality of solar cells according to claim 1, wherein the diodes are disposed between the upper electrode bus bar and the plurality of solar cells, and the diodes are disposed between two adjacent trapezoidal solar cells.

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