WO2018018908A1 - Solar battery cell and assembly, and preparation process therefor - Google Patents

Abstract

A solar battery cell (1), wherein main gate lines (2) thereof and a back electrode (3) on the back side thereof are arranged in a staggered manner. The previous design that positions of the main gate lines and the back electrode overlap in the same plane is replaced. At the same time, the solar battery cell constitutes an assembly, connected by means of stacking and welding. Firstly, solar battery slices (5) obtained after cutting the solar battery cell are applied to a lamination design so as to constitute a new solar battery assembly. Secondly, with regard to material, solder paste (6) is used to replace a solder strip or a bus bar, thereby greatly reducing costs. Moreover, connection is performed by means of stacking, thereby greatly reducing electrical losses and improving overall power generating efficiency of the assembly.

Description

Solar cell sheet and assembly and preparation process thereof Technical field

The invention relates to a solar cell panel assembly, in particular to a solar cell sheet and assembly and a preparation process thereof.

Background technique

In today's world, there is a shortage of energy. The development and utilization of clean energy such as solar energy has become an important project for the use of new energy in the world. How to improve the power generation efficiency of solar cells is the focus of research and development work of major photovoltaic companies. Currently, new technology solar cells, For example, PERC batteries, HIT batteries, MWT batteries, etc. have been developed and tested in various enterprises or in small batch production.

At present, the production of components uses solder ribbons and bus bars to connect their internal solar cells, such as a wedge electrode for crystal silicon solar cell connection (ZL201210106034XCN), a wedge electrode for crystal silicon solar cell connection, which is characterized. In that it comprises a electrode wedge segment and a electrode segment, the electrode wedge segment and the electrode segment are connected together, the electrode wedge segment is in contact with the front surface of the crystalline silicon solar cell sheet and is welded together, the electrode segment and the crystalline silicon solar cell sheet The back side is in contact and welded together. In this way, the higher the optical performance of the battery with better optical performance, the higher the system electrical loss, how to make full use of the electrical performance of the existing solar cell or new technology cell, and reduce the electrical loss of the high efficiency cell at the component end. It is a subject of research by various photovoltaic companies. The new printing graphic design proposed by the present invention can effectively solve such problems.

Summary of the invention

OBJECT OF THE INVENTION: For a crystalline silicon solar cell, the forbidden band width is constant. After laser cutting, the voltage of each cell is theoretically constant, the current becomes smaller, and after these cut cells are connected in series, The cell current is lower than the original cell current, resulting in reduced electrical losses due to component end packaging. The object of the present invention is to provide a solar cell sheet, including a single crystal, polycrystalline or quasi-single crystal battery, especially a high-electricity parameter, high-performance solar cell, which can be used for subsequent laser cutting, and using a solder paste to cut The screen printing graphic design of the cell stack production assembly can increase the relative power of the component by at least 2% to solve the problem that the higher the optical performance of the prior art, the higher the system electrical loss.

Moreover, the invention only needs to make a small modification of the probe system of the IV test device of the solar cell sheet, has small changes to the battery production line, and does not increase the production cost of the battery end, and is an easy-to-implement, low-cost new battery. .

Technical Solution: The present invention adopts the following technical solutions:

A solar cell sheet in which a main gate line of a solar cell sheet and a back electrode of a back surface thereof are alternately arranged, in place of a design in which the previous main gate line and the back electrode overlap in the same plane.

As an optimization, the solar cell sheet is divided into a plurality of solar cell slices by laser cutting lines, each of the solar cell slices having at least one main gate line and one back electrode, and the main grid line is adjacent to the solar cell slice parallel to the laser cutting On one side of the line direction, the back electrode is adjacent to the other side of the solar cell slice parallel to the direction of the laser cutting line.

As an optimization, the main gate lines on each of the solar cell slices are close to the same side.

As an optimization, the shortest linear distance between the main grid line and the laser cutting line is not more than 0.8 mm except for the main grid line near the solar cell frame.

As an optimization, the shortest linear distance between the back electrode and the laser cutting line is not more than 0.8 mm except for the back electrode near the solar cell frame.

As an optimization, the shortest linear distance between the main grid line near the solar cell frame and the solar cell frame parallel to the main grid line direction does not exceed 0.8 mm.

As an optimization, the shortest linear distance between the back electrode adjacent to the solar cell frame and the solar cell frame parallel to the direction of the back electrode does not exceed 0.8 mm.

As an optimization, the width of the main gate line does not exceed 1 mm.

As an optimization, the width of the back electrode does not exceed 1 mm.

A solar cell module using a solar cell chip, comprising at least two solar cell slices, the back electrode of the upper solar cell slice and the main grid line of the next solar cell slice are abutted, and the tin is coated at the abutment The paste is connected.

As an optimization, the solder paste has a thickness of 0.15 to 0.5 mm.

A preparation process of a solar cell module using a solar cell sheet, comprising the following steps:

1) Production of solar cells;

2) delineating the laser cutting line, printing the main grid line and the back electrode of the solar cell according to the position of the laser cutting line, ensuring that the main grid line and the back electrode are alternately arranged;

3) laser cutting the solar cell according to the position of the laser cutting line;

4) After the laser cutting is completed, the solar cell chip is subjected to a splitting operation to be divided into individual solar cell slices;

5) Stacking individual solar cell slices up and down and connecting them into solar cell modules by solder paste.

As an optimization, the solder paste may be performed simultaneously with the printing of the main gate line and the back electrode of the solar cell in step 2), or may be performed after the end of step 4).

As an optimization, the solar cell slices can be stacked on top of each other and coated with solder paste at the joints. The connection is cured by heating and re-cooling.

Working principle: This printing graphic design is different from the existing traditional battery design. In order to ensure that the cut battery pieces can be stacked and welded, the main grid line and the back electrode of the solar cell slice are not in the upper and lower overlapping positions, but are staggered. design. In this way, after the laser is cut along the parallel positive and negative electrode positions, the solder paste can be applied to the contact surface of the main grid line and the back electrode of the battery sheet by printing, spraying, etc., after applying the solder paste, After the typesetting of the solar cell slice in the component is typeset, the solar cell slice is welded and connected by infrared heating or hot air heating.

After the laser is cut along the parallel positive and negative electrode positions, the solder paste can be applied to the contact surface of the main grid line and the back electrode of the battery sheet by printing, spraying, etc., after applying the solder paste and then according to the assembly. After the typesetting of the solar cell slice is required to be typeset, the solar cell slice is welded and connected to form a component by infrared heating or hot air heating.

Advantageous Effects: The present invention is compared with the prior art:

1. At present, the conventional component manufacturing adopts a method in which a solder ribbon and a bus bar are connected to the internal solar cell sheet, and the system has higher electrical loss of the system for the battery sheet with better optical performance. The idea of the present invention is to design a screen printing pattern of a solar cell that can be used for laser cutting, and to solder the cut cell sheet by solder paste, thereby reducing the current of the single cell and causing electrical loss of the component system. cut back. In theory, after cutting the battery sheet by 4 pieces according to this design, the package loss of the component can be relatively reduced by 85%-93%.

2. In order to achieve such an effect, the present application adopts a design in which the main gate line of the solar cell sheet and the back electrode of the back surface thereof are alternately arranged, instead of overlapping the previous main gate line and the back electrode in the same plane, so that When the top and bottom stacking design is carried out, the shading surface can be reduced as much as possible to improve the power generation efficiency of the battery.

3. At present, the front surface area of ordinary silicon-based batteries is about 7%. The solder paste is used in the present invention, so the width of the electrodes can be smaller than that of the conventional battery sheets. The current design is 1 to 1.4 mm. The design is No more than 1mm, the positive electrode area is reduced by 30% to 40%, which can reduce the shading loss of the front main grid of the cell and improve the output power of the component;

4, in the conventional components, the battery chip spacing is generally 2 ~ 3mm, and in this application, the stacking method for component connection can omit the spacing of 2 ~ 3mm, taking 60 battery slices as an example, with 6 batteries The chip slice is connected, and the 10 cell module is used as a solar cell unit. The method of the present application can greatly reduce the occupied area of the solar cell unit. If the same area is used, the design of 60 pieces can be used for laying more by the present application. 2.5 pieces of battery slices, increase the power generation of the cell unit, each manufacturer through experimental demonstration, through different types of components to reduce the spacing of the cell can increase the output power of the component by more than 2%, the assembly of the design of the cell is welded Stack welding effectively reduces the spacing of individual cells in conventional components and improves the conversion efficiency and power of the components.

DRAWINGS

1 is a schematic structural view of a front surface of a solar cell sheet of the present invention;

2 is a schematic structural view of a back surface of a solar cell sheet of the present invention;

3 is a partially enlarged schematic view showing a portion of a main grid line and a laser cutting line of a solar cell sheet of the present invention;

4 is a schematic structural view of a prior art solar cell module;

Figure 5 is a schematic structural view of a solar cell module of the present invention;

Fig. 6 is a view showing the effect of the solar battery module of the present invention after connection.

detailed description

The present invention will be further described below in conjunction with specific embodiments, as shown in Figures 1 through 6:

Example 1

A solar cell sheet using a new printed pattern, the main gate line 2 of the solar cell sheet 1 and the back electrode 3 on the back side thereof are alternately arranged, in place of the previous main gate line 2 and the back electrode 3 overlapping in the same plane. design.

The solar cell sheet is divided into a plurality of solar cell slices 5 by laser cutting lines 4, each of which has at least one main gate line 2 and one back electrode 3, and the main grid line 2 is adjacent to the solar cell slice 5. On the side parallel to the direction of the laser cutting line 4, the back electrode 3 is adjacent to the other side of the solar cell slice 5 in the direction parallel to the laser cutting line 4.

The main gate lines 2 on each of the solar cell chips 5 are close to the same side.

The shortest linear distance between the main grid line 2 and the laser cutting line 4 is 0.8 mm except for the main grid line 2 near the frame of the solar cell sheet 1.

The shortest linear distance between the back electrode 3 and the laser cutting line 4 was 0.8 mm except for the back electrode 3 near the frame of the solar cell sheet 1.

The shortest linear distance between the main grid line 2 near the frame of the solar cell 1 and the frame of the solar cell 1 parallel to the direction of the main grid line 2 is 0.8 mm.

The shortest linear distance between the back electrode 3 near the frame of the solar cell 1 and the frame of the solar cell 1 parallel to the direction of the back electrode 3 was 0.8 mm.

The width of the main gate line 2 is 1 mm.

The back electrode 3 has a width of 1 mm.

Example 2

A solar cell sheet 1 adopting a newly printed pattern, the main gate line 2 of the solar cell sheet 1 and the back electrode 3 on the back side thereof are alternately arranged, in place of the previous main gate line 2 and the back electrode 3 in the same plane position Overlapping design.

The solar cell sheet 1 is divided into a plurality of solar cell slices 5 by laser cutting lines 4, each of which has at least one main gate line 2 and one back electrode 3, and the main grid line 2 is close to the solar cell slice. 5 is parallel to the side of the laser cutting line 4, and the back electrode 3 is adjacent to the other side of the solar cell slice 5 in the direction parallel to the laser cutting line 4.

The main gate lines 2 on each of the solar cell chips 5 are close to the same side.

The shortest linear distance between the main grid line 2 and the laser cutting line 4 is 0.1 mm except for the main grid line 2 near the frame of the solar cell sheet 1.

The shortest linear distance between the back electrode 3 and the laser cutting line 4 was 0.1 mm except for the back electrode 3 near the frame of the solar cell sheet 1.

The shortest linear distance between the main grid line 2 near the frame of the solar cell sheet 1 and the frame of the solar cell sheet 1 parallel to the main grid line 2 is 0.1 mm.

The shortest linear distance between the back electrode 3 near the frame of the solar cell 1 and the frame of the solar cell 1 parallel to the direction of the back electrode 3 was 0.1 mm.

The width of the main gate line 2 is 0.1 mm.

The back electrode 3 has a width of 0.1 mm.

Although there are discussions in the definition that the position does not exceed 0.8mm and 1mm, the actual excess will definitely leave room for it. After all, the laser has a region, so here 0.1mm is used, of course, 0.05mm or 0.01mm can also be used.

This printed graphic design is different from the existing conventional battery design. In order to ensure that the cut battery pieces can be stacked and soldered, the front and back electrodes of the battery sheets are not in the upper and lower overlapping positions, but are staggered. In this way, after the laser is cut along the parallel positive and negative electrode positions, the solder paste can be applied to the front or back electrode of the battery sheet by printing, spraying, etc., after applying the solder paste, and then according to the battery piece in the assembly. After the typesetting is required to be typeset, the battery piece is welded and connected by infrared heating or hot air heating.

Example 3

Take the solar cell laser into four solar cell slices as an example.

A solar cell sheet 1 adopting a newly printed pattern, the main gate line 2 of the solar cell sheet and the back electrode 3 on the back side thereof are alternately arranged, in place of the previous main gate line 2 and the back electrode 3 overlapping in the same plane. design.

The solar cell sheet 1 is divided into four solar cell slices by three laser cutting lines, each of which has at least one main gate line 2 and one back electrode 3, and the main grid line 2 is close to the solar cell. The slice 5 is parallel to one side of the direction of the laser cutting line 4, and the back electrode 3 is adjacent to the other side of the solar cell slice 5 in the direction parallel to the laser cutting line 4.

The main gate lines 2 on each of the solar cell chips 5 are close to the same side.

The arrangement of the main grid lines 2 on the same side may also be replaced by the fact that the main grid lines 2 on the solar cell slice 5 are close to the intermediate position, and the main grid line 2 of each solar cell slice 5 is close to the center of the solar cell sheet 1. The laser cutting line 4 is parallel to the laser cutting line 4, and the back electrode 3 is away from the center laser cutting line 4 side of the solar cell 1 and parallel to the laser cutting line 4.

The shortest linear distance between the main grid line 2 and the laser cutting line 4 is 0.45 mm except for the main grid line 2 near the frame of the solar cell sheet 1.

The shortest linear distance between the back electrode 3 and the laser cutting line 4 is 0.45 mm, except for the back electrode 3 near the frame of the solar cell sheet 1.

The shortest linear distance between the main grid line 2 near the frame of the solar cell sheet 1 and the frame of the solar cell sheet 1 parallel to the direction of the main grid line 2 is 0.45 mm.

The shortest linear distance between the back electrode 3 near the frame of the solar cell 1 and the frame of the solar cell 1 parallel to the direction of the back electrode 3 was 0.45 mm.

The width of the main gate line 2 is 0.2 mm.

The back electrode 3 has a width of 0.5 mm.

The main grid line 2 is designed continuously, and can be segmented according to actual needs; the back electrode is the same.

The thickness of the main gate line 2 and the back electrode 3 can be printed according to the general process requirements of the current screen printing of the battery sheet, and there is no special requirement. Currently, the printing thickness is generally 12 to 25 um.

The laser cutting line 4 has a width of 0.1 to 1.6 mm.

After the laser cutting line 4 is cut, the groove width of the battery sheet may vary according to the size of the laser spot, but will not exceed twice the width of the cutting line;

The distance between two adjacent main grid lines 2 is the width of each solar cell slice.

Comparative example 1

A wedge electrode for connecting a crystalline silicon solar cell, characterized in that it comprises a electrode wedge segment and a electrode segment, the electrode wedge segment and the electrode segment are connected together, and the electrode wedge segment is in contact with the front surface of the crystalline silicon solar cell sheet And soldered together, the electrode segments are in contact with the back side of the crystalline silicon solar cell sheet and soldered together.

In this way, the higher the optical performance of the battery sheet, the higher the system electrical loss.

Example 4

A solar cell module using a laminated design, comprising at least two solar cell slices 5, the back electrode 3 of the upper solar cell slice 5 and the main grid line 2 of the next solar cell slice 5 are in contact with each other The solder paste 6 is applied to the connection.

The back electrode 3 and the main gate line 2 on each of the solar cell chips 5 are alternately arranged.

The back electrode 3 on each of the solar cell slices 5 is adjacent to one side of the solar cell slice 5, and the main gate line 2 is adjacent to the other side of the solar cell slice 5.

The shortest straight line distance between the back electrode 3 and the main grid line 2 and the solar cell slice 5 on each solar cell slice 5 in a direction parallel to the main gate line 2 is not more than 0.8 mm.

The solder paste 6 has a thickness of 0.15 to 0.5 mm.

After the laser is cut along the parallel positive and negative electrode positions, the solder paste 6 can be applied to the abutment of the main gate line 2 and the back electrode 3 of the solar cell slice 5 by printing, spraying, etc., and the solder paste is applied. After 6th, according to the typesetting requirements of the solar cut cell sheet 5 in the module, the solar cell slice 5 is welded and connected to form a component by infrared heating or hot air heating.

Comparative example 2

A wedge electrode for connecting a crystalline silicon solar cell, comprising a wedge segment of the electrode and a segment of the electrode, the wedge segment and the electrode segment being joined together, the wedge segment of the electrode being in contact with the front surface of the crystalline silicon solar cell and soldered together The electrode segments are in contact with the back side of the crystalline silicon solar cell sheet and are soldered together.

As can be seen from the above Example 4 and Comparative Example 2, the biggest difference between the present invention and the comparative example is that:

1. The solar cell slices of the present application are stacked, and the layout of different components can be used to reduce the spacing of the cells to increase the output power of the components by more than 2%.

2. The solar cell slices of the present application are stacked at the same time, and the solder paste layer is applied to the abutment between the slices to realize the connection, so the width of the electrodes can be smaller than that of the current conventional cells, and at the same time, the back of each solar cell slice The shortest straight line distance between the electrode and the main grid line and the solar cell slice along the frame parallel to the main grid line direction does not exceed 0.8 mm. If the frame is 0, the shading area can be effectively reduced and the output power of the component can be improved.

Example 5

A preparation process of a solar cell module using a solar cell sheet, comprising the following steps:

1) producing solar cell sheet 1;

2) Delineating the laser cutting line 4, printing the solar cell main gate line 2 and the back electrode 3 according to the position of the laser cutting line 4, ensuring that the main gate line 2 and the back electrode 3 are staggered;

3) laser cutting the solar cell sheet 1 according to the position of the laser cutting line 4;

4) After the laser cutting is completed, the solar cell sheet is subjected to a splitting operation to be divided into individual solar cell slices 5;

5) Stacking the individual solar cell chips 5 up and down and connecting them into a solar cell module through the solder paste 6.

The solder paste 6 can be simultaneously printed in the step 2) of the printed solar cell 1 main gate line 2 and the back electrode 3 Alternatively, the solder paste 6 may be applied after the end of step 4).

The solar cell chips 5 are stacked one on top of the other and the solder paste 6 is applied to the joints, and then the joints can be solidified by soldering or heating and re-cooling.

The invention provides a solar cell sheet and a component and a preparation process thereof, and the method and the method for realizing the technical solution are many. The above description is only a preferred embodiment of the present invention, and it should be noted that it is common to the technical field. The skilled person will be able to make several modifications and retouchings without departing from the principles of the invention. These modifications and refinements are also considered to be within the scope of the invention, and various components not specifically identified in this embodiment are available. The prior art is implemented.

Claims (13)

A solar cell sheet characterized in that a main gate line of the solar cell sheet and a back electrode on a back surface thereof are alternately arranged, in place of a design in which the previous main gate line and the back electrode overlap in the same plane. The solar cell sheet according to claim 1, wherein the solar cell sheet is divided into a plurality of solar cell slices by laser cutting lines, and each of the solar cell chips has at least one main gate line and one back electrode. The main grid line is adjacent to one side of the solar cell slice parallel to the direction of the laser cutting line, and the back electrode is adjacent to the other side of the solar cell slice parallel to the direction of the laser cutting line. The solar cell sheet according to claim 2, wherein the main gate lines on each of the solar cell slices are close to the same side. The solar cell sheet according to claim 1, wherein the shortest linear distance between the main gate line and the laser cutting line is not more than 0.8 mm except for the main grid line adjacent to the solar cell frame. The solar cell sheet according to claim 1, wherein the shortest linear distance between the back electrode and the laser cutting line is not more than 0.8 mm except for the back electrode adjacent to the solar cell frame. The solar cell sheet according to claim 1, wherein a shortest linear distance between the main grid line adjacent to the solar cell frame and the solar cell frame parallel to the main grid line direction does not exceed 0.8 mm. The solar cell panel of claim 1 wherein the shortest linear distance between the back electrode adjacent the solar cell frame and the solar cell frame parallel to the back electrode direction does not exceed 0.8 mm. The solar cell sheet according to claim 1, wherein the width of the main gate line and the back electrode are not more than 1 mm. A solar cell module using the solar cell sheet of claim 1, comprising at least two solar cell slices, wherein: a back electrode of the upper solar cell slice and a main gate line of the next solar cell slice Apply abutting and apply solder paste to the abutment. The solar cell module according to claim 9, wherein the solder paste has a thickness of 0.15 to 0.5 mm. A process for preparing a solar cell module according to claim 9, comprising the steps of: 1) Production of solar cells; 2) delineating the laser cutting line, printing the main grid line and the back electrode of the solar cell according to the position of the laser cutting line, ensuring that the main grid line and the back electrode are alternately arranged; 3) laser cutting the solar cell according to the position of the laser cutting line; 4) After the laser cutting is completed, the solar cell chip is subjected to a splitting operation to be divided into individual solar cell slices; 5) Stacking individual solar cell slices up and down and connecting them into solar cell modules by solder paste. The process for preparing a solar cell module according to claim 11, wherein the solder paste is performed simultaneously with the printing of the main gate line and the back electrode of the solar cell in step 2), or may be performed after the end of step 4). Paste coating. The process for preparing a solar cell module according to claim 11, wherein the solar cell slices are stacked on top of each other and solder paste is applied at the joint, and the connection can be solidified by soldering or heating and re-cooling.

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