KR20190046356A - Apparatus for tabbing solar cells - Google Patents

Abstract

The present invention relates to a solar cell tabbing device which prevents an outermost electrode and a wire interconnector of a solar cell from being fused without changes of an electrode arrangement structure of a solar cell, and blocks a cell crack phenomenon caused by detachment of the interconnector from the outermost electrode. According to the present invention, the solar cell tabbing device comprises: a cell stage which provides a space where bonding of a wire interconnector and a solar cell electrode is performed; and a soldering device which applies heat to the cell stage and induces fusion of the wire interconnector and the solar cell electrode. A plurality of pinholes are provided in the cell stage, and an elevating pin, which selectively elevates the wire interconnector provided in a region between neighboring solar cells, is provided in each pinhole.

Description

{Apparatus for tabbing solar cells}

[0001] The present invention relates to a solar cell freezing apparatus, and more particularly, to a solar cell freezing apparatus, in which a wire interconnector is detached from an outermost electrode by preventing an outermost electrode of a solar cell and a wire interconnector from fusing, And a cell cracking phenomenon that can be prevented.

The solar cell module is a device for receiving and photoelectrically converting sunlight, and is made up of a plurality of solar cells. Each solar cell constituting the solar cell module may be referred to as a p-n junction diode.

The process of converting sunlight into electricity by solar cells is as follows. When sunlight is incident on the p-n junction of the solar cell, an electron-hole pair is generated, and electrons are transferred to the n-type semiconductor layer and holes are transferred to the p-type semiconductor layer by the electric field to generate photovoltaic power between the p-n junctions. In such a state, if a solar cell is connected to both ends of the solar cell, a current can flow to produce electric power. The front and rear surfaces of the solar cell are provided with front and back electrodes for collecting electrons and holes, respectively.

For example, the front electrode 111 of the first solar cell 110 is connected to the rear electrode 122 of the neighboring second solar cell 120, As shown in FIG. A conductor for electrically connecting the front electrode 111 of the first solar cell 110 to the rear electrode 122 of the second solar cell 120 is generally referred to as an interconnector 130 ).

The interconnector for electrically connecting neighboring solar cells is made of a conductor having a certain width and thickness. The shape for connecting neighboring solar cells is a ribbon shape, and a common interconnector is also referred to as a ribbon.

As described above, the ribbon-shaped inter-connector (hereinafter referred to as ribbon interconnection) has a predetermined width and thickness, for example, a width of about 1.5 mm and a thickness of about 270 탆, I can not help but see that. Since the solar cell receives the sunlight and converts it into electricity, the decrease in the light receiving area of the solar cell means a decrease in the photoelectric conversion efficiency.

In order to solve the problem of reducing the light receiving area by the inter-connector and to improve the efficiency of the solar cell, researches for replacing the ribbon inter-connector with a wire-type inter-connector (hereinafter referred to as wire interconnection) It is progressing. The wire interconnect method uses a conductive wire having a diameter of about 200 to 600 占 퐉 to connect the electrodes of neighboring solar cells.

Since the width of the conductor (diameter) is significantly smaller than that of the ribbon interconnection method, the reduction of the light receiving area by the interconnector can be minimized, and the influence of the reduction of the light receiving area by the interconnector is small In contrast to the ribbon interconnect method, a greater number of interconnects can be disposed in the solar cell, thereby improving the efficiency of the solar cell.

However, in applying a wire interconnection, it is necessary to pay attention to a cell crack phenomenon caused by a wire adhesion failure at an outermost portion.

The process of bonding the wire interconnect to the solar cell is generally referred to as a tabbing process. The solar cell's tapping process generally proceeds as follows.

(For example, a first solar cell and a second solar cell) having a front electrode and a rear electrode formed adjacent to each other are arranged on the front surface electrode of the first solar cell and the rear surface electrode of the second solar cell, Place the inter connector. The wire interconnector is disposed on the front electrode of the first solar cell and in a state extending over the rear electrode of the second solar cell. In this state, when heated using an infrared lamp or the like, the front electrode and the wire interconnector are welded together, and the back electrode and the wire interconnector are fused together, and the tableting process is completed.

The wire interconnector can be bonded to the electrode of the wire interconnector through the above-described tableting process. Since the width of the wire interconnector is much smaller than that of the ribbon interconnector, the wire interconnector is disposed between the first and second solar cells The connection failure of the wire interconnection may occur at the bent portion of the wire interconnection. That is, since the elastic force of the wire interconnector is large at the bending portion between the first solar cell and the second solar cell, the wire interconnector can be detached from the outermost electrode by the small external physical force. When the wire interconnection is detached from the front electrode or the rear electrode, a problem such as a crack (dotted line mark) is generated in the cell as shown in FIG.

In order to solve such a problem, there is a method in which no electrode is disposed at the outermost part of the solar cell. In this case, although the state of connection between the wire interconnector and the outermost electrode can be improved, the efficiency of the solar cell is inevitably lowered due to no electrode disposed at the outermost portion.

Korean Patent No. 1305087

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a solar cell in which the outermost electrode of a solar cell and the wire interconnection are not fused, And to provide a solar cell tableting apparatus capable of preventing a cell cracking phenomenon and the like induced.

According to an aspect of the present invention, there is provided a solar cell freezing device, comprising: a cell stage for providing a space where bonding of a wire interconnector and a solar cell electrode proceeds; And a soldering apparatus for applying heat to the cell stage to induce fusion between the wire interconnector and the solar cell electrode, wherein the cell stage is provided with a plurality of pinholes, And a lifting pin for selectively lifting and lowering the wire interconnector provided in the area between the batteries.

And a lifting pin driving means for controlling the lifting and lowering of the lifting pin is further provided on one side of the cell stage. Further, when the elevator pin lifts up the wire interconnector provided in the area between the neighboring solar cells during the tableting process, the outermost electrodes of the wire interconnector and the solar cell do not contact each other.

The solar cell shutter device according to the present invention has the following effects.

In the case of performing the tableting process for the solar cell under the normal electrode arrangement structure without the avoidance design such as the electrode being not disposed at the outermost portion of the solar cell, by suppressing the fusion between the wire interconnector and the outermost electrode, It is possible to eliminate problems such as cell cracks which are separated from the outermost electrode and are generated thereby, thereby improving the reliability and stability of the solar cell module.

1 is a schematic view of a general solar cell module.
2 is a configuration diagram of a solar cell tableting apparatus according to an embodiment of the present invention;
3 is a configuration diagram of a cell stage according to an embodiment of the present invention;
4 is an EL photograph showing that a crack was generated at a corner portion of the solar cell.

Disclosure of Invention Technical Problem [8] The present invention provides a technique capable of preventing a wire interconnector from being easily detached from an outermost electrode by an external physical force by suppressing fusion between an outermost electrode of a solar cell and a wire interconnection. As mentioned in the Background of the Invention, when the wire interconnector is detached from the outermost electrode in a state where the wire interconnector and the outermost electrode are fusion-bonded through the tableting process, problems such as cell cracks occur.

The present invention relates to a solar cell tableting apparatus capable of suppressing contact between a wire interconnection and an outermost electrode by lifting a wire interconnection between neighboring solar cells during a tabletting process, present.

Hereinafter, a solar cell tableting apparatus according to an embodiment of the present invention will be described in detail with reference to the drawings.

Referring to FIG. 2, the solar cell deicing apparatus according to an embodiment of the present invention includes a cell stage 110 and a soldering apparatus 120.

The cell stage 110 provides a space in which the solar cell is subjected to the tableting process, and a plurality of solar cells 10 are disposed adjacent to the cell stage 110. The cell stage 110 may further include conveying means (not shown) such as a conveyor belt for the efficiency of the tableting process, and the solar cell 10 before and after the tableting process may be moved through the conveying means .

The soldering apparatus 120 applies heat to the solar cell 10 to fuse the wire interconnect 20 and the electrodes of the solar cell 10 together. The soldering apparatus 120 may be composed of a heating apparatus 121 and an inter-connector fixing apparatus 122 in detail. The heating device 121 may include an infrared lamp or the like as a device for applying heat to the solar cell 10 and the interconnection fixing device 122 may be connected to the solar cell 10 via the heating device 121. [ 10 in order to prevent the wire interconnector 20 from deviating from a predetermined position in the process of applying heat to the wire interconnector 20.

As described in the Background of the Invention, the state of bonding between the wire interconnector 20 and the outermost electrode of the solar cell 10 is unstable in the solar cell module having completed the tableting process, The wire interconnector 20 is easily detached from the outermost electrode by the physical force.

In order to solve such a problem, the present invention provides the following constitution.

2 and 3, the cell stage 110 is provided with a plurality of pinholes 111, and each pinhole 111 is provided with a lifting pin 112 selectively lifted and lowered . The pinhole 111 is provided in a region between neighboring solar cells 10 and the elevating pin 112 provided in the pinhole 111 is connected to a wire interconnection (20). A lift pin driving means for controlling the lift of the lift pins 112 is further provided at one side of the cell stage 110.

When the wire interconnector 20 provided in the area between the neighboring solar cells 10 is raised or lifted up via the lifting pin 112, the wire interconnector 20 and the solar cell 10 The outer electrodes do not come into contact with each other. In this state, when the tableting process using the soldering apparatus 120 is performed, electrodes disposed on the outermost portion of the solar cell 10, that is, all the electrodes except for the outermost electrode are connected to the wire interconnector 20 While the outermost electrode of the solar cell 10 is not fused with the wire interconnector 20.

Since the outermost electrodes of the wire interconnector 20 and the solar cell 10 are not fusion-bonded after the completion of the tableting process, the wire interconnector 20 is electrically connected to the solar cell 10 The possibility of separation from the electrode of the electrode assembly becomes small.

10: Solar cell 20: Wire interconnect connector
110: Cell Stage 111: Pinhole
112: lift pin 113: lift pin driving means
120: soldering device 121: heating device
122: Interconnector fixing device

Claims (3)

A cell stage for providing a space in which the connection between the wire interconnector and the solar cell electrode proceeds; And
And a soldering apparatus for applying heat to the cell stage to induce fusion of the wire interconnector and the solar cell electrode,
Wherein a plurality of pinholes are provided in the cell stage, and each pinhole is provided with a lift pin for selectively lifting and lowering a wire interconnector provided in an area between neighboring solar cells.
The solar cell electrostatic chuck according to claim 1, further comprising a lifting pin driving means for controlling lifting and lowering of the lifting pin on one side of the cell stage.
The solar cell module according to claim 1, wherein when the elevator pin lifts up the wire interconnector provided in the area between neighboring solar cells in the tableting process, the outermost electrode of the wire interconnector and the solar cell do not contact each other Solar cell freezing device.

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