KR20130101733A - A solar cell and a manufacturing method there of - Google Patents

Abstract

The present invention relates to a solar cell and a method for manufacturing the same, and more particularly, to an invention that can improve the production efficiency of a solar cell by making the manufacturing process simpler.
The present invention for achieving this object, a plurality of unit cells spaced apart from each other;
A first electrode member comprising a first film provided with a first wiring module attached to one surface of the cell; And a second electrode member including a second film provided with a second wiring module attached to the other surface of the cell, wherein the first electrode member and the second electrode member are arranged to be energized between the plurality of unit cells. It provides a solar cell comprising a connection wiring.

Description

Solar cell and a manufacturing method there of}

The present invention relates to a solar cell and a method for manufacturing the same, and more particularly, to an invention that can improve the production efficiency of a solar cell by making the manufacturing process simpler.

Solar cells are devices that convert light energy into electrical energy using the properties of semiconductors.

The structure and principle of a solar cell will be briefly described. A solar cell has a PN junction structure in which a P (positive) semiconductor and an N (negative) semiconductor are bonded. When solar light enters the solar cell having such a structure, Holes and electrons are generated in the semiconductor due to the energy of incident sunlight.

At this time, the holes (+) move to the P-type semiconductor due to the electric field generated at the PN junction, and the electrons (-) move to the N-type semiconductor, whereby the potential is generated to generate electric power .

Such a solar cell can be classified into a substrate type solar cell and a thin film solar cell. The substrate type solar cell uses a semiconductor material itself such as silicon as a substrate to manufacture a solar cell.

On the other hand, the thin film solar cell is a solar cell in which a semiconductor is formed in the form of a thin film on a substrate such as glass.

Although the substrate-type solar cell has a somewhat higher efficiency than the thin-film solar cell, it has a limitation in minimizing the thickness of the process, and has a disadvantage in that manufacturing cost is increased because an expensive semiconductor substrate is used.

The construction and manufacturing method of a conventional substrate type solar cell are disclosed in FIGS. 14 and 15.

As shown in FIG. 14, a plurality of unit cells 20 constituted from wafers are arranged to be spaced apart from each other, and one side of a specific unit cell 20a and the other surface of the unit cell 20b adjacent to each other are formed on the electrode ribbon 25. As shown in FIG. To connect.

Specifically, in FIG. 14, the front ends of the electrode ribbons 25 are horizontal and the rear ends are vertically disposed.

In this state, the lower surface of each unit cell 20 is brought into contact with the front end of the electrode ribbon 25.

Thereafter, the rear end of the vertically arranged electrode ribbon 25 is lowered to be in contact with the top surface of each unit cell 25 so that each unit cell 20 is electrically connected to an adjacent unit cell 20.

When the unit cells 20 and the electrode ribbon 25 are continuously connected, the unit cells 20 are connected in series.

In this state, hot air is supplied from the upper part of the unit cell 20, and the lower part of the unit cell 20 is in contact with the hot plate 27.

As a result, each electrode ribbon 25 is joined to and connected to one surface and the other surface of each unit cell 20.

In this state, as shown in FIG. 15, the protective sheet 30 is disposed on one surface and the other surface of each unit cell 20 connected by the electrode ribbon 25, respectively.

The protective sheet 30 is disposed on the surface of the unit cell 20 to serve to protect the surface of the unit cell 20 and to prevent penetration of external moisture. The protective sheet 30 may be usually composed of an EVA sheet.

Then, the first substrate 31 and the second substrate 32 are disposed and sealed on one surface and the other surface of each protective sheet 30 to complete the manufacture of the solar cell.

Here, the first and second substrates 31 and 32 may be all made of a transparent material, or one of them may be made of an opaque material.

Under such a structure, when sunlight is irradiated, sunlight passes through the first substrate 31 or the second substrate 32 and the protective sheet 30 to reach the unit cell 20, and unit cells. In 20, power generation is performed by photoelectric conversion.

However, as shown in FIG. 15, damage to the unit cell caused by heat of high temperature (250 to 300 ° C.) during the hot air supply and the joining operation by the hot plate 27 in the state in which the metal ribbon 25 is connected. This may occur, and the degradation of efficiency in photoelectric conversion may occur due to the presence of such damaged unit cells.

In addition, since the number of processes and time required for arranging the ribbon 25 and each unit cell, bonding by high temperature heat and high temperature plate, and the like, there is a problem that the production efficiency of the solar cell is reduced.

Disclosure of Invention The present invention has been made to solve such a problem, and an object thereof is to provide a solar cell and a method of manufacturing the same, which can prevent damage to a unit cell, increase photoelectric efficiency of a solar cell, and improve production efficiency.

The present invention for achieving this object is a plurality of unit cells spaced apart from each other; A first electrode member comprising a first film provided with a first wiring module attached to one surface of the cell; And a second electrode member including a second film provided with a second wiring module attached to the other surface of the cell, wherein the first electrode member and the second electrode member are arranged to be energized between the plurality of unit cells. Characterized in that it comprises a connection wiring.

The first electrode member may be a PCB substrate having the first wiring module exposed on one surface of the cell, and the second electrode member may be a PCB substrate having the second wiring module exposed on the other surface of the cell.

The first wiring module may include a first electrode wiring contacting one surface of the cell and a first connection wiring connected to the first electrode wiring; The second wiring module may include a second electrode wiring contacting the other surface of the cell and a second connection wiring connected to the second electrode wiring to be energized with the first connection wiring.

When the first wiring module is attached to one surface of the first unit cell,

The second wiring module to be connected to the first wiring module is attached to the other surface of the second unit cell adjacent to the first unit cell.

The first electrode wiring and the second electrode wiring are disposed in parallel, and the first connection wiring and the second connection wiring are disposed perpendicular to the first and second electrode wiring to be in contact with each other to conduct electricity. It is done.

The first electrode wiring or the second electrode wiring may be provided in plural and spaced apart from each other on the first film or the second film.

The arrangement direction of the first electrode wiring or the second electrode wiring may be different from the arrangement direction of the first connection wiring or the second connection wiring.

The first and second connection wirings may be arranged to protrude more than the first and second electrode wirings.

The first and second connection wirings may be disposed in an empty space between the unit cell and the unit cell.

The second wiring module may be disposed on the second film in an inverted form of the first wiring module.

At least one of the first film and the second film is provided with a transparent film, wherein the first wiring module and the second wiring module are deposited on the first film and the second film. do.

The first and second connection wirings may be formed on an outer surface thereof, and further include a plating layer formed of a material different from a material constituting the first and second connection wirings.

The first wiring module or the second wiring module is provided in plural, characterized in that arranged on the first film or the second film in a plurality of rows or columns in the horizontal direction or the vertical direction.

And a first bus bar connected to the first connection wires located at the outermost part of the first film or connecting the first connection wires.

A connection bus bar connected to the first bus bar; The connection bus bar is deposited, characterized in that it comprises an insulating film disposed on the first film.

And a second bus bar that connects second connection wires positioned at the outermost portion of the second film.

The first bus bar and the second bus bar is characterized in that disposed in the opposite direction to each other.

And a first bus bar connected to the first connection wires located at the outermost part of the first film or connecting the first connection wires, and a second bus bar connecting the second connection wires to the outermost part of the second film. But

The plurality of unit cells are arranged in a plurality of columns or a plurality of row states,

The plurality of unit cells may be connected in series by the first and second wiring modules and the first and second bus bars.

In addition, the present invention comprises the steps of contacting the first wiring module and the unit cell by attaching a first electrode member including a first film provided with a first wiring module on one surface of a plurality of unit cells spaced apart from each other;

A second electrode member including a second film having a second wiring module provided on the other surface of the plurality of unit cells is attached to contact the second wiring module and the unit cell. It provides a method of manufacturing a solar cell comprising the step of contacting with a portion of the first wiring module.

The first electrode member is a PCB substrate having a first wiring module exposed on one surface of the cell, the second electrode member is composed of a PCB substrate having a second wiring module exposed on the other surface of the cell,

The step of contacting a part of the second wiring module with a part of the first wiring module may include contacting each other so that the first connection wiring and the second connection wiring are energized.

The first wiring module includes a plurality of first electrode wirings contacting one surface of the unit cell and a first connection wiring connected to the first electrode wirings.

The second wiring module includes a plurality of second electrode wirings contacting the other surface of the unit cell and a second connection wiring connected to the second electrode wiring.

The step of contacting a part of the second wiring module with a part of the first wiring module may include contacting each other so that the first connection wiring and the second connection wiring are energized.

When the first wiring module is attached to one surface of the first unit cell of the plurality of unit cells,

The second wiring module to be connected to the first wiring module is attached to the other surface of the second unit cell adjacent to the first unit cell.

The first connection wiring and the second connection wiring are characterized in that the contact is provided to be energized.

And a lamination process step performed to increase adhesion of the first and second films to the unit cells while the first and second films are attached to one surface and the other surface of the unit cell.

According to the present invention, the operation of connecting the unit cells using a separate wire of the solar cell is omitted, and the manufacturing of the solar cell can be made more quickly by attaching the films on which the electrode patterns are formed to the unit cell.

In addition, since the manufacturing process is performed in a lower temperature atmosphere than before, damage to the unit cell is less likely to occur.

If the damage rate or frequency of the unit cell is reduced, the power generation efficiency by photoelectric conversion may be higher than before.

1 is a side cross-sectional view of a solar cell according to the present invention.
2 and 3 are plan views of the first film and the first wiring module.
4 shows an arrangement of unit cells.
5 is a cross-sectional view of a unit cell.
6 is a plan view of a second film and a second wiring module.
7 is an exploded perspective view of a first film, unit cells, and a second film.
8 to 11 is a manufacturing process of the solar cell according to the present invention.
12 is a side view showing an operating state of the solar cell according to the present invention.
13 is a plan view showing an operating state of the solar cell according to the present invention.
14 is a side sectional view showing a manufacturing process of a conventional solar cell.
15 is a side cross-sectional view of a conventional solar cell.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 1, in the solar cell 100 according to the present invention, a first substrate 110 and a second substrate 120 spaced apart from the first substrate 110 form an external appearance thereof.

Both the first and second substrates 110 and 120 may be made of a transparent plastic or glass substrate, and either one may be made of an opaque or translucent substrate.

The first and second substrates 110 and 120 may be formed of rigid substrates or flexible substrates.

Between the first substrate 110 and the second substrate 120, a plurality of unit cells 200 consisting of a wafer and disposed on one surface and the bottom surface of the unit cell 200 in series with each unit cell 200 First and second wirings 310 and 320 are connected to each other.

The first wiring module 310 is connected to the first electrode wiring 311 contacting one surface of the unit cells 200 and the first electrode wiring 311 and is disposed next to the unit cell 200. The first connection wiring 312 is included.

The second wiring module 320 contacts the other surfaces of the unit cells 200 and is connected to the second electrode wiring 321 and the second electrode wiring 321 and disposed next to the unit cell 200. The second connection wiring 322 is included.

The first and second connection wires 312 and 322 are disposed in a space between the unit cell 200 and the unit cell 200, and are provided to be in contact with each other or to be energized.

When the first and second connection wires 312 and 322 are in contact with each other, the height is preferably equal to or slightly higher than that of the unit cell 200.

The first and second wiring modules 310 and 320 are preferably made of a material having excellent conductivity, and may be made of aluminum or copper.

On the other hand, as in A, a separate plating layer 330 may be provided on the surfaces of the first and second connection wirings 312 and 322, which may be more smoothly energized, and the first and second connection wirings ( 312, 322 is provided in order to maintain a more stable contact state.

The plating layer 330 is preferably composed of a tin plating layer, but is not limited thereto.

However, as shown in B, the first and second connection wires 312 and 322 may overlap each other without contact with the plating layer 330.

On the other hand, the first wiring module 310 is provided in a pattern form on the first film 351, the second wiring module 320 is provided in a pattern form on the second film (352).

The first and second wiring modules 310 and 320 are provided in the form of being deposited on the first and second films 351 and 352, respectively, and the deposition process is to deposit a metal material such as plating or sputtering or PVD or PCB printed circuit process. It is made by the process.

The first and second films 351 and 352 may be made of a transparent film made of a polymer-based material having a transmittance of 92% or more, and may be in contact with the unit cell 200. It is preferred that an adhesive component is applied for adhesion.

As will be described later, the first and second wiring modules 310 and 320 provided in the first and second films 351 and 352 are attached to one surface and the other surface of the unit cell 200 and then laminated through the laminating operation. The unit cell 200 is fixedly arranged.

In addition, the first wiring module 310 and the second wiring module 320 are disposed with the unit cell 200 interposed therebetween, the arrangement state of the first wiring module 310 and the second wiring module. The arrangement of 320 is reversed.

The first wiring module 310 is provided on one surface (upper surface) of the specific unit cell 200, and the second wiring module 320 is provided on the other surface (lower surface) of the specific unit cell 200. In the left space of the specific unit cell 200, the second connection wiring 322 of the second wiring module 320 protrudes upward.

In addition, the first connection wiring 312 of the first wiring module 310 is provided to protrude downward in the right space of the specific unit cell 200.

When this state continues in the left and right directions, the first connection wiring 312 of the first wiring module 310 connected to the specific unit cell 200 is connected to the neighboring unit cell 200 of the specific unit cell 200. Contact with the second connection wiring 322 of the second wiring module 320 to be energized.

Through this, serial connection between the plurality of unit cells 200 is possible.

Meanwhile, a first protective sheet 410 is provided between the first film 351 and the first substrate 110, and a second protection is provided between the second film 352 and the second substrate 120. The sheet 420 is provided.

The first and second protective sheets 410 and 420 serve as a sealing member to prevent moisture, etc. from penetrating the outside of the solar cell, and is preferably made of a transparent material to increase light transmittance.

Examples thereof include polyethylene, polypropylene, ethylene / vinyl chloride copolymer, ethylene / vinyl acetate copolymer, ethylene / vinyl alcohol copolymer, chlorinated polyethylene, chlorinated polypropylene, and the like.

The first and second protective sheets 410 and 420 are fused between the first substrate 110 and the first film 351 and between the second substrate 120 and the second film 420 through a laminating process. Can be fixed.

Alternatively, the first and second protective sheets 410 and 420 may be coated on both sides with a double-sided tape, such that the first and second protective sheets 410 and 420 may be interposed between the first substrate 110 and the first film 351 and the second substrate. It may be attached and fixed between the 120 and the second film 420.

In FIG. 1, the first wiring module 310 and the first film 351 may constitute a first electrode member 301, and the second wiring module 320 and the second film 352 may be formed. The second electrode member 302 may be configured.

The first and second electrode members 301 and 302 may be formed of a PCB or an FPCB. Therefore, each unit cell 200 of the present invention can be connected in series using a circuit board on which electrode wirings and connection wirings are formed.

The first electrode member 301 may be a PCB substrate having the first wiring module 310 exposed on one surface of the unit cell 200, and the second electrode member 302 may be formed on the other surface of the unit cell. It may be a PCB substrate on which the second wiring module 320 is exposed.

2 and 3 illustrate a first film 351 and the first wiring module 310.

As shown in FIG. 2, the first wiring module 310 is provided in plural in the left and right directions and the vertical direction on the first film 351 and spaced apart from each other in the left and right directions and the vertical direction.

The first electrode wiring 311 is disposed in an up and down direction in this drawing, and the first connection wiring 312 is disposed in a left and right direction in this drawing. However, the first electrode wiring 311 is not limited thereto. ) And the direction in which the first connection wires 312 are arranged may be perpendicular to each other or may be arranged in different directions.

Here, the position of the first electrode wiring 311 corresponds to a position where the unit cell 200 is to be disposed, and the first connection wiring 312 corresponds to a position where the unit cell 200 is not disposed. .

In one first wiring module 310, the plurality of first electrode wirings 311 are provided to be spaced apart from each other, and the plurality of first electrode wirings 311 may be connected to one first connection wiring 312. Do.

Meanwhile, first bus bars 371 are provided on the first film 351 to be connected to the first connection wires 312 disposed at the outermost side (the uppermost part of the drawing) of the first connection wires 312. do.

The first bus bars 371 collect a charge formed through photoelectric conversion to guide the outside.

Some of the first bus bars 371 are connected to first connection wires 312 provided at the leftmost and rightmost sides.

In addition, some of the first bus bars 371 connect the first connection wires 312 between the first connection wires 312 provided at the leftmost and rightmost sides.

Here, a bus bar connected to the first connection wires 312 provided at the leftmost and rightmost sides is defined as an external bus bar 371a, and is disposed between the first connection wires 312 provided at the leftmost and rightmost. The bus bar connecting the first connection wires 312 are defined as an internal bus bar 371b.

The external bus bar 371a is connected to one first connection wire 312.

The internal bus bar 371b is connected to two adjacent first connection wires 312.

On the other hand, the external bus bar 371a is connected to the first connection bus bar 381, respectively, and the internal bus bar 371b is connected to the second connection bus bar 382, respectively.

The first connection bus bar 381 is disposed in a direction orthogonal to an end of the outer bus bar 371a, and the second connection bus bar 381 is also orthogonal to an end of the inner bus bar 371b. Is placed.

The first connection bus bar 381 is connected to the external bus bar 371a in a state of being deposited on the first insulating film 391, and the second connection bus bar 382 is connected to the second insulating film 392. It is connected to the internal bus bar 371b in a deposited state.

The first and second insulating films 391 and 392 are disposed on the first film 351, so that the other first wiring module 310 and the unit cell 200 and the first and second connection bus bars 381 and 382 are disposed on the first film 351. ) Is prevented from energizing.

The first connection bus bar 381 and the second connection bus bar 382 may be connected to a junction box having a current collecting function.

Figure 4 shows the unit cells of the solar cell according to the present invention.

The unit cells 200 are provided in plural and are spaced apart from each other.

4 illustrates an arrangement of unit cells 200 in a matrix state of 6 × 10.

An interval between the unit cells 200 is preferably about 2 to 5 mm, and the first connection electrode 312 and the second connection electrode 322 are disposed in the space formed by the gap.

As can be seen in FIG. 5, the unit cell 200 of the present invention includes a photoelectric conversion part 240 formed of a semiconductor wafer having a PN structure, a front antireflection layer 250 formed on an upper surface of the photoelectric conversion part 240, and It includes a back reflection prevention layer 270 formed on the lower surface of the photoelectric conversion unit 240.

On the other hand, a first electrode wiring 311 that can function as a front electrode is disposed on the top surface of the front antireflection layer 250, and a second electrode that can function as a back electrode on the bottom surface of the back antireflection layer 270. The wiring 312 is provided.

Here, the function of the front electrode and the function of the back electrode may be interchanged.

The photoelectric conversion unit 240 is formed on the lower surface of the P-type polysilicon layer 241, the N-type polysilicon layer 243 formed on the upper surface of the P-type polysilicon layer 241, and the P-type polysilicon layer 241. The P + polysilicon layer 245 is formed.

The photoelectric conversion unit 240 forms the N-type polysilicon layer 243 by doping the N-type dopant on the upper surface of the P-type polysilicon wafer 241 by using a high temperature diffusion method or a plasma ion doping method. The P-type dopant may be doped on the bottom surface of the polysilicon wafer 241 using a high temperature diffusion method or a plasma ion doping method to form a high concentration P + type polysilicon layer 245.

The high temperature diffusion method is a step of diffusing a dopant at a high temperature, and the process of forming the N-type polycrystalline silicon layer 243 on the upper surface of the P-type polycrystalline silicon wafer 241 using the high temperature diffusion method will be described. The N-type dopant is supplied to the surface of the P-type polysilicon wafer 241 by supplying an N-type dopant gas such as POCl ₃ or PH ₃ while the type-type polysilicon wafer 141 is placed in a diffusion furnace having a temperature of about 800 ° C. or higher. To spread.

Meanwhile, when the high temperature diffusion process is performed, N-type polysilicon is formed on the entire top, side, and bottom surfaces of the P-type polysilicon wafer 241. When such a structure is used, leakage current is generated in the solar cell. Cause problems.

Therefore, in order to prevent the occurrence of leakage current, the N-type polysilicon formed on the side and bottom of the P-type polysilicon wafer 241 is removed by using a wet or dry etching process to remove the P-type polysilicon wafer 241. The N-type polysilicon layer 243 is formed only on the upper surface.

The plasma ion doping method is a process of doping the dopant by plasma ionization.

The process of forming the N-type polysilicon layer 243 on the upper surface of the P-type polysilicon wafer 241 using the plasma ion doping method will first be described. First, the P-type polysilicon wafer 241 is plasma-generated. The N-type dopant gas such as POCl ₃ , PH _3, etc. is supplied while placed in the apparatus.

When the plasma is generated, phosphorus (P) ions in the plasma are accelerated by the RF electric field and incident on the upper surface of the P-type polysilicon wafer 241 to be ion-doped.

Meanwhile, after the plasma ion doping process, an annealing process for heating the P-type polysilicon wafer 241 to an appropriate temperature is preferably performed.

The reason is that when the annealing process is not performed, the doped ions may act as simple impurities, but when the annealing process is performed, the doped ions are combined with Si to be activated.

The N-type polysilicon layer 243 preferably has a concave-convex structure on the surface thereof, because when the concave-convex structure is formed, the absorption area of the solar light is increased, and thus the efficiency of the solar cell can be improved.

The P + type polysilicon layer 245 is not required to be formed, but it is preferable to form the P + type polysilicon layer 245 on the lower surface of the P type polysilicon layer 241, and the reason is the P + type. This is because when the polysilicon layer 245 is formed, electrons formed by sunlight are prevented from recombining and disappearing from the back of the solar cell, thereby improving efficiency of the solar cell.

Although not shown, the photoelectric conversion unit 240 may include an N-type polycrystalline silicon layer, a P-type polysilicon layer formed on an upper surface of the N-type polycrystalline silicon layer, and an N + -type polycrystalline silicon layer formed on a lower surface of the N-type polycrystalline silicon layer. It may be made of.

The photoelectric conversion unit 240 forms a P-type polysilicon layer by doping the P-type dopant on the upper surface of the N-type polycrystalline silicon wafer by using a high temperature diffusion method or a plasma ion doping method, and on the lower surface of the N-type polysilicon wafer. The N-type dopant may be formed through a process of forming a high concentration N + -type polycrystalline silicon layer.

The P-type polysilicon layer formed on the upper surface of the N-type polysilicon wafer is preferably formed of a concave-convex structure so as to widen the absorption area of sunlight.

The front antireflection layer 250 serves to prevent the incident light incident from the upper portion of the photoelectric conversion unit 240 from being reflected to the outside, and the back antireflection layer 270 is the semiconductor wafer 240 having the PN structure. As a role of preventing the reflected light incident from the bottom of the reflection to the outside, the front antireflection layer 250 and the back reflection prevention layer 270 may be omitted, but it is preferable to add to increase the efficiency of the solar cell. Do.

The front antireflection layer 250 and the back antireflection layer 270 may be formed of a material such as ZnO or SiN by sputtering or metal organic chemical vapor deposition (MOCVD).

On the other hand, as described above, the first electrode wiring 311 constituting the front electrode and the second electrode wiring 321 constituting the back electrode may be composed of Al, Cu.

Alternatively, the first electrode wiring 311 constituting the front electrode and the second electrode wiring 321 constituting the rear electrode are Ag, Al, Ag + Al, Ag + Mg, Ag + Mn, Ag + Sb, It may be formed using a metal such as Ag + Zn, Ag + Mo, Ag + Ni, Ag + Cu, Ag + Al + Zn.

It is preferable that the front electrode and the back electrode have a pattern formed such that their cross-sectional area is small because the transmittance of incident light and reflected light into the solar cell can be increased.

FIG. 6 illustrates a second wiring module 320 included in the second film 352.

The second wiring module 320 is provided in plural in the left and right direction and the vertical direction on the second film 352 and spaced apart from each other in the left and right direction and the vertical direction.

The second electrode wiring 321 is disposed in the up and down direction in this drawing, and the second connection wiring 322 is disposed in the left and right direction in this drawing, but is not limited thereto, but the second electrode wiring 321 is not limited thereto. ) And the direction in which the second connection wiring 322 is disposed are orthogonal to each other or arranged in different directions.

Here, the position of the second electrode wiring 321 corresponds to the position where the unit cell 200 is to be arranged, and the second connection wiring 322 corresponds to the position where the unit cell 200 is not arranged. .

In one second wiring module 320, a plurality of second electrode wirings 321 may be provided to be spaced apart from each other, and the plurality of second electrode wirings 321 may be connected to one second connection wiring 322. Do.

The second wiring module 320 is preferably provided in a reverse phase with the arrangement state of the first wiring module 310 shown in FIGS. 2 and 3.

That is, in the first wiring module 310 shown in FIGS. 2 and 3, the first connection wiring 312 is disposed on the upper portion, and the first electrode wiring 311 is connected to the first connection wiring 312. In the connected state, when the lower portion of the first connection line 312 is located, the second connection line 322 of the second wiring module 320 is preferably positioned above the second electrode line 321. Do.

In particular, the position of the first connection line 312 and the position of the second connection line 322 is preferably disposed in a position corresponding to each other, that is, the same position that can be in contact with each other.

Second bus bars 372 are provided on the second film 352 to connect the second connection wires 322 disposed at the outermost part of the second connection wires 322.

The second bus bar 372 is provided in plural, and in this drawing, the connection wires 322 located at the bottom of the connection wires 322 in the first to sixth columns are connected to each other.

Here, the connection wires 322 of the first and second rows are connected, the connection wires 322 of the third and fourth columns are connected, and the connection wires 322 of the fifth and sixth columns are connected, respectively.

The reason for connecting the connection wirings 322 in the neighboring columns as described above is to connect the unit cells 200 arranged in six columns in series.

The second bus bar 372 is preferably made of the same material as the second wiring module 320, and is preferably formed on the second film 352 as the second wiring module 320. Do.

That is, the second wiring module 320 and the second bus bar 382 may be patterned on the second film 352 by plating or sputtering or PVD method.

FIG. 7 illustrates a first film 351 on which the first wiring module 310 is formed, a unit cell 200, and a second film 352 on which the second wiring module 320 is formed. The situation before it was shown.

Here, the plurality of unit cells 200 are disposed to be spaced apart from each other.

The first film 351 is positioned on one surface (or top surface) of the unit cell 200, and the first wiring module 310 is provided on the bottom surface of the first film 351 to provide the unit cell 200. It is provided to be in contact with one surface (or upper surface) of the.

Here, the first electrode wirings 311 of the first wiring module 310 are disposed to contact one surface (or top surface) of the unit cell 200.

On the other hand, the first connection wirings 312 of the first wiring module 310 do not contact the unit cell 200, and the space between the unit cell 200 and the unit cell 200 or the unit cell ( It may be disposed in the space next to 200).

This is for contact with the second connection wiring 322 as described above.

 The first bus bar 371 is disposed at the front side of the first film 351 in this drawing, and is connected to the first connection wires 312 disposed at the foremost of the first connection wires 312. .

The first bus bar 371 is again connected to the connection bus bars 381 and 382 provided on the insulating sheets 391 and 392, and the connection bus bars 381 and 382 are connected to a separate junction box (not shown). Can be connected.

The second film 352 is positioned on the other surface (or lower surface) of the unit cell 200, and the second wiring module 320 is provided on the lower surface of the first film 352 of the unit cell 200. It is provided to be in contact with the other surface (or lower surface).

Here, the second electrode wirings 321 of the second wiring module 320 are disposed to contact the other surface (or the bottom surface) of the unit cell 200.

On the other hand, the second connection wirings 322 of the second wiring module 320 do not contact the unit cell 200, and the space between the unit cell 200 and the unit cell 200 or the unit cell ( It may be disposed in the space next to 200).

This is for contact with the first connection wiring 312 as described above.

 The second bus bar 372 is disposed at the rear side of the second film 352 in this drawing, and is connected to the second connection wires 322 disposed at the rearmost of the second connection wires 322. do.

That is, the positions of the first bus bar 371 and the second bus bar 372 are arranged oppositely.

In this figure, the first connection electrode 312 denoted by ① is located in the front space of the unit cell 200 denoted by ④.

The first connection electrode 312 denoted by ②, that is, the first connection electrode behind the first connection electrode 312 denoted by ① is located in the rear space of the unit cell 200 denoted by ④.

In addition, the second connection electrode 322 denoted by ③ is positioned in the rear space of the unit cell 200 denoted by ④, and is provided to be energized in contact with the first connection electrode 312 denoted by ②.

As the connection is continuously made, the unit cells 200 can be connected in series by the first and second wiring modules 310 and 320.

Hereinafter, the process of manufacturing the solar cell of the present invention will be described.

First, as shown in FIG. 8, the second wiring module 320 is patterned to prepare a deposited second film 352.

 As described above, the second film 352 provided with the second wiring module 320 may be prepared by depositing a conductive metal material (Ag or Cu) on a transparent film according to a predetermined pattern.

The second wiring module 320 is provided on an upper surface of the second film 352, and each second wiring module 320 is provided to be spaced apart from each other.

The second electrode wiring 321 is formed in a shape having a predetermined length on the upper surface of the second film 352, the second connection electrode 322 is higher than the second electrode wiring 321, that is, It is provided to protrude in a direction facing the unit cell 200.

In this state, as shown in FIG. 9, the unit cell 200 is placed on an upper surface of each second electrode wiring 321.

As a result, the lower surface of the unit cell 200 and the upper surface of the second electrode wiring 321 may contact each other. The second connection electrode 322 is disposed between the unit cell 200 and the unit cell 200.

In this case, the connection electrode 322 and the unit cell 200 may be spaced apart from each other so as not to contact each other.

As shown in FIG. 10, the first film 351 on which the first wiring module 310 is deposited is disposed on an upper surface of the unit cell 200.

In this case, the first electrode wiring 311 is disposed on the upper surface of the unit cell 200, and the first connection wiring 312 is disposed in the front and rear spaces of the unit cell 200.

Here, the first connection wiring 312 is preferably not contacted with the unit cell 200 spaced apart. The first connection wire 312 may be in contact with the second connection wire 322 so as to be energized.

At this time, the second connection wiring 322 of the second wiring module 320 placed below the specific unit cell 200 (denoted C2) may be connected to the unit cell (denoted C1) adjacent to the specific unit cell 200. It is provided to be in contact with the first connection wiring 312 of the first connection wiring 312 of the first wiring module 310 placed on the upper.

Alternatively, the first connection wiring 312 of the first wiring module 310 placed on the upper portion of the specific unit cell 200 (indicated by C2) is the lower portion of the unit cell (indicated by C3) adjacent to the specific unit cell 200. It is provided to be in contact with the second connection wiring 322 of the first connection wiring 322 of the second wiring module 320 placed on the.

As such, when the connection between the first and second wiring modules 310 and 320 is made along each unit cell, a series connection between the unit cells 200 may be implemented.

In addition, since the columns of the unit cells placed in parallel with each other by the first and second bus bars 371 and 372 may also be connected in series, a desired voltage may be obtained during power generation by photoelectric conversion.

Meanwhile, as described above, a plating layer may be provided on the first and second connection wires 312 and 322 so as to improve the conduction state between the first and second connection wires 312 and 322. .

Alternatively, an uneven portion or an inclined portion may be provided in the first and second connection wires 312 and 322 so that the contact state of the first and second connection wires 312 and 322 may be more stably maintained and the contact may be easier.

As shown in FIG. 10, the unit cell 200 and the first and second films 351 and 352 are attached to each other to connect the unit cell 200 to the first and second wiring modules 310 and 320. And, when the series connection between each unit cell 200 is completed, through the lamination (lamination) so that the attachment state of the unit cell 200 and the first and second films (351, 352) can be strengthened.

The lamination operation is performed at a temperature of approximately 150 ° C., which is lower than the temperature at the time of hot air supply and hot plate contact (approximately 200 to 250 ° C.) performed in the conventional wire connection operation.

When the lamination is completed, as shown in FIG. 11, the first protective sheet 410 and the first substrate 110 are disposed on the first film 351, respectively, and the second film 352 is disposed. Fabrication of the solar cell can be completed by disposing the second protective sheet 420 and the second substrate 120 at the bottom of the substrate.

Hereinafter, an operation of the present invention will be described with reference to the accompanying drawings.

When sunlight (hv) is irradiated to the solar cell 100, sunlight is incident on each of the unit cells 200, the power generation action occurs by the photoelectric conversion principle in the unit cell (200).

Since each unit cell 200 is connected in series by the first wiring module 310 and the second wiring module 320, the electric charges generated by the power generation action are represented by C1, C2, and C3, respectively. ) Along the first and second wiring modules 310 and 320 connected to the unit cells 200.

In particular, since the first connection wire 312 and the second connection wire 322 are in contact with each other and the connection by the contact is continuous, the series connection is possible.

FIG. 13 is a plan view of the first and second films 351 and 352 and the unit cells 200 overlapping each other.

In FIG. 13, a first bus bar 371 is provided at an upper portion thereof, a second bus bar 372 is provided at a lower portion thereof, and the first bus bar 371 is connected to a first connection wiring 312 at an uppermost end thereof. The second bus bar 372 is connected to the second connection wiring 322 at the bottom.

The first and second connection wires 312 and 322 between the uppermost first connection wire 312 and the lowermost second connection wire 322 are overlapped and contacted with each other.

As described above, the internal bus bar 371b of the first bus bar 371 connects the first connection wiring 312 at the uppermost end of the first connection wiring 312 placed in the second row and the third row.

In addition, another internal bus bar 371b connects the first connection wiring 312 at the uppermost end of the first connection wiring 312 placed in the fourth row and the fifth row.

By such a configuration, the plurality of unit cells 200 placed in the first to sixth columns may be connected in series, and the electricity produced by the photoelectric conversion effect may move in the direction of the arrow shown in FIG. The electricity may be collected in a junction box (not shown) connected to each of the connection bus bars 381 and 382 and connected to the connection bus bars 381 and 382.

In the drawings, the direction indicating words such as upward, backward, front, rear, front, rear, etc. are described to more clearly describe the relative positions between the respective components, and thus, the present invention is not limited to such directions.

110: first substrate 120: second substrate
200: unit cell 310: first wiring module
311: first electrode wiring 312: first connection wiring
320: second wiring module 321: second electrode wiring
322: second connection wiring 330: plating layer
351: first film 352: second film

Claims (22)

A plurality of unit cells spaced apart from each other;
A first electrode member comprising a first film provided with a first wiring module attached to one surface of the cell;
A second electrode member including a second film provided with a second wiring module attached to the other surface of the cell,
And a connection wiring disposed such that the first electrode member and the second electrode member are energized between the plurality of unit cells. The method of claim 1, wherein
The first electrode member is a PCB substrate having a first wiring module exposed on one surface of the cell, the second electrode member is a PCB substrate having a second wiring module exposed on the other surface of the cell. battery. The method of claim 1, wherein
The first wiring module may include a first electrode wiring contacting one surface of the cell and a first connection wiring connected to the first electrode wiring;
The second wiring module includes a second electrode wiring in contact with the other surface of the cell, and a second connection wiring disposed to be connected to the second electrode wiring so as to conduct electricity with the first connection wiring. The method of claim 1,
When the first wiring module is attached to one surface of the first unit cell,
The second wiring module to be connected to the first wiring module is attached to the other surface of the second unit cell adjacent to the first unit cell.
The first electrode wiring and the second electrode wiring are disposed in parallel, and the first connection wiring and the second connection wiring are disposed perpendicular to the first and second electrode wiring to be in contact with each other to conduct electricity. Solar cell. The method of claim 3, wherein
The first electrode wiring or the second electrode wiring is provided with a plurality of solar cells, characterized in that provided on the first film or the second film spaced apart from each other. The method of claim 3, wherein
The arrangement direction of the first electrode wiring or the second electrode wiring is a solar cell, characterized in that formed differently from the arrangement direction of the first connection wiring or the second connection wiring. The method of claim 3, wherein
The first and second connection wirings are arranged to protrude more than the first and second electrode wirings. The method of claim 3,
The first and second connection wirings are disposed in the empty space between the unit cell and the unit cell. The method of claim 1,
The second wiring module is a solar cell, characterized in that disposed on the second film in the form of a reversed phase of the first wiring module. The method of claim 1,
At least one of the first film and the second film is provided as a transparent film,
And the first wiring module and the second wiring module are deposited on the first film and the second film. The method of claim 3, wherein
The first and second connection wirings are formed on the outer surface thereof,
The solar cell of claim 1, further comprising a plating layer composed of a material different from the material constituting the first and second connection wiring. The method of claim 1,
The first wiring module or the second wiring module is provided in plurality,
A solar cell, characterized in that arranged on the first film or the second film in a plurality of rows or columns in the horizontal direction or the vertical direction. 13. The method of claim 12,
And a first bus bar connected to the first connection wires located at the outermost part of the first film or connecting the first connection wires. The method of claim 13,
A connection bus bar connected to the first bus bar;
The connection bus bar is deposited and the solar cell comprising an insulating film disposed on the first film. The method of claim 13,
And a second bus bar connecting second connection wires positioned at the outermost part of the second film. 16. The method of claim 15,
The first bus bar and the second bus bar is a solar cell, characterized in that disposed in the opposite direction to each other. The method of claim 3, wherein
And a first bus bar connected to the first connection wires located at the outermost part of the first film or connecting the first connection wires, and a second bus bar connecting the second connection wires to the outermost part of the second film. But
The plurality of unit cells are arranged in a plurality of columns or a plurality of row states,
The plurality of unit cells are connected in series by the first and second wiring modules and the first and second bus bars. Contacting the first wiring module and the unit cell by attaching a first electrode member including a first film provided with a first wiring module on one surface of a plurality of unit cells spaced apart from each other;
A second electrode member including a second film having a second wiring module provided on the other surface of the plurality of unit cells is attached to contact the second wiring module and the unit cell. Method for manufacturing a solar cell comprising the step of contacting with a portion of the first wiring module. 19. The method of claim 18,
The first electrode member is a PCB substrate having a first wiring module exposed on one surface of the cell, the second electrode member is composed of a PCB substrate having a second wiring module exposed on the other surface of the cell,
Contacting a portion of the second wiring module with a portion of the first wiring module includes contacting the first connection wiring and the second connection wiring so as to be energized. Manufacturing method. 19. The method of claim 18,
The first wiring module includes a plurality of first electrode wirings contacting one surface of the unit cell and a first connection wiring connected to the first electrode wirings.
The second wiring module includes a plurality of second electrode wirings contacting the other surface of the unit cell and a second connection wiring connected to the second electrode wiring.
Contacting a portion of the second wiring module with a portion of the first wiring module includes contacting the first connection wiring and the second connection wiring so as to be energized. Manufacturing method. The method of claim 20,
When the first wiring module is attached to one surface of the first unit cell of the plurality of unit cells,
The second wiring module to be connected to the first wiring module is attached to the other surface of the second unit cell adjacent to the first unit cell.
The first connecting wiring and the second connecting wiring is a manufacturing method of a solar cell, characterized in that provided in contact with each other. 19. The method of claim 18,
The solar cell further comprises a lamination process step performed to increase the adhesion of the first and second film to the unit cell in a state in which the first and second films are attached to one surface and the other surface of the unit cell. Manufacturing method.

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