KR20120083153A - Method and apparatus for assembling solar cell module - Google Patents

Abstract

PURPOSE: A method and apparatus for assembling solar cell modules are provided to increase reliability of a solar cell panel by uniformly gluing a tape by a movement of a ruler to a bus bar, lines and solar cell panel without bubbles. CONSTITUTION: A solar cell panel(110) including a plurality of solar cells(114) serially connected to each other is formed on a transparent substrate. A bus bar is located on the plurality of solar cells. A line(140) is electrically connected to a bus bar from the upper part of a solar cell panel. A junction box(150) accommodates diodes and a plurality of elements to transmit an output power of a solar cell to outside.

Description

Wiring method and wiring device for solar cell module {Method and Apparatus for assembling Solar cell module}

The present invention relates to a method and apparatus for assembling a solar cell module for installing a bus bar and wiring in a solar cell panel.

A solar cell panel is a power generation facility that receives direct sunlight to produce direct current power. Since the solar panel is typically installed outdoors to collect sunlight, the solar panel is fixed to the outdoor structure using a frame. The frame should be able to protect the solar panel from various environmental changes and maintain its durability for a long time.

In order to draw output power from the solar panel to the outside, a solar cell is connected to a bus bar and a wiring process of connecting the bus bar to a wiring is performed. The wiring process includes placing the wiring on the bus bar and the bus bar on the solar cell and fixing the bus bar and the wiring with tape. By the way, since the bus bar and the wiring are located on the solar cell and the step is generated, there is a problem that the tape is not uniformly bonded. In other words, bubbles or the like are generated between the tape and the solar cell panel so that the bus bar and the wiring are not stably fixed.

According to the present invention, in order to uniformly adhere the tape for fixing the bus bar and the wiring to the solar cell panel, the tape is placed at the bonding position and the tape is moved to the solar cell panel through the bus bar and the wiring by moving the roller including the elastic part. An object of the present invention is to provide a wiring method and a wiring apparatus of a solar cell module that are uniformly bonded.

In order to achieve the above object, the present invention comprises the steps of preparing a solar panel comprising a plurality of solar cells; Placing a bus bar on the solar panel and a wire for electrically connecting the bus bar to the plurality of solar cells; Positioning a tape to secure the bus bar and the wiring to the solar cell panel; And pressing the tape to adhere the tape to the bus bar and the wiring and the solar cell panel so as to overcome the step caused by the bus bar and the wiring. Provide a method.

The solar cell panel is moved and lowered by a tape transfer unit including two first cylinder parts driving up and down and two head parts connected to each of the two first cylinder parts and including a suction unit. After the tape conveying part is raised and the tape conveying part is raised, the adhesive part including the second cylinder part and the roller part is lowered to the top of the solar cell panel, and the roller part is in contact with the tape and moves the surface of the tape. It provides a wiring method of a solar cell module characterized in that the tape is elastically pressed to adhere the tape to the bus bar, the wiring and the solar cell panel.

In order to achieve the above object, the present invention is a main body; A support part connected to the main body; A tape feeder connected to the support; And an adhesive part which is connected to the support part and adheres to the tape using a roller part, and which is movable.

The tape conveying apparatus includes two first cylinder portions connected to the support portion; And

And two head portions connected to each of the two first cylinder portions, each head portion adsorbing each of the both ends of the tape in a vacuum, wherein the adhesive portion is connected to the support portion and positioned between the two first cylinder portions. A second cylinder portion; And a roller unit connected to the second cylinder unit.

When the tape is located on the solar cell panel, the two head portion is raised by the driving of the two first cylinder portion, the roller portion of the second cylinder portion is characterized in that moving while pressing the tape A wiring device for a battery panel is provided.

The support part is connected to a plurality of the tape transfer device and a plurality of the adhesive portion, and provides a wiring apparatus of a solar cell panel, characterized in that for moving or bonding a plurality of the tape at the same time or sequentially.

According to the present invention, the step is generated in the solar cell panel by loading the bus bar and the wiring, but the tape is placed in the adhesive area by the movement of the roller including the elastic part. By uniformly bonding, it is possible to improve the reliability of the solar cell panel.

1 is an exploded perspective view of a solar cell module according to an embodiment of the present invention
2 is a schematic diagram of a wiring apparatus of a solar cell module according to an embodiment of the present invention;
3A to 3C are schematic diagrams illustrating a method of wiring a solar cell module using a wiring apparatus of a solar cell module according to an exemplary embodiment of the present invention.
4 is a perspective view illustrating a connection area between bus bars and wirings in a solar cell panel according to an exemplary embodiment of the present invention.
5 is a schematic diagram of a wiring apparatus of a solar cell module according to another embodiment of the present invention;

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

1 is an exploded perspective view of a solar cell module according to an embodiment of the present invention.

The solar cell module 100 according to the embodiment of the present invention includes a solar cell panel 110, a frame 120, a bus bar 130, a wiring 140, and a junction box 150.

The solar panel 110 is formed on the transparent substrate 112 and includes a plurality of solar cells 114 connected in series with each other, and the light receiving area and the light receiving area in which the plurality of solar cells 112 are located. It is divided into a peripheral area surrounding the periphery. Although not shown in the drawings, each of the plurality of solar cells 114 includes a front electrode formed on the transparent substrate 112, a semiconductor layer on the front electrode, and a back electrode, and the plurality of solar cells 114. In order to connect them in series, the adjacent front and rear electrodes are connected to each other. The back electrode is made of a metal material such as aluminum (Al).

Frame 120 is to protect the solar panel 110 by alleviating the impact applied to the outside, and to prevent the entry of foreign matter into the inside of the solar panel 110 and at the same time, the solar cell is installed outdoors The panel 110 is fixed.

The frame 120 includes a plurality of members 122 for receiving and fixing the peripheral region 110b of the solar cell panel 110 and a plurality of fixing means 124 for mechanically connecting and fixing the members 122 adjacent to each other. Include. In order to assemble the solar cell panel 110 formed in a quadrangle, the frame 120 includes four members 122 and four members for receiving and fixing two horizontal and two vertical sides of the solar cell panel 110. Four fastening means 124 for fastening each 122.

The plurality of members 122 and the plurality of fastening means 124 constituting the frame 120 are manufactured by extrusion or roll molding using aluminum or aluminum alloy. If necessary, the plurality of members 122 and the fixing means 124 may be formed of different materials, but it is preferable to form the same material so as to be able to expand and contract in the same way according to the change in temperature.

The bus bar 130 is positioned on the plurality of solar cell 114s arranged in parallel to be spaced apart from each other on the transparent substrate 112 of the solar cell panel 110. The bus bar 130 may include a first bus bar 130a positioned on the first outer solar cell 114a disposed at the outermost side of the plurality of solar cells 114 and a plurality of solar cell cells ( The second bus bar 130b is disposed on the second outer solar cell 114b disposed at the outermost side in the other direction opposite to one side of the one side 114.

The first and second bus bars 130a and 130b are formed of a metal material, for example, aluminum (Al) plate. A rear electrode formed of a metal material is formed on an upper surface of each of the plurality of solar cells 114 facing the transparent substrate 112, so that the first and second outer solar cells 114a and 114b are formed on the first electrode. And when the second bus bars 130a and 130b are positioned, the first and second outer solar cells 114a and 114b and the first and second bus bars 130a and 130b are electrically connected to each other. The first and second bus bars 130a and 130b are fixed to the first and second outer solar cells 114a and 114b using a plurality of tapes 132.

The wiring 140 is electrically connected to the bus bar 130 at an upper portion of the solar cell panel 110 and connected to the first wiring 140a and the second bus bar 130b connected to the first bus bar 130a. The first wiring 140b is connected. The first and second wirings 140a and 140b may be formed of aluminum having the same material as the first and second bus bars 130a and 130b. Each of the first and second wires 140a and 140b is vertically connected to the first and second bus bars 130a and 130b and is introduced into the junction box 150 located in the solar cell panel 110.

The first and second wirings 140a and 140b are connected to the first and second outer solar cells 114a and 114b via the tapes 132 through the first and second bus bars 130a and 130b. It is fixed. Each of the first and second wires 140a and 140b may not be electrically connected to the first and second outer solar cell 130 except for the first and second outer solar cells 130a and 130b. An insulating film (not shown) may be interposed between the first and second wirings 140a and 140b and the plurality of solar cells 130.

The junction box 150 receives the first and second wires 140a and 140b and accommodates a plurality of terminals, diodes, and the like, although not shown in the drawing to transfer the output power of the solar cell panel 110 to the outside. .

2 is a schematic diagram of a wiring apparatus of a solar cell module according to an embodiment of the present invention.

The wiring device 170 of the solar cell module according to the embodiment of the present invention, the main body 172, the first support portion 174, the second support portion 176, the worktable (178), the tape transfer unit 180 ) And the tape adhesive unit 190.

The main body 172 is provided with a control device (not shown), the first support portion 174 is connected. The second support 176 is connected to the first support 174 to move in the first direction in the horizontal plane. The work table 178 has a solar cell panel 110 in which the bus bar 130 and the wiring 140 are located.

The tape feeder 180 is connected to the second support 176 so as to be movable in a second direction, which is a direction perpendicular to the first direction, in a horizontal plane, and the tape is cut to a predetermined size in a tape supply device (not shown). 132 to position the solar cell panel 110. The tape feeder 180 is connected to each of the two first cylinder portions 184 and the two first cylinder portions 184 which are connected to the second support portion 176 and drive up and down, and adsorbs both ends of the tape 132. And two head portions 186. The head portion 186 is provided with a plurality of suction ports (not shown) capable of sucking the tape 132 in a vacuum to transport the tape 132.

The second support 176 moves in the first direction along the first support 174 and the tape feeder 180 moves in the second direction along the second support 176, so that the tape feeder 180 is in the desired position. After stopping at, the two first cylinder portions 184 of the tate conveying portion 180 are lowered in the vertical direction, and the two head portions 186 on which both ends of the tape 132 are adsorbed are vacuumed and the tape 132 is cut. ) Is positioned on the solar cell panel 110 mounted on the work table 178.

The adhesive part 190 is connected to the second support part 176 so as to be movable in a second direction perpendicular to the first direction in a horizontal plane, and the tape 132 is connected to the solar cell panel 110 by the tape transfer part 180. ), The tape transfer unit 180 is raised, and the adhesive unit 190 is lowered to bond the tape 132 to the solar cell panel 110.

The adhesive part 190 is connected between the second cylinder part 192 and the second cylinder part 192 which is located between two first cylinder parts 186 and connected to the second support part 176 and moves vertically, and is a solar cell. And a movable roller portion 194 for adhering the tape 132 to the panel 110, the bus bar 130, and the wiring 140. The roll part 194 includes a rotating shaft 194a connected to the second cylinder part 192 and a rubber material surrounding the rotating shaft 194a and includes an elastic part 194b elastically pressing the tape 132. The elastic part 194b of the roller part 194 may elastically press the tape 132 to uniformly adhere the tape 132 to the solar cell panel 110.

3A to 3C are schematic diagrams illustrating a method of wiring a solar cell module using a wiring apparatus of a solar cell module according to an exemplary embodiment of the present invention.

As shown in FIG. 3A, the solar cell panel 110, the bus bar 130, and the wiring 140 are positioned on the work table 178. The solar panel 110 includes a plurality of solar cells 114, each of which is composed of a front electrode, a semiconductor layer on the front electrode, and a rear electrode, although not shown in the drawings. In order to connect the plurality of solar cells 114 in series, the adjacent front and rear electrodes are connected to each other.

The bus bar 130 may include a first bus bar 130a positioned on the first outer solar cell 114a disposed at the outermost side of the plurality of solar cells 114 and a plurality of solar cell cells ( The second bus bar 130b is disposed on the second outer solar cell 114b disposed at the outermost side in the other direction opposite to one side of the one side 114.

The wiring 140 includes a first wiring 140a connected to the first bus bar 130a and a first wiring 140b connected to the second bus bar 130b. An insulating film (not shown) is interposed between the first and second wirings 140a and 140b and the plurality of solar cells 130.

As shown in FIG. 3B, a plurality of first tapes 132a cut to a predetermined size from a tape supply device (not shown) by the driving of the second support part 174 and the tape transfer part 180 may be formed in the first and second outer portions. Regions where the solar cells 114a and 114b and the first and second bus bars 130a and 130b are connected, respectively, and the first and second bus bars 130a and 130b and the first and second wirings 140a, respectively. The tape 132 is positioned in an area connecting the 140b.

In the tape feeder (not shown), both ends of the tape 132 are adsorbed to the two head portions 188, and the second support portion 176 moves along the first support portion 174 in the first direction and the two After the first cylinder portion 186 moves in the second direction along the second support portion 176 and is positioned on the work table 178, the two first cylinder portions 186 are lowered and two head portions ( 188 stops vacuum suction and places the tape 132 on the solar cell panel 110.

When the tape 132 is transferred by the tape transfer unit 180, the roller 194 of the adhesive unit 190 does not contact the tape 132. In other words, the altitude of the two head portions 188 of the tape conveyance unit 180 is lower than the altitude of the roller portion 194 of the adhesive unit 190 in the conveyance process of the tape 132.

As shown in FIG. 3C, when the first tape 132a is positioned on the solar cell panel 110, the two first cylinder portions 186 are raised to form an adhesive portion located between the two first cylinder portions 186. The second cylinder portion 192 of 190 descends to bring the roller portion 194 into contact with the tape 132a. The roller 194 rotates to both sides to adhere the tape 132. The elastic part 194b of the roller part 194 elastically presses the tape 132 to uniformly fix the bus bar 130 and the wiring 140 to the solar cell panel 110.

4 is a perspective view illustrating a connection area between bus bars and wires in a solar cell panel according to an exemplary embodiment of the present invention.

The first bus bar 130a is mounted on the solar cell 114a located at the outermost side of the solar cell panel 110. Since the first bus bar 130a is formed of a metal material such as aluminum, a step is generated on the surface of the solar cell 114a. Therefore, in order to fix the solar cell 114 including the first bus bar 130a with the tape 132, the head portion 186 of the tape feeder 180 of FIG. Since the head part 186 is made of a metal material and the lower part thereof is in a planar state, the head part 186 is not uniformly bonded due to the step by the first bus bar 130a.

Further, the step is more severe in the region where the first bus bar 130a and the first wiring 140a are connected. Therefore, the tape 132 cannot be adhered uniformly by pressing the head portion 186 of FIG. 2. In order to overcome the step caused by the first bus bar 130a and the first wiring 140a, the first bus bar while the roller portion 194 of the adhesive part 190 of FIG. 2 moves over the tape 132. When the elastic part 194b of the roller part 194 of FIG. 2 absorbs the step | step by 130a and the 1st wiring 140a, the tape 132 can be pressurized uniformly. Accordingly, the tape 132 is uniformly adhered to the surface of the solar cell panel 110 as well as the first bus bar 130a and the first wiring 140a.

5 is a schematic diagram of a wiring apparatus of a solar cell module according to another embodiment of the present invention;

The wiring device 170 of the solar cell module according to another embodiment of the present invention shown in FIG. 5 is a solar cell module of FIG. 2 except that a plurality of tape transfer units 180 and a tape adhesive unit 190 are installed. Since it is similar to the wiring apparatus 170, the same code | symbol is used for the same component. The wiring device 170 of the solar cell module according to another embodiment of the present invention simultaneously or sequentially a plurality of tapes 132 cut to a predetermined size in a tape supply device (not shown) on the solar cell panel 110. Can be positioned and bonded to improve working efficiency.

The wiring device 170 of the solar cell module according to another embodiment of the present invention, the main body 172, the first support portion 174, a plurality of second support portion 176, a worktable (178), a plurality It comprises a tape transfer unit 180 and a plurality of tape adhesive unit 190 of the.

The main body 172 is provided with a control device (not shown), the first support portion 174 is connected. A plurality of second supports 176 are connected to the first support 174 to move in the first direction in the horizontal plane. The work table 178 has a solar cell panel 110 in which the bus bar 130 and the wiring 140 are located.

Each of the plurality of tape transfer units 180 is connected to be movable in a second direction, which is a direction perpendicular to the first direction, in a horizontal plane along the plurality of second support units 176, and has a predetermined size in a tape feeder (not shown). A plurality of tapes 132, which are cut, are positioned on the solar cell panel 110. Each of the plurality of tape transfer units 180 is connected to be movable in a second direction, which is a direction perpendicular to the first direction, in a horizontal plane along the plurality of second support units 176, and has a predetermined size in a tape feeder (not shown). A plurality of tapes 132, which are cut, are positioned on the solar cell panel 110.

The plurality of second supports 176 includes a second upper support 176a and a second lower support 176b. In order to prevent collision of the plurality of second supports 176 moving along the first support 174, the second upper support 176a is connected to the upper portion of the first support 174, and the second lower support 174 176b is connected to the bottom of the second support 174.

The plurality of tape feeders 180 are connected to each of the second upper and lower supports 176a and 176b. Each of the plurality of tape feeders 180 is connected to each of the first and second first cylinder portions 184 and 184 which are connected to the second upper and lower support portions 176a and 176b and are driven up and down. Two head portions 186 for adsorbing both ends of the tape 132 are included. The head portion 186 is provided with a plurality of suction ports (not shown) capable of sucking the tape 132 in a vacuum to transport the tape 132.

The plurality of second supports 176 move simultaneously or sequentially in the first direction along the first support 174 and the plurality of tape feeders 180 simultaneously or in the second direction along the plurality of second supports 176. After the sequential movement and the plurality of tape feeders 180 stop at a desired position, the two first cylinder portions 184 of each of the plurality of feed feeders 180 are lowered in the vertical direction and both ends of the tape 132 are moved. The two head portions 186 adsorbed are positioned on the solar cell panel 110 mounted on the work table 178 as the vacuum is cut off.

The plurality of adhesive parts 190 are connected to each of the second upper and lower support parts 176a and 176b. Each of the plurality of adhesive parts 190 is connected to be movable in a second direction, which is a direction perpendicular to the first direction in the horizontal plane, along the plurality of second support parts 176, and the tape 132 is connected by the tape conveying part 180. When positioned on the solar cell panel 110, the tape transfer part 180 rises, and each of the plurality of adhesive parts 190 descends to adhere the tape 132 to the solar cell panel 110.

Each of the adhesive parts 190 is connected between the second cylinder part 192 and the second cylinder part 192 which are located between two first cylinder parts 186 and connected to the second support part 176 and move vertically. And a roller unit 194 movable to attach the tape 132 to the solar cell panel 110, the bus bar 130, and the wiring 140. The roll part 194 includes a rotating shaft 194a connected to the second cylinder part 192 and a rubber material surrounding the rotating shaft 194a and includes an elastic part 194b elastically pressing the tape 132. The elastic part 194b of the roller part 194 may elastically press the tape 132 to uniformly adhere the tape 132 to the solar cell panel 110.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

Claims (6)

Preparing a solar panel including a plurality of solar cells;
Placing a bus bar on the solar panel and a wire for electrically connecting the bus bar to the plurality of solar cells;
Positioning a tape to secure the bus bar and the wiring to the solar cell panel; And
Pressing the tape to adhere the tape to the bus bar and the wiring and the solar cell panel to overcome the step caused by the bus bar and the wiring;
Wiring method of a solar cell module comprising a.
The method of claim 1,
The solar cell panel is moved and lowered by a tape transfer unit including two first cylinder parts driving up and down and two head parts connected to each of the two first cylinder parts and including a suction unit. Located on of
After the tape conveying portion is raised, the adhesive portion including the second cylinder portion and the roller portion is lowered to the upper portion of the solar cell panel, and the roller portion is elastically pressurized while the roller portion is in contact with the tape and moves the surface of the tape. And attaching the tape to the bus bars, the wirings, and the solar cell panel.
main body;
A support part connected to the main body;
A tape feeder connected to the support; And
An adhesive part connected to the support part and adhering the tape using a roller part, and capable of moving up and down;
Wiring device for a solar cell panel comprising a.
The method of claim 3, wherein
The tape feeder,
Two first cylinder portions connected to the support portion; And
Two head parts connected to each of the two first cylinder parts and configured to suck each end of the tape by vacuum;
Including,
The adhesive part,
A second cylinder portion connected to the support portion and positioned between the two first cylinder portions; And
A roller portion connected to the second cylinder portion;
Wiring device for a solar cell panel comprising a.
The method of claim 4, wherein
When the tape is located on the solar cell panel, the two head portion is raised by the driving of the two first cylinder portion, the roller portion of the second cylinder portion is characterized in that moving while pressing the tape Wiring device for the battery panel.
The method of claim 3, wherein
A plurality of the tape transfer device and a plurality of the adhesive portion is connected to the support portion, the wiring apparatus of the solar cell panel, characterized in that for moving or bonding a plurality of the tape at the same time or sequentially.

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