KR101709966B1 - Ribbon bonding device for solar cell - Google Patents

Abstract

The present invention relates to a ribbon bonding apparatus for solar cells. The ribbon bonding apparatus for solar cells comprises: a conductive film supply unit (10) to which a conductive film roll in which a separation sheet is attached to a band-shaped conductive film and which unwinds the conductive film roll while separating the separation sheet from the conductive film so as to supply the conductive film; a selective cutting unit (20) which is disposed in the conductive film supply unit (10) and which selectively cuts only the conductive film before the conductive film is separated from the separation sheet so that the separation sheet is continuously discharged after the separation sheet has been separated from the conductive film; an attaching unit (30) to which solar cells are supplied and which attaches the conductive film, supplied by the conductive film supply unit (10), to bus lines of the solar cells; a pre-bonding unit (60) to which the solar cells, configured such that the conductive film has been attached to the solar cells by the attaching unit (30), are supplied and which pre-bonds a ribbon, supplied by a ribbon supply unit (50), to the conductive film; a buffer unit (60) which transfer the solar cells, configured such that the ribbon has been pre-bonded thereto by the pre-bonding unit (60), to a next stage so that a number of solar cells can be continuously pre-bonded; a transfer unit (70) which transfers the solar cells, transferred by the buffer unit (60) and configured such that the ribbon has been pre-bonded thereto, together; and a bonding unit (80) which sequentially performs thermal bonding on the ribbon, pre-bonded to the solar cells transferred by the transfer unit (70), so that the ribbon is firmly bonded to the solar cells.

Description

(Ribbon bonding device for solar cell)

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ribbon bonding apparatus for a solar cell, and more particularly, to a ribbon bonding apparatus for a solar cell capable of improving productivity and capable of stable feeding regardless of the elongation of the ribbon.

Generally, solar cells for solar power generation can be produced from silicon or various compounds, and can be produced by solar cells. However, since one cell does not have sufficient output, each cell must be connected in series or parallel. This state of connection is called a "solar module".

Solar modules consist of back sheet, solar cell, ribbon, EVA and glass. TPT (Tedlar / PET / Tedlar) type is widely used for the back sheet, and the ribbon is used as a flow path for the current. Therefore, the material coated with silver or tin lead is used for the copper.

Eva plays a role in the chemistry of each element of the solar cell, and glass uses less iron to help prevent reflection of light.

As an apparatus for bonding a ribbon in the above-described structure, for example, the applicant's patent 10-1153271 of the present invention can be exemplified. As described above, the ribbon is coated with silver or tin lead in copper, and the bonding is performed in a relatively high temperature atmosphere in order to melt and bond the coated silver or tin lead.

In recent years, a technique of replacing a ribbon with a conductive film has been proposed in order to prevent a solar module from being subjected to thermal stress due to such a high temperature bonding atmosphere, thereby lowering the efficiency.

It is known that the conductive film can be bonded at a relatively low temperature as compared with the conventional ribbon after being adhered to a film having adhesive property on one side, thereby minimizing the efficiency degradation of the photovoltaic module by reducing the occurrence of heat stress.

In particular, Japanese Patent Application Laid-Open No. 2008-300403 discloses that the method for producing such a conductive film and the conductive film can be applied to a solar cell. It is known that the conductive film can be used as a ribbon of a solar cell. However, there is no description of an apparatus for specifically bonding such a conductive film to a solar cell.

Usually, in order to attach the conductive film, it is necessary to separate the conductive film and the release paper, to release the release paper continuously without cutting, and to cut the conductive film into a proper size, The structure of the apparatus is required.

In addition, the ribbon of the solar cell generally had a width of 2.0 mm in 2010, but the width was reduced to 1.5 mm in 2012 and 1.0 mm in width after 2014.

The reduction in the width of the ribbon means an increase in the area directly receiving the sunlight in the solar module, and the increase in the area of the cell can increase the efficiency of the generation per solar module.

It is required to place the ribbon cut to a predetermined length on the surface of the supplied solar cell in order to directly bond or solder the ribbon to the solar cell. And a loader capable of horizontal reciprocating motion.

The structure of positioning the ribbon cut through the horizontal reciprocating motion on the surface of the solar cell is disclosed in Japanese Patent Application No. 10-1113027 (Ribbon bonding device of solar module, registered on Jan. 31, 2012) Includes a loader for clamping a ribbon of the ribbon supply unit and drawing the ribbon in a horizontal direction, and releasing the clamping while pressing the drawn ribbon against the bus of the solar cell, .

However, according to the invention disclosed in the Japanese Patent No. 10-1113027, the loader directly clamps one end of the ribbon. However, as the width of the ribbon becomes 1.0 mm, the width of the ribbon decreases, There has been a problem that a phenomenon of slackening occurs.

This is because the width of the ribbon is narrowed to increase the elongation rate, and the ribbon is stretched without keeping the circular shape, so that the ribbon of the designed line width can not be bonded.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a ribbon bonding apparatus for a solar cell which can cut and supply a conductive film with a predetermined length while smoothly discharging release paper.

Another object of the present invention is to provide a ribbon bonding apparatus for a solar cell that can improve productivity by reducing the downtime of the process.

Another object of the present invention is to provide a ribbon bonding apparatus for a solar cell capable of moving a ribbon having a width of 1.0 mm or less without deformation by using a vacuum picker without clamping the ribbon.

Another object of the present invention is to provide a ribbon bonding apparatus for a solar cell capable of shortening a process time by transferring a ribbon using a vacuum picker and bonding the ribbon with a vacuum picker at the same time .

In order to solve the above problems, a ribbon bonding apparatus for a solar cell according to the present invention comprises a strip-shaped conductive film roll 1 to which a releasing paper is attached, and the conductive film roll 1 is unwound to supply the conductive film 2 (3) and the conductive film (2); and a conductive film supply unit (10) disposed on the conductive film supply unit (10) and separated from the release paper (3) (2) and a solar cell (5), and the solar cell (5) is supplied with the conductive film (2) and the solar cell (5) to cut off only the conductive film so that the release film And a ribbon 4 supplied from the ribbon supply unit 50 and supplied with the solar cell 5 to which the conductive film 2 is adhered, Bonded to the conductive film (2) bonded to the conductive film (5) A buffer unit 60 for moving and receiving the solar cells 5 pre-bonded with the ribbon 4 by the pre-bonding unit 40; And a transfer unit 70 for transferring the transfer units 5 to a bonding unit 80 positioned in parallel with the buffer unit 60 and bonding the bonding units 80 to the bonding unit 80.

The ribbon bonding apparatus of the present invention can selectively cut only the conductive film without cutting the releasing paper in the process of supplying the conductive film with the releasing paper, so that the releasing paper can be continuously discharged, thereby enhancing the reliability of the apparatus There is an effect that can be.

In the ribbon bonding apparatus of the present invention, the conductive film is adhered to the surface of the solar cell, the ribbon is pre-bonded, and the solar cell pre-bonded with the ribbon is transferred to a bonding position requiring a relatively long process time. Thereby improving the productivity.

In addition, the present invention can prevent breakage of the solar cell during the bonding process, and can perform stable bonding irrespective of the horizontal state, thereby preventing reduction in the yield.

In the ribbon bonding apparatus of the present invention, the ribbon is directly clamped to the surface of the solar cell and is not transferred to the upper part of the solar cell. Instead, the ribbon bonding apparatus is provided with a bonding position for bonding the ribbon using a plurality of vacuum chucks There is an effect that the ribbon can be prevented from being stretched by clamping by separating the standby position where the cut ribbon is positioned before bonding and transferring the ribbon from the standby position to the bonding position using a plurality of vacuum pickers.

Further, in the ribbon bonding apparatus of the present invention, the ribbon is transferred from the standby position to the bonding position, the ribbon is seated on the solar cell and the bonding is performed, thereby improving the productivity by shortening the process time .

1 is a block diagram of a ribbon bonding apparatus for a solar cell according to a preferred embodiment of the present invention.
2 is a schematic block diagram of a ribbon bonding apparatus for a solar cell according to a preferred embodiment of the present invention.
Fig. 3 is a configuration diagram of the selective cutting portion in Fig.
FIG. 4 is a configuration diagram of the pre-bonding unit in FIG.
5 is a configuration diagram of the bonding waiting unit in FIG.
FIGS. 6 and 7 are diagrams showing the structure of a vacuum picker for explaining the pre-bonding process of the present invention, respectively.
Fig. 8 is a configuration diagram of the conveyance unit in Fig. 1. Fig.
Fig. 9 is a configuration diagram of the bonding portion in Fig. 1; Fig.

Hereinafter, embodiments of a ribbon bonding apparatus for a solar cell according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a ribbon bonding apparatus for a solar cell according to the present invention.

1, a ribbon bonding apparatus for a solar cell according to the present invention comprises: a strip-shaped conductive film roll having a releasing paper attached thereto; and the conductive film roll is unrolled to supply a conductive film, A conductive film supply unit 10 for supplying a conductive film to the conductive film supply unit 10 and cutting the conductive film before the conductive film is separated from the release film and selectively cutting only the conductive film so that the release film can be continuously discharged after being separated A bonding portion 30 for bonding the conductive film supplied from the conductive film supply portion 10 to the bus line of the solar cell by supplying the solar cell and a bonding portion 30 for bonding the conductive film to the bus line, A pre-bonding unit 60 for pre-bonding the ribbon supplied from the ribbon supply unit 50 to the conductive film by supplying the cell, A buffer unit 60 for transferring a plurality of solar cells pre-bonded with ribbons to the rear end so as to be able to pre-bond the ribbon in a plurality of successive repetition cycles in the buffer unit 60, and a plurality of solar cells A transfer unit 70 for simultaneously moving the cells and a bonding unit 80 for firmly bonding the ribbons to the solar cells by thermocompression bonding the ribbons in the solar cells pre-bonded with the ribbons sequentially transferred through the transfer unit 70 .

Hereinafter, the structure and operation of a preferred embodiment of the ribbon bonding apparatus of the present invention constructed as described above will be described in more detail.

First, the conductive film supply unit 10 is equipped with conductive film rolls wound with a conductive film, and the conductive film rolls are unwound and fed to the prebonding unit 40 side.

2 is a schematic view showing a part of a ribbon bonding apparatus of a solar cell according to the present invention.

2, the conductive film supply unit 10 includes a winding roll 11 for supporting the conductive film roll 1 in a rotatable state, a conductive film roll 1 from the winding roll 11, A separator for separating the release paper 2 from the conductive film 2 at the rear end of the third supply roller 13, and a separator for separating the release paper 2 from the conductive film 2, 14).

A plurality of conductive film supply units 10 may be provided according to the number of bus lines. The concrete structure of the conductive film supply units 10 may be changed in various ways as required. In FIG. 2, the simplest structure is shown.

A selective cut 20 is located between the first feed roller 12 and the second feed roller 13. The selective cutting portion 20 cuts the conductive film 2 attached to one surface of the release paper 3 moving between the first supply roller 12 and the second supply roller 13, The conductive film 2 is selectively cut so that the conductive film 2 is not broken, and this structure will be described in more detail below.

Since the conductive film 2 is not separated from the release paper 3 until it passes the second supply roll 13 even in the state where only the conductive film 2 is selectively cut as described above, The conductive film is supplied to the prebonding part 40 in a predetermined length unit, and the release paper 3 is continuously discharged to the outside through a discharge part (not shown).

The discharging portion can use a roller, and the present invention is not limited by the structure of the discharging portion if it is a structure capable of smoothly discharging a releasing paper such as a vacuum pressure.

3 is a detailed configuration diagram of the selective cutting section 20. As shown in FIG.

3, the selective cutting portion 20 includes through holes 29 penetrating through the through holes 30 in the state where the release paper 3 (refer to FIG. 2) and the conductive film 2 are attached to each other, And a fixing frame 21 located on the side of the through hole 29 of the fixing frame 21 so as to be in contact with the release paper 3 so as to smoothly cut the conductive film 2, A fixing guide 22 provided at a position symmetrical to the fixing body 28 with the through hole 29 therebetween to provide a guide groove; A lower fixing part 24 coupled to the upper portion of the moving guide 23 and a lower fixing part 24 which is capable of adjusting the position of the lower fixing part 24, A cutter (25) fixed to the lower fixing part (24), a cutter It is configured to include a fixing portion (26) is coupled to the side of the lower side of the lower fixing portion 24 of the cutter 25, the interval adjusting unit 27 for adjusting the degree of protrusion of the cutter (25).

In such a configuration, the fixing body 28 is fixed on one fixing frame 21 of the through hole 29 in such a state that the position thereof can not be changed, and the cutter 25 is attached to the side surface of the fixing body 28 Only the conductive film 2 is selectively cut in the structure of attaching the conductive film 2 and the release paper 3 passing through the through hole 29 when the conductive film 2 moves in a direction tangential to the conductive film 2.

That is, when the end of the cutter 25 directly contacts the fixing body 28, both the conductive film 2 and the release paper 3 are cut off, The cutter 25 is brought into direct contact with the fixture 28 and the cutter 25 is separated from the side surface of the fixture 28 by the thickness of the release paper 3 and does not cut the release paper 3.

Therefore, the conductive film 2 having passed through the separating portion 4 of FIG. 2 is divided into a predetermined length, but the releasing paper 3 can be continuously discharged through the discharging portion without being divided.

The conductive film 2 cut by the selective cutting portion 20 and separated from the releasing paper by the separating portion 14 is supplied to the bonding portion 30 and is transported by the moving means such as a robot, And adhered on the bus line.

The configuration of the bonding portion 30 can be configured simply to the extent that the conductive film 2 is simply placed at the position of the bus line of the solar cell and a weak pressure is applied downward.

The adhesive is adhered by the adhesive force of the conductive film (2).

Then, the solar cell to which the conductive film 2 is adhered is supplied to the pre-bonding section 40. The prebonding unit 40 may be configured such that the ribbon supplied from the ribbon supplying unit 50 is placed on the conductive film 2 adhered to the solar cell and then the pressure is applied so that the adhesive is applied only by the adhesive force of the conductive film 2 In this case, since the bonding time is longer than the other process time, the supply of the conductive film 2 of the conductive film supply unit 10, The ribbon feeding operation of the ribbon feeding section 50 must be interrupted for a relatively long bonding time, thereby delaying the whole process time and lowering the productivity.

In order to solve such a problem, in the present invention, a ribbon-pre-bonded solar cell is sequentially transferred to the rear end so that pre-bonding for bonding the ribbon to the conductive film of the solar cell can be continuously performed, The buffer unit 60 can be connected without interruption.

The buffer unit 60 is provided with a rail, pre-bonding the ribbon to the sheet-fed solar cell in the pre-bonding unit 40, and then transferring the ribbon in a state in which the ribbon is not broken, Thereby accommodating the bonded solar cell.

The solar cells accommodated in the buffer unit 60 and connected by ribbons are simultaneously transferred to the bonding unit 80 by the transfer unit 70.

The minimum time for bonding the ribbon to the conductive film of the solar cell is determined by the bonding unit 80. In order to prevent stagnation of the process, 10 solar cells are successively pre-bonded during the bonding in the bonding unit 80 And is accommodated in the buffer unit 60, so that the productivity can be further improved.

4 is a detailed configuration diagram of the pre-bonding section 40. As shown in FIG.

4, the pre-bonding part 40 according to the present invention includes a bonding base part 410 where the cut ribbons 4 are positioned and a ribbon 4 positioned at the bonding base part 410 A vacuum picker unit 420 for vacuum-picking and transferring the ribbon 4 to the solar cell 5, placing the ribbon 4 on the solar cell 5 and heating and bonding the vacuum picker unit 420 and the vacuum picker unit 420, And a bonding portion 430 for providing a space through which the ribbon 4 can be bonded by the bonding portion 420.

 The present invention can include a cut-out portion for uncoiling and feeding a ribbon in a ribbon supply portion (50) for rotatably supporting a roll on which the ribbon (4) is wound, and cutting the ribbon to a required length. Since various known methods can be used, detailed description thereof will be omitted in the present invention.

The ribbon 1 may have a normalized width of 1.0 mm or a width of less than 1.0 mm.

The ribbon 1 may be positioned above the bonding standby portion 410 while being cut to a required length.

FIG. 5 is a view illustrating the structure of the bonding standby portion 10. As shown in FIG. 5, the bonding base portion 410 includes a seating groove 411 on which the ribbon 4 cut at the top is seated, A plurality of vacuum adsorption holes 412 are formed at predetermined intervals in the vacuum chamber 411.

One or two or more vacuum picker parts 420 may be sequentially vacuum-adsorbed on the ribbon 4 located at each bonding base part 410, It is possible to reduce the waiting time and improve the productivity.

The seating groove 411 and the vacuum suction hole 412 prevent the ribbon 4 from being warped or displaced in a state where the ribbon 4 is properly positioned so that the vacuum picker portion 420, As shown in Fig.

FIGS. 6 and 7 are diagrams showing the structure of a vacuum picker for explaining the pre-bonding process of the present invention, respectively.

6, the vacuum picker unit 420 includes a plurality of vacuum pickers 421 for adsorbing or releasing the ribbon 4 according to the vacuum pressure transmitted through the tube 424, A supporting part 422 which buffers and supports the vacuum pickers 421 by means of an internal spring 423 and moves by the action of the conveying part 440, a fixing part 425 provided on the supporting part 422, The vacuum pickers 421 are located below the support portions 422 by the springs 426 provided in the support 425 and can vertically dampen the vacuum pickers 421 while the ends of the vacuum pickers 421 are inserted. And a heating block (227) for pre-bonding the ribbon (4) in a state where the ribbon (4) is placed on the solar cell (5) with the conductive film (2) attached thereto.

The support part 422 is connected to the transfer part 440 and is movable up and down and left and right. Particularly, the vacuum picker part 420 is hollow and has a plurality of vacuum pickers 421, So that the buffering action can be performed vertically by the spring 423 provided inside.

The upper end of the vacuum picker 421 is connected to the tube 424 so that the vacuum pressure is supplied or the vacuum pressure is released so that the ribbon 4 can be vacuum adsorbed or vacuum adsorbed on the vacuum adsorbed ribbon 4 .

In addition, the vacuum picker part 420 includes a heating block 427 for bonding the ribbon 4. The heating block 427 may have a heater inserted therein and may be spaced apart from the lower portion of the support portion 422 by a fixing portion 425. The heating block 427 may include a heating portion 422, And a spring 426 whose both ends are in contact with the bottom surface of the heating block 422 and the upper surface of the heating block 427.

The buffering action of the heating block 427 prevents the solar cell 5 from being damaged when the ribbon 4 is pressed on the upper surface of the solar cell 5 as shown in FIG. The spring 426 may be compressed by the contact during bonding and the fixing portion 425 may be pushed up and pushed upwardly of the supporting portion 422. [

The present invention is not limited by the structure of the bonding portion 430 so long as the bonding portion 430 is configured so that the cell 5 is transferred and positioned at a predetermined position.

The process of pre-bonding the ribbon 4 to the solar cell 5 to which the conductive film 2 is attached will be described in more detail. First, the ribbon 4 is cut into the bonding cavity 410, And is placed in the seating groove 411 of the bonding standby portion 410. At this time, a vacuum pressure is applied to the vacuum hole 412 so that the ribbon 4 can be closely fixed.

In this state, the vacuum picker part 420 moves to the upper part of the bonding standby part 410 and then moves downward so that the lower ends of the vacuum pickers 421 are positioned in the seating groove 411 4).

At this time, each of the vacuum pickers 421 can be buffered while being fixed to the supporter 422 by the spring 423, and can receive the vacuum pressure through the tube 424 in the contact state, ) Is vacuum-adsorbed.

At the same time, the vacuum pressure supplied through the vacuum hole 412 of the bonding base 410 is no longer supplied, and the ribbon 4 can be moved in a state of being vacuum-adsorbed by the vacuum pickers 421 do.

It is possible to prevent displacement or damage of the ribbon 4 that may occur when the vacuum picker unit 420 vacuum-adsorbs the ribbon 4 by using the vacuum hole 412 and the mounting groove 411 as described above do.

Then, the vacuum picker unit 420 moves upward, moves horizontally again, and moves to the upper portion of the bonding unit 430. At this time, the solar cell 5 bonded in the previous state is unloaded to the bonding part 430, and the new solar cell 5 to which the conductive film 2 is bonded again is loaded.

The unloaded solar cell 5 is horizontally transported to the buffer unit 60 as described above.

The vacuum picker unit 420 is moved to the upper portion of the solar cell 5 to which the ribbon 4 is to be bonded and then moves downward so that the ribbon 4 vacuum-adsorbed by the vacuum pickers 421, (5).

The vacuum picker 421 is moved upward by the action of the spring 423 and the heating block 427 is brought into contact with the top of the ribbon 4 at a predetermined pressure do.

At this time, the heating block 427 also acts to buffer the solar cell 5 by the action of the fixing part 425 and the spring 426, thereby preventing damage to the solar cell 5.

The ribbon 4 is pre-bonded on the conductive film adhered to the bus of the solar cell 5 by holding the above-mentioned contact state for a predetermined time, and the bonding pressure and the vacuum pressure supplied through the tube 424 are cut off Thereby releasing the ribbon (4).

A new ribbon 4 is supplied to the bonding standby portion 410 together with the bonding process and the vacuum picker portion 420 is moved to the upper portion of the bonding standby portion 410 and the bonding of the ribbon 4 The completed solar cell 5 is unloaded from the bonding unit 430 and transferred to the buffer unit 60.

As described above, the present invention can perform pre-bonding at the same time as the positioning of the ribbon 4 in the pre-bonding process, thereby shortening the process time and increasing the productivity.

As described above, the solar cells 5 pre-bonded with the ribbon 4 in the pre-bonding unit 40 are transferred to the bonding unit 80 by the transfer unit 70.

8 is a detailed configuration diagram of the transfer unit 70. As shown in FIG.

Referring to FIG. 8, there are shown a conveying guide 71 which is coupled to one side of the driving means 72, a moving unit 73 which linearly reciprocates in one direction along the conveying guide 71 by the driving means 72, A fixed frame 75 fixedly coupled to the movable supporting portion 74 at a position spaced apart from each other by a predetermined distance from the movable supporting portion 74, A vacuum chuck 76 which is fixed to the vacuum chuck 76 so as to absorb the solar cell 5 to which the ribbon 4 is pre-bonded and move from the pre-bonding part 40 side to the bonding part 80; And a vertically moving cylinder portion 78 provided between the moving portion 73 and the moving support portion 74 for moving the moving support portion 74 upward and downward. The vacuum port portion 77, As shown in FIG.

The configuration of the transfer unit 70 is such that the solar cell 5 to which the ribbon 4 is pre-bonded in the pre-bonding unit 40 is transferred to and received by the buffer unit 60, (5) are configured to be transferred to a bonding portion (80) arranged side by side on the side of the transfer portion (50).

The solar cells 5 accommodated in the buffer unit 60 and pre-bonded with the ribbon 4 are adsorbed by the vacuum chucks 76 of the transfer unit 70 and moved by the vertically moving cylinder unit 78 The holding portion 74 is moved upward to move the fixing frame 75 fixed to the moving support portion 74 and the vacuum chuck 76 and the solar cell fixed to the vacuum chuck 76 upward.

In this state, the moving unit 73 is moved to the bonding unit 80 side along the conveying guide 71 by the driving unit 72, and the moving support unit 74 is moved downward by the up-down moving cylinder unit 78 Thereby placing the solar cell on the bonding portion 80.

Then, the vacuum chucks 76 are released from vacuum pressure and returned to their home positions.

In the figure, the tube connecting the vacuum chucks 76 and the vacuum port 77 is omitted.

As described above, according to the present invention, the conductive film 2 is adhered to a plurality of solar cells 5 within a minimum required time for bonding in the bonding portion 80, and the ribbon 4 is pre- The waiting time for the bonding time is not required, so that the productivity can be improved.

9 is a detailed configuration diagram of the bonding unit 80. As shown in FIG.

Referring to FIG. 9, the bonding unit 80 according to the preferred embodiment of the present invention includes a guide unit 82 for supporting the substrate 80 in such a manner as to be movable up and down, and a bonding unit 82 for bonding the ribbon and the solar cell in the pre- A fixing part 83 for supporting the bonding head part 85 and fixing the upper center of the bonding head part 85 by a support shaft 84 so as to be moved laterally, And a cylinder 81 which is guided by the guide portion 82 so that the fixing portion 83 is vertically fed.

A heater is provided in the bonding head 85.

In the above structure, the bottom surface of the bonding head 85 is a flat surface which is in contact with the solar cell and the conductive film. The bottom surface of the bonding head 85 has a flat shape, and when the solar cell is transported by the transporting unit 80, If the bonding head 85 is in contact with the solar cell, the solar cell may be damaged or damaged.

In the case of using the conductive film 2, as described above, relatively low-temperature bonding is possible to prevent the damage of the solar cell 5, but it may be damaged due to the physical position of the solar cell 5 have.

In order to prevent this, the upper center of the bonding head 85 is fixed to the fixing portion 83 by the support shaft 84, and it can be tilted right and left with respect to the support shaft 84, There is a feature that the breakage of the solar cell can be prevented.

The fixing portion 83 is vertically moved by the cylinder 81. The bonding head 85 moves the fixing portion 83 downward to bond the ribbon to the solar cell, After the bonding is completed, the fixing portion 83 is moved upward, and then the solar cell to which the ribbon is bonded is unloaded to the outside by means of a robot or the like. do.

As described above, according to the present invention, it is possible to bond electrodes to a solar cell using relatively low temperature heat, thereby preventing damage to the solar cell and to stably bond the ribbon to a solar cell that is loaded in a physical non- .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And this also belongs to the present invention.

1: conductive film roll 2: conductive film
3: Release paper 4: Ribbon
5: solar cell 10: conductive film supply unit
11: Winding roll 12: First supply roller
13: second supply roller 14: separating portion
20: selective cutting portion 21: fixed frame
22: fixed guide 23: moving guide
24: lower fixing part 25: cutter
26: Upper fixing part 27:
28: Fixture 29: Through hole
40: pre-bonding section 410: bonding-
411: seating groove 412: vacuum hole
420: Vacuum picker part 421: Vacuum picker part
422: supports 423, 424: spring
425: Fixing portion 426: Spring
427: heating block 430: bonding part
440: feeder 50: ribbon feeder
60: buffer unit 70:
71: conveying guide 72: driving means
73: moving part 74: moving supporting part
75: fixing part 76: vacuum chuck
77: Vacuum port part 78: Upper and lower moving cylinder part
80: bonding portion 81: cylinder
82: guide portion 83:
84: support shaft 85: bonding head

Claims (7)

The release film 3 and the conductive film 2 are separated from each other and supplied to the conductive film 2 by supplying the conductive film 2 by unrolling the conductive film roll 1, A conductive film supply unit 10;
A selective cut portion 20 for cutting the conductive film 2 before being separated from the release paper 3 and selectively cutting only the conductive film so that the release paper can be continuously discharged after being separated from the release paper 3, );
A bonding portion 30 receiving the conductive film 2 and the solar cell 5 and bonding the conductive film 2 to the solar cell 5;
Bonding the ribbon 4 supplied from the ribbon supply part 50 to the conductive film 2 bonded to the solar cell 5 by receiving the solar cell 5 to which the conductive film 2 is bonded, A bonding section 40;
A buffer unit 60 for moving and receiving the solar cells 5 pre-bonded with the ribbon 4 in the pre-bonding unit 40; And
And a transfer unit 70 for transferring the solar cells 5 accommodated in the buffer unit 60 to a bonding unit 80 disposed in parallel with the buffer unit 60 and bonding the same to the bonding unit 80 A ribbon bonding apparatus for a solar cell,
The pre-bonding unit 40 may be,
A bonding base portion 410 where the ribbon 4 is positioned,
A vacuum picker unit 420 for sucking and conveying the ribbon 4 located in the bonding space 410 by vacuum and placing the ribbon 4 on the solar cell 5 and heating and bonding the ribbon 4,
And a bonding part 430 for providing a space through which the ribbon 4 can be bonded by the vacuum picker part 420 while the solar cell 5 is being loaded on the upper part. .
delete The method according to claim 1,
The bonding standby portion 410 may be formed of,
And a plurality of vacuum holes 412 for vacuum-absorbing the ribbons 4 that are seated in the seating grooves 411. The ribbons 412 are formed on the upper surface Device.
The method according to claim 1,
The vacuum picker part (420)
A plurality of vacuum pickers 421 that adsorb or adsorb the ribbon 4 according to the vacuum pressure transmitted through the tube 424,
A plurality of vacuum pickers 421 cushioning and supporting the plurality of vacuum pickers 421 using a spring 423 therein, a support portion 422 moved by the transfer portion 440,
A fixing portion 425 provided on the support portion 422,
The vacuum picker 421 is located at a lower portion of the support portion 422 by a spring 426 provided at the fixing portion 425. The vacuum picker 421 can vertically buffer the vacuum picker 421 while the end of the vacuum picker 421 is inserted. And a heating block (427) for bonding the ribbon (4) to the solar cell (5) by means of the heating block (427).
The method according to claim 1,
The selective cut section (20)
A fixing frame having through holes penetrating vertically so as to pass through the through holes when the release paper 3 and the conductive film 2 are attached to each other;
A fixing body positioned on a side surface of the through hole of the fixing frame and being contacted with the release paper so that cutting of the conductive film occurs smoothly;
A fixing guide provided at a position symmetrical to the fixing body with the through hole being interposed therebetween to provide a guide groove;
A moving guide capable of reciprocating linearly on the stationary guide toward the stationary member;
A lower fixing part coupled to an upper portion of the movement guide;
A cutter coupled to the lower fixing part such that the position thereof can be adjusted;
An upper fixing part for firmly fixing the cutter to the lower fixing part; And
And a gap adjusting unit coupled to a side surface of the lower fixed part of the cutter to restrict a degree of protrusion of the cutter so that only the conductive film can be selectively cut by the cutter.
The method according to claim 1,
The transfer unit
A conveying guide in which the driving means is coupled to one side;
A moving unit that linearly reciprocates in one direction along the transport guide by the driving unit;
A bar-shaped moving support portion coupled to a lower portion of the moving portion;
A fixed frame coupled to a side of the moving support portion at a position spaced apart from each other by a predetermined distance;
A vacuum chuck that is fixed to the stationary frame and sucks the solar cell pre-bonded with the ribbon to move from a pre-bonding unit side to a selected one of the plurality of bonding units;
A vacuum port portion for providing a vacuum pressure to each of the vacuum chucks; And
And a vertically moving cylinder part installed between the moving part and the moving support part to move the moving support part up and down.
The method according to claim 1,
The bonding unit may include:
A guide portion for supporting the movable member so as to be vertically movable;
A bonding head for bonding the ribbon and the solar cell in the pre-bonding state by heat and pressure;
A fixing unit that supports the bonding head unit and fixes an upper center of the bonding head unit as a support shaft so as to be able to move left and right; And
And a cylinder which is guided by the guide portion and is vertically conveyed by the fixing portion.

Images