KR101122121B1 - Laminating method for manufacturing solar cell module - Google Patents

Abstract

The present invention is a vacuum (low pressure) state by sealing and decompressing an upper chamber and a lower chamber of a laminate apparatus having an upper chamber having a diaphragm expandable downward and a lower chamber having a heater panel (hot plate). In the heating method of the laminating apparatus which pressurizes a pyramidizing body between a diaphragm and the upper surface of a heater panel by heating into the said diaphragm after making it become, and a lower side thereof is flexible, A main heating means for heating the atmosphere introduced into the upper chamber forming one closed chamber together with the closing diaphragm is installed in the inlet tube for introducing the atmosphere into the upper chamber, and the pyramid is provided in the space consisting of the heater panel and the diaphragm. Disposing a nate; Heating the heater panel to heat one surface of the pyramid body; Operating the main heating means to heat one surface of the pyramid body corresponding to the inner surface of the diaphragm; And supplying air pressure into the space between the diaphragm and the main heating means to pressurize the pyramid body with the diaphragm.

Description

Laminating method for manufacturing solar cell module

The present invention relates to a laminate apparatus and a method, and more specifically, in manufacturing a thin panel-like pyramid body such as a solar cell module, no deformation of glass occurs and no disturbance of the solar cell module occurs. , And a laminate apparatus and method in which bubble defects are not generated.

The laminate apparatus according to the present invention can be variously applied to a thin laminate body of a laminate, but for the convenience of the following description, the laminate is limited to a solar cell module.

Recently, due to global environmental pollution and fossil energy depletion, development of environmentally friendly alternative energy sources and diversification of future energy sources have emerged as international issues. Under these circumstances, solar cells utilizing solar energy are attracting attention as a viable alternative energy source of the future, and as the price of solar cells decreases, the global market size is rapidly increasing.

Such solar cells may be made of monocrystalline silicon, polycrystalline silicon, or amorphous silicon, but in any case, silicon itself is susceptible to chemical changes, and is also susceptible to physical impact. Solar cell modules laminated with tempered glass or heat-resistant glass are used.

In general, the lamination method for manufacturing a solar cell module is as follows, specifically, arrange a solar cell (cell) between the glass and glass or between the glass and the back seat, the solar cell and the glass By filling an adhesive sheet, for example, an ethylene vinyl acetate (EVA) film in between, and heating under vacuum to melt the EVA film, the solar cells are also packed in series or in parallel.

Such a lamination process corresponds to a core process of a solar cell module manufacturing process, and in the related art, there is a problem in that deformation of glass occurs, solar cell alignment is disturbed, or bubbles occur during a heating process in a vacuum atmosphere.

The present invention has been made to solve the above problems, an object of the present invention is to reduce the process defects such as deformation of the glass during the lamination process, disordered solar cell alignment, bubble defects, etc. To provide a laminate apparatus and method that can improve the productivity by shortening the process time.

To achieve these and other advantages and in accordance with the purpose of the present invention,

The upper chamber and the lower chamber of the laminate apparatus having the upper chamber with the diaphragm expandable downward and the lower chamber with the heater panel (hot plate) are sealed and depressurized to be in a vacuum (low pressure) state. In the heating method of the laminating apparatus, after that, by introducing air into the diaphragm, the laminating body is pressed between the diaphragm and the upper surface of the heater panel and heated by the heater panel.

A main heating means for heating the atmosphere introduced into the upper chamber forming one closed chamber together with a diaphragm that closes its lower side is installed in the inlet pipe introducing the atmosphere into the upper chamber,

Disposing a pyramid body in a space consisting of the heater panel and a diaphragm;

Heating the heater panel to heat one surface of the pyramid body;

Operating the main heating means to heat one surface of the pyramid body corresponding to the inner surface of the diaphragm; And

And supplying air pressure to the space between the diaphragm and the main heating means to pressurize the pyramid body with the diaphragm.

According to the present invention, the difference in the heating time between the solar cell modules M can be eliminated, and the plurality of solar cell modules M can be heated to a uniform temperature, and the bubbles inside the solar cell module M due to the heating before laminating treatment can be obtained. It is possible to prevent the occurrence of, and to produce a high quality solar cell module M, which is very excellent effect.

1 is a structural diagram showing a laminate device including a conveying conveyor according to an embodiment of the present invention,
2 is a structural diagram showing only the laminating device in FIG.
3 is a plan view of FIG. 2.

Looking at the configuration of the laminate device of the present invention in detail as follows. In describing the present invention, detailed descriptions of related well-known functions or configurations are omitted in order not to obscure the subject matter of the present invention.

The term solar cell module used in the present invention refers to glass, a solar cell disposed between the glass, and an adhesive sheet disposed between the solar cell and the glass (for example, ethylene vinyl acetate (EVA) Represents a module containing).

1 is a conceptual diagram showing a laminate device according to an embodiment of the present invention.

The pyramid body is disposed in the space between the heater panel and the diaphragm, the pyramid body is the pyramid body (M) as described above, and the glass and the back sheet, or the glass and the solar cell disposed between the glass and And an adhesive sheet (eg, ethylene vinyl acetate (EVA)) disposed between the solar cell and the glass.

Here, each glass corresponds to the upper surface of the heater panel 35 and the inner surface of the diaphragm 25.

The diaphragm 25 constituting the laminate device according to an embodiment of the present invention may be a membrane, and a silicon rubber sheet or the like may be used as the membrane.

In particular, the cross-linking rate of the photovoltaic module using the membrane is preferably 70 to 90%, and the membrane corresponding to the upper surface of the heater panel 35 is preferably flexible.

The laminate apparatus according to an embodiment of the present invention may further include a plurality of lifting mechanisms 50 mounted on the heater panel 35 to lift up and down the upper surface of the heater panel.

Here, the elevating mechanism 50 adjusts the height of the upper chamber 13 to elevate so as to be spaced apart at an appropriate position, and serves to transport the laminated body M without interference.

The method of laminating the laminated body (M) using the lamination apparatus which has such a structure is demonstrated concretely through an accompanying drawing.

As shown in FIG. 1, after the laminate body M is disposed in a space consisting of the heater panel 35 and the diaphragm 25, one surface of the laminate body M is heated through the heater panel 35. do.

Here, it is important to arrange the glass of the solar cell module in close contact with the upper surface of the heater panel 35 and the inner surface of the diaphragm 25, and heat one surface of the laminate M through the heater panel 35. Before the above, the solar cell module as the laminate M may be elevated by the elevating mechanism 50 and then preheated.

Thereafter, the heating means 11 is operated to heat the laminated body M corresponding to the inner surface of the diaphragm 25.

Here, the main heating means 100 may be a silicon rubber heater, an induction heater, an infrared heater, and the like, and the silicon rubber heater and the infrared heater may be a plurality of silicon rubber heaters and infrared lamps arranged at regular intervals. .

On the other hand, the space between the heater panel 35 and the diaphragm 25 is maintained in a vacuum atmosphere using the above-described vacuum pump simultaneously with both-side heating of the laminate M.

Thus, by simultaneously heating both sides of the laminate (M), it is possible to minimize the glass deformation, to prevent the disturbance of the cell alignment of the laminate (M), and to minimize the bubble defects generated during the laminate process Can be.

In particular, hot air is distributed at the top of the membrane to directly heat the adhesive sheet, thereby compensating for the low thermal conduction rate by the heater panel, and reducing the thermal variation of the upper and lower glass of the laminate (M) to reduce glass deformation. Can be minimized.

On the other hand, at the same time as heating both sides of the laminate body M, air pressure is supplied to the upper chamber 13, which is a space between the diaphragm 25 and the heating means 11, to pressurize the laminate body M with the diaphragm 25. do.

In this case, as described above, a vacuum pump may be used, and the upper chamber 13 is preferably maintained at 0 mbar.

In addition, the preferable Example of this invention is demonstrated based on the lamination apparatus suitable for laminating process on the solar cell module M as an example of a to-be-laminated body. As shown to FIG. 1 and FIG. 2, the lamination apparatus is equipped with the lamination unit 3 provided with the laminated part inside.

The lamination apparatus is equipped with the conveyance sheet 5 which mounts three solar cell modules M, for example, carries in to the lamination unit 3, and carries out from the lamination unit 3 after lamination. On the right side of the lamination unit 3, the supply conveyor 6 which conveys the solar cell module M to which laminating process is to be performed to the lamination unit 3 direction is arrange | positioned. On the other hand, the carry-out conveyor 7 which carries out solar cell module M from the lamination unit 3 side is arrange | positioned at the left side of the lamination unit 3. And the solar cell module is conveyed sequentially in the left direction of FIG. 1, conveying in order of the supply conveyor 6, the conveyance sheet 5, and the unloading conveyor 7. As shown in FIG.

As shown in FIG. 1, the laminate unit 3 includes an upper case 10 and a lower case 12. An upper chamber 13 is formed inside the upper case 10, and a lower chamber 15 is formed inside the lower case 12.

The upper case 10 can move up and down along the elevating mechanism 50 including the piston, and can move up and down from the lower case 12 while maintaining a posture parallel to the lower case 12. It is made up.

The heating method in the laminate apparatus according to the present invention is a laminate apparatus having an upper chamber 13 having a diaphragm 25 that is expandable downward and a lower chamber having a heater panel 35 (hot plate). After sealing the upper chamber 13 and the lower chamber 15 to reduce the pressure to a vacuum (low pressure) state, air is introduced into the diaphragm 25, whereby the pyramidizing body M is connected to the diaphragm 25. In the heating method of the laminating apparatus, which is pressed between the upper surfaces of the heater panels 35 and heated by the heater panels 35, one closed chamber is provided with a diaphragm 25 that flexibly closes the lower side thereof. The main heating means 100 for heating the atmosphere introduced into the upper chamber 13 is installed in the inlet pipe 23 for introducing the atmosphere into the upper chamber 13, and thus, the heater panel 35. And diaphragm (25) Disposing a pyramid body (M) in a space consisting of; Heating the heater panel 35 to heat one surface of the pyramid body M; Heating one surface of the pyramid body (M) corresponding to the inner surface of the diaphragm through the main heating means (100); And providing air pressure to the space on the diaphragm 25 side to pressurize the pyramid body M with the diaphragm 25.

In addition, the heating means 100 disposed on the introduction pipe 23 side may be a plurality of infrared lamps, coil heaters, silicon rubber heaters, or induction heating arranged at a plurality of regular intervals.

In addition, the heater disposed on the inlet pipe 23 side is controlled to operate during the step of providing the air pressure to press the pyramid body M with the diaphragm 25.

In addition, when the main heating means 100 is stopped by the auxiliary heating means 200 in addition to the introduction pipe 23, the main heating means 100 is operated at the upper side of the upper chamber 13. In order to maintain the temperature at a constant temperature, the air in the upper chamber 13 is continuously circulated by the auxiliary air pump P1 at a set temperature along with the hourly inflow rate, together with the air in the upper chamber 13. A plurality of circulation ports 13a and 13b, to which the circulation line 210 is communicably connected, are formed, and are circulated and controlled through the circulation ports 13a and 13b.

As shown in the figure, an expandable diaphragm 25 is mounted so as to partition the inside of the upper case 10 horizontally, and the space surrounded by the inner wall of the diaphragm 25 and the upper case 10 includes an upper chamber. (13) is comprised. In addition, as shown in the figure, in the state where the upper case 10 descends and the laminate portion is sealed, the space surrounded by the inner wall surfaces of the diaphragm 25 and the lower case 12 constitutes the lower chamber 15. As the diaphragm 25, elastic materials, such as a silicon diaphragm and a butyl diaphragm, are used, for example. In addition, an intake and exhaust mechanism 26 is formed on the upper surface of the upper case 10 so as to communicate with the upper chamber 13.

The vacuum pump 28 is connected to the intake / discharge mechanism 26 via the valve 27, and the tank 31 is connected via the valve 30. It is comprised so that the inside of the upper chamber 13 may be vacuum-sucked by the vacuum pump 28, and air may be introduce | transduced into the upper chamber 13 from the tank part 31. FIG.

In the side surface of the tank part 31, the air supply port 32 for introducing external air into the tank part 31 is opened. In addition, the tank 31 is connected to the heater 34 via a valve 33. The heater 34 is comprised, for example with a hot air fan.

When the valve 33 is opened, the air in the tank portion 31 is circulated to the heater 34, and the air heated by the heater 34 is stored in the tank portion 31.

The heater panel 35 is disposed inside the lower case 12. This heater panel 35 has a structure in which a heater (not shown) is provided inside an aluminum metal plate, for example. In addition, an inlet and outlet mechanism 37 is formed on the lower surface of the lower case 12 so as to communicate with the lower chamber 15, and a vacuum pump 39 can communicate with the inlet and outlet mechanism 37 via a valve 38. Is connected. The vacuum pump 39 is configured to vacuum the inside of the lower chamber 15 and to introduce air into the lower chamber 15 from the intake and exhaust mechanism 37.

As shown in the figure, the upper chamber 10 is lowered to be in close contact with the upper surface of the lower case 12, and in a state where the laminate part is sealed, the internal pressure of the upper chamber 10 is greater than the internal pressure of the lower chamber 15. When the internal pressure difference is generated, the diaphragm 25 is expanded, and the laminated body M is pressurized to the heater panel 35 side, and is comprised so that a pressure may be received.

As shown in the figure, the support part 51 of the lifting mechanism 50 which moves up and down to the solar cell module M via the conveyance sheet 5 is provided in the upper surface of the heater panel 35 so that it can move up and down. The lifting mechanism 50 is configured to move the upper chamber 13 up and down.

The solar cell module M after laminating process is carried out on the carrying-out conveyor 7 arrange | positioned at the left side of the laminated part in FIG. 1 by operation of the conveying sheet 5 and the carrying-out conveyor 7. And the solar cell module M is moved from the carrying-out conveyor 7 by means, such as a robot which is not shown in figure, and is conveyed to the next process. And the solar cell module M which lamination process is completed in this way may be carried out on the carrying-out conveyor 7, and the solar cell module M which carries out lamination may be carried in to a lamination part.

Herein, the air in the upper chamber 13 is continuously maintained by the sub-heating means 200 so that the air temperature in the heater 35 and the upper chamber 13 in the lower chamber 15 is maintained. By reducing the deviation, it is possible to make a reliable product with minimum defects such as cell breakage.

According to the above embodiment, since the air heated in the introduction pipe 23 side through the main heating means 100 is introduced into the upper chamber 13, when the solar cell module M is pressurized, It will not cool. Therefore, a temperature difference does not generate | occur | produce inside the solar cell module M, and the product of stable quality can be obtained. In addition, by preventing the cooling of the solar cell module M, the temperature can be quickly increased to a reaction temperature such as an EVA resin as a filler. Therefore, laminating processing time can be shortened and manufacturing efficiency improves. In addition, since the temperature of the air introduced into the upper chamber 13 can be made constant regardless of the season, laminating conditions are constant in winter and summer, and the product quality is stabilized.

In addition, when the solar cell module M is carried in the laminate part, since the solar cell module M mounted on the conveyance sheet 5 is lifted upward and spaced apart from the heater panel 35, the solar cell module M is carried in. Until this is completed, the solar cell module M can be prevented from being heated in the heater panel 35 of the laminate portion. For example, when the plurality of solar cell modules M are treated in the laminate portion, the difference in heating time between the solar cell module M carried in the laminate portion first and the solar cell module M carried in the laminate portion later is eliminated. Solar cell modules M can be heated to a uniform temperature. In addition, it is possible to prevent generation of air bubbles inside the solar cell module M due to heating before the laminating treatment, and to produce a high quality solar cell module M.

Preferred embodiments of the present invention described above are disclosed for purposes of illustration, and those skilled in the art having various ordinary knowledge of the present invention may make various modifications, changes, and additions within the spirit and scope of the present invention. And additions should be considered to be within the scope of the following claims.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but it will be apparent to those skilled in the art that various modifications are possible without departing from the scope of the present invention.

In the above description with reference to the accompanying drawings, the present invention has been described with reference to specific shapes and directions, but the present invention may be variously modified and changed by those skilled in the art, and such modifications and changes are included in the scope of the present invention. Should be interpreted as

3: laminate unit 13: upper chamber
15: lower chamber 25: diaphragm
35: heater panel M: py laminated body
100: main heating means 200: auxiliary heating means

Claims (4)

The upper chamber and the lower chamber of the laminate apparatus having the upper chamber with the diaphragm expandable downward and the lower chamber with the heater panel (hot plate) are sealed and depressurized to be in a vacuum (low pressure) state. In the heating method of the laminating apparatus, after that, by introducing air into the diaphragm, the laminating body is pressed between the diaphragm and the upper surface of the heater panel and heated by the heater panel.
The main heating means for heating the atmosphere introduced into the upper chamber constituting one closed chamber together with the diaphragm to close the lower side of the upper chamber is installed in the introduction tube for introducing the atmosphere into the upper chamber,
Disposing a pyramid body in a space consisting of the heater panel and a diaphragm;
Heating the heater panel to heat one surface of the pyramid body;
Operating the main heating means to heat one surface of the pyramid body corresponding to the inner surface of the diaphragm; And
Pressurizing the pyramid body with a diaphragm by providing air pressure into the space between the diaphragm and the main heating means,
In addition to the air in the upper chamber above the upper chamber, in order to be able to maintain a constant temperature rising state when the main heating means when the main heating means is stopped by auxiliary heating means other than the introduction tube. At a set temperature, a plurality of circulation ports are formed so that a circulation line is communicatively connected so that air in the upper chamber is continually circulated by the auxiliary air pump in accordance with the inflow rate per hour, thereby allowing the circulation control through the circulation holes. A heating method for a laminate device, characterized in that.
The method of claim 1,
The main heating means disposed in the introduction tube is a heating method of the laminate device, characterized in that selected from a plurality of infrared lamps or coil heaters, silicon rubber heater, induction heating heater arranged at a plurality of regular intervals.
The method according to claim 1 or 2,
And a main heating means arranged in said introduction tube is controlled to operate during the step of providing air pressure to pressurize the pyramid body with a diaphragm.
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