KR101263337B1 - Laminator - Google Patents

Abstract

Laminator is disclosed. Laminator according to an embodiment of the present invention, the loader unit for supplying a solar cell module; A lamination unit having a upper case, a lower case, a diaphragm provided in an inner space of the upper case and a lower case inner space, and a heating stage unit on which the solar cell module is mounted, for laminating the solar cell module supplied from the loader unit; And an unloader unit supplied with the solar cell module to be carried out from the lamination unit, wherein the heating stage includes a plurality of heaters, the heater panel having a plurality of heating regions divided so that the area decreases from the center portion to the end portion thereof. ; At least one temperature sensor provided in each of the plurality of heating zones; And a control unit for controlling the plurality of heaters based on the measurement result of the temperature sensor, respectively.

Description

Laminator {LAMINATOR}

The present invention relates to a laminator, and more particularly, to a laminator capable of uniformly heating a solar cell module.

Fossil fuels such as liquefied natural gas and petroleum are the most used energy sources in the world. These fossil fuels have a great influence on industrialization and industrialization, but recently, research on fuels to replace them has been actively conducted due to concerns about depletion of fossil fuels and environmental pollution.

Among the alternative fuels, solar energy has the characteristics of pollution-free, indefinite, and noiseless, and thus, many studies have been conducted as alternative energy in the future, and recently, many solar cells that accumulate and use solar energy have been introduced.

In general, solar cells include crystalline solar cells using monocrystalline silicon or polycrystalline silicon, and thin-film solar cells using amorphous silicon (amorphous silicon), CIGS (copper indium gallium cesium), CdTe (cadnium tellurium), and the like.

However, crystalline and thin-film solar cells tend to cause chemical changes when the components constituting the cell are exposed to the external environment, and are also weak in physical impact.

Therefore, in general, a solar cell module in which a solar cell is laminated with a transparent film, tempered glass, heat-resistant glass, or the like is used.

The lamination of the solar cell module is performed by sandwiching the solar cell between the vinyl film or the back sheet, for example, an intermediate of the filler such as EVA (ethylene vinyl acetate) resin, and heating it in a vacuum to melt the filler inside the solar cell. .

The conventional solar cell module laminating apparatus includes an upper chamber having a diaphragm expandable downward and a lower chamber provided with a heating stage part (aka, hot plate).

Such a lining apparatus seals the upper chamber and the lower chamber and reduces the pressure to obtain a vacuum state, and then heats the solar cell module with the heating stage part, introduces an atmosphere into the diaphragm, and connects the solar cell module between the diaphragm and the upper surface of the heating stage part. Pressurize. On the other hand, a plurality of heaters are provided in the heating stage to heat the solar cell module.

However, the above-described conventional laminating apparatus has a problem in that the central portion of the heating stage portion is heated more than both ends due to the plurality of heaters installed in the heating stage portion, causing a heating deviation for the solar cell module.

In addition, there is a problem that it is difficult to uniformly heat the solar cell module when the shape and size of the solar cell module is changed.

[Document 1] KR 10-2010-0030775 A (Lead Co., Ltd.) 2010.03.19. [Document 2] KR 10-2010-0030776 A (Lead Co., Ltd.) 2010.03.19.

Therefore, the present invention is to provide a laminator capable of uniformly heating the solar cell module by actively controlling the heating stage unit.

According to an aspect of the invention, the loader unit for supplying a solar cell module; The solar cell module supplied from the loader unit is provided with an upper case, a lower case, a diaphragm provided in the inner space of the upper case, and a heating stage provided in the inner space of the lower case, in which the solar cell module is seated. A lamination unit for boiling; And an unloader unit supplied with the solar cell module carried out from the lamination unit, wherein the heating stage includes a plurality of heaters, the plurality of heaters being provided and divided into a plurality of heating zones so that the area decreases from the center portion to the end portion. One heater panel; At least one temperature sensor provided in each of the plurality of heating zones; And a controller configured to control the plurality of heaters, respectively, based on the measurement result of the temperature sensor.

Each of the plurality of heaters may be divided into a plurality of heating units, and each of the plurality of heating units may be independently controlled by the controller.

At least one heat generating unit may be provided in each of the heating regions of the heater panel.

The heater includes a rod-shaped cartridge heater, the heater comprises a hollow tube; A core inserted into the hollow tube; A first lead wire penetrating the inside of the core; And a plurality of second lead wires having one end wound on an outer circumferential surface of the core respectively corresponding to positions of the plurality of heat generating parts, and the other end connected to the first lead wire.

The plurality of heaters may be arranged parallel to each other in the longitudinal direction of the heater panel.

The heating stage unit may further include a heat conductive member filled between the heater and the heater panel.

The heating stage part may further include a pin support part that protrudes to an upper portion of the heater panel through a hole formed in the heater panel as the heater panel moves up and down, and supports a bottom surface of the solar cell module supplied from the loader unit. Can be.

The pin support portion, the pin member is installed in the height direction of the lower case from the bottom surface of the lower case; And it may include a support roller installed on the upper end of the pin member.

The lamination unit is provided between the diaphragm and the heating stage part, and is in close contact with a filler used for laminating the solar cell module when the solar cell module is pressurized to prevent the filler from being attached to the diaphragm. The prevention sheet may further include.

The lamination unit may further include a lift unit configured to vertically move the upper case on an upper portion of the lower case, wherein the lift unit is coupled to the upper case to support and lift the upper case; And it may include a drive for allowing the support member to move up and down.

Embodiments of the present invention, the solar cell module by independently controlling a plurality of heat generating parts of the heater penetrating the heater panel based on the measured temperature of each of the temperature sensor disposed in the plurality of heating area divided on the upper surface of the heater panel. Can be heated uniformly.

1 is a perspective view showing a laminator according to an embodiment of the present invention.
Figure 2 is a side view schematically showing a laminator according to an embodiment of the present invention.
3 to 4 are cross-sectional views schematically showing an upper case and a lower case according to an embodiment of the present invention.
5 is a perspective view showing a state in which the heater panel and the fin member according to an embodiment of the present invention protrudes.
6 is a schematic plan view showing a state in which a heating area is partitioned on a heater panel according to an embodiment of the present invention.
7 is a rear view showing a heater panel according to an embodiment of the present invention.
8 is a cross-sectional view schematically showing the structure of a heater according to an embodiment of the present invention.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

Hereinafter, the present invention will be described in detail with reference to the preferred embodiments of the present invention with reference to the accompanying drawings. Like reference symbols in the drawings denote like elements.

In the present invention, the solar cell module is a crystalline solar cell module using monocrystalline silicon or polycrystalline silicon, and a thin film solar cell using amorphous silicon (amorphous silicon), CIGS (copper indium gallium cesium), CdTe (cadnium tellurium), or the like. Contains modules

1 is a perspective view showing a laminator according to an embodiment of the present invention, Figure 2 is a side view schematically showing a laminator according to an embodiment of the present invention, Figure 3 to Figure 4 according to an embodiment of the present invention 5 is a cross-sectional view schematically illustrating an upper case and a lower case, and FIG. 5 is a perspective view illustrating a protruded state of a heater panel and a fin member according to an embodiment of the present invention, and FIG. 6 is a heater panel according to an embodiment of the present invention. Is a plan view schematically showing a state in which a heating zone is partitioned, FIG. 7 is a rear view showing a heater panel according to an embodiment of the present invention, and FIG. 8 schematically shows a structure of a heater according to an embodiment of the present invention. It is sectional drawing shown.

1 and 2, the laminator according to an embodiment of the present invention, the loader unit 100 for supplying the solar cell module (M), and the solar cell module (M) supplied from the loader unit 100 It includes a lamination unit 300 for laminating a, and an unloader unit 200 for receiving the solar cell module (M) to be carried out from the lamination unit 300 to cool.

The loader unit 100 serves to supply the solar cell module M to the lamination unit 300, and includes a roller conveyor for transporting the solar cell module M. The roller conveyor consists of conventional configurations for transferring the solar cell module M to the lamination unit 300.

In the loader unit 100, the solar cell module M waits. When the solar cell module M that is finished in the lamination unit 300 is taken out to the unloader unit 200, the solar cell module M waits in the loader unit 100. The solar cell module M was supplied to the lamination unit 300.

The unloader unit (UNLOADER UNIT, 200) receives the solar cell module (M) that has been processed in the lamination unit 300 and serves to cool it, and includes a roller conveyor for transporting the solar cell module (M). do.

In addition, although not shown, the unloader unit 200 may include a cooling unit (not shown) to which various cooling methods, such as a blowing fan and an air spray cooling method, may be applied to cool the transferred solar cell module (M). have. The solar cell module M cooled by the unloader unit 200 is transferred to a facility for subsequent processing through a separate conveyor.

1 to 8, the lamination unit LAMINATION UNIT 300 includes an upper case 311, a lower case 315, a diaphragm 320 provided in an inner space of the upper case 311, and a lower case ( 315 is provided in the interior space, the heating stage unit 350, the solar cell module (M) is seated, the transfer unit (not shown) for transferring the solar cell module (M), the diaphragm 320 and the heating stage unit 350 The anti-fouling sheet 330 provided between the and, and the lifting unit 340 to move the upper case 311 up and down in the upper portion of the lower case 315.

1 to 4, the upper case 311 is in close contact with the lower case 315 while moving up and down at the upper portion of the lower case 315 to form a vacuum chamber 310. The upper case 311 is moved up and down on the lower case 315 by the lifting unit 340.

At this time, the lifting unit 340 includes a support member 341, one side of which is coupled to the upper case 311 to move up and down, and a driving unit 343 to move the support member 341 up and down. The upper case 311 moves up and down according to the up and down movement of the plurality of support members 341 respectively installed on both sides, and moves up and down from the lower case 315 while maintaining a posture parallel to the lower case 315. It is composed.

The driving unit 343 may include a hydraulic cylinder (not shown). As shown in FIG. 3, when the piston rod of the hydraulic cylinder is extended, the upper case 311 rises to fall from the upper surface of the lower case 315, and thus the vacuum chamber 310 is opened. On the other hand, as shown in Figure 4, when the piston rod of the hydraulic cylinder is contracted, the upper case 311 is lowered in close contact with the upper surface of the lower case 315, the vacuum chamber 310 is in a closed state.

In addition, the transfer unit transfers the solar cell module M supplied from the loader unit 100 to an upper portion of the heating stage unit 350, in particular, the heater panel 355, which will be described later, and transfers the solar cell module M that has been laminated. It serves to transfer to the unloader unit 200. In addition, the transfer unit may be configured in a rotary conveyor method to circulate through the upper and lower portions of the lower case 315.

3 and 4, the diaphragm 320 is provided in the inner space of the upper case 311. The diaphragm 320 is mounted so that the inner space of the upper case 311 is horizontally partitioned. The space surrounded by the inner wall surface of the upper case 311 and the diaphragm 320 constitutes the upper chamber 312. In addition, a space surrounded by the inner wall surface of the lower case 315 and the heater panel 355 which will be described later constitutes the lower chamber 316.

The diaphragm 320 may be a silicon-based diaphragm, a butyl-based diaphragm, or the like. In addition, an intake and exhaust mechanism 313 is installed on the side of the upper case 311 so as to communicate with the upper chamber 312. The inside of the upper chamber 312 may be vacuum sucked through the intake and exhaust 313, or atmospheric pressure may be introduced into the upper chamber 312.

Meanwhile, the solar cell module M is pressurized by the diaphragm 320 in a state in which the heating stage 350 to be described later, specifically, the heater panel 355 is placed. In particular, the pressurization of the solar cell module M is performed in a state in which the diaphragm 320 is inflated in the vacuum chamber 310 due to the pressure difference between the upper chamber 312 and the lower chamber 316.

In this case, the pressure applied to the solar cell module M is such that the pressure caused by the expansion of the diaphragm 320 is greater than the pressure caused by the rising operation of the heating stage unit 350. That is, the pressurization by the raising operation of the heating stage unit 350 is acted auxiliary.

In addition, the heating stage 350 is provided in the inner space of the lower case 315. The heating stage unit 350 serves to heat the solar cell module M carried into the vacuum chamber 310.

3 to 8, the heating stage unit 350 includes a heater panel 355 including a plurality of heaters 360, a temperature sensor 370 disposed on the heater panel 355, and a temperature sensor. The control unit 375 controls the plurality of heaters 360 based on the measurement result of 370, and a pin support unit 380 that is mounted on the upper surface of the heater panel 355.

The solar cell module M carried into the vacuum chamber 310 is seated on the heater panel 355, and the solar cell module M is heated by a plurality of heaters 360 installed in the heater panel 355. do.

On the other hand, as shown in Figure 3, the solar cell module (M) introduced into the vacuum chamber 310 is first pin support portion 380 protruding to the upper portion of the heater panel 355 before being seated on the heater panel 355 Bottom) is supported. This is because the solar cell module M is preheated in advance and seated on the heated heat panel.

The pin support part 380 emerges through a plurality of hole parts 356 formed in the heater panel 355 as the heater panel 355 moves up and down. The pin supporting part 380 is installed in the height direction of the lower case 315 on the bottom surface of the lower case 315 and is pinned to the member 381 and the solar cell module, which emerges through the hole part 356 of the heater panel 355. And a support roller 383 provided at the upper end of the pin member 381 so as to be in contact with the bottom surface of M. As shown in FIG.

The heater panel 355 serves to heat the solar cell module (M) seated in contact with the top.

The heater panel 355 has a plurality of heaters 360 therein. In this case, each of the plurality of heaters 360 may be divided into a plurality of heating units 367, 368, and 369. Each of the plurality of heat generating units 367, 368, and 369 is independently controlled by the controller 375 to be described later.

6 to 8, in the present embodiment, the heater 360 may include a rod-shaped cartridge heater 360 penetrating the inside of the heater panel 355. In addition, the heater 360 may be arranged in parallel to be spaced apart in the longitudinal direction of the heater panel 355, but is not limited thereto and may be arranged in parallel in a width direction of the heater panel 355. .

As shown in FIG. 8, the heater 360 includes a hollow tube 361, a core 362 inserted into the hollow tube 361, and a first lead wire penetrating the interior of the core 362. 363 and a plurality of second lead wires 364,365, and 366 wound on the outer circumferential surface of the core 362 to correspond to the positions of the plurality of heat generating parts 367, 368, and 369, respectively, and connected to the first lead wires 363.

Here, the hollow tube 361 may be made of iron, brass, stainless steel, Inconel, or the like. In addition, the core 362 may be composed of sintered magneside or the like. On the other hand, a powder with high thermal conductivity is filled between the hollow tube 361 and the core 362.

For example, as shown in FIG. 8, in the present embodiment, when the heater 360 is divided to have three heat generating parts 367, 368, and 369, the first lead wire 363 may have one end inside the core 362. In the first to third heat generating portion (367, 368, 369) is arranged in a straight line to pass through the other end of the hollow tube (361). The plurality of second lead wires 364, 365, and 366 are wound around the outer circumferential surface of the core 362 corresponding to the first to third heat generating parts 367, 368, and 369, and are commonly connected to the first lead wires 363.

That is, the second lead wire 364 wound on the outer circumferential surface of the core 362 corresponding to the first heat generating part 367 has one end connected to the first lead wire 363 and the other end to the outside of the hollow tube 361. Exit In addition, one end of the second lead wire 365 wound on the outer circumferential surface of the core 362 corresponding to the second heat generating part 368 is connected to the first lead wire 363, and the other end of the second lead wire 365 is outside of the hollow tube 361. Exit In addition, one end of the second lead wire 366 wound on the outer circumferential surface of the core 362 corresponding to the third heat generating part 369 is connected to the first lead wire 363, and the other end thereof is outside the hollow tube 361. Exit

As such, a current flows through each of the first lead wires 363 and the plurality of second lead wires 364, 365, and 366 that have escaped to the outside of the hollow tube 361 to correspond to the three heat generating parts 367, 368, and 369 divided by the heater 360. Heating by the heater 360 is achieved by heating the core 362.

As such, the plurality of heat generating parts 367, 368, and 369 divided by one heater 360 may be independently controlled by the controller 375 to be described later. The controller 375 is connected to the heat generating units 367, 368, and 369 of all the heaters 360.

As shown in FIG. 7, when the plurality of heaters 360 are installed in the heater panel 355, a heat conductive member 377 having a high thermal conductivity is filled between the heater 360 and the heater panel 355. . This is to improve the thermal conductivity by eliminating the non-contact section between the heater 360 and the heater panel 355.

On the other hand, in heating the heater panel 355 using the plurality of heaters 360, in order to uniformly heat the entire heater panel 355 and to uniformly heat the entire solar cell module M, first, the heater The upper surface of the panel 355 is divided into a plurality of heating zones Z1 to Z27, and a plurality of heat generations of the heater 360 and the heater 360 arranged in the plurality of heating zones Z1 to Z27 through the control unit 375. The parts 367, 368, and 369 are controlled independently.

For example, in order to evenly heat the heater panel 355, as shown in FIG. 6, the upper surface of the heater panel 355 is divided into 27 rectangular heating zones Z1 to Z27. The 27 heating zones Z1 to Z27 decrease in area from the central portion of the heater panel 355 to both ends in the longitudinal direction of the heater panel 355. Since the central portion of the heater panel 355 is heated more than both ends due to the heat conduction by the plurality of heaters 360, the temperature difference between the central portion of the heater panel 355 and the both ends of the heater panel 355 is in an error range (eg, For example, to precise control within ± 2 ° C.

At least one temperature sensor 370 is disposed in each of the heating zones Z1 to Z27. The temperature of the heater panel 355 measured by the temperature sensor 370 is transmitted to the controller 375. Each of the heating zones Z1 to Z27 of the heater panel 355 is provided with heat generating parts 367, 368, and 369 of at least one heater 360.

In addition, information about the shape and size of the solar cell module M to be heated is input to the controller 375. For information on the shape and size of the solar cell module M, the solar cell module M is located on which heating zones Z1 to Z27 of the plurality of heating zones Z1 to Z27 of the heater panel 355. It includes information such as.

Information about the shape and size of the solar cell module (M) may be stored before the solar cell module (M) is carried in the vacuum chamber 310, but a separate input device (not shown) when heated by the heater panel 355 It may also be inputted through).

Accordingly, the controller 375 separately controls the plurality of heaters 360 and the heater heating units 367, 368, and 369 based on the measurement result transmitted from the temperature sensor 370 and the information on the shape and size of the solar cell module M. The heater panel 355 is uniformly heated by the control, and the solar cell module M having various shapes and sizes is uniformly heated. In addition, the solar cell module (M) having a variety of shapes and sizes can be manufactured using the same laminator, and because the unnecessary heater 360 does not need to be operated, the energy efficiency is improved to increase the manufacturing cost of the solar cell module (M). Can be saved.

The pollution prevention sheet 330 serves to prevent the EVA, which is a filler used for lamination, when the solar cell module M is heated and pressurized, to be attached to the diaphragm 320. When a part of the filler is contaminated by the diaphragm 320 in the process of laminating the solar cell module (M), the filler attached to the diaphragm 320 should be removed. Therefore, since the diaphragm 320 may be damaged in the process of removing the filler, a pollution prevention sheet 330 is provided between the diaphragm 320 and the heater panel 355 to prevent this.

In addition, the anti-fouling sheet 330 may be continuously supplied by the rotary conveyor 331. That is, it is configured to circulate through the upper and lower portions of the upper case 311. At this time, the pollution prevention sheet 330 may be formed in a long strip shape.

In addition, the surface of the anti-fouling sheet 330 is not easily attached to the filler in order to prevent the filler from escaping from the solar cell module (M), and excellent peelability so that the filler can be easily peeled off. It is formed of a material. For example, the antifouling sheet 330 may be a heat-resistant glass fiber fabric sheet coated with a fluorine resin, or the surface thereof may be coated with a material having excellent peelability such as fluorine resin.

Referring to the operation of the laminator according to the present invention configured as described above are as follows.

The solar cell module M is provided to the lamination unit 300 by a roller conveyor of the loader unit 100. At this time, the upper case 311 is in a state lifted to the upper portion of the lower case 315 by the lifting unit 340.

The bottom surface of the solar cell module M provided in the lamination unit 300 is supported by the fin member 381 protruding from the hole 356 of the heater panel 355.

Then, the upper case 311 is lowered to be in close contact with the lower case 315. The upper case 311 is in close contact with the lower case 315 to form a vacuum chamber 310 inside the vacuum state.

Then, the upper chamber 312 and the lower chamber 316 are vacuum suctioned at the same time through the suction ports 313 and 317. While vacuuming the upper chamber 312 and the lower chamber 316, the heater 360 is heated to preheat the solar cell module M. Preheating of the solar cell module M is started by supplying a current to the heater 360 by the operation of the control unit 375 in a state in which the solar cell module M is supported by the fin member 381.

When the preheating of the solar cell module M is completed, the heater panel 355 is raised to allow the solar cell module M to be seated on the upper surface of the heater panel 355 and further raised to contaminate the diaphragm 320. The prevention sheet 330 and the solar cell panel are in close contact.

Then, the solar cell module M mounted on the heater panel 355 is heated continuously. Heating to the solar cell module (M) is controlled by the control unit 375. By heating the solar cell module (M), a chemical reaction such as EVA resin as a filler is promoted.

The solar cell module M is heated by introducing an atmospheric pressure into the upper chamber 312 through the inlet and outlet 313 while the solar cell module M is heated, thereby expanding the diaphragm 320 downward. Press between the upper surface of the diaphragm and the diaphragm (320). Thus, laminating process of the solar cell module M is performed by heating and pressurizing in the state which pinched the solar cell module M. As shown in FIG.

On the other hand, the heating of the solar cell module (M) is performed by the control unit 375, the control unit 375 is the information on the shape and size of the solar cell module (M), the solar cell module (M) at the time of heating The position of the heating area | regions Z1-Z27 of the heater panel 355 located is grasped | ascertained beforehand. The control of the heater 360 by the controller 375 is performed based on the measurement results of the temperature sensors 370 disposed in the plurality of heating zones Z1 to Z27 of the heater panel 355.

When the measurement result of each temperature sensor 370 is input to the control unit 375, the control unit 375 extracts the temperature information of the heating zones Z1 to Z27 in which the solar cell module M is located, thereby extracting these heating zones ( It is analyzed whether the temperature of Z1 to Z27) is uniform. The controller 375 may analyze temperature information including the heating zones Z1 to Z27 where the solar cell module M is located, as well as the heating zones Z1 to Z27 around the solar cell module M. FIG.

The controller 375 individually controls the heaters 360 and the heating units 367, 368, and 369 of the heaters through the temperature analysis of the heating zones Z1 to Z27, and increases or decreases the temperature thereof to thereby increase the solar cell module ( The temperature is controlled so that temperature nonuniformity does not occur between the heating zones Z1 to Z27 where M) is located.

For example, when the temperature of the heating zones Z1 to Z27 in the center of the heater panel 355 on which the solar cell module M is mounted is higher than the temperature of the heating zones Z1 to Z27 located at both ends, the controller 375. The temperature is lowered by lowering the output of the heater 360 and the heater heating units 367, 368, and 369 disposed at the center, and at the same time increasing the output of the heater 360 and the heater heating units 367, 368, and 369 disposed at both ends, thereby raising the temperature. .

The controller 375 analyzes the temperature distribution between the plurality of heating zones Z1 to Z27 after adjusting the temperatures of the heating zones Z1 to Z27. As a result of analysis, when the temperature between the heating zones Z1 to Z27 is uniform, the temperatures of the heaters 360 and the heater heating units 367, 368, and 369 are maintained as they are, and when the temperature between the heating zones Z1 to Z27 is uneven, the heater 360 is maintained. ) And the temperature of the heater heating units 367, 368, 369 are adjusted again by increasing or decreasing.

In this way, the upper surface of the heater panel 355 is divided into a plurality of heating zones Z1 to Z27, and a temperature sensor 370 is installed in each of the heating zones Z1 to Z27, and the temperature sensor 370 By individually controlling the plurality of heaters 360 and the heater heating units 367, 368, and 369 according to the measurement result, appropriate heating zones Z1 to Z27 may be heated according to the shape and size of the solar cell module M. In addition, the heater 360 and the heater heating units 367, 368, and 369 may be individually controlled such that the temperature of the heating zones Z1 to Z27 where the solar cell module M is located is uniform.

Therefore, the solar cell module M can be uniformly heated regardless of the shape and size of the solar cell module M, thereby improving the quality of the manufactured solar cell module M, and using the same laminator device. The solar cell module M having various shapes and sizes can be laminated, and energy efficiency is improved since unnecessary heaters 360 and heater heating units 367, 368, and 369 do not need to be operated.

After the laminating process of the solar cell module M is finished, atmospheric pressure is introduced into the lower chamber 316 through the intake and exhaust mechanism 317 in the lamination unit 300. Then, the heating temperature of the heater 360 is adjusted, and the heater panel 355 is cooled to a predetermined temperature in preparation for the next laminating process. In addition, using the lifting unit 340 to lift the upper case 311 and to make the lower case 315 open.

In the state in which the lower case 315 is opened, the solar cell module M in which lamination is completed is carried out to the unloader unit 200 and then subjected to a cooling process.

As described above, the present invention is not limited to the described embodiments, and various modifications and changes can be made without departing from the spirit and scope of the present invention, which will be apparent to those skilled in the art. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

100: loader unit 200: unloader unit
300: lamination unit 311: upper case
315: lower case 320: diaphragm
330: antifouling sheet 340: elevation
350: heating stage unit 355: heater panel
360: heater 370: temperature sensor
375: control unit 377: heat conductive member
380: pin support

Claims (10)

A loader unit for supplying a solar cell module;
Laminating the solar cell module supplied from the loader unit having an upper case, a lower case, a diaphragm provided in the inner space of the upper case and a heating stage portion provided in the inner space of the lower case, on which the solar cell module is seated. Lamination unit; And
It includes an unloader unit supplied with the solar cell module carried out from the lamination unit,
The heating stage unit,
A heater panel provided with a plurality of heaters and having a plurality of heating regions;
At least one temperature sensor provided in each of the plurality of heating zones; And
A control unit for controlling the plurality of heaters based on the measurement result of the temperature sensor,
Each of the plurality of heaters is divided into a plurality of heat generating units independently controlled by the control unit,
The heater,
One end is wound around a hollow tube, a core inserted into the hollow tube, a first lead wire penetrating the inside of the core, and an outer circumferential surface of the core corresponding to positions of the plurality of heat generating parts, respectively, 1. A laminator comprising a rod-shaped cartridge heater having a plurality of second leads connected to one lead. delete The method of claim 1,
Laminator according to claim 1, wherein at least one heating unit is provided in each of the plurality of heating regions of the heater panel. delete The method of claim 1,
The plurality of heaters, the laminator, characterized in that arranged in parallel to each other in the longitudinal direction of the heater panel. The method of claim 1,
The heating stage unit,
Laminator further comprises a heat conduction member filled between the heater and the heater panel. The method of claim 1,
The heating stage unit,
And a pin support part which protrudes to an upper portion of the heater panel through a hole formed in the heater panel as the heater panel is lifted and supports a bottom surface of the solar cell module supplied from the loader unit. The method of claim 7, wherein
The pin support portion,
A pin member installed in the height direction of the lower case at the bottom surface of the lower case; And
Laminator comprising a support roller is installed on the upper end of the pin member. The method of claim 1,
The lamination unit,
It is provided between the diaphragm and the heating stage unit, the contact is in close contact with the filler used to laminate the solar cell module when pressing the solar cell module further comprises a pollution prevention sheet to prevent the filler is attached to the diaphragm. Laminator. The method of claim 1,
The lamination unit,
Further comprising a lifting unit for vertically moving the upper case in the upper portion of the lower case,
The lifting unit,
A support member coupled to the upper case to lift the upper case; And
Laminator comprising a drive for moving the support member up and down.

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