KR20120121760A - Laminater for solar cell module - Google Patents

Abstract

PURPOSE: A laminator for a solar cell module is provided to improve productivity since manufacturing time reduces by increasing the number of solar cell modules. CONSTITUTION: A lower chamber(100) is fixed in a supporting frame. An upper chamber(200) is installed at an upper side of each lower chamber to be mobile to the top and bottom. A vacuum pressure generation system forms the vacuum pressure in the upper chamber. The vacuum pressure generation system forms vacuum pressure in each lower chamber. Upper and lower driving parts(400) drive the upper chamber to the top and bottom.

Description

Solar Module Laminator {LAMINATER FOR SOLAR CELL MODULE}

The present invention relates to a solar cell module, and more particularly, to a solar cell module laminator for modularizing by applying heat to a plurality of solar cell modules.

A solar cell is a device that converts light energy of sunlight into electrical energy.

The solar cell is generally manufactured as a solar cell module by heating a plurality of solar cell elements by laminating a thermosetting resin and a back sheet after the device manufacturing step by a semiconductor process or the like.

Meanwhile, solar cells are in the spotlight as alternative energy sources due to the depletion of fossil fuels, which are represented by petroleum, and the demand is rapidly increasing.

Therefore, development of a solar cell manufacturing apparatus for mass production of solar cells is urgently needed, and a laminator for manufacturing a solar cell module needs to be developed.

However, the conventional solar cell module laminator has a problem that is not suitable for mass production of solar cell modules.

The object of the present invention devised in view of the above point is to increase the number of solar cell modules that can be produced at the same time by stacking the multi-liner used as one of the equipment in the manufacturing process of the solar cell module at the same time It is to provide a solar cell module laminator that can improve the productivity of the solar cell module by reducing the time required to manufacture the solar cell module.

Solar cell module laminator for achieving the object of the present invention as described above, the support frame; A plurality of lower chambers spaced apart in a height direction of the support frame and fixed to the support frame; A plurality of upper chambers installed on the upper side of each of the lower chambers to enable vertical movement; A vacuum pressure generating device for forming a vacuum pressure in the lower chamber and the upper chamber; It characterized in that it comprises a vertical drive for driving the upper chamber up and down.

Here, the vacuum pressure generating device may be composed of an exhaust pipe connected to one side of the lower chamber, and a vacuum pump communicating with the exhaust pipe to exhaust the air inside the lower chamber and the upper chamber to the outside.

The lower chamber and the upper chamber may be disposed in an inner space of the housing, and the exhaust pipe may communicate with an inner space of the housing, respectively, and the vacuum pump may be provided at one side of the housing.

In addition, one side of the exhaust pipe may be provided with a suction pipe for sucking external air into the lower chamber and the upper chamber.

In addition, the exhaust pipe and the suction pipe may be provided with a check valve for selectively opening and closing the exhaust pipe and the suction pipe.

In addition, the up and down drive unit may be configured with a plurality of lifting units connected to each of the upper chamber to drive up and down so that the upper chamber is in close contact with and separately from each of the lower chamber.

In addition, the elevating unit may be composed of a cylinder fixed to one side of the lower chamber, and a pneumatic cylinder consisting of a piston fixed to one side of the upper chamber to be pulled out.

The upper and lower driving parts may include a connecting member connected to each of the upper chambers, and a lifting unit configured to vertically drive the connecting members so that the upper chamber is in close contact with and spaced apart from each of the lower chambers.

In addition, the elevating unit may be composed of a cylinder fixed to one side of the lower chamber and a pneumatic cylinder consisting of a piston fixed to one side of the connecting member is provided to be pulled out.

In addition, one side of the housing may be provided with a supply carrying unit for supplying the solar cell module to the lower chamber or to carry out the solar cell module from the lower chamber.

The supply carrying unit may include a seating member on which the solar cell module is seated, a support frame for supporting the seating member at a predetermined height, and the seating member with respect to the support frame at the same height as each upper chamber. And driving means for driving the mounting member to move up and down to be positioned at the lower side, and a transmission means for supplying the solar cell module seated on the seating member to the lower chamber or to carry out the solar cell module seated at the lower chamber. have.

In addition, the transmission means may be composed of a plurality of rollers provided on both sides of the seating member so that the seating member is deployed toward the lower chamber with respect to the support frame, and a drive motor for rotating the roller.

As described above, the solar cell module laminator according to the present invention increases the number of solar cell modules that can be produced at the same time by stacking multiple layers of the laminator used as one of the manufacturing processes of the solar cell module. By shortening the time required for the manufacture of the solar cell module has the effect of improving the productivity.

1 is a side view showing the overall structure of a solar cell module laminator according to an embodiment of the present invention,
Figure 2 is a side view showing the overall structure of the solar cell module laminator according to another embodiment of the present invention,
3 is a cross-sectional view showing the structure of a pair of upper chamber and the lower chamber in the solar cell module laminator of FIGS.
4 is a cross-sectional view illustrating a structure in which an upper chamber and a lower chamber of the solar cell module laminator of FIGS. 1 and 2 are combined;
FIG. 5 is a schematic diagram schematically showing the structure of the oven-type reliners of FIGS. 1 and 2;
6 is an enlarged view showing an enlarged structure of a close contact means of the solar cell module laminator according to an embodiment of the present invention,
7A and 7B are operation diagrams sequentially showing a process in which the contact means of FIG. 6 operates,
8 is a front view showing the structure of the lift assembly of the solar cell module laminator according to an embodiment of the present invention,
9 is a side view showing the structure of a lift assembly of a solar cell module laminator according to an embodiment of the present invention,
10A, 10B, and 10C are operation diagrams sequentially illustrating a process in which the lift assembly of the solar cell module laminator according to an embodiment of the present invention operates.

Hereinafter, the solar cell module laminator according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a side view showing the overall structure of a solar cell module laminator according to an embodiment of the present invention, Figure 2 is a side view showing the overall structure of a solar cell module laminator according to another embodiment of the present invention, Figure 3 1 is a cross-sectional view showing the structure of a pair of the upper chamber and the lower chamber in the solar cell module laminator of Figure 1, Figure 4 is a combination of the upper chamber and the lower chamber of the solar cell module laminator of Figures 1 and 2 Figure 5 is a cross-sectional view showing the structure, Figure 5 is a schematic diagram schematically showing the structure of the oven type laminator of Figure 1 and Figure 2, Figure 6 is a structure of the contact means of the solar cell module laminator according to an embodiment of the present invention 7A and 7B are enlarged views illustrating an operation of the contact means of FIG. 6 in sequence, and FIG. 8 is a solar cell according to an embodiment of the present invention. 9 is a front view showing the structure of the lift assembly of the laminator, Figure 9 is a side view showing the structure of the lift assembly of the solar cell module laminator according to an embodiment of the present invention, Figure 10a, Figure 10b, Figure 10c of the present invention FIG. 1 is an operation diagram sequentially illustrating a process of operating a lift assembly of a solar cell module laminator according to an embodiment. FIG.

As shown in these drawings, the solar cell module laminator according to an embodiment of the present invention is spaced apart along the height direction of the support frame 1 and the support frame 1 is fixed to the support frame 1 Vacuum pressure is applied to the plurality of lower chambers 100, the plurality of upper chambers 200, and the lower chambers 100 and the upper chambers 200, which are installed to be able to move up and down above the lower chambers 100, respectively. It is configured to include a vacuum pressure generating device 300 to be formed, and a vertical drive unit 400 for driving the upper chamber 200 up and down.

As shown in Figures 1 to 5, the lower chamber 100 is a member that seats the solar cell module M to be laminated is possible in various configurations, the heater 110 and the heater for heating the solar cell module, Lift assembly to selectively drive up and down to support the protective film 120 and the solar cell module (M) supplied into the lower chamber 100 to prevent foreign matter is attached to the upper surface of the (110) 800 and the like are installed.

The upper chamber 200 is provided on the upper side of the lower chamber 100 so as to be selectively contacted and detached from the lower chamber 100, and can be lifted up and down, in close contact with the lower chamber 100 to lyin the solar cell module. Various configurations are possible as the configuration for forming the processing space.

The diaphragm 210 for pressurizing the solar cell module toward the heater 110 is installed in the processing space of the upper chamber 200, and the surface of the diaphragm 210 is provided on the bottom surface of the diaphragm 210. It may be provided with a separate protective film 220 to protect the.

The protective films 120 and 220 provided in the lower chamber 100 and the upper chamber 200 may be made of any material as long as the material is resistant to high heat for the laminating process without damaging the solar cell module (M).

The vacuum generator 300 is connected to one side of the lower chamber 100 and the upper chamber 200, the exhaust pipe 310 and the exhaust pipe 310 in communication with the lower chamber 100 and the upper chamber 200 It may be composed of a vacuum pump 320 for exhausting air to the outside.

In addition, the lower chamber 100 and the upper chamber 200 are disposed in the interior space of the housing 500, and the exhaust pipe 310 communicates with the interior space of the housing 500, respectively, and the vacuum pump 320 is the housing 310. It may be provided on one side of.

One side of the exhaust pipe 310 is a separate to suck the outside air into the lower chamber 100 and the upper chamber 200 to release the vacuum pressure formed in the lower chamber 100 and the upper chamber 200 It is preferable that the suction pipe 330 is provided.

The suction pipe 330 may be provided at one side of the exhaust pipe 310, but is directly connected to the lower chamber 100 and the upper chamber 200 to be used to release the vacuum pressure inside the lower chamber 100 and the upper chamber 200. It may be.

In addition, the exhaust pipe 310 and the suction pipe 330 are provided with an exhaust pipe 310 and the suction pipe 330 to effectively form a vacuum pressure in the lower chamber 100 and the upper chamber 200 or to release the vacuum pressure effectively. It is effective to provide check valves 341 and 342 for opening and closing, respectively.

The vertical driving unit 400 is connected to each upper chamber 200, and the upper chamber 200 is composed of a plurality of lifting units 410 which are vertically driven so as to be in close contact with and spaced apart from each lower chamber 100. The lifting unit 410 may have any configuration as long as it can lift the upper chamber 200.

The elevating unit 410 in one embodiment of the present invention is provided with a cylinder 411 fixed to one side of the lower chamber 100 and a drawer in and out of the cylinder 411 and on one side of the upper chamber 200. It may be composed of a pneumatic cylinder 410 consisting of a fixed piston (412).

As shown in FIG. 2, the upper and lower driving units 400 may include a connection member 420 connected to each upper chamber 200, and a connection member such that the upper chamber 200 is in close contact with and spaced apart from each lower chamber 100. It may be configured as a lifting unit 430 for driving the up and down 420, and the lifting unit 420 may be any configuration as long as the configuration can raise and lower the upper chamber 200.

Lifting unit 430 in another embodiment of the present invention is provided with a cylinder 431 fixed to one side of the lower chamber 100, the cylinder 431 is retractable to one side of the connecting member 420 It may be composed of a pneumatic cylinder 430 composed of a fixed piston 432.

On the other hand, one side of the housing 500 is provided with a supply carrying unit 600 for supplying the solar cell module (M) to the lower chamber 100 or to carry out the solar cell module (M) from the lower chamber (100). desirable.

The supply carrying unit 600 may be provided on both sides of the housing 500 along the movement path of the solar cell module M, and may be provided to play a supplying role and a carrying out role, respectively. In order to reduce the space occupied at the same time and to reduce the cost of manufacturing equipment, the supply role and the export role of the solar cell module (M) is supposed to be performed in the supply and export unit 600.

The supply carrying unit 600 includes a seating member 610 on which the solar cell module M is mounted, a support frame 620 for supporting the seating member 600 at a predetermined height, and a support frame 620. Driving means (not shown) for driving the mounting member 610 up and down so as to position the seating member 610 at the same height as each lower chamber 100, and the solar cell module seated on the seating member 610 It may be configured to include a transmission means (640) for supplying (M) to the lower chamber 100 or to carry out the solar cell module (M) seated on the lower chamber (100).

On one side of the support frame 620 is a guide rail 630 for guiding the ascending and descending path while holding the support frame 620 so that the seating member 610 prevents the flow occurs during the elevating operation It may be provided.

The transmission means 640 may include a plurality of rollers provided at both sides of the seating member 610 so that the seating member 610 may be deployed toward the lower chamber 100 with respect to the support frame 620, and the outer peripheral surface of the plurality of rollers. It may be made of a wound belt and a drive motor for rotating the roller.

On the other hand, the contact means 700 may be provided on one side of the diaphragm 210 and the frame member 230 to closely contact the frame member 230 to the diaphragm 210.

As shown in FIG. 6, the contact means 700 includes a protruding member 710 protrudingly attached to the circumferential surface of the diaphragm 210, and a rotation lever 720 hinged to one side of the protruding member 710. , The ring member 730 rotatably coupled to the pivoting lever 720 at a position spaced a predetermined distance from the pivoting central axis 721 of the pivoting lever 720, and the frame member at a position corresponding to the protruding member 710. It is formed to protrude on the peripheral surface may be configured to include a locking member 740 is fastened to the ring member 730.

Protruding member 710 is a plate-like member that is fixedly coupled to the circumferential surface of the diaphragm 210, the central surface of the plate is formed so as to project the pivoting lever 720 is rotatably coupled.

The pivoting lever 720 is pivotally coupled to the central region of the protruding protruding member 710 so that the ring member 730 is caught by the locking member 740 so that the frame member 230 is in close contact with the diaphragm 210. It plays a role.

A rotation shaft 731 to which the ring member 730 is fixedly coupled may be provided at a position spaced a predetermined distance from the rotation center axis of the rotation lever 720 rotatably coupled to the protruding member 710.

In the state where the rotation lever 720 is erected by hooking the hook member 730 to the locking member 740 so that the frame member 230 can keep the state in close contact with the diaphragm 210 side, the rotation shaft 731 is the rotation lever ( It is preferably arranged at least on the same line as the pivotal center axis of 720.

In addition, the pivoting lever 720 is bent at a central portion thereof so that the frame member 230 can be easily released from the diaphragm 210 so that the frame member 230 is in close contact with the diaphragm 210. Can be placed upright.

The ring member 730 is inserted into the insertion hole of the rotation shaft 731, the end of which is rotatably coupled to the rotation lever 720 so that the length can be varied, and the ring member 730 at the end inserted into the insertion hole. The fastening screw 732 is coupled so that the state can be inserted into the rotating shaft 731.

This adjusts the length of the ring member 730 according to the thickness of the protective film 220 to protect the surface of the diaphragm 210 so that the frame member 230 is crimped with a force greater than or equal to the set value of the protective film 220 This is to prevent sagging down when broken.

The catching member 740 is fixedly coupled to the side of the frame member 230 at a position corresponding to the protruding member 710 to serve to catch the ring member 730, the end of the catching member 740 is a ring member ( 730 is bent downward to prevent inadvertent departure.

The close contact means 700 having the configuration as described above is the diaphragm 210 and the frame member 230 so that the contact force is uniformly distributed without being eccentric to one side when the frame member 230 is in close contact with the diaphragm 210. It is more effective to be provided in plural in positions opposed to each other along the circumferential direction of.

As shown in FIGS. 8 and 9, the lift assembly 800 is lifted in conjunction with a lift member 810 provided to be movable along a height direction of the lower chamber 100 and one side of the lift member 810. Drive to move the interlocking member 820 along the longitudinal direction of the lower chamber 100, the interlocking member 820 is provided to be movable along the longitudinal direction of the lower chamber 100 to raise and lower the member 810 Means 830 may be included.

The lift member 810 includes a plate-shaped lift plate 811, a lift pin 812 protruding along the height direction of the lift plate 811, and provided on an upper surface of the lift plate 811, and the lift plate 811. The lower surface may be provided as a plate-like driven member 813 provided on both sides and interlocked with the interlocking member 820.

The lift plate 811 is provided to be movable only along the height direction of the lower chamber 100, and a lift pin 812 protrudes from an upper surface thereof.

The lift pin 812 may protrude to a position higher than the height of the heater 110 provided in the lower chamber 100 when the lift plate 811 is elevated upward along the height direction of the lower chamber 100. It should be formed to have a length.

The plate-shaped driven member 813 protrudes from both sides of the lower surface of the lift plate 811, and the interlocking hole 813 is formed through the plate surface of the driven member 813.

In addition, a separate stopper 840 in contact with one side of the driven member 813 is preferably provided to prevent the driven member 813 from flowing along the longitudinal direction of the lower chamber 100.

The interlocking hole 813a is formed to be inclined downward to allow the lift pin 812 to move up and down when the interlocking member 820 moves forward. On the contrary, the lift pin 812 is raised and lowered when the interlocking member 820 moves backward. In order to drive, it must be formed to be inclined upwardly.

The interlocking member 820 is interlocked with the interlocking plate 821 moving along the longitudinal direction of the lower chamber 100 by the driving means 830 and the interlocking plate 821 so as to protrude along the width direction of the interlocking plate 821. It may be provided with an interlocking protrusion 822 is inserted into the interlocking hole (813a).

The diameter of the interlocking protrusion 822 inserted into the interlocking hole 813a is preferably formed to have a diameter substantially equal to the width of the interlocking hole 813a so that play does not occur, and the interlocking protrusion 822 is interlocking hole 813a. The width of the interlocking plate 821 is preferably formed to be substantially the same as the width of the lift plate 811 so as not to deviate from.

One side of the interlocking plate 821 is provided with a ring member 821a with a thread formed on its inner surface, and the driving means 830 has a rotating shaft 831 inserted into the ring member 821a with a thread formed on its outer surface. One drive motor 830 may be configured.

The driving means 830 may be any configuration as long as it can move the interlocking plate 821 along the longitudinal direction of the lower chamber 100. Thus, the driving means 830 can draw in and out of the cylinder 832 and the cylinder 832. If provided, it may be configured by a pneumatic cylinder 830 consisting of a piston 833, the end of which is fixedly coupled to the interlocking plate 821.

The operation of the solar cell module laminator according to an embodiment of the present invention configured as described above is as follows.

In the state where the upper chamber 200 is spaced apart from the lower chamber 100, the check valve 342 installed in the intake pipe 330 is locked, and the check valve 341 installed in the exhaust pipe 310 is opened to the vacuum pump 320. A vacuum pressure is formed in the upper chamber 200 so that the diaphragm 210 comes into close contact with the upper surface side of the upper chamber 200.

When the solar cell module M to be laminated is seated on the seating member 610 of the supply carrying unit 600, the height of the seating member 610 is lowered by a driving means (not shown) of the supply carrying unit 600. It is disposed equal to the height of the chamber 100.

When the height of the lower chamber 100 and the height of the seating member 610 are the same, the driving motor of the transmission means 640 is operated to rotate the roller so that the seating member 610 on which the solar cell module M is seated is lowered. The chamber 100 is deployed toward the inside of the lower chamber 100.

Thereafter, the lift assembly 800 rises along the height direction of the lower chamber 100 to support the solar cell module M to a predetermined height, and in this state, a seating member positioned inside the lower chamber 100 ( 610 will return to its original position.

When the seating member 610 returns to its original position, the lift assembly 800 lowers the supporting solar cell module M into the lower chamber 100, and the film to be laminated is the solar cell module M. The upper chamber 200 is in close contact with the lower chamber 100 at the same time.

When the lower chamber 100 and the upper chamber 200 are in close contact with each other, the check valve 341 of the exhaust pipe 310 is locked and the check valve 342 of the suction pipe 330 is opened to the upper chamber 200 through the suction pipe 330. Since the outside air is introduced and the vacuum pressure is released, the diaphragm 210 presses the solar cell module M toward the heater 110.

At the same time, the check valve 341 of the exhaust pipe 310 connected to the lower chamber 100 is opened, and the check valve 342 of the suction pipe 330 is locked so that the air inside the lower chamber 100 is transferred to the vacuum pump 320. Since the vacuum pressure is formed in the lower chamber 100 by exhausting, the diaphragm 210 further pressurizes the solar cell module M toward the heater 110 so that the film is heated to the solar cell module M by the heat of the heater 110. Laminated.

When the lamination of the film is completed, the check valve 342 installed in the suction pipe 330 is locked, and the check valve 341 installed in the exhaust pipe 310 is opened to exhaust the air inside the upper chamber 200 by the vacuum pump 320. After the vacuum pressure is formed to move the diaphragm 210 holding the solar cell module (M) to the upper surface of the upper chamber 200, and in the same manner to release the vacuum pressure formed in the lower chamber 100, The upper chamber 200 is separated from the lower chamber 100.

Thereafter, the laminated solar cell module M is carried out to the outside of the lower chamber 100 by the same method as described above by the supply carrying unit 600 and transferred to the subsequent process, thereby completing the laminating process.

Here, look at the method of bringing the protective film for protecting the surface of the diaphragm close to the diaphragm as follows.

As shown in FIG. 7A, the protective film 220 is disposed between the diaphragm 210 and the frame member 230, and when the protective film 220 and the diaphragm 210 overlap each other, the frame member 230 is disposed. ) Is in contact with the lower surface of the diaphragm (210).

As shown in FIG. 7B, when the frame member 230 is in contact with the diaphragm 210, the hook member 730 is fastened to the locking member 740, and the pivoting lever 720 is moved in the lateral direction of the diaphragm 210. When the rotating member 730 is fixed to the rotating shaft 731 and the rotation center axis of the pivoting lever 720 is arranged on the same line while the frame member 230 is in close contact with the diaphragm 210 even if As shown in 7c, the protective film 220 is in a state capable of protecting the lower surface of the diaphragm 210.

The method of detaching the frame member 230 in close contact with the diaphragm 210 in order to replace the protective film 220 is to rotate the rotation lever 720 in a state where the lower chamber 100 and the upper chamber 200 are in close contact. The ring member 730 is separated from the locking member 740 so that the frame member 230 is seated on the upper side of the lower chamber 100.

Thereafter, when the upper chamber 200 is lifted from the lower chamber 100, the protective film 220 is exposed to the upper side of the frame member 230 seated on the upper side of the lower chamber 100, and the protective film 220 is exposed. Remove and replace the new protective film 220 and then lower the upper chamber 200 in contact with the lower chamber 100.

When the lower chamber 100 and the upper chamber 200 are in contact with each other, the hook member 730 is hooked to the locking member 740 and the pivoting lever 720 is rotated to the side of the diaphragm 210. The rotating shaft 731 fixedly coupled and the pivot center axis of the pivot lever 720 are arranged on the same line, and the frame member 230 is kept in close contact with the diaphragm 210 to complete the replacement of the protective film 220. do.

In addition, the method of supporting the solar cell module (M) at the time of drawing out using the lift assembly of the solar cell module laminator in detail as follows.

As shown in FIG. 10A, when the solar cell module M mounted on the seating member 610 of the supply carrying unit 600 is introduced into the lower chamber 100, the driving motor 830 is driven to drive the screw thread. The formed rotating shaft 831 is rotated.

As the ring member 821a which is screwed to the rotating shaft 831 is moved forward by the rotation of the rotating shaft 831, the interlocking plate 821 fixedly coupled to the ring member 821a moves forward.

As the interlocking plate 821 moves forward on both sides of the interlocking plate 821 and the interlocking protrusion 822 inserted into the interlocking hole 813a moves along the inclined surface of the interlocking hole 813a, the driven member 813 and the lift plate 811 move upwards to lift the lift pin 812 to lift the solar cell module M mounted on the seating member 610 as shown in FIG. 10B.

When the solar cell module M is lifted by the lift pin 812, the seating member 610 is drawn out of the lower chamber 100, and when the withdrawal of the seating member 610 is completed, the above-described process is performed in the reverse order. While the solar cell module (M) is seated on the upper surface of the heater 110, the solar cell module (M) is drawn into the lower chamber (100).

In addition, the process of drawing out the solar cell module M to the outside of the lower chamber 100 may be performed in the reverse order, and detailed description thereof will be omitted.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

100: lower chamber 200: upper chamber
300: vacuum pressure generating device 400: up and down drive unit
500: housing 600: supply carrying unit
700: lift assembly 800: contact means

Claims (12)

A support frame;
A plurality of lower chambers spaced apart in a height direction of the support frame and fixed to the support frame;
A plurality of upper chambers installed on the upper side of each of the lower chambers to enable vertical movement;
A vacuum pressure generating device for forming a vacuum pressure in the lower chamber and the upper chamber;
The solar cell module laminator comprising a vertical drive unit for driving the upper chamber up and down. The method according to claim 1,
The vacuum pressure generating device is a solar cell module comprising a exhaust pipe connected to one side of the lower chamber and the upper chamber, respectively, and a vacuum pump communicating with the exhaust pipe to exhaust the air inside the lower chamber and the upper chamber to the outside. Laminator. The method according to claim 2,
The lower chamber and the upper chamber is disposed in the inner space of the housing and the exhaust pipe is in communication with the inner space of the housing, respectively, the vacuum pump module laminator, characterized in that provided on one side of the housing. The method according to claim 3,
One side of the exhaust pipe is a solar cell module laminator, characterized in that the suction pipe for sucking the outside air into the lower chamber and the upper chamber. The method of claim 4,
The exhaust pipe and the suction pipe is a solar cell module laminator, characterized in that provided with a check valve for selectively opening and closing the exhaust pipe and the suction pipe. The method according to claim 1,
The vertical driving unit is connected to each of the upper chamber solar cell module laminator, characterized in that the plurality of lifting unit for driving up and down so that the upper chamber is in close contact with and separately from each of the lower chamber. The method of claim 6,
The elevating unit is a solar cell module laminator, characterized in that the pneumatic cylinder consisting of a cylinder fixed to one side of the lower chamber, and the drawer is retractable to the cylinder and fixed to one side of the upper chamber. The method according to claim 1,
The vertical driving unit is a solar cell module laminator comprising a connecting member connected to each of the upper chamber, and the elevating unit for driving the connecting member up and down so that the upper chamber is in close contact with the lower chamber as a whole. The method according to claim 8,
The elevating unit is a solar cell module laminator, characterized in that the pneumatic cylinder consisting of a cylinder fixed to one side of the lower chamber and a piston fixed to one side of the connecting member is provided to be pulled out. The method according to claim 3,
One side of the housing is a solar cell module laminator, characterized in that the supply chamber unit for supplying the solar cell module to the lower chamber or to carry out the solar cell module from the lower chamber. The method of claim 10,
The supply carrying unit may include a seating member on which the solar cell module is seated, a support frame for supporting the seating member at a predetermined height, and the seating member with respect to the support frame at the same height as each lower chamber. And driving means for driving the mounting member to move up and down, and transmission means for supplying the solar cell module seated on the seating member to the lower chamber or to carry out the solar cell module seated on the lower chamber. Solar Module Laminator. The method of claim 11,
The transmission means comprises a plurality of rollers provided on both sides of the seating member such that the seating member is deployed toward the lower chamber with respect to the support frame, and a drive motor for rotating the roller. .

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