KR101037437B1 - Polaroid film cutting apparatus using laser - Google Patents

Abstract

The present invention relates to a polarizing film (POL) cutting device using a laser, the process of releasing and supplying the roll polarizing film in the roll state and the process of cutting the supplied polarizing film into a polarizing plate of a certain size and a polarizing plate cut to a certain size The purpose of the present invention is to automate the cutting of the polarizing film through a device structure capable of continuously performing a series of discharge and alignment processes. The present invention configured for this purpose is a polarizing film cutting device for cutting to a certain size in the middle of continuously unrolling and supplying a roll polarizing film wound in a roll state, the polarizing film cutting device is continuously supported by rotatable roll polarizing film A winder unit to allow supply to be made while unwinding; A dancing roller unit which stretches the curled polarizing film onto a flat plate while changing the direction of the polarizing film supplied through the winder through a plurality of rollers; A polarizing film transfer unit for transferring the flattened polarizing film to the rear horizontal plane of the transfer line through the dancing roller unit; A polarizing film adsorption unit for fixing the polarizing film transferred through the polarizing film conveying unit through vacuum adsorption; A laser cutting unit which is vacuum-absorbed by the polarizing film adsorption unit and cuts through the projection of a laser while moving the fixed polarizing film in a lateral direction to form a polarizing plate; A polarizing plate discharging unit for discharging and discharging the polarizing plate cut to a predetermined size through a laser cutting unit onto a rear-side horizontal plane; And a polarizing plate alignment unit configured to stack and arrange the polarizing plates transferred to the rear side on the transfer line through the polarizing plate discharge unit.

Polarizing Film, Polarizing Plate, POL, Laser, Cutting Equipment

Description

Polarizing film cutting apparatus using laser {Polaroid film cutting apparatus using laser}

The present invention relates to a polarizing film (POL) cutting device using a laser, and more particularly, the process of releasing and supplying a roll polarizing film in a roll state and cutting the supplied polarizing film into a polarizing plate having a predetermined size and a predetermined size. A series of processes of discharging the cut polarizing plate are continuously performed to automate the cutting of the polarizing film, and to cut the polarizing film using a laser, thereby eliminating the need for a separate polishing process due to the defective cutting plane. It relates to a polarizing film (POL) cutting device used.

In general, as much attention has been paid to the increase in size and quality of display devices as a medium for transmitting image information, it is noted that various flat panel display devices have been developed and disseminated in place of CRT (Cathode Ray Tube), which has been used until now. same. One of the flat panel display devices, the liquid crystal display device has developed far beyond the CRT in terms of image quality and color, and has become a main product dominating the world market.

The general manufacturing process of the general TFT-LCD panel (Thin Film Transistor Liquid Crystal Display Panel) constituting the liquid crystal display device as described above is as follows. First, as an overview, one pixel (comprising three subpixels R, G, and B) of a TFT-LCD panel is as fine as about 0.3 mm in width. Of course, the TFT (Thin Film Transistor) that fits in it is smaller. Furthermore, to reach a resolution of 1600 x 1200, the number of pixels is 1.19 million, which requires 3 times (R, G, B), considering each sub-pixel, and requires 576 million TFTs. Therefore, a semiconductor level process is required as a process that requires high precision of the entire process itself.

Meanwhile, the manufacturing process of the TFT-LCD panel as described above is largely divided into a TFT process, a color filter (CF) process, a cell process, and a module process, and has two glasses that have undergone a TFT process and a CF process. One panel is made through a cell process, and a panel processed through a cell process is made through a module process, and a TFT-LCD panel that is actually used for a monitor or a TV is made.

First, the TFT (Thin Film Transistor) process is a process of forming a basic electrode, which makes the electrode of each cell the most basic and essential process. The process sequence includes five steps of gate electrode generation, insulating film and semiconductor film generation, data electrode generation, protective film generation, and pixel electrode generation, but at least one pattern process is required for each step. This pattern process can be called the core of the TFT-LCD panel manufacturing process. Similar pattern processes are required for the CF process as well as the TFT process.

The pattern process as described above is a very precise and complicated process by itself. At least this process is performed several times to make a single TFT-LCD panel. Of course, the same process is not used then, but the schematic process is similar. This pattern process consists of deposition, cleaning, photoresist (PR) coating, exposure, development, etching (PR) process, PR stripping (Strip process), and inspection process. This is necessary.

TFT-LCD, on the other hand, does not emit light on its own like PDP or OLED (organic EL), but controls the brightness of light by controlling the arrangement of liquid crystals in each cell for constant light from the backlight. Since the backlight itself is white light, CF (Color Filter) plays an important role in changing the arrangement of liquid crystals to control the amount of light, but to make R, G, and B to realize color. This CF is located on the top of the TFT-LCD panel and is made through a process separate from the TFT process. The CF process also requires the pattern process described above.

The above-described CF (Color Filter) process requires a BM (Black Matrix) process (deposition, cleaning, PR coating, exposure, development, etching, and peeling pattern process), and pixel-by-pixel process (this pattern process was performed as described above. It is a slightly different process from the process of evaporation and cleaning without the need for the deposition and cleaning process, by applying a color-sensitive photosensitive material to the process of exposure and development) and the ITO process (Indium Tin Oxide: good permeability and conductivity, chemical and thermal stability Excellent transparent electrode material). In addition, some additional processes may be added depending on the type of panel (VA, IPS, TN, etc.).

In addition, the Cell process is a process of combining and cutting two glasses made in the CF process and the TFT process into one, and cleaning the CF and TFT, polyamide printing, rubbing process, spacer scattering, and bonding. (TFT substrate and CF substrate are precisely bonded), cutting (the bonded substrate is cut and separated into respective panels), liquid crystal injection, and final inspection.

The module process of the above-described TFT-LCD panel manufacturing process is a final step for attaching a polarizing film (or a polarizing plate), a PCB, a backlight unit, etc. to a panel made of a cell process as a final process for making a finished product panel. , Polarizer film attachment, TAB attachment, autoclave, PCB attachment, BLU (Back Light Unit) assembly, and inspection.

In the above-described module process, the polarizing film attached to the upper and lower parts of the panel has a function of making the incident light while vibrating in various directions to be light that vibrates only in one direction (that is, polarization). The polarizing film is usually attached to cross 90 degrees. In this case, a protective film for protecting the polarizing film is attached to each of the upper and lower surfaces of the polarizing film. In order to attach the polarizing film to the upper and lower surfaces of the panel, the protective film on the upper and lower surfaces of the polarizing film is first applied. After removal, it should be attached to the upper and lower surfaces of the panel.

On the other hand, the polarizing film (Polaroid Film) refers to a film having a property that can pass or block the vertical or horizontal polarization of the incident light, thin film transistor liquid crystal display device (TFT-LCD) such as notebook computers and monitors And optical films used for camera special effects filters and stereoscopic glasses. Although the intensity of light emitted from the backlight of the LCD module is equal in all directions, the polarizing film transmits only the light oscillating in the same direction as the polarization axis, and absorbs or reflects the other light to create polarization in a specific direction. Do it. When the polarization passes the LCD liquid crystal, the brightness of the pixel is changed by electrically adjusting the alignment direction of the liquid crystal for each pixel.

In order to attach the polarizing film to the upper and lower surfaces of the panel, the polarizing film is subjected to a process of cutting the polarizing film into a polarizing plate having a predetermined size so as to correspond to the size of the panel. The mechanical cutter is used to cut the polarizing film to correspond to the size of the panel.

Therefore, in the case of the polarizing film cutting device according to the prior art as described above, since a large amount of dust is generated in the process of cutting the polarizing film through the shooter cutter, a separate treatment process for treating the generated dust is required. do. Since a separate dust treatment process is required as described above, the production cost increases considerably and the yield decreases due to the occurrence of environmental treatment costs.

In addition, in the case of the polarizing film cutting device according to the prior art as described above, if the polarizing film is cut through the shooter cutter, the cutting surface of the polarizing film is not uniform, requiring a polishing process to uniformly polish the cutting surface of the polarizing film. As a result, the additional process causes problems such as an increase in production cost and a decrease in production volume.

The present invention has been made to solve the above-mentioned problems of the prior art, the process of releasing and supplying the roll polarizing film of the roll state and the process of cutting the supplied polarizing film into a polarizing plate of a predetermined size and the polarizing plate cut to a certain size It is an object of the present invention to provide a polarizing film (POL) cutting device using a laser to automate the cutting of the polarizing film through a device structure capable of continuously performing a series of processes to discharge the alignment.

Another object of the technology according to the present invention is to provide a cutting device using a laser in the process of cutting the supplied polarizing film into a polarizing plate of a certain size to minimize the generation of dust when cutting the polarizing film to minimize contamination of the polarizing plate Of course, the purpose of the present invention is not to require a separate environmental treatment process, thereby reducing the environmental treatment cost and thus reducing the production cost.

In addition, another object of the technology according to the present invention is to provide a cutting device using a laser in the process of cutting the supplied polarizing film into a predetermined size of the polarizing plate to uniformly cut the surface of the polarizing film when cutting the polarizing film to a certain size The purpose is not to require a separate cutting process, as well as to expect a reduction in production costs.

The present invention configured to achieve the above object is as follows. That is, the polarizing film (POL) cutting device using a laser according to the present invention is a polarizing film cutting device for cutting to a certain size while continuously supplying the roll polarizing film wound in a roll state, the polarizing film cutting device A winder unit to rotatably support the roll polarizing film so that supply can be made while continuously being unrolled; A dancing roller unit which stretches the curled polarizing film onto a flat plate while changing the direction of the polarizing film supplied through the winder through a plurality of rollers; A polarizing film transfer unit for transferring the flattened polarizing film to the rear horizontal plane of the transfer line through the dancing roller unit; A polarizing film adsorption unit for fixing the polarizing film transferred through the polarizing film conveying unit through vacuum adsorption; A laser cutting unit which is vacuum-absorbed by the polarizing film adsorption unit and cuts through the projection of a laser while moving the fixed polarizing film in a lateral direction to form a polarizing plate; A polarizing plate discharging unit for discharging and discharging the polarizing plate cut to a predetermined size through a laser cutting unit onto a rear-side horizontal plane; And a polarizing plate alignment unit configured to stack and arrange the polarizing plates transferred to the rear side on the transfer line through the polarizing plate discharge unit.

Winder unit in the configuration of the present invention as described above is a winder unit fixed frame consisting of the same height on both sides; A pair of frame support shafts rotatably installed in a predetermined range on each of the opposing surfaces of the winder unit fixing frame; A pair of winder support frames installed on each of the frame support shafts in the same shape with a predetermined size; Roll support shafts rotatably supported by both winder support frames to support both sides of the branch pipe of the roll polarizing film; A support shaft drive motor installed outside the winder support frame on both sides to rotate the roll support shaft at the same speed; A tension adjusting cylinder installed at each upper side of the inner surface of the winder unit fixing frame to adjust the tension of the polarizing film released from the roll state by rotating the winder support frame up and down through hydraulic pressure; And it is installed on the upper side of both winder unit fixing frame can be made rotatable configuration of the polarizing film guide roller for guiding the polarizing film released from the roll state.

In addition, the above-described dancing roller unit is a dancing roller unit support frame which is installed on both sides of the rear of the predetermined distance of the winder unit; The rotating roller unit is rotatably installed on the lower side of the support frame, and the polarizing film guided to the dancing roller unit by the polarizing film guide roller of the winder unit downward, rearward, upward, forward and upward. A plurality of dancing rollers for turning; A plurality of rotatable rollers are rotatably installed on the upper side of the supporting frame, and the polarizing film, which is turned downward, backward, upward, forward and upward by the plurality of dancing rollers, is turned back and guided. A plurality of back guide rollers; A tension adjusting roller for adjusting the tension of the polarizing film guided backward by the rear guide roller; And installed on the opposite surface of the dancing roller unit support frame may be made of a configuration of the tension control cylinder to rotatably support the tension control roller to move up and down to adjust the tension of the polarizing film.

On the other hand, in the configuration according to the invention the polarizing film transport unit is a transport unit support frame which is installed on the rear of the dancing roller unit a certain distance; A flat guide roller installed at an upper side of the transfer unit support frame to guide the polarizing film transferred from the dancing roller unit onto a plane in the transfer line; A polarizing film forced feed roller which is installed to face up and down a predetermined distance behind the planar guide roller and forcibly transfers the polarizing film to the rear through the top and bottom; A driving motor for driving the polarizing film forced feed roller; And it can be made of a configuration of a conveyor conveying means for supporting the polarizing film forcedly conveyed backward by the polarizing film forced feed roller to the upper side and conveyed to the polarizing film adsorption unit. At this time, the conveyor conveying means is a driving roller which is installed on the rear side of the predetermined distance of the polarizing film forced feed roller; A motor for driving a motor roller; A driven roller installed vertically on the rear side of the driving roller in a vertical direction so that the polarizing film can be transferred through the vertical roller; The transfer conveyor connects the prime roller and the lower driven roller to rotate a fixed orbit by the rotation of the prime roller, but supports the polarized film forcedly conveyed backward by the polarized film forced feed roller through the upper part and transfers it to the polarizing film adsorption unit. belt; And it is installed between the prime roller and the driven roller, but the rolling roller is configured at the tip thereof may be made of a configuration of the belt tension adjusting bar for adjusting the tension of the conveying conveyor belt. In addition, the rotational speed of the winder unit side support shaft drive motor, the polarizing film transfer unit side drive motor, and the conveyor transfer means side prime mover motor is more preferably configured to rotate at the same rotational speed.

In the configuration of the present invention as described above, the polarizing film adsorption unit includes an adsorption unit supporting frame installed at a rear of a predetermined distance of the polarizing film transport unit; And a plurality of vacuum adsorption holes are formed on the upper side of the adsorption unit support frame at a predetermined interval, respectively, and a plurality of vacuum adsorption holes are formed in each of the polarizing film adsorption plates for fixing the polarization films by vacuum adsorption through vacuum adsorption by a vacuum pump. Can be made.

In the configuration of the polarizing film adsorption unit, the polarizing film is vacuum-adsorbed to the upper surface of the polarizing film adsorption plate through the vacuum adsorption hole of the polarizing film adsorption plate, and then the polarizing film is cut and then discharged. The air is discharged through the vacuum adsorption hole of the polarizing film adsorption plate, so that the polarizing film and the polarizing plate on the upper side of the polarizing film adsorption plate are floated from the upper surface of the polarizing film adsorption plate by air so that the transfer is performed. Good.

And, the laser cutting unit of the present invention is a cutting unit support frame which is installed on the rear of the polarizing film adsorption unit; A plate having a predetermined thickness fixedly installed on the cutting unit support frame; A laser oscillator which is installed to be movable from side to side on the top of the flat plate, and the oscillation of the laser is performed; A laser nozzle installed downward on the front side of the laser oscillator and installed toward an upper gap between the front and rear polarization film adsorption plates to cut the polarization film fixed on the polarization film adsorption plate through the projection of the laser; An LM guide installed at a predetermined distance before and after the laser oscillator to allow left and right movement of the laser oscillator; A linear motor for moving the laser oscillator from side to side on the plate; And combustion gas suction means for suctioning and removing combustion gas generated during laser cutting of the polarizing film.

Combustion gas suction means in the configuration of the above-described laser cutting unit is provided with a combustion gas suction tube is installed toward the lower side gap between the polarizing film adsorption plate before and after suction suction combustion gas generated during laser cutting of the polarizing film; And a suction pump connected to the combustion gas suction pipe to generate a suction pressure.

In addition, the polarizing plate discharge unit in the configuration according to the present invention is a discharge unit support frame which is installed a predetermined distance behind the cutting unit support frame of the laser cutting unit; A polarizing plate discharge driving roller installed at an upper side of the discharge unit support frame; A driving motor installed at an upper side of the discharge unit support frame to drive the polarizing plate discharge roller; A polarizing plate discharge driven roller spaced apart from the bottom of the flat plate of the laser cutting unit so as to face the upper and lower sides of the upper side of the cutting unit support frame so as to be discharged by transferring the cut polarizing plate therebetween; A discharge conveyor belt which connects the polarizing plate discharge driving roller and the lower side polarizing plate discharge driven roller to rotate a predetermined trajectory by the rotation of the polarizing plate discharge driving roller, but transfers the cut polarizing plate to the rear; And it is provided between the polarizing plate discharge drive roller and the polarizing plate discharge driven roller, but the rolling roller is configured at the tip of the polarizing plate discharge driving roller can be made of a configuration of the belt tension adjusting bar for adjusting the tension of the discharge conveyor belt.

Furthermore, in the configuration according to the invention the polarizing plate alignment unit is an alignment unit support frame which is installed in the rear of the polarizing plate discharge unit; A basket which is coupled to the hinge on the upper rear side of the alignment unit support frame, the front end of which is installed to be rotated up and down about the hinge to collect the polarizing plates discharged through the polarizing plate discharge unit; And it may be made of a configuration of the lifting cylinder which is installed on the upper front side of the alignment unit support frame to lift the front end of the basket up and down.

According to the present invention, a process of releasing and supplying a roll polarizing film in a roll state, cutting the supplied polarizing film into a polarizing plate having a predetermined size, and discharging the polarizing plate cut to a predetermined size may be continuously performed. The device structure can be used to automate the cutting of the polarizing film, thereby reducing the production cost and maximizing the yield.

In addition, according to the technology of the present invention by providing a cutting device using a laser in the process of cutting the supplied polarizing film into a polarizing plate of a certain size, it is possible to minimize the generation of dust during cutting of the polarizing film, of course, Contamination can be minimized. This effect eliminates the need for a separate environmental treatment process, thereby reducing the environmental treatment cost and thus reducing the production cost.

In addition, according to the technology of the present invention by providing a cutting device using a laser in the process of cutting the supplied polarizing film into a polarizing plate of a predetermined size has the effect that the cut surface of the polarizing film can be uniform when cutting the polarizing film to a certain size Expressed. Accordingly, it is possible not only to require a separate cutting surface grinding process, but also to reduce production costs.

Hereinafter, a polarizing film (POL) cutting device using a laser of the present invention will be described in detail with reference to the accompanying drawings.

1 is a plan view showing the overall configuration of a polarizing film (POL) cutting device using a laser according to the present invention, Figure 2 is a side configuration showing the overall configuration of a polarizing film (POL) cutting device using a laser according to the present invention Figure 3 is a side configuration view showing an enlarged winder unit (Winder Unit) for supplying a polarizing film in the roll state in the configuration of a polarizing film (POL) cutting device using a laser according to the present invention, Figure 4 Side view showing an enlarged dancing roller unit for spreading the polarizing film into a flat plate in the configuration of a polarizing film (POL) cutting device using a laser according to the invention, Figure 5 is a laser using the laser according to the present invention 6 is a side configuration view showing an enlarged polarizing film conveying unit for conveying a polarizing film onto a flat plate in the configuration of a polarizing film cutting device, FIG. Polarizing film adsorption unit for fixing polarizing film, laser cutting unit for cutting fixed polarizing film and polarizing film discharging unit for discharging polarized film cut to a certain size in the configuration of polarizing film cutting device Side view showing an enlarged polarizing film alignment unit for aligning the polarizing film.

1 to 6, the polarizer film cutting apparatus 100 using the laser according to the present invention is rotatable to support the roll polarizing film 10 so that the supply can be made while continuously unwinding Dancing roller unit 120 for unfolding the curled polarizing film 10 in a flat shape while the direction of the polarizing film 10 supplied through the unit 110, the winder unit 110 through a plurality of rollers, Polarizing film 10 which is transferred through polarizing film conveying unit 130, polarizing film conveying unit 130 to convey the flattened polarizing film 10 through the dancing roller unit 120 to the rear horizontal plane of the transfer line ) Is fixed by vacuum adsorption, the polarizing film adsorption unit 140 and the polarizing film 10 are vacuum-absorbed by the polarization film adsorption unit 140 to be fixed in the transverse direction while cutting through the projection of the laser polarizing plate. Mold with 20 The polarizing plate discharging unit 160 and the polarizing plate discharging unit 160 for discharging the polarizing plate 20 cut to a predetermined size through the laser cutting unit 150 and the laser cutting unit 150 to be transported onto the rear-side horizontal plane. It consists of a configuration of the polarizing plate alignment unit 170 for laminating the polarizing plate 20 transferred to the rear side on the transfer line through.

Looking at the transfer process of the polarizing film 10 through the polarizing film cutting device 100 using a laser according to the present invention configured as described above, first, rotating the polarizing film 10 in a roll state to the winder unit 110 When coupled to the polarizing film conveying unit 130 via the dancing roller unit 120 in the coupled state, and then transferred through the drive of the polarizing film conveying unit 130, the polarization of the roll state coupled to the winder unit 110 The film 10 is unwound and the polarizing film 10 in a curled state is spread out on a flat plate while passing through the dancing roller unit 120.

On the other hand, as described above, the polarizing film 10 which is flattened through the dancing roller unit 120 is transferred to a size set by a control controller (not shown) through the polarizing film transfer unit 130 to adsorb the polarizing film. After being guided to the unit 140, the transfer of the polarizing film 10 is stopped, whereby the polarizing film adsorption unit 140 is vacuum-adsorbed and fixed to the polarizing film 10 located thereon. That is, while the polarizing film 10 is fixed by the polarizing film adsorption unit 140, the transfer of the polarizing film 10 is stopped.

As described above, when the polarizing film 10 is fixed to the upper portion of the polarizing film adsorption unit 140 by vacuum adsorption, the laser cutting unit 150 is driven to cut the polarizing film 10 to a set size. That is, the laser cutting unit 150 cuts the polarizing film 10 to a predetermined size to form the polarizing plate 20. After forming the polarizing plate 20 through the cutting of the polarizing film 10, the vacuum adsorption of the polarizing film 10 and the polarizing plate 20 is released and at the same time, air is absorbed from the polarizing film adsorption unit 140. By discharging, the polarizing film 10 and the polarizing plate 20 are floated so that the transfer of the polarizing film 10 and the polarizing plate 20 can be performed smoothly.

Next, as described above, the polarizing film 10 and the polarizing plate discharge unit in a state in which the polarizing film 10 and the polarizing plate 20 are floated by air discharged from the adsorption unit 140. When the driving of the 160 is made, the polarizing plate 20 is discharged by the polarizing plate discharge unit 160 and the polarizing film 10 is transferred to the polarizing film adsorption unit 140 by the polarizing film transfer unit 130. Lose. At this time, the polarizing film 10 and the polarizing plate discharge unit 160 for transferring the polarizing film 10 and the polarizing plate 20 are driven at the same speed and the polarizing film 10 and the polarizing plate 20 are transferred in the same direction. Do not cause interference.

As described above, when the polarizing film 10 and the polarizing plate 20 are transferred by the driving of the polarizing film conveying unit 130 and the polarizing plate discharging unit 160, the polarizing plate 20 is formed by the polarizing plate discharging unit 160. The transfer is aligned with the polarizing plate alignment unit 170, and is moved at the same speed as the polarizing plate discharge unit 160 to transfer the polarizing film 10 of the polarizing film adsorption unit 140. Therefore, the cutting of the polarizing film 10 by the laser cutting unit 150 can be seen that the transfer of the polarizing film 10 and the polarizing plate 20 is made at the same time.

Referring to the polarizing film cutting device 100 using a laser according to the invention in more detail as follows. First, the winder unit 110 is to support the roll polarizing film 10 wound in a roll state through the branch pipe 12 so as to be supplied while being continuously released, such a winder unit 110 is configured to supply a roll polarizing film 10 wound in a state configured in the front side of the polarizing film cutting device 100 using a laser according to the present invention as shown in FIGS.

Looking at the configuration of the winder unit 110 as described above, as shown in FIGS. 1 to 3, the winder unit fixing frame 111 and the winder unit fixing frame 111 configured to have the same height on both sides thereof. A pair of frame support shafts 112 are installed on each of the surfaces so as to be rotatable in a predetermined range, and a pair of winder support frames 113 are installed on the frame support shafts 112 in the same shape, respectively. It is rotatably supported by the winder support frame 113 and is installed outside the roll support shaft 114 and both winder support frames 113 to support both sides of the branch pipe 12 of the roll polarizing film 10. The drive motor 115 for driving the support shaft 114 to rotate at the same speed, and is installed on each upper side of the winder unit fixing frame 111 to rotate the winder support frame 113 up and down through hydraulic pressure. Of the polarizing film 10 to be released from the roll state The polarization film guide roller 117 is installed on the tension adjusting cylinder 116 to adjust the tension and the upper side of the winder unit fixing frame 111 but rotatably installed to guide the polarizing film 10 released from the roll state. Consists of the configuration.

Meanwhile, the winder unit 110 configured as described above is the branch tube 12 of the polarizing film 10 wound in a roll state through the roll support shaft 114 installed on each of the pair of winder support frames 113. Both sides are coupled so that the polarizing film 10 in a roll state is rotatably supported on the winder support frame 113 through the roll support shaft 114. The polarizing film 10 rotatably supported as described above connects the upper portions of both winder unit fixing frames 111 in a state of being released from the roll state by the rotation of the roll supporting shaft 114 by the driving of the driving motor 115. It is guided to the dancing roller unit 120 through the polarizing film guide roller 117 is rotatably installed.

As described above, the polarizing film 10 wound in the roll state to the dancing roller unit 120 through the polarizing film guide roller 116 in a state of rotating and releasing the roll supporting shaft 114 by the driving of the driving motor 115. When the tension of the polarizing film 10 to be supplied in the guide is loosened in the process of supplying the), the polarizing film made of a roll state by rotating the winder support frame 113 up and down a certain range through the operation of the tension adjusting cylinder 115. By adjusting the position of the (10) to adjust the tension of the polarizing film 10 is supplied to the unfolded state.

The dancing roller unit 120 constituting the polarizing film (POL) cutting device 100 using a laser according to the present invention is a polarizing film 10 supplied through the winder unit 110 described above through a plurality of rollers. In order to straighten the curled polarizing film 10 while changing the direction of the flat plate, the dancing roller unit 120 is a predetermined distance of the winder unit 110, as shown in Figure 1, 2 and 4 Dancing roller unit support frame 121 installed opposite to the rear side, a plurality of rotatable film guide roller 117 of the winder unit 120 is rotatably installed on the opposite surface of the dancing roller unit support frame 121 A plurality of dancing rollers 122a, 122b, 122c, 122d, 122e, and dancing rollers for turning the polarizing film 10 guided by the dancing roller unit 120 by downward, backward, upward, forward, and upward directions. On the upper facing surface of the unit support frame 121 It is possible to install a plurality of guided by the plurality of dancing rollers (122a, 122b, 122c, 122d, 122e) down, rearward, upward, forward and upward direction of the polarizing film 10 to reverse the guide Tension adjusting roller 124 and the dancing roller unit for adjusting the tension of the polarizing film 10 that is guided back by a plurality of rear guide rollers (123a, 123b, 123c), the rear guide rollers (123a, 123b, 123c) It is installed on the opposite surface of the support frame 121 is made of a configuration of the tension adjusting cylinder 125 for rotatably supporting the tension control roller 124 to move up and down to adjust the tension of the polarizing film 10.

As illustrated in FIG. 4, the dancing roller unit 120 configured as described above is installed at the lower side of the dancing roller unit support frame 121 in a form in which a location point forms a quadrangle and guided to the dancing roller unit 120. Cured state by winding the polarizing film 10 in a roll state by successively turning down, backward, upward, forward and upward through a plurality of dancing rollers 122a, 122b, 122c, 122d, 122e. The polarizing film 10 is to be spread out on the flat plate while changing the direction.

On the other hand, as described above, the polarizing film 10 guided from the winder unit 110 to the dancing roller unit 120 through the plurality of dancing rollers 122a, 122b, 122c, 122d, 122e After unfolding in a flat shape while changing the direction upward, forward and upward continuously, the polarizing film 10 in the unfolded state through the plurality of rear guide rollers 123a, 123b, and 123c is polarized film transfer unit 130 To guide). At this time, between the plurality of rear guide rollers (123a, 123b, 123c) is configured a tension adjusting means for adjusting the tension of the polarizing film 10 is guided to the rear.

As described above, as the tension adjusting means for adjusting the tension of the polarizing film 10, as described above, the tension of the polarizing film 10 guided backward by the rear guide rollers 123a, 123b, and 123c may be adjusted. The tension control roller 124 and the tension control roller 124 is rotatably supported by the configuration of the tension control cylinder 125 to adjust the tension of the polarizing film 10 by the vertical action of the piston (125a). That is, when the tension of the polarizing film 10 guided backward is loose, the piston 125a is drawn out to maintain a constant tension, and when the tension of the polarizing film 10 is too strong, the piston 125a is drawn in. To maintain a constant tension.

Then, the polarizing film transfer unit 130 constituting the polarizing film (POL) cutting device 100 using a laser according to the present invention transfers the polarizing film 10 stretched in a flat plate through the dancing roller unit 120 In order to transfer to the rear side of the horizontal plane, the polarizing film transfer unit 130 is a transport unit support frame which is installed at a rear of the constant distance of the dancing roller unit 120 as shown in Figs. 131, a plurality of flat guide rollers 132, planar guides installed on an upper side of the transport unit support frame 131 to guide the polarizing film 10 transferred from the dancing roller unit 120 in a plane in a transport line. It is installed to face up and down a certain distance behind the roller 132 to drive the polarizing film forced feed roller 133, the polarizing film forced feed roller 133 for forcibly conveying the polarizing film 10 through the upper and lower sides. Motor 134 and polarization Flow to support the polarizing film 10 to be forcibly transferred to the top and then by force transfer roller 133 to the upper part consists of a conveyor belt feed means for conveying the polarizing film absorption unit 140. The

The polarizing film transfer unit 130 configured as described above is forcibly held by the polarizing film forced feed roller 133 driven by the driving motor 134 the polarizing film 10 guided from the dancing roller unit 120. While the force is conveyed backwards on the transfer line, the polarizing film 10 pulled backwards on the transfer line through the polarizing film force feed roller 133 is supported on a plane through the conveyor conveying means so that the polarizing film adsorption unit of the rear side is supported. And to 140. At this time, the rotation speed of the polarizing film forced conveying roller 133 and the conveyor conveying means is made of the same rotational speed, the drive motor 115 of the winder unit 110 also the polarizing film forced conveying roller 133 and the conveyor conveying means It is driven at the same rotational speed as.

On the other hand, looking at the configuration of the conveyor conveying means in the configuration of the polarizing film conveying unit 130 configured as described above, the conveyor conveying means is a driving roller (135a), which is installed on the rear side of the predetermined distance of the polarizing film forced conveying roller 133, A driving roller 135c for driving the driving roller 135a and a driving roller 135c vertically installed on the rear side of the driving roller 135a up and down at a predetermined distance to allow the transfer of the polarizing film 10 through the upper and lower sides. ), By connecting the driving roller (135a) and the lower side driven roller (135c) to rotate a constant orbit by the rotation of the driving roller (135a), the polarizing film forcibly conveyed backward by the polarizing film forced feed roller (133) ( 10) is supported between the transfer conveyor belt (135d) and the driving roller (135a) and the driven roller (135c) for supporting the polarizing film adsorption unit (140) through the upper portion of the rolling roller (135e-) 1) is configured It consists of a structure of a belt tension adjusting bar (135e) for adjusting the tension of the transmission belt conveyor (135d).

Conveyor conveying means configured as described above of the conveying belt (135d) connecting the motive roller (135a) and the driven roller (135c) when the rotation of the motive roller (135a) is made in accordance with the drive of the motor (135b) The polarization film 10 pulled backwards on the transfer line through the polarizing film forced transfer roller 133 is rotated to support the upper surface of the transfer conveyor belt 135d to be transferred backwards on the transfer line. At this time, the polarizing film 10 conveyed backward on the conveying line by the conveying conveyor belt 135d is transferred to the polarizing film adsorption unit 140 through the driven roller 135c configured at the rearmost side of the polarizing film conveying unit 130. Are transferred.

Then, in the configuration of the conveyor conveying means described above, the driven roller 135c is vertically installed on the rear side of the predetermined distance of the driving roller 135a as described above, and the polarizing film 10 is transferred through the upper and lower sides. It is configured to be. At this time, the transfer conveyor belt 135d is connected to the primary roller 135a and the lower side driven roller 135c so that a fixed trajectory is rotated so that the polarizing film is supported and transported on the upper surface of the transfer conveyor belt 135d. In fact, it can be said that 10 is conveyed through the transfer conveyor belt 135d different from the upper driven roller 135c and the lower driven roller 135c.

In the configuration of the conveyor conveying means as described above, a belt tension adjusting bar 135e provided with rolling rollers 135e-1 is formed between the prime rollers 135a and the driven rollers 135c to form an elastic spring (not shown). By means of the constant force to control the tension of the conveying conveyor belt (135d). And, the function of the driven roller 135c constituting the polarizing film transfer unit 130 will be described as described when explaining the polarizing plate discharge driven roller 164 constituting the polarizing film discharge unit 160 to be described later.

On the other hand, the polarizing film adsorption unit 140 constituting the polarizing film (POL) cutting device 100 using a laser according to the present invention is vacuum adsorption of the polarizing film 10 transferred through the polarizing film transfer unit 130 To be fixed through, the polarizing film adsorption unit 140 is a constant distance of the driven roller (135c) of the conveyor conveying means constituting the polarizing film conveying unit 130 as shown in Figure 1, 2 and 6 A pair of adsorption unit support frame 142 and a rear side of the adsorption unit support frame 142 which are installed in the rear is installed at regular intervals before and after spaced apart, respectively, a plurality of vacuum adsorption holes (144a) are formed and a polarizing film ( 10) is made of a configuration of a polarizing film adsorption plate 144 for vacuum adsorption fixing of the polarizing film 10 by vacuum adsorption by a vacuum pump (not shown).

The polarizing film adsorption unit 140 configured as described above is transported to a size to be cut and the vacuum pump (not shown) configured for the polarizing film 10 of the polarization film adsorption unit 140 is stopped. By suctioning the air between the polarizing film adsorption plate 144 and the polarizing film 10 through the vacuum pressure, the polarizing film 10 on the polarizing film adsorption plate 144 is vacuumed to the upper surface of the polarizing film adsorption plate 144. It has a function of being fixed by being adsorbed. At this time, when the polarizing film 10 is fixed to the upper surface of the polarizing film adsorption plate 144 by vacuum adsorption, the driven roller 135c constituting the polarizing film transfer unit 130 before and after the polarizing film adsorption plate 144. ) And a polarizing plate discharge driven roller 164 constituting the polarizing film discharge unit 160, and the front and rear of the polarized film 10 fixed and vacuum-adsorbed by the polarizing film adsorption plate 144 is a polarizing film transfer unit ( 130 is a structure that is held by the driven roller 135c and the polarizing plate discharge driven roller 164 of the polarizing film discharge unit 160.

In addition, the polarizing film adsorption unit 140 of the present invention sucks air between the polarizing film adsorption plate 144 and the polarizing film 10 through the vacuum pressure of a vacuum pump (not shown). (144) After the polarizing film 10 is cut through the polarizing film cutting unit 150 to be described later in addition to the function of fixing the upper polarizing film 10 to the upper surface of the polarizing film adsorption plate 144 to be fixed. In addition, the vacuum adsorption of the polarizing film 10 on the front side and the rear polarizing plate 20 on the polarization film adsorption plate 144 is released, and at the same time, the air is discharged through the vacuum adsorption hole 144a. In this way, the polarizing film 10 and the polarizing plate 20 in which vacuum adsorption is released are floated on the upper surface of the polarizing film adsorption plate 144 to prevent scratches from being transferred.

In other words, the polarizing film adsorption unit 140 vacuum-adsorbs the polarizing film 10 to the upper surface of the polarizing film adsorption plate 144 through the vacuum adsorption holes 144a of the polarization film adsorption plate 144. In the state of cutting the polarizing film 10 after cutting the polarizing film 10 in the state discharged the air (air) through the vacuum adsorption hole (144a) of the polarizing film adsorption plate 144 polarizing film adsorption plate 144 The upper polarizing film 10 and the polarizing plate 20 is configured to be floated (floating) from the upper surface of the polarizing film adsorption plate 144 by air to be carried out.

Then, the laser cutting unit 150 constituting the polarizing film (POL) cutting device 100 using a laser according to the present invention transversely vacuum-adsorbed by the polarizing film adsorption unit 140 fixed to the polarizing film 10 The laser cutting unit 150 is a polarizing film transfer unit 130 as shown in FIGS. 1, 2 and 6 by cutting through projection of a laser while moving in the direction to be shaped as a polarizing plate 20. The polarizing film 10 is fixed by cutting the fixed polarizing film 10 in a stationary state by the driven roller 135c and the polarizing film adsorption plate 144 and the polarizing plate discharge driven roller 164 of the polarizing film discharge unit 160. It is formed by (20). At this time, the cutting position of the polarizing film 10 is cut in the gap between the polarizing film adsorption plate 144 configured to be spaced forward and backward.

Looking at the configuration of the laser cutting unit 150 as described above, the cutting unit support frame 151 installed on the rear of the polarizing film adsorption plate 144 of the polarizing film adsorption unit 140, the upper portion of the cutting unit support frame 151 Flat plate 152 of fixed thickness, which is fixedly installed in the upper portion of the plate 152 to be movable to the left and right, the laser oscillator 153, the laser oscillator 153 is provided downward in the front side of the laser oscillator 153 A laser nozzle 154 installed toward the upper gap between the front and rear polarizing film adsorption plates 144 and cutting the polarizing film 10 fixed on the polarizing film adsorption plates 144 through the projection of a laser; An LM guide 155 installed at a predetermined distance from the front and rear to allow the laser oscillator 153 to move left and right on the flat plate 152, a linear motor 156 for moving the laser oscillator 153 to the left and right on the flat plate 152; Polarizing film (1 Combustion gas suction means for suctioning off the combustion gas generated during laser cutting of 0).

The laser cutting unit 150 configured as described above is driven by the driven roller 135c of the polarizing film transfer unit 130 and the polarizing plate discharge driven roller 164 of the polarizing film adsorption plate 144 and the polarizing film discharge unit 160. When it is fixed in the stopped state, the laser oscillator is oscillated and the laser is projected through the laser nozzle 154 while the linear movement of the laser oscillator 153 is performed by the driving of the linear motor 156. The polarization film 10 is cut in the gap between the adsorption plates 144 to form the polarizing plate 20. At this time, since the laser oscillator 153 is moved in the lateral direction of the polarizing film 10 through the LM guide 155, precise cutting of the polarizing film 10 can be made. After the cutting of the polarizing film 10 by the laser as described above, the laser oscillator 153 is in place to prepare for the next cutting.

Meanwhile, as described above, the laser is projected through the laser nozzle 154, and the polarizing film 10 is cut in the gap between the polarizing film adsorption plates 144 before and after. Combustion gas generated at the cut portion of 10) is sucked out through the combustion gas suction means to prevent contamination of the polarizing film 10 and the polarizing plate 20 by the combustion gas. At this time, the configuration of the combustion gas suction means is installed toward the lower side gap between the front and rear polarizing film adsorption plate 144, the combustion gas suction pipe for suctioning and removing the combustion gas generated during laser cutting of the polarizing film 10 ( 157 and the combustion gas suction pipe 157 is connected to the suction pump 158 for generating a suction pressure.

The combustion gas suction means configured as described above operates the suction pump 158 during laser cutting of the polarizing film 10 and the combustion gas of the polarizing film 10 generated by laser cutting through the combustion gas suction pipe 157. Suction is removed to prevent contamination on the surface and the cut surface of the polarizing film 10 and the cut polarizing plate 20. At this time, the inlet 157a of the combustion gas suction pipe 157 is formed to be larger than the width of the polarizing film 10 so that the combustion gas can be smoothly sucked between the left and right widths of the polarizing film 10.

The polarizing plate discharge unit 160 constituting the polarizing film (POL) cutting device 100 using a laser according to the present invention is a polarizing plate 20 formed by cutting a predetermined size through the laser cutting unit 150 on the rear-side horizontal plane. In order to transport and discharge, such a polarizing plate discharge unit 160 is fixed to the adsorption fixed to the polarizing film adsorption plate 144 as shown in Figure 1, 2 and 6 to a predetermined size by the laser cutting unit 150 The polarizing plate 20 in the cut state is transferred to and discharged from the polarizing plate alignment unit 170 through the conveyor structure.

The configuration of the polarizing plate discharge unit 160 as described above is the discharge unit support frame 161, the discharge unit support frame 161 of the discharge unit support frame 161 which is installed a predetermined distance from the cutting unit support frame 151 of the laser cutting unit 150. The polarizing plate discharge driving roller 162 installed on the upper side, the drive motor 163 installed on the upper side of the discharge unit support frame 161 to drive the polarizing plate discharge driving roller 162, the flat plate of the laser cutting unit 150 (152) Polarizing plate discharge driven roller 164, polarizing plate discharged to be discharged by transporting the polarizing plate 20 is cut up and down and installed in the upper front side of the cutting unit support frame 151 spaced apart from the lower portion therebetween Discharge conveyor bell for connecting the driving roller 162 and the lower side polarizing plate discharge driven roller 164 to rotate a predetermined trajectory by the rotation of the polarizing plate discharge driving roller 162, but to convey and discharge the cut polarizing plate 20 to the rear. 165 and the polarizing plate discharge driven roller 162 and the polarizing plate discharge driven roller 164 is installed between the rolling roller 166a at the tip of the belt tension adjusting bar for adjusting the tension of the discharge conveyor belt 165 166 is made up of.

The polarizing plate discharge unit 160 configured as described above may rotate the polarizing plate discharge driving roller 162 and the polarizing plate discharge driven roller 164 when the rotation of the polarizing plate discharge driving roller 162 is performed by the driving motor 163. The polarizing plate 20 cut by the laser cutting unit 150 is supported by the upper surface of the discharge conveyor belt 165 while the discharge conveyor belt 165 is rotated to be connected to the rear surface of the transfer line. At this time, the polarizing plate 20 conveyed backward on the transfer line by the discharge conveyor belt 165 is transferred to the polarizing plate alignment unit 170 through the polarizing plate discharge driven roller 164 configured at the foremost side of the polarizing plate discharge unit 160. Is discharged.

In addition, in the configuration of the polarizing plate discharge unit 160 as described above, between the polarizing plate discharge drive roller 162 and the polarizing plate discharge driven roller 164, the belt tension adjusting bar 166 provided with a rolling roller 166a at the tip is configured. The elastic spring (not shown) is a function to adjust the tension of the discharge conveyor belt 165 with a constant force through the elastic force at all times.

On the other hand, in the configuration of the polarizing plate discharge unit 160 described above is installed on the front side of the polarizing plate discharge unit 160, the driven roller 164 consisting of a configuration installed opposite to the polarizing film through the polarizing film adsorption unit 140 In the case of fixing by vacuum adsorption (10) by holding the portion of the polarizing film 10 located before and after the polarizing film adsorption unit 140 together with the driven roller (135c) of the polarizing film transfer unit 130, the polarizing film adsorption unit This is to further improve the fixing force of the polarizing film 10 adsorbed and fixed on the polarizing film adsorption plate 144 of 140.

In addition, the polarizing plate alignment unit 170 constituting the polarizing film (POL) cutting device 100 using a laser according to the present invention is laminated the polarizing plate 20 transferred to the rear side on the transfer line through the polarizing plate discharge unit 160. In order to arrange, the polarizing plate alignment unit 170 is configured to be adjacent to the rear of the polarizing plate discharge driving roller 162 of the polarizing plate discharge unit 160 as shown in FIGS. 1, 2 and 6.

Looking at the configuration of the polarizing plate alignment unit 170 constituting the present invention as described above, the polarizing plate alignment unit 170 is an alignment unit support frame 172 installed on the rear of the polarizing plate discharge unit 160, the alignment unit support frame ( Hinge 174a on the upper rear side of the 172, but the front end of the basket is installed so as to rotate in a predetermined range around the hinge to collect the polarizing plate 20 discharged through the polarizing plate discharge unit 160 (174) And it is provided in the upper front side of the alignment unit support frame 172 is made of a configuration of the lifting cylinder 176 for lifting up and down the front end of the basket 174.

On the other hand, the polarizing plate alignment unit 170 configured as described above is the lifting cylinder 176 when the rear end of the polarizing plate 20 of a predetermined size through the polarizing plate discharge unit 160 reaches the position of the polarizing plate discharge driving roller 162. Operate to raise the tip portion of the basket 174 upwards about the hinge 174a so that the polarizing plate 20 conveyed and discharged through the polarizing plate discharge unit 160 is more easily discharged and aligned than the upper surface of the basket 174. do. As such, when the polarizing plate 20 is aligned with the upper portion of the basket 174, the lifting cylinder 176 is lowered to maintain the basket 174 on a plane.

Although not shown in the drawings of the present invention, as described above, the polarizing plate 20 is discharge-aligned to the upper surface of the basket 174 so that the basket 174 is kept flat, and then the polarizing plate 20 is absorbed from the upper side. It is mounted on the polarizing plate loading carrier 180 through the lifting device.

As described above, the polarizing film (POL) cutting device 100 using the laser according to the present invention includes a winder unit 110, a dancing roller unit 120, a polarizing film transfer unit 130, and a polarizing film adsorption unit 140. ), Through the laser cutting unit 150, the polarizing plate discharge unit 160 and the polarizing plate alignment unit 160 to release the roll polarizing film in the roll state and to supply and to cut the supplied polarizing film into a predetermined size polarizing plate and It is possible to continuously perform a series of processes of discharging and aligning the polarizing plate cut to a certain size, it is possible to improve the cutting quality of the polarizing film, reduce the production cost and maximize the yield.

Meanwhile, as described above, the winder unit 110, the dancing roller unit 120, the polarizing film transfer unit 130, the polarizing film adsorption unit 140, the laser cutting unit 150, the polarizing plate discharge unit 160, and Polarizing film (POL) cutting device 100 using a laser according to the present invention made of a polarizing plate alignment unit 160 is controlled by a control controller (not shown) to control the present invention polarizing film 10 and the polarizing plate ( The feed rate of 20) is constantly controlled.

The present invention is not limited to the above embodiments, and various modifications can be made within the scope of the technical idea of the present invention.

1 is a plan view showing the overall configuration of a polarizing film (POL) cutting device using a laser according to the present invention.

Figure 2 is a side view showing the overall configuration of a polarizing film (POL) cutting device using a laser according to the present invention.

Figure 3 is a side configuration view showing an enlarged winder unit (Winder Unit) for supplying a polarizing film in a roll state in the configuration of a polarizing film (POL) cutting device using a laser according to the present invention.

Figure 4 is an enlarged side view showing a dancing roller unit (Dancing Roller Unit) for flattening the polarizing film in the configuration of a polarizing film (POL) cutting device using a laser according to the present invention.

Figure 5 is a side configuration view showing an enlarged polarizing film transfer unit for transferring the polarizing film in the form of a polarizing film (POL) cutting device using a laser according to the present invention.

Figure 6 is a polarizing film adsorption unit for fixing a polarizing film and a laser cutting unit for cutting a fixed polarizing film in a configuration of a polarizing film (POL) cutting device using a laser according to the present invention and a polarizing plate cut to a certain size Side view showing an enlarged polarizing plate discharge unit for discharging and the polarizing plate alignment unit for aligning the discharged polarizing plate.

[Description of Symbols for Main Parts of Drawing]

100. Cutting device 110. Winder unit

111. Winder unit fixed frame 112. Frame support shaft

113. Winder support frame 114. Roll support shaft

115. Drive motor 116. Tension adjustment cylinder

117. Polarizing film guide roller 120. Dancing roller unit

121. Dancing Roller Unit Support Frame 122. Dancing Roller

123. Rear Guide Roller 124. Tension Roller

125. Tension adjusting cylinder 130. Polarizing film transfer unit

131. Transport frame support frame 132. Flat guide roller

133. Polarizing film feed roller 134. Drive motor

135a. Driving roller 135b. Motor

135c. Follow roller 135d. Conveyor belt

135e. Belt tensioning bar 140. Polarizing film adsorption unit

142. Support frame of adsorption unit 144. Polarization film adsorption plate

144a. Vacuum Suction Hole 150. Laser Cutting Unit

151. Cutting Unit Support Frame

153. Laser Oscillator 154. Laser Nozzle

155.LM Guide 156.Linear Motor

157. Combustion gas suction line 158. Suction pump

160. Polarizer Discharge Unit 161. Discharge Unit Support Frame

162. Polarizing plate discharge roller 163. Drive motor

164. Polarizing Discharge Follower Roller 165. Discharge Conveyor Belt

166. Belt tensioning bar 170. Polarizer alignment unit

172. Alignment Support Frame 174. Basket

176. Lifting cylinder 180. Carrier for polarizer loading

Claims (12)

In the polarizing film cutting device for cutting to a certain size while continuously unrolling the roll polarizing film wound in a roll state, The polarizing film cutting device includes a winder unit for rotatably supporting the roll polarizing film so that supply can be made while continuously unwinding; A dancing roller unit which spreads the curled polarizing film onto a flat plate while changing the direction of the polarizing film supplied through the winder unit through a plurality of rollers; A polarizing film conveying unit for conveying the polarizing film, which is flattened through the dancing roller unit, to a rear horizontal surface of a conveying line; The adsorption unit support frame and the upper side of the adsorption unit support frame, which are installed after a predetermined distance of the polarizing film transport unit, are spaced apart from each other by a predetermined interval. Polarizing film adsorption unit consisting of a polarizing film adsorption plate for fixing the polarization film by vacuum adsorption by vacuum adsorption; A laser cutting unit which cuts through the projection of a laser while moving the polarizing film fixed by vacuum adsorption by the polarizing film adsorption unit in the transverse direction to form a polarizing plate; A polarizing plate discharging unit for discharging and discharging the polarizing plate cut to a predetermined size through the laser cutting unit onto a rear-side horizontal plane; And Polarizing film (POL) cutting device using a laser, characterized in that consisting of a configuration including a polarizing plate alignment unit for stacking the polarizing plate transferred to the rear side on the transfer line through the polarizing plate discharge unit. According to claim 1, wherein the winder unit comprises a winder unit fixed frame composed of the same height on both sides; A pair of frame support shafts rotatably installed in a predetermined range on each of the opposing surfaces of the winder unit fixing frame; A pair of winder support frames installed on each of the frame support shafts in the same shape with a predetermined size; A roll support shaft rotatably supported by both winder support frames to support both sides of the branch pipe of the roll polarizing film; A support shaft drive motor installed outside the winder support frames on both sides to rotate the roll support shaft at the same speed; A tension adjustment cylinder installed at each upper side of the inner side of the winder unit fixing frame to adjust the tension of the polarizing film released from the roll state by rotating the winder support frame up and down through hydraulic pressure; And The polarizing film (POL) cutting device using a laser, characterized in that made of a configuration of a polarizing film guide roller which is installed on the upper side of the winder unit fixed frame but rotatably installed to guide the polarizing film released from the roll state. According to claim 2, wherein the dancing roller unit is a dancing roller unit support frame which is installed on both sides of the rear of the predetermined distance of the winder unit; A plurality of rotatably installed on the lower side facing surface of the dancing roller unit support frame, the polarizing film guided to the dancing roller unit by the polarizing film guide roller of the winder unit downward, rearward, upward, front A plurality of dancing rollers for turning direction and upward; The rotating roller unit is supported on the upper surface of the upper side of the supporting frame rotatably installed in a plurality of the direction of the polarizing film which is turned down, rearward, upward, forward and upward by the plurality of dancing rollers to reverse the direction backward A plurality of back guide rollers for guiding; A tension adjusting roller for adjusting the tension of the polarizing film guided rearward by the rear guide roller; And The laser is installed on the opposite surface of the dancing roller unit support frame to support the tension control roller rotatably but move up and down to make the tension adjusting cylinder for adjusting the tension of the polarizing film using a laser, characterized in that Polarizing film (POL) cutting device. According to claim 3, wherein the polarizing film transport unit is a transport unit support frame which is installed after a certain distance of the dancing roller unit; A flat guide roller installed on an upper side of the transfer unit support frame to guide the polarizing film transferred from the dancing roller unit onto a plane in a transfer line; A polarizing film forcing roller which is installed to face up and down a predetermined distance behind the flat guide roller and forcibly transfers the polarizing film through the upper and lower sides; A driving motor for driving the polarizing film forced feed roller; And The polarizing film cutting device using a laser, characterized in that consisting of a conveyor conveying means for supporting the polarizing film forcedly conveyed backward by the polarizing film forced conveying roller to the upper and conveyed to the polarizing film adsorption unit. According to claim 4, The conveyor conveying means is a driving roller which is installed on the rear side of the predetermined distance of the polarizing film forced feed roller; A driving motor for driving the driving roller; A driven roller installed vertically on the rear side of the driving roller in a vertical direction so that the polarizing film can be transferred through the vertical roller; Connect the driving roller and the lower driven roller to rotate a constant track by the rotation of the driving roller, but to support the polarizing film which is forcibly conveyed backward by the polarizing film forced feed roller through the upper portion of the polarizing film adsorption unit A conveyer belt for conveying the oil; And The polarizing film (POL) cutting device using a laser, characterized in that the roller is installed between the driven roller and the driven roller, but the tip of the rolling roller is configured to adjust the tension of the conveying belt. . The method of claim 5, wherein the rotational speed of the winder unit side support shaft drive motor, the polarizing film transfer unit side drive motor and the conveyor transfer means side drive motor is configured to rotate at the same rotational speed. Polarizing film (POL) cutting device. delete The discharge of the cut polarizing plate after cutting the polarizing film in a state in which the polarizing film is fixed by vacuum adsorption to the upper surface of the polarizing film adsorption plate through the vacuum adsorption hole of the polarizing film adsorption plate. The air is discharged through the vacuum adsorption hole of the polarizing film adsorption plate, so that the polarizing film and the polarizing plate on the upper surface of the polarizing film adsorption plate are floated by air from the upper surface of the polarizing film adsorption plate and transported. Polarizing film (POL) cutting device using a laser, characterized in that configured to be made. According to claim 8, wherein the laser cutting unit is a cutting unit support frame which is installed on the rear of the polarizing film adsorption unit; A plate having a predetermined thickness fixedly installed on the cutting unit support frame; A laser oscillator which is installed to be movable from side to side on the top of the flat plate and oscillates with the laser; A laser nozzle installed downward on the front side of the laser oscillator and installed toward an upper gap between the front and rear polarization film adsorption plates to cut the polarization film fixed on the polarization film adsorption plate through the projection of a laser; ; An LM guide installed at a predetermined distance before and after the laser oscillator to allow left and right movement of the laser oscillator; A linear motor for moving the laser oscillator from side to side on the plate; And Polarizing film (POL) cutting device using a laser, characterized in that consisting of a combustion gas suction means for suctioning and removing the combustion gas generated during laser cutting of the polarizing film. 10. The apparatus of claim 9, wherein the combustion gas suction means comprises: a combustion gas suction tube installed toward the lower side gap between the front and rear polarizing film adsorption plates to suck and remove the combustion gas generated during laser cutting of the polarizing film; And Polarizing film (POL) cutting device using a laser, characterized in that the combustion gas suction pipe is connected to generate a suction (Suction) to generate a suction pressure. 11. The apparatus of claim 10, wherein the polarizing plate discharging unit comprises: a discharging unit supporting frame installed at a rear of the cutting unit supporting frame of the laser cutting unit; A polarizing plate discharge driving roller installed on an upper side of the discharge unit support frame; A driving motor installed at an upper side of the discharge unit support frame to drive the polarizing plate discharge roller; A polarizing plate discharge driven roller spaced apart from the bottom of the flat plate of the laser cutting unit so as to face the upper and lower sides of the upper side of the cutting unit support frame to transport and discharge the polarized plate cut through therebetween; A discharge conveyor belt connecting the polarizing plate discharge driving roller and the lower polarizing plate discharge driven roller to rotate a predetermined trajectory by the rotation of the polarizing plate discharge driving roller, and conveying and discharging the cut polarizing plate backward; And Polarizing film (POL) cutting device using a laser consisting of a belt tensioning bar is installed between the polarizing plate discharge drive roller and the polarizing plate discharge driven roller, the tip roller is composed of a rolling roller to adjust the tension of the discharge conveyor belt . The method of claim 11, wherein the polarizing plate alignment unit is an alignment unit support frame which is installed on the rear of the polarizing plate discharge unit; A basket configured to be hinged on an upper rear side of the alignment unit support frame, the front end of which is installed to be rotated up and down about a hinge to collect the polarizing plate discharged through the polarizing plate discharge unit; And The polarizing film (POL) cutting device using a laser, characterized in that the configuration of the lifting cylinder is installed on the upper front side of the alignment unit support frame to move up and down the front end of the basket.

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