KR101299780B1 - Enclosed-Type Optical Film Receiving Device - Google Patents

Abstract

The present invention relates to a sealed optical film storage device for safely transporting an optical film used in the manufacture of a liquid crystal display device, the tray for loading the optical film on the plate-shaped bottom, and the optical film loaded on the tray so as not to be separated It includes an edge portion which is raised from the plate bottom along the outer periphery to form a fence, and an exhaust portion which draws air out of the tray to seal the outside.
The hermetic optical film storage device can safely transport the optical film by sealing it with the outside and can change the stacking height of the tray by using a detachable stacking structure, as well as vacuuming the tray and The vacuum release for withdrawal can be handled easily.

Description

Enclosed Optical Film Receiving Device

In the manufacturing process of producing, processing, and inspecting an optical film, the film produced is safely transported by being sealed to the outside in the process of storing and transporting the film.

As demand for liquid crystal display devices continues to increase, and production volumes soar, demand for optical films such as FPR (Film Patterned Retader) films, polarizing plates, prisms, and diffusion plates required for the production of liquid crystal displays is rapidly increasing.

Optical films are made of products through manufacturing processes such as tensile, extrusion, surface coating, lamination, and cutting to impart functionality to the resin film. Such an optical film is usually made of a product through a multi-step process of overlapping the film for each characteristic, and when the work is completed in the unit process, the film is loaded in the tray for transfer between processes to be transferred to the subsequent process.

The management of foreign matters and moisture is an important quality control item because defects can be caused by foreign matters or moisture during the manufacturing process. In particular, polarizing plates and 3D film patterned retarder (FPR) films used in liquid crystal display devices are very sensitive to moisture, and therefore, there is a demand for minimizing exposure to moisture in the process and storing and moving them.

Conventionally, a method of loading and transporting a film in a tray without a cover is used. In order to exclude the effect of foreign matter or moisture, the film is vacuum-packed and transported per unit process, and the packaging is peeled off again, and then a subsequent process is performed. Accordingly, the vacuum packaging requires a lot of man-hours and manpower, as well as the size of the optical film is increasing the handling difficulties.

In order to solve the above problems, one side of the present invention is to safely transport the optical film loaded in the tray sealed with the outside.

Another aspect of the present invention is to change the stack height of the tray in accordance with the number of the optical film using a tray of a detachable laminated structure to facilitate handling of the transfer operation.

Another aspect of the present invention is to conveniently handle the operation of evacuating the tray for transfer and of the vacuum release for withdrawal of the optical film.

Such a sealed optical film receiving device according to an embodiment of the present invention, the tray for loading the optical film on the plate-shaped bottom; An edge portion formed to form a fence by being raised from the plate bottom along the outer periphery of the tray so that the optical film loaded on the tray is not separated; And an exhaust unit installed in the edge portion to seal the loading space of the tray by removing the air of the tray to the outside.

The edge portion includes a stepped portion formed on the upper portion of the edge portion, a holder formed on the lower portion of the edge portion, and an airtight member embedded in the holder to maintain airtightness.

The stepped portion and the airtight member of the rim are coupled to the upper tray and the lower tray by press fitting, respectively, and the airtight member is composed of a band-shaped rubber packing.

The edge portion further includes a through hole for communicating with the outside, wherein the exhaust portion communicates with the inside of the tray to form a working space for bleeding air; A communication hole formed in the housing, a push rod reciprocating in the operating space of the housing, and the push rod being returned to its original position when compressed by the push rod in the operating space of the housing or released from the push rod. Compression spring to return and includes a head and a stopper respectively coupled to one side and the other side of the push rod.

The head is made of rubber sealing, and the stopper is combined with the air pump.

The exhaust part has a plurality of air passages connecting between the loading space of the tray and the outside and a receiving hole formed on one side of the edge portion, and a stopper accommodated in the receiving hole to selectively block the loading space and the outside. Contains wealth.

The stopper part is made of a silicone material, including a body and a push button, the plurality of air flow passages are composed of a fitting hole and a through hole, the fitting hole is always closed by the body of the stopper is fitted, the through hole is one side of the loading It communicates with the space and the other side is in close contact with the push button, or is opened when the push button is lifted.

The exhaust portion is connected to the loading space and the outside of the tray and the receiving hole formed on one side of the rim portion, the stopper portion accommodated in the receiving hole to selectively block between the loading space and the outside, and the plug portion It is coupled to include an operating lever for operating the stopper in the closed position or the open position, and a guide groove for guiding the movement of the operating lever.

The stopper includes a stopper body, a compression spring coupled to the stopper body, and a ball elastically supported by the compression spring and moved by the operation lever, wherein the exhaust part includes a loading space of the tray and the accommodation. A common passage connecting a hole and a nozzle hole connected to the common passage and accommodating the plug body, wherein the nozzle hole is closed when the ball is blocking the common flow passage and the ball is not blocking the common passage. The nozzle hole opens.

As described above, the hermetic optical film accommodating device according to the present exemplary embodiment may seal the optical film loaded on the tray with the outside to be safely transported, and may use a tray having a stackable structure to separate the trays according to the number of optical films. The stacking height can be changed to facilitate the conveying operation, and the process of vacuuming the tray for conveying and releasing the vacuum for extracting the optical film can be easily performed.

1 is a perspective view for explaining the overall configuration of the sealed optical film receiving apparatus according to an embodiment of the present invention.
FIG. 2 is a view for explaining an edge by disassembling a part of the sealed optical film accommodating device of FIG. 1.
3 is an exploded view illustrating an exhaust part by disassembling a part of the sealed optical film accommodating device of FIG. 1.
FIG. 4 is a cross-sectional view illustrating an exhaust part of the hermetic optical film accommodating device of FIG. 1.
Figure 5 is a perspective view for explaining the main part of the sealed optical film receiving apparatus according to another embodiment of the present invention.
FIG. 6 is a view of a portion cut away to explain an exhaust part of the sealed optical film accommodating device of FIG. 5.
FIG. 7 is a cross-sectional view of a portion of the closed optical film accommodating device of FIG.
8 is a perspective view for explaining the main part of the sealed optical film receiving apparatus according to another embodiment of the present invention.
FIG. 9 is an enlarged view of a part of an exhaust part of the sealed optical film accommodating device of FIG. 8.
FIG. 10 is a cross-sectional view of a portion of the closed optical film accommodating device of FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As can be seen in Figure 1, the sealed optical film receiving device 1 is a tray 100 having a plate-like bottom for loading the optical film and the edge portion 110 forming a fence along the outer edge of the tray 100 And an exhaust unit 120 provided at the edge portion 100.

The hermetic optical film accommodating device 1 may apply a coupling structure that can be stacked and separated in the vertical direction in individual units. As can be seen in FIG. 1, another second storage device 2 may be stacked below one first storage device 1, and the tray 100 of the first storage device 1 may have a second storage device. It serves as a cover to cover the top of the device (2). The stacking structure may be repeatedly stacked upwards or downwards to adjust the overall stacking height of the storage device.

Since the same shape and structure apply to the 1st storage device 1 and the 2nd storage device 2, the individual structure of the hermetically sealed optical film storage device is demonstrated below.

As can be seen in Figures 2 to 4, the edge portion 110 forms a fence along the outside of the tray 100.

The edge portion 110 traps several optical films loaded on the tray 100 so that the loaded optical films are not separated. Separately, a support member may be added to limit the movement of the optical film loaded on the tray 100.

The edge portion 110 includes a holder 114 coupled to a tray placed below, a stepped 115 coupled to a tray placed above, and an airtight member 111 embedded in the holder 114.

A strip-shaped airtight member 111 is fitted into the recessed groove of the holder 114. The airtight member 111 is manufactured by rubber packing and is fixedly installed by pressing.

The step 115 is formed with a protrusion facing the holder to enter the holder recess groove of the upper tray.

As the step 115 of the edge portion 110 press-fits the airtight member fitted into the holder recess groove of the upper tray, the loading space of the tray 100 has a sealed structure in which outside and air are blocked. That is, the stepped portion 115 of the edge portion may prevent the air from escaping through the gap by pressing the airtight member embedded in the holder of the upper tray by the weight of the upper tray and the weight of the loaded optical film.

Even when the optical film is loaded on the tray 100 and the other tray is covered on the top to form a sealed structure, it is necessary to remove the air remaining in the loading space of the tray 100 to maintain proper humidity. To this end, the exhaust portion 120 for extracting air from the loading space to the outside and sealing the vacuum is applied.

The exhaust unit 120 is fixed to the outside of the rim 110, the housing 122 for providing an operating space, and the communication hole formed in the housing 122 facing the through hole 112 of the tray 100 ( 121, the push rod 124 reciprocating in the operating space of the housing 122 and the push rod 124 in the operating space of the housing 122, the push rod 124 is pushed when the compression force of the push rod 124 is released Compression spring 125 for returning the rod to its original position, and the head 123 and the stopper 126 coupled to one side and the other side of the push rod 124, respectively.

Referring to FIG. 4, the head 123 of the push rod 124 is supported by the compression spring 125. Here, the head 123 may be manufactured by rubber sealing. In general, the head 123 is located at the rear of the communication hole 121 to seal the operating space of the housing 122.

One end of the stopper 126 is coupled to close one side of the housing 122 and the other end is in contact with the push rod 124, the center of the stopper 126 is a nozzle (not shown) that can be coupled to the inlet of the air pump It can form a hole.

When the inlet of the air pump is coupled to the nozzle hole of the stopper 126 to push the stopper 126, the push rod 124 is pushed into the working space by the stopper 126 to compress the compression spring 125. Accordingly, when the head 123 passes through the communication hole 121, the communication hole 121 communicates with the outer space of the push rod 124 having a small diameter, and the outer space and the nozzle hole are connected to each other. When the air pump is operated in a state in which the air pump is blocked by the airtight member 111, the air remaining in the loading space of the tray 100 by the suction force of the air pump passes through the through hole 112, the communicating hole 121, and the push rod. It is sucked through the outer space of 124 and the nozzle hole of the stopper 126, and the loading space of the tray 100 is evacuated as this suction process continues.

Since the loading space is sealed in a vacuum state, the push rod 124 may be retracted to the rear of the working space of the housing 122 by the elastic force of the compression spring 125 as the pressing force is released to the push rod 124. . When the head 123 of the push rod 124 is returned to the rear of the communication hole 121, the outer space of the communication hole 121 and the push rod 124 is blocked from each other, so that the loading space of the tray 100 is vacuumed. State can be maintained.

In this manner, the storage device 1 may be safely transported in a vacuum sealed state of the tray 100 so as to process a subsequent process. When the optical film is taken out of the storage device 1 in preparation for the subsequent process, when the stopper 126 is pressed, external air flows in through the nozzle hole, and the introduced external air communicates with the outer space of the push rod 124. 121) and enters the loading space of the tray 100 through the through hole 112, and after a predetermined time, the stacked tray 100 may be easily peeled off to take out the optical film.

The exhaust unit 120 described above applies a method of extracting or injecting air by advancing and pushing the push rod 124 in the operating space of the housing 122, but is not limited thereto. Various types of exhaust structures that can intake and inject air can be applied. Hereinafter, another embodiment of the exhaust unit will be described with reference to the drawings.

5 to 7 are views for explaining the hermetic optical film accommodating device 1A to which an exhaust port according to another embodiment is applied.

As can be seen in the figure, the receiving device 1A includes a tray 100A, an edge portion 110A, and an exhaust portion 130, where the tray 100A and the edge portion 110A are the same as in the above-described embodiment. It may include a functionally identical configuration in the tray 100 and the edge portion 110. That is, it can be configured to include a step, the holder and the airtight member.

The exhaust unit 130 may include a stopper 133 accommodated in the accommodation hole 131 and the accommodation hole 131 to selectively block the load space between the tray 100A and the outside.

The receiving hole 131 has a plurality of air passages 132A and 132B connecting between the loading space of the tray 100A and the outside and is formed at one side of the edge portion 110A. One air passage 132A is a fitting hole for fitting the plug portion 133, and the other air passage 132B is a through hole used to extract air from the loading space or inject external air.

The stopper 133 includes a body 134 and a push button 135. The stopper 133 may be made of a silicon material.

The body 134 extends along the center of the shaft and is fixedly embedded in the fitting hole 132A, and the fitting hole 132A is always closed by fitting the body 134 of the stopper 133.

The push button 135 extends to one side of the body 134 and includes a wing formed to be convex in a circle. The wing of the push button 135 is in close contact with the through-hole 132B to shield the outside. One end of the through hole 132A communicates with the loading space of the tray 100A, and the other end is in close contact with the push button 135.

As illustrated in FIG. 7, when the push button 135 is connected by connecting the inlet of the air pump, the wing is lifted and the through hole 132B is opened. When the air pump is operated in this state, the air remaining in the loading space of the tray 100A is sucked through the through hole 132B to make the loading space into a vacuum state.

Since the loading space is sealed in a vacuum state, the release space of the tray 100A may be maintained in a vacuum state as the through hole 132B is blocked by releasing the pressing force to the push button 135.

When the optical film is taken out of the loading space of the tray 100A, the push button 135 is pressed, and at this time, the outside air is introduced into the gap of the push button 135 where the outside air is lifted and enters the loading space through the through hole 132B. After a period of time, the trays stacked on top can be easily peeled off.

8 to 10 are views for explaining the hermetic optical film accommodating device 1B to which an exhaust port according to another embodiment is applied.

As can be seen in the figure, the storage device 1B includes a tray 100B, an edge portion 110B, and an exhaust portion 140, wherein the tray 100B and the edge portion 110B are formed in the above-described embodiment. It may include a functionally identical configuration in the tray 100 and the edge portion 110. That is, it can be configured to include a step, the holder and the airtight member.

The exhaust unit 140 connects between the loading space of the tray 100B and the outside and accommodates the receiving hole 141 formed at one side of the edge portion 110B, and is accommodated in the receiving hole 141 to load the tray 100B. A stopper portion 142 for selectively blocking the space between the outside and the outside, an operation lever 148 coupled to the stopper portion 142 to operate the stopper portion 142 in a closed position or an open position, and an operation lever 148 Guide groove 149 for guiding the movement of the).

The stopper 142 includes a stopper body 143, a compression spring 144 coupled to the stopper body 143, and a ball 145 elastically supported by the compression spring 144 and moved by the operation lever 148. ), Including Ball 145 may be made of a silicon material, the operation lever 148 is hinged to the support shaft 148A, it can move up and down in the guide groove 149.

The exhaust unit 140 includes a common passage 146 connecting the loading space of the tray and the receiving hole, and a nozzle hole 147 connected to the common passage 146 and accommodating the stopper body 143.

The ball 145 may be located at a point connecting the common flow path 146 and the nozzle hole 147. When the ball hole 145 is blocking the common flow path 146 and the nozzle hole 147 is closed and lifted by the operation lever 148, the common flow path 146 and the nozzle hole 147 are connected to each other and the nozzle hole 147 is connected. Is opened.

As shown in FIG. 10, when the inlet of the air pump is connected to the nozzle hole 147 and the ball 145 is lifted by the operation lever 148, the common flow path 146 and the nozzle hole 147 are connected to each other. When the air pump is operated in this state, the air remaining in the loading space of the tray 100B is sucked through the common flow path 146 and the nozzle hole 147 to make the loading space vacuum.

After the loading space is sealed in a vacuum state, when the ball 145 blocks the common flow path 146 by the operation lever 148, the loading space of the tray 100B may maintain a vacuum state.

When the optical film is taken out of the loading space of the tray 100B, when the ball 145 is lifted by the operation lever 148, outside air is introduced through the nozzle hole 147 and the common flow path 146 of the tray 100B is removed. Enter the loading space. After a period of time, the trays stacked on top can be easily peeled off.

100, 100A, 100B: Tray
110, 110A, 110B: Border
120, 130, 140: exhaust

Claims (9)

delete delete delete A tray for loading the optical film on the plate bottom;
An edge portion formed to form a fence by being raised from the plate bottom along the outer periphery of the tray so that the optical film loaded on the tray is not separated;
And an exhaust unit installed at the edge portion to seal the loading space of the tray by removing air from the tray to the outside.
The edge portion further includes a through hole for communicating with the outside,
The exhaust portion communicates with the inside of the tray to form an operating space for extracting air, a communication hole formed in the housing facing the through hole to communicate between the through hole and the operating space, and the operating space of the housing. A push rod reciprocating at a, a compression spring for returning the push rod to its original position when the push rod is compressed by the push rod in the operating space of the housing or released from the push rod, and at one side and the other side of the push rod. Sealed optical film receiving device comprising a head and a stopper, respectively coupled.
5. The method of claim 4,
The head is made of a rubber seal, the closure is sealed optical film receiving device coupled to the air pump.
A tray for loading the optical film on the plate bottom;
An edge portion formed to form a fence by being raised from the plate bottom along the outer periphery of the tray so that the optical film loaded on the tray is not separated;
And an exhaust unit installed at the edge portion to seal the loading space of the tray by removing air from the tray to the outside.
The exhaust part has a plurality of air passages connecting between the loading space of the tray and the outside and a receiving hole formed on one side of the edge portion, and a stopper accommodated in the receiving hole to selectively block the loading space and the outside. Sealed optical film receiving device comprising a portion.
The method according to claim 6,
The stopper is made of a silicone material, including a body and a push button,
The plurality of air flow passages are composed of fitting holes and through holes,
The fitting hole is always closed by fitting the body of the stopper,
The through-hole is sealed optical film storage device that one side is in communication with the loading space and the other side is in close contact with the push button or open when the push button is lifted.
A tray for loading the optical film on the plate bottom;
An edge portion formed to form a fence by being raised from the plate bottom along the outer periphery of the tray so that the optical film loaded on the tray is not separated;
And an exhaust unit installed at the edge portion to seal the loading space of the tray by removing air from the tray to the outside.
The exhaust portion is connected to the loading space and the outside of the tray and the receiving hole formed on one side of the rim portion, the stopper portion accommodated in the receiving hole to selectively block between the loading space and the outside, and the plug portion And an operation lever coupled to operate the stopper in a closed position or an open position, and a guide groove for guiding the movement of the operation lever.
9. The method of claim 8,
The stopper portion comprises a stopper body, a compression spring coupled to the stopper body, and a ball elastically supported by the compression spring and moved by the operation lever,
The exhaust part includes a common passage connecting the loading space of the tray and the receiving hole and a nozzle hole connected to the common passage and accommodating the stopper body.
And the nozzle hole is closed when the ball is blocking the common flow path and the nozzle hole is opened when the ball is not blocking the common flow path.

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