KR101036366B1 - Electronic paper display device and manufacturing method thereof - Google Patents

Abstract

The present invention relates to an electronic paper display device and a method of manufacturing the same.

A lower electrode on the plate; Barrier rib structures formed on the lower electrodes; A twist ball injected into each cell formed by the partition wall of the partition structure; An upper electrode attached to an upper portion of the barrier rib structure; And two kinds of oils having different specific gravity filled between the upper electrode and the lower electrode, wherein the twisted ball is positioned at an interface formed by different kinds of oils so that the outer surface of the twisted ball is partitioned. Thus, by preventing the contact with the lower substrate can be produced an effect that can lower the drive speed and drive voltage of the twist ball.

Electronic paper, lower electrode, bulkhead structure, twist ball, upper electrode, oil, adhesive

Description

Electronic paper display device and manufacturing method thereof

The present invention relates to an electronic paper display device and a method of manufacturing the same. More specifically, the twist balls injected between the upper and lower substrates have different specific gravity and are uniformly arranged at regular intervals and heights in oils separated from phases. An electronic paper display device and a method of manufacturing the same.

BACKGROUND With the development of technology related to displays, displays such as liquid crystal displays (LCDs), plasma display panels (PDPs), and organic electroluminescent devices (elector luminescence) are widely used.

Recently, the development of electronic paper display elements, called digital paper displays (DPDs), has been accelerated as the next-generation display devices following the aforementioned display devices, and electronic papers are flexible display devices. As an alternative to the aforementioned flat panel display device, it is in the spotlight.

The electronic paper display device is a flat-panel display device in which letters or images can be displayed by realizing the effect of ink by millions of twist balls or capsules injected between flexible substrates such as thin plastics. Since it does not require a backlight or continuous recharging, it can be driven with very little energy, so the energy efficiency is excellent.

In addition, since the electronic paper display device has a clear and wide viewing angle and a memory function in which displayed characters or images do not disappear completely even when the power supply is momentarily cut off, the electronic paper display element can be folded including print media such as books, newspapers or magazines. It is expected to be widely used in a wide range of fields such as screens and electronic wallpaper.

On the other hand, the technical method to implement the electronic paper display device is largely a liquid crystal method, an organic EL method, a reflective film reflective display method, an electrophoretic method, a twist ball method, an electrochromic method, a mechanical reflective display method, etc. The development is divided into.

Among these, the electronic paper display device using the twist ball has a dielectric liquid on the surface of the twist ball in arranging a plurality of twist balls having optical and electrical anisotropy between two parallel conductors, namely, the upper and lower substrates. And a twisted ball coated with a dielectric liquid are attached to an elastomer sheet to produce an electronic paper display device.

In this case, in the conventional electronic paper display device, the twisted ball is positioned between the lower and upper substrates to which the twisted ball is applied, and is rotated around the dielectric sheet on the elastomer sheet by the applied electric field, thereby being transparent or opaque. Due to the positional arrangement of the segments, text or image display is made.

However, the twist ball, which is rotationally driven by the electric field in the elastomer sheet, has a disadvantage in that a uniform arrangement is difficult because it is arranged in a line in an application manner on the elastomer sheet.

In other words, when arranged in an application manner on the elastomer sheet, the twist balls must be constantly arranged, but may not be arranged in line but arranged out of place.

In addition, if an electric field is applied to the upper and lower electrodes after the arrangement of the twist balls, the twist balls may be rotated and rotated, thereby causing stacking between the twist balls.

Therefore, the conventional electronic paper display device using a twist ball has a problem that the manufacturing process is difficult and complicated as the twist ball is to be arranged uniformly or a separate spacer must be installed so that a constant distance is maintained between the upper and lower electrodes. There was this.

Accordingly, the present invention was devised to solve the above-mentioned disadvantages and problems in the conventional electronic paper display device, and a twist ball is injected into the partition structure formed on the lower electrode, and the upper and lower electrodes are sealed therebetween. An object of the present invention is to provide an electronic paper display device and a method of manufacturing the same, by which two kinds of oils having different specific gravity and phase-separated oils can be arranged uniformly while maintaining a constant distance from the upper and lower electrodes. have.

The object of the present invention, the lower electrode; Barrier rib structures formed on the lower electrodes; A twist ball injected into each cell formed by the partition wall of the partition structure; An upper electrode attached to an upper portion of the barrier rib structure; And two kinds of oils, which are filled between the upper electrode and the lower electrode and separated from each other with different specific gravity, to achieve an electronic paper display device.

The lower electrode is composed of a thin plate-like substrate having conductivity, and the partition structure is provided in various patterns on the top. The partition structure is formed with a plurality of cells divided through partitions of various shapes in a state where the upper surface and both sides are open.

In addition, the barrier rib structure may be manufactured by an imprint process through a roll stamp, and a cell having various types of barrier ribs may be formed by a roll stamp made of a thermosetting resin or a UV curable resin.

Meanwhile, twist balls divided into transparent or opaque segments are injected into each cell of the barrier rib structure. The twist ball is applied to the upper portion of the partition structure and then injected into each cell through a squeeze method, and in this case, the squeeze method may be repeated several times to increase the filling rate of the twist ball.

An upper electrode is attached to an upper portion of the barrier rib structure in which the twist ball is injected into each cell. The upper electrode is preferably composed of a transparent electrode (ITO) so that light can be transmitted and reflected or absorbed through the transparent or opaque segment of the twist ball.

In this case, the upper electrode may be attached to the partition structure by an adhesive, and may be joined by a roll to roll method when forming the partition structure by a roll stamp and injecting twist balls by a squeeze process.

On the other hand, two kinds of oils which are phase-separated in the barrier ribs are injected into the barrier rib structure between the upper electrode and the lower electrode, and the twist ball is filled in each cell of the barrier rib structure. By being located on the phase-separated boundary of the, the phase, the lower electrode and the twist ball to maintain a constant interval, and to be rotatable on the phase-separated interface of the oil when forming the electric field between the upper and lower electrodes.

At this time, one of the two types of oil has a specific gravity lower than the twist ball, the other type of oil is composed of oil having a higher specific gravity than the twist ball, so that the twist ball is located at the phase separation interface due to the specific gravity difference. It is preferable to.

The oil may be filled through an oil inlet formed by exposing portions of both sides of the barrier rib structure, and the oil inlet is sealed after being filled without bubbles between the upper and lower electrodes in various ways including a vacuum injection method.

Another object of the present invention is the step of applying a resin layer on the lower electrode on the plate, forming a partition structure consisting of a plurality of cells separated by the partition wall on the resin layer, and a twist ball inside the cell of the partition structure Electronic paper comprising the steps of: injecting, and attaching an upper electrode to the upper portion of the partition structure and injecting two kinds of oil having a different specific gravity on the partition structure between the upper and lower electrodes, phase separated The manufacturing method of the display element is achieved.

The resin layer applied on the lower electrode may be formed of a thermosetting resin or a UV curable resin, and is formed as a barrier rib structure having a plurality of cells in an imprint method through a roll stamp on the conductive lower electrode.

At this time, it is preferable that the pressing surface of the roll stamp is easy to be released from the resin layer by being released.

The two types of oil injected between the upper and lower electrodes are one type of oil larger than the specific gravity of the twisted ball, and the other type of oil is smaller than the specific gravity of the twisted ball so that the twist ball is located at the phase separation interface of the oil. It is preferred to consist of oil.

As described above, the electronic paper display device of the present invention has a predetermined distance from the upper and lower electrodes by the twist balls are arranged inside the cell formed in the barrier rib structure and the oil injected from the upper and lower barrier ribs having different specific gravity. By maintaining it, there is an advantage that the contrast ratio is improved by preventing the phenomenon in which the twist balls are stacked when voltage is applied, and there is an advantage that a uniform arrangement of the twist balls in two kinds of oils having a phase separation interface is possible.

In addition, the electronic paper display device of the present invention simplifies the display device fabrication process by performing a batch process as a twist ball is injected at the same time as forming the partition structure through a roll stamp, and then the upper electrode is attached by a roll-to-roll process There is an advantage to this.

In addition, the electronic paper display device of the present invention is that the twist ball is located on the boundary surface formed by different kinds of oil, thereby preventing the outer surface of the twist ball from contacting the partition wall and the upper and lower substrates to drive the twist ball. The effect of lowering the speed and the driving voltage can be exerted.

The matters relating to the operational effects including the technical configuration for the above object of the electronic paper display device and the manufacturing method of the present invention will be clearly understood by the following detailed description with reference to the drawings showing preferred embodiments of the present invention.

First, Figure 1 is a cross-sectional view of the electronic paper display device according to the present invention.

As shown, the electronic paper display device 100 according to the embodiment of the present invention includes a lower substrate 110 on a plate, a partition structure 120 formed on the lower substrate 110, and each of the partition structure 120. Two kinds of oils 150a and 150b injected between the twist ball 130 injected into the cell 121, the upper electrode 140 tightly coupled to the partition structure 120, and the upper and lower partitions 110. It consists of

The lower substrate 110 is formed of a conductive substrate such as Cu, Au, and the partition structure 120 is divided into a plurality of cells 121 by the partition wall 122 formed at a predetermined interval on the upper portion of the predetermined thickness. Is formed.

The partition structure 120 is separately injected with a twist ball 130 divided into a transparent segment 131 and an opaque segment 132 inside each cell 121 divided by the partition wall 122. In this case, the partition wall 122 may be formed as a partition wall having various shapes and heights that can prevent the twist ball 130 from moving to the neighboring cells 121, and preferably cross the center portion It is preferable that the barrier rib is formed in the shape of a).

In addition, the partition wall 122 formed in the partition structure 120 is preferably formed to a height of approximately 50 to 110㎛ so that the twist ball 130 injected into each cell 121 does not move to the neighboring cell 121. The inner width of each cell 121 may be 50 to 100 μm, and the width of the partition wall 122 may be 20 to 30 μm.

In addition, the barrier rib structure 120 may be formed of the barrier rib 122 and the cell 121 by using an imprint method. In this embodiment, the barrier rib 122 and the cell 120 may be formed using a roll stamp. ) Is formed, and the pattern formation and the process of the barrier rib structure 120 will be described in more detail in the following description of the electronic paper display device manufacturing method.

The barrier rib structure 120 is configured in such a way that the oil inlet 123 formed on the upper surface and a part of both sides thereof is open, and a plurality of twist balls 130 are applied to the upper surface to each cell 121 by a squeeze method. Twist ball 130 is injected separately.

At this time, the twist ball 130 injected into each cell 121 of the partition structure 120 may repeat the squeeze process several times to increase the filling rate of the twist ball 130 injected into each cell 121. It is preferable to.

When the twist ball 130 is individually filled in each cell 121 of the barrier rib structure 120, the upper electrode 140 is attached to the upper portion of the barrier rib structure 120.

The upper electrode 140 is composed of a transparent electrode (ITO), the external light is transmitted through the transparent upper electrode 140 and reflected through the transparent segment 131 or the opaque segment 132 of each twist ball 130 Or a combination of light reflected or absorbed by the twist ball 130 so that a character or an image can be displayed to the outside through the upper electrode 140.

At this time, the positive electrode and the negative electrode are connected to the upper and lower electrodes 140 and 110, respectively, so that an electric field is generated by applying a voltage to each of the electrodes 140 and 110. As the twist ball 130 injected into each cell 121 of the barrier rib structure 120 is rotated by the electric field generated between the electrodes 140 and 110, the light reflection and the light absorption by the twist ball 130 are reduced. Will be done.

Meanwhile, the twist ball 130 filled in the barrier rib structure 120 between the upper and lower electrodes 140 and 110 is rotated through an electric field, and within each cell 121 of the barrier rib structure 120. Rotation is made by itself inside each cell 121 with the oil 150 being filled as a medium.

The two kinds of oils 150a and 150b are composed of a liquid material having some viscosity and specific gravity, and are liquid materials capable of converting liquid phase and having a lubricating component, that is, Dow corning 10, Centistoke 200, and vinyl ( Two kinds of oils are selectively used in the liquid substance group such as vinyl), nylon and accrylic.

The oils 150a and 150b may be injected through oil inlets 123 formed on both sides of the barrier rib structure 120, and a vacuum injection method in a vacuum chamber is mainly adopted to allow the upper and lower electrodes 140 ( 110) can be filled without bubbles. The oil inlet 123 is sealed after the oil injection is completed, and after the upper electrode 140 is attached to the partition structure 120, the oil structures 150a and 150b are injected from both sides or one side of the partition structure 120. Since there is no residual oil on the attachment surface of the upper electrode 140, the bonding reliability of the upper electrode 140 may be improved.

In the electronic paper display device 100 of the present embodiment configured as described above, the individual twist balls 130 are each cell through the partition wall 122 of the partition structure 120 provided between the upper and lower electrodes 140 and 110. Twist ball 130 in two kinds of oils 150a and 150b which are individually positioned inside the 121 and have different specific gravity filled in each cell 121 between the upper and lower electrodes 140 and 110. ) Is located.

At this time, the oil (150a, 150b) is phase separated on the partition structure 120 by different specific gravity, the twist ball 130 is located on the phase separation interface of each oil (150a, 150b), The twist ball 130 may be rotated by using the oils 150a and 150b as a medium due to an electric field generated when the voltages of the upper and lower electrodes 140 and 110 are applied.

In addition, the oil 150a and 150b has a specific gravity greater than that of the twist ball 130 so that the twist ball 130 is located at the phase separation interface, and the other type of oil 150b. ) Is preferably formed with a specific gravity smaller than the twist ball (130).

Accordingly, the twist ball 130 is suspended in the phase separation interface through two kinds of oils 150a and 150b having different specific gravity filled in each cell 121 and the upper portion of the partition structure 120. And maintained at a predetermined distance from the upper and lower electrodes 140 and 110, and phase separation of the oils 150a and 150b by an electric field generated between the upper and lower electrodes 140 and 110. As the transparent or opaque segments 131 and 132 are rotated on the upper electrode 140 to be rotated at the interface, text or image display is possible by the rotation combination of the respective twist balls 130.

Meanwhile, a method of manufacturing an electronic paper display device having the above technical configuration will be described with reference to FIGS. 2 to 4 as shown below.

2 is a configuration diagram of a process for manufacturing an electronic paper display device according to the present invention, FIG. 3 is a plan view of a partition structure of the electronic paper display device according to the present invention, and FIG. 4 is an oil of the electronic paper display device according to the present invention. Sectional view during injection.

As shown, the electronic paper display device of the present embodiment first prepares a lower electrode 110 composed of a thin plate-like substrate, and then applies a resin layer on the lower electrode 110 to a predetermined thickness.

At this time, the resin layer may be composed of a thermosetting resin or UV curable resin, the thickness thereof when the partition wall 122 is formed, the twist ball 130 does not flow through the partition wall 122 and at the edge portion When the upper electrode 140 is attached, the twist ball 130 is preferably formed to a thickness that can be injected into the partition structure 120 without interfering with the upper electrode 140.

The resin layer is formed of a barrier rib structure 120 formed of a plurality of cells 121 separated by the barrier rib 122, and the barrier rib structure 120 is an imprint method using a roll stamp 200 as shown in FIG. 2. Is formed.

The partition wall structure 120 has the partition wall 122 and the cell 121 formed in the resin layer by the rotation of the roll stamp 200. The partition wall 122 is formed according to the shape of the stamp 210 of the roll stamp 200. ), And the shape of the cell 121 is preferably formed through the bulkhead 122 having a cross shape, as shown in FIG. 3.

The roll stamp 200 should be made of a roll stamp 200 that can be processed to the precise partition wall 122 and the cell 121 on the partition structure 120, the roll stamp 200 is the angle of the circumferential surface The stamp 210 has a suitable strength and a uniform stamp surface of the pressing surface by copper plating in which a strength agent is added to the pressing surface.

In addition, the roll stamp 200 polishes the surface of each stamp 210, and then performs chrome plating and performs a release process by dipping or vaporizing the water through the roll stamp 200. When the imprint of the strata is easy release, the precise partition wall 122 and the cell 121 can be formed.

At this time, the pressure of each stamp 210 of the roll stamp 200 to pressurize the resin layer is preferably applied to the pressure of about 1.5kgf / ㎠, the partition wall 122 by the rotation of the roll stamp 200 and After the cell 121 is formed and cured at 100 ° C. for 30 minutes, the cell 121 is cured at 180 ° C. for 1 hour to be completely cured into the partition wall structure 120 in which the partition wall 122 and the cell 121 are formed.

In addition, when the partition 122 and the cell 121 are formed by the roll stamp 200, the size of each cell 121 is a cube having a width of 100 × 100 μm or more and a depth of 100 μm or more in an open state. It is preferable that the concentricity of the twist ball 130 filled in each cell 121 is configured in the form of to be maintained within 5㎛.

Next, when the barrier rib structure 120 is formed on the lower electrode 110, the twist balls 130 are individually filled in the cells 121 of the barrier rib structure 120.

The twist ball 130 is applied on the partition structure 120 when the lower electrode 110 on which the partition structure 120 is formed is horizontally transported, as shown in FIG. The twist ball 130 is injected into each cell 121 of the barrier rib structure 120 through S).

In this case, the filling rate of the twist ball 130 injected into each cell 121 of the barrier rib structure 120 may be increased by repeatedly transferring the squeeze S on the barrier rib structure 120.

When the filling of the twist ball 130 is completed in each cell 121 of the barrier rib structure 120, the upper electrode 140 made of a transparent electrode ITO is attached to the barrier rib structure 120. The upper electrode 140 is attached on the barrier rib structure 120 using the adhesive 160.

When the upper electrode 140 is attached to the partition structure 120 as described above, only the twist ball 130 is filled between each of the upper and lower electrodes 140 and 110 in the cell 121. As the 140 is bonded, contamination of the upper surface of the barrier rib structure 120 may be prevented, and reliability at the time of bonding the upper electrode 140 may be secured.

Next, when the twist ball 130 is sealed by the upper and lower electrodes 140 and 110 with the partition structure 120 interposed therebetween, the partition structure 120 through the oil inlet 123 of the partition structure 120. Two kinds of oils 150a and 150b having different specific gravity are injected into the upper portion of each cell 121 and the inside of each cell 121 in the same amount.

The oils 150a and 150b may be injected through the oil inlets 123 formed on one side or both sides of the partition structure 120, and the oils 150a in the upper and lower electrodes 140 and 110. Preferably, 150b is injected in a vacuum manner so that it can be completely filled.

That is, the electronic paper display element sealed by the upper and lower electrodes 140 and 110 is positioned in the vacuum chamber, and the oil inlet 123 of one or both sides is positioned in the oil 150 by maintaining the vacuum chamber in a vacuum state. After the injection, pressurized by injecting an inert gas such as argon (Ar) into the vacuum chamber so that oils 150a and 150b may be injected through the oil inlet 123 by the pressure difference.

At this time, the present embodiment adopts a method of filling the oil 150a, 150b without bubbles between the upper and lower electrodes 140 and 110 by a pressure difference using a vacuum chamber. However, the oil injection method is not limited thereto, and may be a method in which oils 150a and 150b are injected between the upper and lower electrodes 140 and 110 in various ways.

In addition, a twist ball 130 floats inside each cell 121 on a phase separation interface formed by two kinds of oils 150a and 150b injected between the upper and lower electrodes 140 and 110. When the voltage is applied to the upper and lower electrodes 140 and 110, the phase separation interface of the oils 150a and 150b is formed in each cell 121 by the oils 150a and 150b as a medium. The rotation is made around the center.

Accordingly, in order to allow the twist ball 130 to float in the two kinds of oils 150a and 150b at regular intervals with the upper and lower electrodes 140 and 110, the twist ball 130 may be used as a reference to the twist ball 130. One type of oil 150a is larger than the specific gravity of the twist ball 130, and the other type of oil 150b is preferably composed of an oil smaller than the specific gravity of the twist ball 130.

Meanwhile, as shown in FIG. 2, the electronic paper display device according to the present embodiment forms a partition structure 120 through the roll stamp 200 and at the same time, the twist ball using the squeeze S at the rear of the roll stamp 200. The filling of the 130 is performed, and the upper electrode 140 is bonded to the upper part of the partition structure 120 by a roll to roll method when the lower electrode 110 is formed. It is possible to carry out a series of paper making operations once.

Next, Figure 5 is a cross-sectional view according to an embodiment of the oil injection structure employed in the electronic paper display device according to the present invention.

As shown, Figure 5a relates to the oil injection structure applied to this embodiment, the twist ball 130 of the two types of oil (150a, 150b) having different specific gravity as described above due to the difference in specific gravity In this case, the twist ball 130 is positioned at the phase separation interface formed by the difference in specific gravity of the oils 150a and 150b.

In addition, Figure 5b relates to another oil injection structure that can be applied to this embodiment, so that the twist ball 130 can be located in the three types of oil (150a ~ 150c) having different specific gravity. At this time, the specific gravity of each of the oils 150a to 150c is greater than that of the oil 150b and the twist ball 130 having a greater specific gravity than the oil 150a and the twist ball 130 having the same specific gravity based on the twist ball 130. It consists of the oil 150c which has a small specific gravity.

 Accordingly, in the electronic paper display device employing the oil injection structure of FIG. 5B, the twist ball 130 is maintained in the floating state in the oil 150a having the same specific gravity, and the specific gravity is higher in the upper and lower portions of the oil 150a, respectively. Or the small oils 150b and 150c are separated from each other, so that the twist ball 130 may maintain a constant distance from the upper and lower electrodes 140 and 110.

Preferred embodiments of the present invention described above are disclosed for the purpose of illustration, and various substitutions, modifications, and changes within the scope without departing from the spirit of the present invention for those skilled in the art to which the present invention pertains. It will be possible, but such substitutions, changes and the like should be regarded as belonging to the following claims.

1 is a cross-sectional view of an electronic paper display device according to the present invention.

2 is a block diagram of a manufacturing process of an electronic paper display device according to the present invention.

3 is a plan view of a partition structure of the electronic paper display device according to the present invention.

Figure 4 is a cross-sectional view of the oil injection of the electronic paper display device according to the present invention.

5 is a cross-sectional view according to an embodiment of an oil injection structure employed in the electronic paper display device according to the present invention.

<Explanation of symbols for the main parts of the drawings>

110. Lower electrode 120. Partition structure

130. Twist ball 140. Upper electrode

150a, 150b. Oil 160. Glue

Claims (17)

A lower electrode on the plate; Barrier rib structures formed on the lower electrodes; A twist ball injected into each cell formed by the partition wall of the partition structure; An upper electrode attached to an upper portion of the barrier rib structure, attached to the barrier rib structure by an adhesive, and bonded by a roll to roll method; And Two kinds of oils having different specific gravity filling the partition structure between the upper electrode and the lower electrode; Electronic paper display device comprising a. The method of claim 1, The lower electrode is formed of a conductive thin plate-like substrate, the upper surface and the side portion of the electronic paper display device is formed with an oil injection opening on both sides. The method of claim 1, The barrier rib structure is composed of a resin layer of any one of a thermosetting resin or a UV curable resin, and an electronic paper display device in which a barrier rib in a cross shape is formed by a roll stamp. The method of claim 1, An electronic paper display device in which twist balls divided into transparent or opaque segments are injected one by one through a squeeze method in each cell of the barrier rib structure. The method of claim 1, The upper electrode is an electronic paper display device comprising a transparent electrode (ITO) so that light is transmitted through the transparent or opaque segment of the twist ball to be reflected or absorbed. delete The method of claim 2, The oil is filled through the oil inlet, the electronic paper display device in which the two different types of oil is filled in the same amount. The method of claim 7, wherein The oil is an electronic paper display device comprising a lubricating component having a viscosity and specific gravity and composed of a liquid material capable of photoconversion, the phase separation interface is formed by the specific gravity difference. The method of claim 8, The oil may include one type of oil having a higher specific gravity than the twist ball and another type of oil having a specific gravity smaller than the twist ball so that the twist ball is positioned in a phase separation interface formed by the two types of oil. Paper display element. Applying a resin layer over the lower electrode on the plate; Forming a barrier rib structure including a plurality of cells separated by the barrier rib on the resin layer; Injecting a twist ball into a cell of the barrier rib structure; Attaching an upper electrode to an upper portion of the barrier rib structure; And Injecting two kinds of oils having different specific gravity on the partition structure between the upper and lower electrodes; Method of manufacturing an electronic paper display device comprising a. The method of claim 10, The resin layer is made of a thermosetting resin or a UV curable resin, the method of manufacturing an electronic paper display device is formed of a partition structure having a plurality of cells provided by the imprint method through a roll stamp. The method of claim 11, The said roll stamp is a manufacturing method of the electronic paper display element by which the pressing surface of each stamp was release-processed. The method of claim 10, The twist ball is applied to the upper portion of the barrier rib structure, and is injected into each cell individually through a squeeze method, and the electronic paper is filled with the twist ball in each cell by repeating the squeeze method several times. Manufacturing method of display element. The method of claim 10, The oil is injected through an oil inlet formed on one side or both sides of the barrier rib structure, and a method of manufacturing an electronic paper display device in which two kinds of oil are injected in the same amount by filling in a vacuum state using a vacuum chamber. . The method of claim 11, The upper electrode may form the barrier rib structure through the roll stamp and at the same time the twist ball is filled by the squeeze method at the rear of the roll stamp, and then the roll to roll on the upper portion of the barrier rib structure during transfer of the lower electrode. A method of manufacturing an electronic paper display device bonded by a roll to roll method. delete delete

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