KR20060070939A - E-paper panel and manufacturing method thereof - Google Patents

Abstract

TECHNICAL FIELD The present invention relates to a two-paper panel and a method for manufacturing the same, and methods such as photolithography, photosensitive polymer, laminating, and the like, which have been used for generating bulkheads, are difficult to apply to a large area. There was a problem that a process is required. In view of the above problems, the present invention uses a double-sided adhesive film attached to both sides of the protective film to form a partition wall in a separate process, and then removes one side of the protective film and attaches it to the lower plate, and after spraying toner particles, the top of the partition wall. Residual toner particles are removed while the other side of the protective film is removed, and the adhesive layer on the surface is used for adhesion to the top plate, which simplifies the process and forms a large-area bulkhead structure using simple and inexpensive equipment. The large area of the panel is possible, and the flexibility of the double-sided adhesive film makes it possible to easily manufacture a flexible panel.

Description

E-PAPER PANEL AND MANUFACTURING METHOD THEREOF

1 is a cross-sectional view showing a conventional two-paper panel structure.

Figure 2a to 2f is a cross-sectional view showing a conventional process for manufacturing a two-paper panel.

Figure 3a to 3e is a cross-sectional view showing a manufacturing process of an embodiment of the present invention.

*** Explanation of symbols for main parts of drawing ***

10: lower substrate 20: lower electrode

30: lower insulating layer 40: partition wall

50: toner particles 60: upper substrate

70: upper electrode 80: upper insulating layer

100: partition film 105, 107: adhesive layer

110 and 120: protective film 150: toner particles

200: lower plate 300: upper plate

The present invention relates to a two-paper panel and a method for manufacturing the same, and in particular to partition the partition wall of the collision charging type two-paper panel using a double-sided adhesive film and to apply the electrode between the upper plate and the lower plate to simplify the process. TECHNICAL FIELD The present invention relates to a two-paper panel and a method of manufacturing the same.

With the necessity of various display devices, E-paper technology has been developed that can provide a clear image quality for a long time with smaller driving power.

E-paper technology uses the rapid movement of microparticles by an electric field to electrostatically move charged particles suspended in a certain space to display colors. Removing the particles does not change the position of the particles, so that the image does not disappear, as if printed on paper with ink. In other words, it does not emit light by itself, but the visual fatigue is very low, so it is possible to enjoy comfortable viewing like a real book, and the panel's flexibility is high enough to bend and the thickness can be formed very thin. Expecting. In addition, as mentioned above, since the image displayed once is maintained for a long time unless the panel is reset, the power consumption is extremely low, and thus the utility as a portable display device is excellent. In particular, low prices due to simple processes and low cost materials are expected to contribute to the popularization of e-paper panels.

1 is a cross-sectional view of a conventional collision-charged two-paper panel using dry particles, the structure of which is the upper and lower substrates formed with transparent electrodes (ITO) 20, 70 coated with an insulating layer (30, 80) The partition walls 40 are formed between the fields 10 and 60, and the toner particles charged and the toner particles 50 charged in the space secured by the partition walls 40 are relatively simple. .

The thickness of the lower substrate 10 and the upper substrate 60 is not limited, but since the toner particles 50 must be moved by the electrostatic force, the thickness of the actual partition wall 40 (tens of tens to hundreds of micrometers) or the toner particles 50 is not limited. Note that the size of is very small. In addition, the thickness of the transparent upper and lower electrodes 20 and 70 is much thinner than that of the upper and lower substrates 10 and 20, and the thicknesses of the electrodes 20 and 70 and the toner particles 50 may be reduced. Note that the thickness of the insulating layer 30 coated on the electrodes 20 and 70 is also thin so as to prevent electron movement by contact.

Referring to the principle of operation of the two-paper structured as described above, it is first assumed that the black toner particles are positively charged, and that the white toner particles are negatively charged (which may be oppositely charged). First, when a negative voltage is applied to the upper electrode 70 and a positive voltage is applied to the lower electrode 20, white particles positively charged by the coulomb force move toward the upper substrate 60, and the negatively charged black particles Move toward the lower substrate 10. Since the white toner particles 50 are located on the upper substrate 60 side, they appear white when viewed from the outside. On the contrary, when + voltage is applied to the upper electrode 70 and-voltage is applied to the lower electrode 20, the negatively charged black particles move toward the upper substrate 60, and the positively charged white particles move to the lower substrate 10. It will move to) and display in black. Therefore, after applying voltage to make all cells appear white at first, only the desired cell is applied with opposite voltage to make it appear black.

FIG. 2 is a cross-sectional view illustrating a process of manufacturing a conventional dry two-paper panel shown in FIG. 1.

First, as illustrated in FIG. 2A, a transparent lower electrode 20 and an insulating layer 30 are sequentially formed on the lower substrate 10. Since the basic electrode structure of the e-paper panel is a matrix structure, the lower electrode 20 has a shape similar to the perspective view shown on the right side. It is preferable that the transparent electrode is ITO, and there is no problem in driving even if the insulating layer 30 applied thereon is omitted. However, when the toner particles are in close contact with the electrode and electron movement occurs, the memory effect is reduced. It may be difficult to preserve an image for a long time without applying power, so it is desirable to apply it.

As shown in FIG. 2B, a partition wall 40 is formed on the substrate. Since the barrier 40 is simply used to distinguish cell units, the material may be a polymer, an inorganic material, or the like. In general, a method for configuring the barrier 40 includes photolithography using photoresist. A method, a method of using a photosensitive polymer, a laminating method of cutting and using a pre-made material, and the like may be used, and in the case of adhesion, it may be applied on a bottom plate previously formed by a method such as UV adhesive and UV irradiation. The general partition 40 has a lattice structure as shown in the right perspective view.

As shown in FIG. 2C, negatively charged toner particles 50 using a corona discharge lamp are injected into a nozzle and injected into a space separated by the partition wall 40. At this time, by applying a positive voltage to the lower electrode 20 or a means for applying a positive electric field to the lower portion of the substrate 10 so that the toner particles 50 injected can easily reach the inside of the partition 40. . The toner particles 50 have an additive material for controlling charging characteristics internally, and when the toner particles 50 collide with each other, the charging characteristics appear. When you apply AC, you will be able to find your match characteristics.

As shown in FIG. 2D, the toner particles 50a disposed on the partition 40 are removed by various methods. The most common method is to adsorb and remove toner particles 50a on the top of the partition wall 40 using an adhesive roller or the like, and after the toner jet is finished with a separate mask disposed on the top of the wall 40. The method of removing the mask can also be used.

As shown in FIG. 2E, the transparent upper electrode 70 and the upper insulating layer 80 are sequentially formed on the transparent upper substrate 60 in the same process as the lower plate for use as the upper plate. In this case, the upper electrode 70 may also have a structure as shown in FIG. 2A, but has a direction perpendicular to the lower electrode.

As shown in FIG. 2F, the formed upper plates 60, 70, and 80 are disposed on the lower plates 10, 20, 30, and the partition 40, and joined to each other. Then, if necessary, by repeatedly applying the opposite voltage to each electrode, the toners 50 are moved and run to each other so as to be negatively or positively charged, respectively.

The dry two-paper panel is superior to the conventional liquid phase in terms of response speed and ease of processing, but a systematic manufacturing method has not yet been established. In particular, if the panel is to be implemented in a large area, the size of pixels and partitions increases, so it is difficult to apply a method of photolithography, photosensitive polymer, laminating, and the like, which has been used to create a partition for a small area. In addition, as described through the manufacturing process of the E-paper panel, when using the photolithography process, the process is complicated, the process cost is high, expensive equipment is required, and the cost is high, and the large area is also implemented due to the limitation of the equipment. It is difficult, and if the partition is formed separately from a separate polymer or inorganic material and then applied to the lower plate, there is a problem that a process for adhesion must be further added. Further, after the toner particles are injected, additional processes such as using a mask or removing the toners on the partition walls with a roller or the like to remove the toner particles remaining on the partition walls formed in the above manner are required. In addition, in the case of using a substrate that is not bent, the upper plate and the lower plate may be bonded after arranging the upper plate on the upper part of the partition wall, but for the flexible panel, an adhesive process for separately bonding the upper part and the upper part of the partition wall when joining the upper plate. There was a problem that the process for manufacturing the partition wall must be very complicated and precise because it must be added further.

The present invention for solving the conventional problems as described above has a thickness that can be used as a partition wall, after forming the partition wall in a separate process using a double-sided adhesive film attached to both sides of the protective film, the protective film of one side Attaching the double-sided adhesive film formed by the barrier rib pattern to the lower plate, and removing the remaining toner particles on the upper side of the barrier rib after spraying the toner particles while simultaneously removing the other protective film, and using the adhesive layer on the surface for adhesion to the upper plate. It is an object of the present invention to provide a two-paper panel and a method of manufacturing the same, which can be carried out through the double-sided adhesive film to form a partition, joining a panel, and removing residual toner particles.

In order to achieve the above object, the present invention includes a lower substrate formed with a lower electrode; An upper substrate on which the upper electrode is formed; A partition wall having a pattern for cell configuration and a double-sided adhesive film bonding the upper substrate and the lower substrate with an adhesive component formed on upper and lower portions thereof; And dry toner particles injected into the cell region defined by the pattern of the barrier rib.

In addition, the present invention comprises the steps of preparing a lower plate by forming a lower electrode on the lower substrate; Preparing a double-sided adhesive film having a thickness suitable for the partition and having an adhesive component on both sides and applying a protective film to protect the partition, and forming a predetermined partition pattern by vertically removing a portion of the double-sided adhesive film; Removing one side of the protective film of the double-sided adhesive film on which the barrier rib pattern is formed, and then attaching the protective film to the lower plate; Applying toner particles to the formed structure and removing the other protective film to remove toner particles on the partition wall; After preparing a top plate by forming a transparent upper electrode on a transparent upper substrate, it characterized in that it comprises the step of bonding the upper plate and the lower plate by using the adhesive component exposed on the partition wall of the pre-formed structure.

Removing a portion of the double-sided adhesive film vertically to form a predetermined barrier rib pattern may include vertically moving a portion of the double-sided adhesive film by using one of physicochemical patterning techniques including punching, etching, and sandblasting. Characterized in that it comprises a step of removing.

The present invention as described above will be described in detail through one embodiment as follows.

Figure 3 is a procedure cross-sectional view showing a manufacturing process of an embodiment of the present invention, showing a process that can be carried out very easily using a double-sided adhesive film having an adhesive layer and a protective film on both sides as a partition material as shown. will be.

First, FIG. 3A illustrates a structure of a double-sided adhesive film to be used in the present embodiment, and adhesive layers 105 and 107 are formed on both sides of a barrier film 100 to be used as a partition as shown, and to protect it. It has a structure to which the films 110 and 120 are attached.

The material used as the barrier film 100 may be a polymer material such as polyethylene, polystyrene, PET, polycarbonate, PES, and the like, and the films made of these materials are commercialized in various ways, such as material, height, and width. The size of the product can be precisely determined and it is easy to manufacture and supply. The thickness of the partition film 100 used in the above embodiment uses that of about tens to hundreds of micrometers.

An adhesive material is formed on upper and lower portions of the barrier film 100 to form adhesive layers 105 and 107, which will then be used to bond the upper and lower plates. In addition, protective films 110 and 120 are attached to prevent contamination of the adhesive layers 105 and 107.

Next, as shown in FIG. 3B, the barrier rib pattern is partially removed by physically chemically removing a double-sided adhesive film made of the barrier film 100 having the protective films 110 and 120 and the adhesive layers 105 and 107 formed thereon. Form. As the patterning method, punching, etching, sandblasting, or the like using a punching machine may be used, and various other physical chemical polishing and patterning methods may be used.

Next, as shown in FIG. 3C, one side of the protective film 120 of the double-sided adhesive film is removed and adhered to the preformed bottom plate 200 (substrate, transparent electrode, and optionally formed insulating layer). The alignment may be made through the electrode pattern of the lower plate 200. Then, the toner particles 150 are sprayed in the same manner as in the prior art to distribute evenly inside the double-sided adhesive film attached in the form of the partition wall. At this time, the toner particles may remain on the partition wall due to the injection, which is located on the protective film 100 attached to one side of the partition film 110.

Next, as shown in FIG. 3D, when the protective film 110 remaining on the barrier film 110 is removed, unnecessary toner particles positioned on the barrier film 110 are also removed. This eliminates the need for a separate partition toner particle removal process, mask, or the like.

Finally, as shown in FIG. 3E, the upper plate 300 (transparent substrate, transparent electrode, and optionally formed by using the adhesive layer 105 on the upper part of the barrier film 110 exposed due to the removal of the protective film 110 is selectively provided. Consisting of an insulating layer formed). In addition, additional processes such as edge bonding for upper and lower plate bonding, and an AC voltage applying process for imparting charging characteristics to the toner particles 150 distributed inside the cell may be further performed.                     

As described above, after the barrier rib structure is formed by using a double-sided adhesive film that can be easily implemented and inexpensive, a separate process is performed, and the bonding between the top plate and the bottom plate is easily performed using the adhesive layer applied to both sides of the film. In addition, it is possible to easily remove the toner particles on the partition wall to simplify the process.

As described above, the present invention two-paper panel and a method of manufacturing the same using a double-sided adhesive film attached to both sides of the protective film to form a partition wall in a separate process, and then remove the protective film on one side and attach to the lower plate, After spraying the toner particles, the remaining toner particles on the upper part of the partition wall are simultaneously removed while the other side protective film is removed, and the adhesive layer on the surface is used for adhesion to the top plate, thereby simplifying the process and simplifying the large-area partition structure. It can be formed by using inexpensive equipment, the large area of the panel is possible, and the flexibility of the flexible panel can be easily manufactured through the flexibility of the double-sided adhesive film.

Claims (4)

A lower substrate on which a lower electrode is formed; An upper substrate on which the upper electrode is formed; A partition wall having a pattern for cell configuration and a double-sided adhesive film bonding the upper substrate and the lower substrate with an adhesive component formed on upper and lower portions thereof; E-paper panel comprising dry toner particles injected into the cell region defined by the pattern of the partition wall. Preparing a lower plate by forming a lower electrode on the lower substrate; Preparing a double-sided adhesive film having a thickness suitable for the partition and having an adhesive component on both sides and applying a protective film to protect the partition, and forming a predetermined partition pattern by vertically removing a portion of the double-sided adhesive film; Removing one side of the protective film of the double-sided adhesive film on which the barrier rib pattern is formed, and then attaching the protective film to the lower plate; Applying toner particles to the formed structure and removing the other protective film to remove toner particles on the partition wall; After preparing the upper plate by forming a transparent upper electrode on the transparent upper substrate, the step of bonding the upper plate and the lower plate using an adhesive component exposed on the upper part of the partition wall of the pre-formed structure comprising the step of manufacturing a two-paper panel Way. The double-sided adhesive film of claim 2, wherein the forming of the predetermined barrier rib pattern by vertically removing a portion of the double-sided adhesive film is performed by using one of physicochemical patterning techniques including punching, etching, and sandblasting. Removing a portion of the region vertically. The method of claim 2, wherein the double-sided adhesive film is made of a material including at least one of polyethylene, polystyrene, PET, polycarbonate, and PES.

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