JP5450932B2 - Electrophoretic display device - Google Patents

Description

  The present invention relates to an electrophoretic display device that displays information such as characters, graphics, and time by a display module using an electrophoretic display element.

As thin display devices, liquid crystal display devices are widely used in various electronic devices, and in recent years, they are also used as large color displays such as computers and televisions. Plasma displays are also used as large color displays for televisions.
However, although liquid crystal display devices and plasma displays are much thinner than CRT displays, they are still not thin enough for some applications and cannot be bent. When used as a display of portable equipment Needing and Prospective the further reduction of power consumption.

Therefore, as a display device that realizes further thinning and low power consumption, a display module, also called electronic paper using an electrophoretic display element, has been developed. An electronic book, an electronic newspaper, an electronic advertising billboard, and a guidance display board are developed. Attempts have been made to use it.
A display module using this electrophoretic display element is composed of a substrate, an electrode layer, an image display layer, a transparent electrode layer, and a transparent surface layer, as can be seen, for example, in Patent Document 1.

  The image display layer is a display layer made of microcapsules (electronic ink) having a diameter of several tens of μm containing white particles and black particles charged to different polarities and a dispersion medium for dispersing them, and the electrode layer sandwiching them Depending on the direction of the electric field generated between the transparent electrode layers, white particles and black particles in the microcapsule are electrophoresed, and one of them gathers on the surface side to display white or black. Once a display is applied by applying an electric field, it has non-volatility (memory property) that maintains the display state even when no electric field is applied. Therefore, it is possible to significantly reduce power consumption.

  Although a glass substrate may be used for a display module using such an electrophoretic display element, it has been developed using a light and flexible plastic substrate. Since the sealing material that seals the outer periphery of a pair of plastic substrates sandwiching the plastic substrate and the electrophoretic display element cannot sufficiently block moisture in the air, moisture that has permeated through the plastic substrate and the sealing material ( Due to the influence of moisture), the durability of the display element is lowered, and there is a problem that the display quality is deteriorated and the life is shortened.

Therefore, in such an electro-optical device in which a display element such as an electrophoretic display element is sandwiched between a pair of plastic substrates, a low moisture-permeable film is provided on the inner surface of the pair of plastic substrates and the outer peripheral portion is welded. It has been proposed that, for example, Patent Document 2 can prevent the moisture (humidity) from entering from the outside and prevent the deterioration and life of the display element from being shortened.
JP 2005-156759 A Japanese Patent No. 2005-227450

  However, even if a low moisture permeable film is provided on the inner surface of the plastic substrate, it is not possible to completely prevent the transmission of moisture (humidity) in a high temperature and high humidity environment. Therefore, the plastic substrate is enclosed inside the electrophoretic display element. There was a possibility that moisture could penetrate through the film and deteriorate the electrophoretic display element. Further, in order to weld the outer peripheral portions of the pair of plastic substrates, there is a problem that it is expensive because a high-level and complicated process such as laser light irradiation processing, ultrasonic processing, and hot plate overheating processing is required.

  Also, in a high temperature and low humidity environment, the moisture in the electrophoretic display element goes out through the low moisture permeable film on the inner surface of the plastic substrate, the humidity in the electrophoretic display element is lowered, and the memory property is lowered. As a result, a decrease in display contrast occurred.

  The present invention has been made in view of such a background, and prevents the deterioration of the electrophoretic display device due to moisture and the deterioration due to drying, thereby extending the life of the electrophoretic display device and allowing it to be manufactured at a low cost by a simple sealing process. The purpose is to.

In order to achieve the above object, a display device according to the present invention includes a display module using an electrophoretic display element, a moisture-proof transparent plate that covers the display surface side, and a moisture-proof cover member that covers the back surface side. Each of the moisture-proof transparent plate and the moisture-proof cover member is bonded to each other by extending the peripheral portion of the display module, and the display module is hermetically sealed. At least the moisture-proof transparent plate and the moisture-proof cover member provide the display. A moisturizing material containing moisture is disposed in a region where the module is sealed so as to keep the humidity in the region at 30 to 70% .

The moisturizing material is disposed in layers along the entire inner surface of the moisture-proof cover member up to the extension portion, and the extension portion of the moisture-proof cover member and the extension portion of the moisture-proof transparent plate are It is recommended that the layers of the moisturizing material be bonded together.
Alternatively, a transparent moisturizing material may be disposed between the display surface side of the display module and the moisture-proof transparent plate, or between the inner surface of the moisture-proof cover member and the back side of the display module. A moisturizing material may be disposed on both.

The display device according to the present invention includes a display module using an electrophoretic display element and a moisture-proof transparent plate that covers the display surface side of the display module, and includes a peripheral portion of the moisture-proof transparent plate and a bottom of the display module. The display module is sealed by bonding the peripheral edge of the substrate with a sealing material, and at least in the region where the display module is sealed by the moisture-proof transparent plate and the lower substrate of the display module . Moisturizing material containing moisture may be disposed so as to keep the humidity at 30 to 70% .
These moisturizing materials may be disposed in a state where the moisture content is absorbed to 50% or more.

Alternatively, a display device according to the present invention includes a display module using an electrophoretic display element, a moisture-proof transparent plate that covers a display surface side of the display module, and a moisture-proof cover member that covers a back surface side. The peripheral edge of the transparent plate and the lower substrate of the display module are bonded together using a sealing material, and a moisture-proof cover member is bonded to the back surface of the lower substrate to seal the display module. At least the lower substrate and the moisture-proof A moisturizing material having a moisture content of 50% or more may be disposed between the protective cover member.

The moisturizing material may be an organic moisturizing material containing a polymer material such as nylon .

An electrophoretic display device according to the present invention seals a display module using an electrophoretic display element by a moisture-proof transparent plate and a moisture-proof cover member, and prevents moisture from entering the display module in a high-temperature and high-humidity environment. At the same time, even if moisture gradually enters through the moisture-proof transparent plate and the moisture-proof cover member itself or its bonding part, the moisture is absorbed by the moisturizing material, so that the internal humidity is always kept appropriate, and the electrophoretic display device It is possible to extend the service life by preventing deterioration due to moisture.

In addition, the electrophoretic display device according to the present invention provides moisture retention even if the moisture in the electrophoretic display element is scattered little by little through the moisture-proof transparent plate, the moisture-proof cover member itself, and its bonding portion in a high-temperature and low-humidity environment. Since it is compensated by moisture contained in the material, the internal humidity is always kept in an appropriate range, and deterioration due to drying of the electrophoretic display device can be prevented to extend the life. In addition, the sealing process with the moisture-proof transparent plate and the moisture-proof cover member can be performed by simply sticking the extension part by a simple process such as passing a laminator or simply bonding the moisture-proof transparent plate with a sealing material. It can be manufactured inexpensively with a simple process.

Hereinafter, the best mode for carrying out the present invention will be specifically described with reference to the drawings.
FIG. 1 is a longitudinal sectional view schematically showing a configuration of a first embodiment of an electrophoretic display device according to the present invention. FIG. 2 is a partial view showing details of a moisture-proof transparent plate, a moisture-retaining material layer, and a moisture-proof cover member. FIG. 3 is a schematic enlarged cross-sectional view of the main part for explaining the display principle of the display module using the electrophoretic display element shown in FIG.

  An electrophoretic display device 1 shown in FIG. 1 includes a display module 10 using an electrophoretic display element, a moisture-proof transparent plate (also referred to as a front barrier) 3 that covers the display surface side of the display module 10, and a moisture-proof cover that covers the back surface side. Peripheral portion 1a formed by bonding together extension portions 3a and 5a extending from the periphery of display module 10 of moisture-proof transparent plate 3 and moisture-proof cover member 5, respectively. Thus, the display module 10 is sealed. Then, the moisture retaining material is disposed at least in the region where the display module 10 is sealed by the moisture-proof transparent plate 3 and the moisture-proof cover member 5. In this example, the moisture retaining material is layered, and the inside of the moisture-proof cover member 5. The moisturizing material 7 is disposed along the entire surface up to the extending portion 5a, and the extending portion 5a of the moisture-proof cover member 5 and the extending portion 3a of the moisture-proof transparent plate 3 are bonded together with the moisturizing material 7 interposed therebetween. Yes.

Here, the details of the moisture-proof transparent plate 3, the moisture-proof cover member 5, and the moisture retaining material 7 in this embodiment will be described with reference to FIG.
The moisture-proof transparent plate 3 is laminated and laminated by sandwiching a transparent moisture-proof film 32 between transparent plastic sheets 31 and 33 such as a sheet made of polyethylene terephthalate (PET) (hereinafter referred to as “PET sheet”). Is a bendable plastic plate having a hot melt adhesive layer 34 formed on the entire surface thereof, and has a total thickness of about 100 μm. As the transparent plastic sheets 31 and 33, polyester sheets can be used instead of PET sheets.
As the moisture-proof film 32, a transparent film such as a PET sheet coated with an inorganic oxide using a vapor deposition method or a sputtering method, a fluorine-based organic polymer film, or the like can be used. As the organic polymer film, Aclar (registered trademark) which is a barrier film using ethylene trifluoride chloride is suitable.

On the other hand, the moisture-proof cover member 5 is formed by laminating a highly moisture-proof aluminum foil 52 on the entire inner surface of a plastic sheet 51 such as a PET sheet and forming a hot melt adhesive layer 53 on the entire surface on the side where the moisturizing material 7 is bonded. It is a bendable sheet. Alternatively, the moisture retaining material 7 may be further laminated with the adhesive layer 53 on the aluminum foil 52 of the moisture-proof cover member 5. In that case, the total thickness is about 100 μm.
Further, as the plastic sheet 51, a polyester sheet can be used instead of the PET sheet, and as the moisture-proof cover member 5, a film having a sandwich structure of PET sheet / aluminum foil / polyester sheet can be used. Further, a moisture-proof film coated with various metal foils or a low moisture-permeable film may be used.

The moisturizing material 7 is formed of a moisturizing film 71 and a hot melt adhesive layer 72 , and various kinds of inorganic adsorbing materials and organic adsorbing materials can be used for the moisturizing film 71. Examples of the inorganic adsorbent include polymer films mixed with porous inorganic materials such as alumina, silica gel, and zeolite. As the organic adsorbent, for example, any one of polystyrene, polyethylene, polypropylene, nylon, polyurethane, polyolefin, polycarbonate, polysulfone, or a mixture of two or more kinds may be used.
As described above, the moisture retaining material 7 may be laminated together with the moisture-proof cover member 5.

Then, in the peripheral portion (generally referred to as an ear portion) 1a outside the display module 10 shown in FIG. 1, a moisture-retaining material 7 is sandwiched between the moisture-proof transparent plate 3 and the moisture-proof cover member 5, and the roll by thermocompression bonding through the laminator, each of the extended portion 3a and 5a of the moisture resistance transparent plate 3 and the moisture-proof cover member 5, the hot melt adhesive of the hot-melt adhesive layer 34 and the moisturizing member 7 moisture-proof transparent plate 3 The agent layer 72 is softened and adhered.

Note that the moisture-proof cover member 5 to which the moisture-retaining material 7 or the moisture-retaining film 71 is bonded needs to absorb moisture before the step of bonding to the moisture-proof transparent plate 3. As the moisture of the moisturizing material, it is important that the ratio of the moisture actually absorbed to the saturated moisture that the moisturizing material can absorb at room temperature (defined as the moisture content) is 50% or more.
That is, if the moisture content of the moisturizing material 7 is too low (does not reach 50%), the effect of preventing deterioration under a high temperature and low humidity environment is lowered, so that the moisture content of the moisturizing material 7 is 50 % or more, It is preferable to arrange the display module 10 in a sealed space. Further, if the moisture content of the moisturizing material 7 is too high (over 90%), the effect of preventing deterioration under a high-temperature and high-humidity environment may be reduced, so the moisture content of the moisturizing material 7 is 50 to 90%. The state is most preferable. Therefore, in this example, the moisturizing material 7 was left in a high temperature and humidity chamber of 80% at 40 ° C. for 24 hours to absorb the moisture content of the moisturizing material to about 80%.

In the display module 10 shown in FIG. 1, a transparent electrode 12 made of an ITO (indium tin oxide) film is formed on the entire back surface of a transparent resin substrate 11, and a microcapsule display layer 13 also called electronic ink is formed thereon. To form a film. The film is adhered to the lower substrate 15 made of a polyimide film having an electrode pattern 16 for each pixel formed on the surface with an adhesive layer 18.

  In the microcapsule display layer 13, a large number of microcapsules 20 having a diameter of about several tens of μm are dispersed in a mixture of a binder, a surfactant, a thickener, pure water, and the like. As shown in FIG. 3, the microcapsule 20 includes white particles 23 made of titanium oxide or the like and black particles 24 made of carbon black or the like inside a capsule shell 21 made of transparent methacrylic resin or the like, such as silicone oil. It is enclosed in a state of being dispersed in a transparent dispersion medium 22 having a high viscosity. The white particles 23 are negatively charged and the black particles 24 are positively charged.

  Therefore, among the electrodes arranged so as to sandwich the microcapsule display layer 13, one part of the entire transparent electrode 12 is grounded, and a negative voltage is applied to the electrode pattern 16 on the other lower substrate 15. The negatively charged white particles 23 in the microcapsule 20 are moved to the transparent electrode 12 side by the electric field, and the positively charged black particles 24 are moved to the electrode pattern 16 side. Therefore, when viewed from the viewing side (upper side in FIG. 3). Looks white. On the other hand, in a portion where a positive voltage is applied to the electrode pattern 16, the positively charged black particles 24 in the microcapsule 20 are applied to the transparent electrode 12 side by the opposite electric field, and the negatively charged white particles 23 are the electrode pattern 16. Since it moves to the side, it looks black when viewed from the viewing side.

  As in the central microcapsule 20 in FIG. 3, in the microcapsule 20 at a position straddling the electrode pattern to which a negative voltage is applied and the electrode pattern to which a positive voltage is applied, a part of the white particles 23 is a transparent electrode. 12 side, the rest moves to the electrode pattern 16 side, a part of the black particles 24 moves to the electrode pattern 16 side, and the rest moves to the transparent electrode 12 side. Is possible.

Further, by adjusting the applied voltage and the application time, it is possible to hold the black particles 24 and the white particles 23 in a state of being mixed in the middle and display a grayscale or the like.
Accordingly, the display state can be changed to white, black, or gray depending on the polarity of the voltage applied between the transparent electrode 12 and the electrode pattern 16. At this time, the white particles 23 and the black particles 24 move in the dispersion medium 22 by electrophoresis. However, since the viscosity of the dispersion medium 22 is high and the intermolecular force acting between the particles is strong, a voltage is applied to change the display state. After changing, the memory effect is maintained even when the application of the voltage is stopped.
Thus, since the display module 10 has a memory property, it is sufficient to apply a driving voltage only when changing the display, so that power consumption is very small.

The electrophoretic display device 1 according to the first embodiment of the present invention configured as described above includes a display module 10 using an electrophoretic display element and a moisture content by using a moisture-proof transparent plate 3 and a moisture-proof cover member 5. Has a structure in which the moisture retention material 7 in a moisture absorption state of 50% or more is sealed. Therefore, even if moisture invades little by little through the moisture-proof transparent plate 3 and the moisture-proof cover member 5 itself or the bonded portion in a high temperature and high humidity environment, the moisture is absorbed by the moisture retaining material 7. Further, since the extending portions 3a and 5a, which are the bonded portions of the moisture-proof transparent plate 3 and the moisture-proof cover member 5, are bonded to each other with the moisturizing material 7 interposed therebetween, moisture that tries to enter from the outside reaches the inside. Since the moisture is previously absorbed by the moisturizing material 7 , it hardly penetrates into the interior. Further, even when the moisture in the microcapsule display layer 13 is scattered in a high temperature and low humidity environment, the moisture is supplied from the moisturizing material 7.

  Therefore, the internal humidity sealing the display module 10 is always kept appropriate (humidity 30 to 70%), and the display module 10 can be prevented from deteriorating due to moisture or drying, thereby extending the life. In addition, since the sealing process by the moisture-proof transparent plate 3 and the moisture-proof cover member 5 is simply pasting the extending portions 3a and 5a, it can be manufactured at a low cost by a simple process such as thermocompression bonding through a roll laminator.

  In particular, use of an organic moisturizing material, particularly a moisturizing material containing a polymer material such as nylon, as the moisturizing material 71 is effective in keeping the internal humidity in an appropriate humidity state because it has hygroscopicity and appropriate moisturizing properties. In addition, it is easy to integrate with the moisture-proof cover member in advance, and it can be manufactured at low cost.

Further, conventionally, ear or frame portion with bonding two barrier member (corresponding to the peripheral portion 1a shown in FIG. 1) was large and has prevented the invasion of moisture from the bonding unit Therefore, the overall size of the display device has become considerably larger than the effective display screen size. According to the first embodiment, the intrusion of moisture from the bonding portion is extremely reduced as described above, so that the minimum size necessary for the bonding can be obtained, and the ear portion or the frame portion. The overall size of a display device having the same display screen size can be reduced.

  Further, if the moisture retaining material 7 is layered and disposed on the entire inner surface of the moisture proof cover member 5 as in the first embodiment, the area where the moisture retaining material is exposed in the sealed space increases, and the moisture proof property is increased. Since it also intervenes in the bonded portion between the transparent plate 3 and the moisture-proof cover member 5, the moisture absorption effect can be sufficiently obtained, but it is not essential, and at least by the moisture-proof transparent plate 3 and the moisture-proof cover member 5 It is effective if a moisturizing material is disposed in a region where the display module 10 is sealed.

  Here, the experimental result for confirming the effect by this invention is demonstrated with reference to FIG. 4 and FIG. 4 and 5 are the same as in the first embodiment in which the electrophoretic display device is provided with a moisturizing material, but the reliability test using the same electrophoretic display device except that no moisturizing material is provided (to shorten the experiment period). Fig. 4 is a diagram showing the change in display contrast ratio with respect to the number of days elapsed in a high-temperature, low-humidity environment (60 ° C dry) test. 5 is a diagram showing a change in display contrast ratio with respect to the number of days elapsed in a high-temperature and high-humidity environment (45 ° C. 90%) test. In both cases, the solid line indicates the contrast ratio in the case of the first embodiment in which the moisturizing material is provided, and the broken line indicates the contrast ratio in the case of the conventional example in which the moisturizing material is not provided.

  As can be seen from FIG. 4, when no moisturizing material is provided, in the high-temperature and low-humidity environment test, the microcapsule display layer dries from 5 days onward, and the memory property deteriorates, so that white and black cannot be retained. The contrast ratio begins to drop significantly. On the other hand, in the case of the first embodiment of the present invention provided with a moisturizing material, the contrast ratio starts to decrease somewhat, but moisture is replenished from the moisturizing material and the memory property is maintained. Much less than without moisturizing material.

Further, as can be seen from FIG. 5, in the high temperature and high humidity environment test, when no moisturizing material is provided, the resistance of the microcapsule display layer decreases after 10 days and the driving voltage is applied to the adhesive layer. Since the voltage is not sufficiently applied, the display contrast ratio starts to decrease. On the other hand, in the case of the first embodiment of the present invention in which the moisturizing material is provided, the contrast ratio starts to decrease somewhat after the lapse of 15 days, but the degree of decrease is considerably less than that in the case where no moisturizing material is provided. These experiments proved the effect of extending the life of the electrophoretic display device according to the present invention.

In this embodiment, the moisturizing material 7 is provided between the display module 10 and the moisture-proof cover member 5 , but a transparent moisturizing material is provided between the display surface side of the display module 10 and the moisture-proof transparent plate 3. It is also possible to arrange. Alternatively, it is better to provide a moisture retaining material between the display module 10 and the moisture-proof cover member 5 and between the display surface side of the display module 10 and the moisture-proof transparent plate 3.

Next, another embodiment of the present invention will be described. 6 to 9 are longitudinal sectional views schematically showing configurations of second to fifth embodiments of the electrophoretic display device according to the present invention.
In these drawings, portions corresponding to those in FIG. 1 showing the first embodiment described above are denoted by the same reference numerals, and description thereof is omitted. The configuration and function of the display module 10 are the same as those described with reference to FIGS.

  The electrophoretic display device 1 ′ of the second embodiment shown in FIG. 6 is similar to the electrophoretic display device 1 of the first embodiment shown in FIG. 1 between the moisture-proof cover member 5 and the display module 10. In addition to the moisturizing material 7B, the moisturizing material 7A is also disposed between the moisture-proof transparent plate 3 and the display surface side of the display module 10. The moisturizing material 7A is arranged in layers along the entire inner surface of the moisture-proof transparent plate 3 up to the extension portion 3a, and the extension portion 3a of the moisture-proof transparent plate 3 and the moisture-proof cover member 5 are extended. The part 5a is bonded to each other with the layers of the moisturizing materials 7A and 7B interposed therebetween. Since the moisturizing material 7A is installed on the upper side of the microcapsule display layer 13, transparency is required and an organic moisturizing material having a high transmittance is used.

  The electrophoretic display device 1 ″ of the third embodiment shown in FIG. 7 omits the moisture retention material 7B between the moisture-proof cover member 5 and the display module 10 in the second embodiment described above, and is moisture-proof and transparent. A moisturizing material 7 </ b> A is disposed only between the plate 3 and the display surface side of the display module 10.

  The electrophoretic display device 25 of the fourth embodiment shown in FIG. 8 includes a display module 10 using an electrophoretic display element, a moisture-proof transparent plate 3 that covers the display surface side of the display module 10, and a transparent moisturizing material 7. The sealing material 17 is used for the extension part 3a which is a peripheral part extending from the peripheral part of the display module 10 of the moisture-proof transparent plate 3 and the peripheral part 15a which the lower substrate 15 of the display module 10 is extended. The display module 10 is sealed at the peripheral portion 25a. A moisture retention material is disposed at least in a region where the display module 10 is sealed by the moisture-proof transparent plate 3 and the lower substrate 15. In this embodiment, the transparent moisture-retaining material 7 is placed inside the moisture-proof transparent plate 3. The extended portion 3a is disposed in layers over the entire surface, and the extended portion 3a, which is the peripheral portion of the moisture-proof transparent plate 3, the extended portion 7a of the moisturizing material 7, and the peripheral portion 15a where the lower substrate 15 extends. Are attached using a sealing material 17.

  The moisture-proof transparent plate 3 and the microcapsule display layer 13 used here are the same as those in the first embodiment. Also in the display module 10 used in this embodiment, the microcapsule display layer 13 and the electrode pattern 16 are bonded with an adhesive layer 18. Further, in the fourth embodiment, the moisture-proof cover member provided in the first embodiment is not provided, but a thick printed board having low moisture permeability is used as the material of the lower substrate 15 of the display module 10. Intrusion of moisture from the back surface of the microcapsule display layer 13 is prevented. Alternatively, it is possible to use a moisture-proof plastic substrate or the like in which the lower substrate is coated with an inorganic oxide or the like in advance.

The sealing material 17 uses an epoxy or acrylic liquid adhesive, and is poured between the extending portion 3a of the moisture-proof transparent plate 3 and the peripheral portion 15a of the lower substrate 15 using a dispenser, and heat or ultraviolet rays. Cured and glued. In addition, since water | moisture content permeate | transmits also from the sealing material 17, the material whose moisture permeability is as low as possible was selected. Since the moisturizing material 7 is also installed on the upper side of the microcapsule display layer 13, transparency is required and an organic moisturizing material having a high transmittance is used.

  Note that the moisture-proof transparent plate 3 to which the moisturizing material 7 is bonded needs to be absorbed by the moisturizing material 7 before being bonded to the lower substrate 15. As in the first embodiment, the moisture retention state of the moisturizing material 7 is such that the moisture content is 50% or more, preferably 50 to 90%, and the moisturizing material 7 is placed in a high temperature and humidity chamber at 40 ° C. and 80%. It was left for 24 hours to absorb moisture so that the moisture content of the moisturizing material was about 80%.

  A reliability test similar to that of the first embodiment was performed by the electrophoretic display devices of the second to fourth embodiments. As in the first embodiment, a high temperature and high humidity environment test and a high temperature and low humidity environment were performed. In the test, good results were obtained in which a decrease in display contrast ratio was suppressed, and the effect of extending the life of the electrophoretic display device according to the present invention was demonstrated.

  Next, an electrophoretic display device 26 of the fifth embodiment shown in FIG. 9 includes a display module 10 using an electrophoretic display element, a moisture-proof transparent plate 3 that covers the display surface side of the display module 10, and a back surface side. A moisture-proof cover member 5 that covers the outer periphery of the display module 10, and an extension portion 3 a that is a peripheral portion extending from the periphery of the display module 10, and a peripheral portion 15 a of the lower substrate 15 that extends from the display module 10. Are bonded using a sealing material 17. Further, a moisture-proof cover member 5 in which a film of the moisture-retaining material 7 (corresponding to the moisture-retaining film 71 shown in FIG. 2) is bonded is attached to the back surface of the lower substrate 15, and the display module 10 is attached at its peripheral portion 26a. Sealed.

The moisture-proof cover member 5 and the moisture-retaining material 7 used here are the same as those used in the first embodiment, but provided on the surface of the moisture-retaining film 71 constituting the moisture-retaining material 7 shown in FIG. As the hot melt adhesive layer 72 , an adhesive type that can be bonded at room temperature was used. As a material for the lower substrate 15 of the display module 10, a highly permeable polyimide substrate, a PET film, or a thin printed substrate can be used.

  Using the electrophoretic display device of the fifth embodiment, a reliability test similar to that of the first embodiment was performed. As in the first embodiment, in the high-temperature and high-humidity environment test and the high-temperature and low-humidity environment test, According to the present invention, it is possible to obtain a good result that suppresses a decrease in display contrast ratio, and to provide the moisture retaining material 7 and the moisture-proof cover member 5 on the back surface of the lower substrate even when the lower substrate 15 having high moisture permeability is used. The effect of extending the lifetime of the electrophoretic display device was demonstrated.

  In the fourth embodiment and the fifth embodiment, the moisture-proof transparent plate 3 is extended from the resin base 11 of the display module 10 to the peripheral portion 25a or 26a, and the extended portion 3a is used as a sealing material. 17 is bonded to the extended peripheral edge 15a of the lower substrate 15, but the moisture-proof transparent plate 3 is cut into the same outer shape as the resin base 11 of the display module 10, and the sealing material 17 is removed from the lower substrate 15. A structure in which coating is performed from the peripheral edge 15a to the side surface which is the peripheral edge of the moisture-proof transparent plate 3 is also possible. Or conversely, the lower substrate 15 is cut into the same outer shape as the resin base material 11 of the display module 10, and the sealing material 17 is removed from the lower surface of the extending portion 3 a that is the peripheral portion of the moisture-proof transparent plate 3. It is also possible to have a structure in which the side surface as a part is applied and bonded.

  Further, although an electrophoretic display device using a plastic substrate has been described, it is obvious that the present invention can achieve the same effect even in an electrophoretic display device using glass as the lower substrate 15 of the display module. .

  The electrophoretic display device (display panel) in which the moisturizing material is sealed together with the display module according to the present invention has extremely low power consumption, can be extended in both high temperature and high humidity environment and high temperature and low humidity environment, and can be manufactured at low cost. It can be used as a display for portable devices such as mobile phones, portable electronic terminals or watches, and for various uses such as electronic books and electronic newspapers.

1 is a longitudinal sectional view schematically showing a configuration of a first embodiment of an electrophoretic display device according to the present invention. It is a partial expanded sectional view which shows the detail of the moisture-proof transparent board, a moisture retention material layer, and a moisture-proof cover member. It is a typical expanded sectional view of the principal part for demonstrating the display principle of the display module using the electrophoretic display element shown in FIG. It is a diagram which shows the difference of the change of the display contrast ratio with respect to the elapsed days of the high temperature, low humidity environment test by the presence or absence of a moisture retention material in an electrophoretic display device. It is a diagram which shows the difference in the change of the display contrast ratio with respect to the elapsed days of the high-temperature, high-humidity environment test by the presence or absence of a moisturizing material in the electrophoretic display device. It is a longitudinal cross-sectional view which shows typically the structure of the 2nd Example of the electrophoretic display device by this invention. It is a longitudinal cross-sectional view which shows typically the structure of the 3rd Example of the electrophoretic display device by this invention. It is a longitudinal cross-sectional view which shows typically the structure of the 4th Example of the electrophoretic display device by this invention. It is a longitudinal cross-sectional view which shows typically the structure of the 5th Example of the electrophoretic display device by this invention.

1, 1 ', 1 ", 25, 26: Electrophoretic display devices 1a, 25a, 26a: Peripheral part (ear part)
3: Moisture-proof transparent plate 3a: Extension portion of moisture-proof transparent plate 5: Moisture-proof cover member 5a: Extension portion of moisture-proof cover member 7, 7A, 7B: Moisturizing material 10: Display using electrophoretic display element Module 11: Resin base material 12: Transparent electrode 13: Microcapsule display layer 15: Lower substrate 16: Electrode pattern 17: Sealing material 18: Adhesive layer 20: Microcapsule 21: Capsule shell 22: Dispersion medium 23: White particles 24 : Black particles
31, 33: Transparent plastic sheet 32: Moisture-proof film 34: Hot-melt adhesive layer 51: Plastic sheet 52: Aluminum foil 53: Hot-melt adhesive layer 71: Moisturizing film 72: Hot-melt adhesive layer

Claims (9)

A display module using an electrophoretic display element, a moisture-proof transparent plate that covers the display surface side of the display module, and a moisture-proof cover member that covers the back side,
The display module is hermetically sealed by bonding the moisture-proof transparent plate and the moisture-proof cover member to each extending portion extending from the periphery of the display module,
A moisture retention material containing moisture is disposed in an area where the display module is sealed by at least the moisture-proof transparent plate and a moisture-proof cover member so as to keep the area at a humidity of 30 to 70%. An electrophoretic display device.   The electrophoretic display device according to claim 1, wherein the moisturizing material is disposed between the moisture-proof transparent plate or the moisture-proof cover member and the display module.   The moisturizing material is disposed in layers along the entire inner surface of the moisture-proof transparent plate or the moisture-proof cover member up to the extension portion, and the extension portion of the moisture-proof cover member and the moisture-proof transparent plate The electrophoretic display device according to claim 1, wherein the extending portion is bonded to the moisturizing material layer.   4. The moisture retaining material according to claim 1, wherein the moisture retaining material is disposed both between the moisture-proof transparent plate and the display module and between the moisture-proof cover member and the display module. The electrophoretic display device according to one item.   The moisture-proof transparent plate or the moisture-proof cover member is a bendable sheet in which the moisturizing material is laminated on the entire surface using an adhesive layer, and a hot melt adhesive layer is formed on the moisturizing material. The electrophoretic display device according to claim 1, wherein the electrophoretic display device is a liquid crystal display device. A display module using an electrophoretic display element, and a moisture-proof transparent plate covering the display surface side of the display module,
The display module is sealed by bonding a peripheral edge of the display module of the moisture-proof transparent plate and a peripheral edge of the lower substrate of the display module using a sealing material,
A moisture retaining material containing moisture is disposed in an area where the display module is sealed by at least the moisture-proof transparent plate and the lower substrate of the display module so as to keep the area at a humidity of 30 to 70%. An electrophoretic display device. A display module using an electrophoretic display element, a moisture-proof transparent plate that covers the display surface side of the display module, and a moisture-proof cover member that covers the back side,
The display module is formed by laminating a peripheral edge of the display module of the moisture-proof transparent plate and a peripheral edge of the lower substrate of the display module using a sealing material, and attaching a moisture-proof cover member to the back surface of the lower substrate. Is sealed
An electrophoretic display device, wherein a moisture retention material having a moisture content of 50% or more is disposed between at least the lower substrate and the moisture-proof cover member.   The electrophoretic display device according to claim 1, wherein the moisturizing material is an organic moisturizing material containing a polymer material. Wherein the coercive Shimezai electrophoretic display device according to any one of claims 1 to 6, the moisture content is characterized by being arranged in a state of being hygroscopic above 50%.

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