JP4028756B2 - Display panel - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a protection structure for a wiring board that protects wiring from moisture, reactive gas, and foreign matter in the surrounding atmosphere. In the present invention, the corrosion of the wiring includes chemical corrosion and electrical corrosion. Chemical corrosion is a phenomenon in which metal ions dissolved in water become hydroxides by hydrolysis with water and reaction with hydroxide ions, and precipitate on the metal and change into oxides. Electrical corrosion is a phenomenon in which a metal component moves across and through a surface of a non-metallic medium by an electric field generated when a current flows through a wiring, and is so-called electromigration.
[0002]
In the present invention, the volume shrinkage means the rate of change in volume before and after the curing of the substance. The volume shrinkage is expressed as V2 / V1 when the volume before curing is V1, and the volume after curing is V2. The The moisture permeability in the present invention is a value measured based on Japanese Industrial Standard Z0208 under the condition of temperature 40 ° C. × relative humidity 90%.
[0003]
[Prior art]
Conventionally, there is a display panel in which a periphery of a connection portion between an electrode terminal provided in a liquid crystal display element and an electrode terminal of a film wiring board on which a driving circuit is mounted is covered with a moisture-proof synthetic resin.
[0004]
FIG. 5 is a cross-sectional view of a connection portion between a liquid crystal display element 2 of a liquid crystal display panel 1 according to the prior art and a film wiring board 3 on which a drive circuit is mounted. The liquid crystal display panel 1 includes a liquid crystal display element 2 manufactured by interposing a liquid crystal layer 6 between a pair of substrates 4 and 5 and sealing the liquid crystal layer 6 with a sealing material 7. And a film wiring board 3 on which a driving circuit for driving a liquid crystal by applying a voltage to the liquid crystal layer 6 of the liquid crystal display element 2 is mounted.
[0005]
On the first substrate 4, active elements such as thin film transistors are arranged in a matrix, and a plurality of driving wirings 7 for driving the thin film transistors are arranged in the row direction and the column direction. The driving wiring 7 extends to the outside of the liquid crystal layer 6 and is connected to the wiring 8 provided on the film wiring substrate 3 at the end of the first substrate 4 via the conductive adhesive 9.
[0006]
In the liquid crystal display panel 1, when the driving wiring 7 of the first substrate 4 and the wiring 8 of the film wiring substrate 3 between the second substrate 5 and the film wiring substrate 3 are exposed, moisture and reactive gas in the surrounding atmosphere are exposed. In addition, since the foreign matter comes into contact with the driving wiring 7 and the wiring 8 and these wirings are corroded, the area where each wiring is exposed around the connection portion between the first substrate 4 and the film wiring substrate 3 is moisture-proof coated. Covered by layer 10. This prevents corrosion of the electrodes and wiring. The reactive gas is, for example, a gas containing sulfur. The first moisture-proof coating layer 10 </ b> A covering the driving wiring 7 is provided over the first substrate 4, the second substrate 5, and the film wiring substrate 3, and the second moisture-proof coating layer 10 </ b> B covering the wiring 8 is formed on the first substrate 4. And the film wiring board 3.
[0007]
As the moisture-proof coating layer 10, a synthetic resin having moisture resistance is used, and specifically, any one of a silicon resin, an acrylic resin, and a urethane resin is used.
[0008]
Silicone resin is excellent in filling in gaps and has a property of moisture curing in which the curing rate is accelerated as the humidity increases, so there is almost no volume change at the time of curing. Therefore, when the moisture-proof coating layer 10 is formed using silicon resin, the moisture-proof coating layer 10 formed by curing the silicon resin, the liquid crystal display element 2 and the film wiring board 3 are formed in the portion filled with the silicon resin. Adhering closely, there is an advantage that no gap is formed at the interface between the moisture-proof coating layer 10 and the liquid crystal display element 2 and the film wiring board 3. When a gap is formed at the interface between the moisture-proof coating layer 8 and the liquid crystal display element 2 and the film wiring board 3, the wiring is likely to be corroded by moisture, reactive gas, and foreign matter entering through the gap. However, by forming the moisture-proof coating layer 10 using silicon resin, it is possible to prevent a gap from being formed at the interface between the moisture-proof coating layer 10 and the liquid crystal display element 2 and the film wiring board 3 as described above.
[0009]
However, since silicon resin has high moisture permeability, that is, it can easily permeate moisture and reactive gas, it may cause a part of moisture and reactive gas in the surrounding atmosphere to permeate and induce corrosion of wiring. is there.
[0010]
When the moisture-proof coating layer 10 is formed using silicon resin, if the thickness of the moisture-proof coating layer 10 is increased, the permeation of moisture and reactive gas in the surrounding atmosphere can be suppressed. The peripheral portion of the liquid crystal display element 2 to be provided is a region held by a frame member or the like when the product is manufactured as a liquid crystal display device. Therefore, if the thickness of the moisture-proof coating layer 10 is increased, pressure is applied only to this region. Damage may occur. In addition, when a product is manufactured as a liquid crystal display device, the thickness of the moisture-proof coating layer 10 cannot be simply increased due to dimensional restrictions. Furthermore, when the thickness of the moisture-proof coating layer 10 is increased, there is a problem that the cost increases because more materials are used.
[0011]
Acrylic resins and urethane resins have lower moisture permeability than silicon resins, and are superior in moisture proofing and gas barrier properties, but these synthetic resins have the property of solvent evaporation and curing that is cured by evaporation of the solvent. When the synthetic resin is applied and the moisture-proof coating layer 10 is formed, the volume is reduced, and when cured, a gap may be formed at the interface between the moisture-proof coating layer 10 and the liquid crystal display element 2 and the film wiring board 3. There is. When moisture and reactive gas enter from such a gap, there is a problem of inducing corrosion of the wiring.
[0012]
Another conventional technique for solving such a problem is disclosed in Japanese Patent Laid-Open No. 10-170942. FIG. 6 is a cross-sectional view showing a part of a connection portion between the liquid crystal display element 2 and the film wiring board 3 of the liquid crystal display panel 15 which is another conventional technique. The display panel 15 has the same configuration as that of the liquid crystal display panel 1 shown in FIG. 5 described above, and the same reference numerals are assigned to regions corresponding to the configuration of the liquid crystal display panel 1 and the description thereof is omitted.
[0013]
In the liquid crystal display panel 15, the moisture-proof plate 16 is disposed so as to overlap the first moisture-proof coating layer 10 </ b> A provided over the first substrate 4, the second substrate 5, and the film wiring substrate 3 of the liquid crystal display panel 1 described above. A first moisture-proof coating layer 10A on the driving wiring 7 of the first substrate 4 exposed between the second substrate 5 and the film wiring substrate 3, and a plate-like moisture-proof plate 16 made of an acrylic resin plate, a glass plate, etc. Are arranged in layers. The moisture-proof plate 11 is bonded together when the first moisture-proof coating layer 10A is formed, that is, when a moisture-proof synthetic resin is applied and dried.
[0014]
The outer surface 16a of the moisture-proof plate 16 is disposed so as to substantially coincide with the outer surface 5a of the second substrate 5, and one end 16b of the moisture-proof plate 16 opposite to the side facing the second substrate 5 is the first substrate. 4 is provided so as to coincide with one end 4b.
[0015]
In the liquid crystal display panel 15, the driving wiring 7 is covered with the first moisture-proof coating layer 10A and the moisture-proof plate 16, so that the drive wiring 7 is driven only by the first moisture-proof coating layer 10A as in the liquid crystal display panel 1 shown in FIG. As compared with the case where the wiring 7 is covered, moisture and impurities are prevented from entering the driving wiring 7. As the material of the moisture-proof coating layer 10, acrylic resin, epoxy synthetic resin, silicon rubber, or the like is used.
[0016]
In the liquid crystal display panel 15, the second moisture-proof coating layer 10 </ b> B is provided between the wiring 8 of the film wiring substrate 3 and the first substrate 4 at the end of the first substrate 4.
[0017]
As another conventional technique of a liquid crystal display panel, Japanese Patent Application Laid-Open No. 9-185998 discloses that a pair of substrates are bonded together and a conductive film is provided on the outer surface of a sealing material that holds the liquid crystal between the substrates. A display panel is disclosed in which moisture intrusion is prevented and antistatic is performed. As a material for this conductive film, one or two or more synthetic resins selected from silicon resin, vinyl chloride resin, vinylidene chloride resin, phenol resin, polystyrene resin, polyurethane resin or these knitting resins are used. It is disclosed that these synthetic resins are excellent in applicability to glass and plastic substrates and sealing materials.
[0018]
[Problems to be solved by the invention]
In the liquid crystal display panel 15 described above, the plate-shaped moisture-proof plate 16 is placed on the first moisture-proof coating layer 10A. Therefore, the moisture-proof plate 16 always has a liquid crystal display via the first moisture-proof coating layer 10A. The element 2 and the printed wiring board 3 are bonded to each other. That is, the moisture-proof plate 16 is not in close contact with the liquid crystal display element 2 and the printed wiring board 3. Therefore, the first moisture-proof coating layer 10A is provided in the first region 17 between the moisture-proof plate 16 and the second substrate 5 of the liquid crystal display element 2 and in the second region 18 between the moisture-proof plate 16 and the printed wiring board 3. Only exists.
[0019]
When silicon rubber is used for the first moisture-proof coating layer 10A, moisture, reactive gas, foreign matter, etc. may enter from this region, and acrylic resin, urethane resin, or the like may enter the first coating layer 10A. Is used, as described above, a gap is formed at the interface between the first coating layer 10A, the liquid crystal display element 15, and the second substrate 3, and moisture, reactive gas, foreign matter, and the like can enter from the gap. There is sex.
[0020]
Further, when an impact, heat, or the like is applied to the liquid crystal display panel 15 and the first moisture-proof coating layer 10A is peeled off from the first substrate 4 or the printed wiring board 3, the moisture-proof plate 16 is also peeled off from the first moisture-proof coating layer 10A. Since it peels off with it, there exists a problem that the reliability of wiring protection is inferior.
[0021]
In the protective structure disclosed in Japanese Patent Laid-Open No. 9-184998, moisture can be prevented from permeating through the sealing material and entering the liquid crystal layer, but wiring cannot be prevented from corroding.
[0022]
In the liquid crystal display panel, the interval between wirings is reduced as the display image becomes higher in definition. When the wiring interval is reduced, the electric field applied between the wirings is increased. When moisture, reactive gas and foreign matter come into contact with the wiring of such a liquid crystal display panel, there is a problem that the wiring is easily corroded.
[0023]
  The object of the present invention is to prevent wiring corrosion caused by moisture, reactive gas and foreign matter in the surrounding atmosphere, and to prevent the wiring from being cut and short-circuited.Display panelIs to provide.
[0024]
[Means for Solving the Problems]
  The present inventionA first substrate provided with a first wiring;
  A second substrate provided with a second wiring;
  A third substrate formed smaller than the first substrate and facing the first substrate on which the first wiring is provided;
  Provided between the peripheral portion of the first substrate and the peripheral portion of the third substrate, and bonds the first substrate and the third substrate to each other and forms a space sandwiched between the first substrate and the third substrate. A sealing layer provided by being retracted from the end of the third substrate;
  A conductive adhesive that bonds the second substrate to each other so that the first wiring and the second wiring face each other in a region where the first substrate is exposed to the third substrate;
  A synthetic resin having a predetermined first moisture permeability and a predetermined first volume shrinkage,A first contact portion that contacts a surface of the first substrate on which the first wiring is provided; a second contact portion that contacts the seal layer; a third contact portion that contacts a surface of the third substrate facing the first substrate; A fourth contact portion that contacts one end surface of the substrate facing the second substrate, a fifth contact portion that contacts one end portion of the second substrate facing the third substrate, and a side opposite to the first substrate in the thickness direction of the second substrate A first contact portion in a region where the first wiring is exposed between the second substrate and the third substrate.A first protective layer provided in contact with the substrate;
  Than the predetermined second moisture permeability smaller than the predetermined first moisture permeability and the predetermined first volume shrinkage rate.smallMade of a synthetic resin having a predetermined second volume shrinkage rate, covering the first protective layer so that the first protective layer is not exposed to the outside, and1st to 3rdAnd a second protective layer provided in contact with the substrate.Display panelIt is.
[0031]
  According to the present invention, tableThe wiring of the display panel can be protected from moisture, reactive gas, and foreign matter, and the disconnection and short circuit of the wiring caused by the corrosion of the wiring can be prevented. In particular, it is possible to reliably prevent a migration phenomenon that is likely to occur due to an increase in the electric field applied between the electrodes because the interval between the wirings extending in parallel with the increase in the definition of the display panel is reduced. Therefore, the reliability of the display panel is improved.
[0033]
  AlsoThe conductive adhesive adheres to the first wiring and the second substrate in such a manner that the first wiring and the second wiring face each other in a region where the first substrate is exposed to the third substrate. The second wirings can be electrically connected to each other.
[0034]
  AlsoSecond protection with low moisture permeability, which can prevent moisture, reactive gas and foreign matter from entering the region where the wiring is provided from between the first protective layer and the second protective layer and the first to third substrates. By providing the layer outside the first protective layer, it is possible to prevent moisture and reactive gas from penetrating into the region where the wiring is provided directly through the inside of the synthetic resin. Even if one or more of the second protective layer and the first substrate, the second protective layer and the second substrate, and the second protective layer and the third substrate are peeled off, the inner side of the second protective layer Since the first protective layer is provided, moisture and reactive gas entering from between the second protective layer and any of the first to third substrates can be blocked by the first protective layer.
[0035]
  In particular, the synthetic resin forming the first protective layer has a lower moisture permeability than that of the synthetic resin forming the second protective layer.Volume change after curingTherefore, no gap is formed at the interface between the first protective layer and each substrate. Accordingly, it is possible to prevent moisture, reactive gas, and the like from entering the region where the wiring is provided from between the first protective layer and the first to third substrates.
[0036]
Thus, the first protective layer and the second protective layer provide moisture, that is, H₂O and reactive gases such as H₂A substance such as S can be reliably prevented from entering the region where the wiring is provided, and the moisture resistance and the reliability of the gas barrier can be significantly improved.
[0037]
Furthermore, even if heat, impact, or the like is applied from the outside and either one of the first protective layer and the second protective layer is peeled off from the first substrate, the second substrate, and the third substrate on which wiring is provided, for example, Either of the second protective layers can maintain the state of being adhered to the substrate, and moisture and reactive gas can enter the region where the wiring is provided from between the first protective layer or the second protective layer and the substrate. Can be prevented. Therefore, the reliability of wiring protection against undesired external stress can be improved. In addition, the conductive adhesive between the first substrate and the second substrate can be covered, and the connection reliability can be improved as well.
[0047]
In the present invention, the predetermined first moisture permeability is 2.0 × 10 when the thickness is 100 μm.²g / m²・ It is 24 hours or more and 4.0 × 10²g / m²The second moisture permeability determined in advance at 24 hr or less is 15 g / m when the thickness is 100 μm.²・ It is 24 hours or more and 2.0 × 10²g / m²-Less than 24 hr, the predetermined first volume shrinkage ratio is 0.8 or more and less than 0.99, and the predetermined second volume shrinkage ratio is 0.2 or more and 0.4 or less. It is characterized by.
[0048]
When the thickness is 100 μm, the moisture permeability is 2.0 × 10²g / m²-Synthetic resin that is less than 24 hours can pass hydrogen sulfide, which is a reactive gas, which is one of the causes of migration in wiring. Moisture permeability is 4.0 × 10²g / m²-Synthetic resin exceeding 24 hr facilitates the permeation of moisture and reactive gas. The moisture permeability is 15g / m²-With synthetic resin of 24 hours or more, moisture and reactive gas can be sufficiently blocked.
[0049]
Further, the predetermined first volume shrinkage ratio is 0.8 or more and less than 0.99, and the change between the volume before curing and the volume after curing is reduced, whereby the first moisture-proof layer and the substrate are reduced. It is possible to prevent a gap from being formed between the two. The predetermined second volume shrinkage ratio is 0.2 or more and 0.4 or less, and even in the case of such a synthetic resin whose volume is greatly shrunk, the moisture permeability is 4.0 × 10 4 as described above.²g / m²・ It is 24hr or less, 15g / m²-By using a synthetic resin of 24 hours or more, moisture resistance of the wiring and reliability of the gas barrier can be improved.
[0050]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a cross-sectional view showing a part of a display panel 20 using a wiring board protection structure according to an embodiment of the present invention. The display panel 20 is an active matrix type liquid crystal display panel using a thin film transistor (abbreviated as TFT), which is a three-terminal element, as a switching element. In the present embodiment, the surface of the substrate on which the electrode layer or the wiring layer is provided on the substrate includes the surface of the electrode layer and the surface of the base material exposed between the electrode layers.
[0051]
The display panel 20 includes a first substrate 22 provided with an electrode layer 21 serving as a first wiring, a second substrate 24 provided with a wiring layer 23, a third substrate 25 facing the first substrate 22, a first substrate 22 and a first substrate 22. 3 includes a seal layer 26 for bonding the substrate 25, a liquid crystal layer 27, an adhesive layer 28 for bonding the first substrate 22 and the second substrate 24, and a first seal portion A and a second seal portion B.
[0052]
The first substrate 22 and the third substrate 25 have a rectangular shape, have a predetermined thickness, and at least one of the two substrates has translucency.
[0053]
The first substrate 22 is, for example, a scanning formed of an individual electrode provided for each pixel, a thin film transistor (abbreviated TFT) provided for each individual electrode, and a metal conductor on the surface of a base material such as a glass substrate and a plastic substrate. Wiring and signal wiring, an individual electrode, a thin film transistor, a scanning wiring, an alignment film provided in a predetermined region covering the signal wiring, and an electrode layer 21 are provided. The electrode layer 21 is realized by copper, for example. The alignment film is provided in a region where a liquid crystal layer 27 described later is interposed. The individual electrode is electrically connected to the drain of the thin film transistor, the scanning wiring is electrically connected to the gate of the thin film transistor, and the signal wiring is electrically connected to the source of the thin film transistor. In the display panel 20, a plurality of scanning wirings and a plurality of signal wirings are arranged in a matrix on the first substrate 22, and one end of the scanning wiring is connected to the electrode layer 21. The electrode layer 21 is a terminal of the scanning wiring and extends from the liquid crystal layer 27 to the one end 22 a of the first substrate 22. In the present embodiment, the electrode layer 21 is used as a scanning wiring terminal. However, in another embodiment of the present invention, the electrode layer 21 may be used as a signal wiring terminal.
[0054]
The third substrate 25 includes, for example, a common electrode, a color filter, and an alignment film provided to cover the common electrode and the color filter on the surface of a base material such as a glass substrate and a plastic substrate. The alignment film is provided in a region where a liquid crystal layer 27 described later is interposed.
[0055]
The individual electrode and the common electrode described above are transparent electrodes, and are realized by, for example, indium tin oxide (abbreviated as ITO).
[0056]
The first substrate 22 and the third substrate 25 are provided in parallel with a predetermined interval so that the alignment films face each other. The thickness direction of the third substrate 25 is parallel to the thickness direction of the first substrate 22 in a state where the first substrate 22 and the third substrate 25 are provided in parallel to each other with a space therebetween. The first substrate 22 is configured to be larger than the third substrate 25, and the first end portion 22 a of the first substrate 22 is exposed from the facing third substrate 25 in a state of facing the third substrate 25.
[0057]
The sealing layer 26 is provided between the peripheral portion of the first substrate 22 and the peripheral portion of the third substrate 25, and adheres the first substrate 22 and the third substrate 25 to each other, and An accommodation space sandwiched between the three substrates 25 is formed. The seal layer 26 is provided by being retracted from the end portion of the third substrate 25.
[0058]
The liquid crystal layer 27 is provided between the first substrate 22 and the third substrate 25. The liquid crystal layer 27 is formed of liquid crystal sealed in a housing space sandwiched between the first substrate 22 and the third substrate 25 and is surrounded by the seal layer 26.
[0059]
A liquid crystal display element 31 is configured including the first substrate 22, the third substrate 25, the seal layer 26, and the liquid crystal layer 27 described above.
[0060]
The second substrate 24 is a film wiring substrate and is realized by a flexible substrate having flexibility and a film tape. The thickness of the second substrate 24 is smaller than that of the first substrate 22 and the third substrate 25. The second substrate 24 includes a wiring layer 23 that is a second wiring and a drive circuit that is a semiconductor integrated circuit. The second substrate 24 includes a base material 32, a wiring layer 23 provided on one surface of the base material 32 and made of a metal conductor, and a coating layer 33 that covers the wiring layer 23. The wiring layer 23 is exposed at one end 24 a of the second substrate 24. The other end of the wiring layer 23 is connected to a drive circuit (not shown). The wiring layer 23 is realized by copper, for example.
[0061]
The drive circuit is mounted on the substrate 32 or the covering layer 33 and is electrically connected to the wiring layer 23. The second substrate 24 on which the drive circuit is mounted is a tape carrier package (abbreviated as TCP), a flexible printed circuit (abbreviated as FPC), a chip on FPC (abbreviated as COF), or the like. Called.
[0062]
The second substrate 24 includes a plurality of wiring layers 23, and the drive circuit is connected to the plurality of electrode layers 21 via the plurality of wiring layers 23. One or more second substrates 24 are provided depending on the number of pixels of the liquid crystal display element 31.
[0063]
The adhesive layer 28 bonds the one end 22 a of the first substrate 22 and the one end 24 a of the second substrate 24 to each other. As shown in FIG. 1, the first substrate 22 on which the electrode layer 21 is provided so that the electrode layer 21 and the wiring layer 23 face the surface of the one end 24 a of the second substrate 24 on which the wiring layer 23 is provided. A predetermined region is overlapped on the surface of the substrate, and an adhesive layer 28 is provided in the overlapping region.
[0064]
FIG. 2 is a cross-sectional view of the display panel 20 cut along a plane parallel to the extending direction of each electrode layer 21 between the electrode layer 21 and the electrode layer 21. The surface of the first substrate 22 includes the surface of each electrode layer 23 and the surface of a base material such as a glass substrate and a plastic substrate exposed between the electrode layers 21. The surface of the second substrate 24 includes the surface of each wiring layer 23 and the surface of the base material 32 exposed between the wiring layers 23.
[0065]
The one end portion 22a of the first substrate 22 and the one end portion 24a of the second substrate 24 are bonded to each other by an anisotropic conductive adhesive which is an adhesive layer 28, and one end portion 21a of the electrode layer 21 and one end portion of the wiring layer 23 are bonded. 23a is electrically connected to each other by an anisotropic conductive adhesive. The anisotropic conductive adhesive passes a current between the electrode layer 21 and the wiring layer 23, but does not pass a current between the plurality of electrode layers 21 provided in parallel or between the plurality of wiring layers 23 provided in parallel. It does not pass through. The anisotropic conductive adhesive 27 is realized by an adhesive including a conductive spacer, for example.
[0066]
A predetermined gap is provided between one end 24 a of the second substrate 24 facing the third substrate 25 and one end 25 a of the third substrate 25 facing the second substrate 24.
[0067]
A region where the electrode layer 21 provided on the first substrate 22 is exposed between the second substrate 24 and the third substrate 25 on the surface of the first substrate 22, that is, the sealing layer 26 and one end 24 a of the second substrate 24. The 1st seal | sticker part A is provided in the area | region between. The first seal portion A includes an element side first protective layer 37 and an element side second protective layer 39. The first seal portion A covers all of the plurality of electrode layers 21 in the width direction of the connection portion between the first substrate 22 and the second substrate 24, that is, the direction perpendicular to the paper surface of FIG.
[0068]
The element-side first protective layer 37 covers the electrode layer 21 and is provided across one end 25a of the third substrate 25 facing the second substrate 24 and one end 24a of the second substrate 24 facing the third substrate 25, The first substrate 22, the second substrate 24, and the third substrate 25 are in contact with each other. The element-side first protective layer 37 is formed so as to be inclined toward the one end portion 24a of the second substrate 24 from the one end portion 25a of the third substrate 25, and the electrode layer 21 of the first substrate 22 is provided. The first contact portion 41 that contacts the surface to be formed, the second contact portion 42 that contacts the seal layer 26, the third contact portion 43 that contacts the surface of the third substrate 25 facing the first substrate 22, and the third substrate 25. A fourth contact portion 44 that contacts one end surface facing the second substrate 24, a fifth contact portion 45 that contacts one end portion 24a facing the third substrate 25 of the second substrate 24, and one surface in the thickness direction of the second substrate 24. It has the 6th contact part 46 which contacts the base material 32. FIG.
[0069]
In the first to sixth contact portions 41 to 46 of the element-side first protective layer 37, the surface on which the element-side first protective layer 37 is in contact with the liquid crystal display element 31 and the second substrate 24 is different. Due to the impact and heat, it is possible to prevent the peeling at the same time at all the contact portions where the element-side first protective layer 37 contacts. Since the element-side first protective layer 37 also covers the adhesive layer 28 that bonds the first substrate 22 and the second substrate 24 at the same time, the connection reliability between the electrode layer 21 and the wiring layer 23 is improved.
[0070]
In the element-side second protective layer 39, the electrode layer 21 is not exposed to the outside across the one end 25a of the third substrate 25 facing the second substrate 24 and the one end 24a of the second substrate 24 facing the third substrate 25. That is, that is, the electrode layer 21 covers the exposed element side first protective layer 37 in the surrounding atmosphere, and contacts the first substrate 22, the second substrate 24, and the third substrate 25.
[0071]
The element-side second protective layer 39 is in contact with the seventh contact portion 47 contacting the one end portion 25a of the third substrate 25 facing the second substrate 24 and the base material 32 on one surface in the thickness direction of the second substrate 24. The contact portion 58 is provided so as to be inclined from the third substrate 25 toward the second substrate 24. One end portion 39 a on the second substrate 24 side of the element-side second protective layer 39 is formed with an interval of a dimension W from the one end surface 22 </ b> C of the first substrate 22 to the inside of the first substrate 22. By forming the element-side second protective layer 39 in this way, it is possible to prevent the element-side second protective layer 39 from being caught and damaged by a transfer device or the like during transfer.
[0072]
The second seal portion B is provided in a region where the wiring layer 23 provided on the second substrate 24 is exposed, that is, a region between the first substrate 22 and the covering layer 33. The second seal portion B includes a drive circuit side first protective layer 38 and a drive circuit side second protective layer 40. The second seal portion B covers all of the plurality of wiring layers 23 in the width direction of the connection portion between the first substrate 22 and the second substrate 24, that is, the direction perpendicular to the paper surface of FIG.
[0073]
The drive circuit side first protective layer 38 is a region where the wiring layer 23 of the second substrate 24 is exposed from the first substrate 22, that is, a region where the wiring layer 23 is exposed from the first substrate 22 at one end 24 a of the second substrate 24. And is provided across the one end 22a of the first substrate 22 and the coating layer 33 on the other surface in the thickness direction of the second substrate 24. The drive circuit side first protective layer 38 contacts the ninth contact portion 49 that contacts one end surface 22 </ b> C that is a surface perpendicular to the thickness direction of the one end portion 22 b of the first substrate 22, and the coating layer 33 of the second substrate 24. 10th contact part 50 to be included.
[0074]
The drive circuit side second protective layer 40 covers the drive circuit side first protective layer 38 so that the drive circuit side first protective layer 38 is not exposed to the outside, and the end surface 22C of the first substrate 22 and the second substrate 24 are covered. The covering layer 33 is provided. The drive circuit side second protective layer 40 includes an eleventh contact portion 51 that contacts the one end face 22 </ b> C of the first substrate 22 and a twelfth contact portion 52 that contacts the coating layer 33 of the second substrate 24. The drive circuit side first protective layer 38 and the drive circuit side second protective layer 40 are provided to be inclined from the one end face 22 </ b> C of the first substrate 22 toward the second substrate 24.
[0075]
In the present embodiment, the element side first protective layer 37 and the drive circuit side first protective layer 38 are formed of silicon resin, and the element side second protective layer 39 and the drive circuit side second protective layer 40 are formed of acrylic resin. To do.
[0076]
Since the silicone resin is excellent in filling in the gap, it can be filled in the gap 36 between the first substrate 22 and the third substrate 25 outside the sealing layer 26 of the liquid crystal display element 31. In this case, it is possible to prevent direct contact between the electrode layer 21 and the outside air.
[0077]
The silicon resin is a synthetic resin having a humidity curing property in which the curing rate is accelerated as the humidity is higher. Since the volume hardly changes during the curing, the silicon resin is applied to the element side first protective layer 37 and the drive circuit. Since the applied state can be maintained as it is when the first side protective layer 38 is formed, the silicon resin, the liquid crystal display element 31 and the second substrate 24 can be maintained even if the silicon resin is dried and cured in the region where the silicon resin is applied. Is maintained, and no gap is formed at the interface between the element-side first protective layer 37 and the drive circuit-side first protective layer 38, the liquid crystal display element 31, and the second substrate 24. Silicone resin hardly changes in volume when cured, and the application state can be maintained as it is, so that the filling state can be easily controlled by the application means.
[0078]
The moisture permeability of silicon resin is 400 g / m with a thickness of 100 μm.²-It is 24 hr, and moisture resistance and gas barrier properties are inferior, so there is a possibility that a sufficient moisture-proof effect cannot be obtained by using a single layer of silicon resin, but as described above, silicon resin has excellent filling properties, Since the volume does not change, there is an advantage that no gap is formed at the interface between the liquid crystal display element 31 and the second substrate 24 when the element-side first protective layer 37 and the drive circuit-side first protective layer 38 are formed.
[0079]
The acrylic resin is diluted to about 30% with a solvent before drying, and the volume shrinkage is about 0.3, and the volume shrinkage is larger than that of the silicone resin. At 100 μm, 160 g / m²・ Because it is 24 hours, the moisture permeability is lower than that of silicon resin, and the moisture resistance and gas barrier properties are excellent. Therefore, it is possible to sufficiently block moisture and reactive gas in the surrounding atmosphere. As described above, the element-side second protective layer 39 and the drive circuit-side second protective layer 40 can suppress moisture and reactive gas penetrating through and penetrating to an extremely low level.
[0080]
The first seal part A and the second seal part B are a silicone resin having an advantage that no gap is formed at the interface between the liquid crystal display element 31 and the second substrate 24, and an acrylic having an advantage of excellent moisture resistance and gas barrier properties. By setting the resin to the above-described configuration, the possibility that the electrode layer 21 and the wiring layer 23 come into contact with moisture, reactive gas, foreign matter, and the like can be extremely reduced. Therefore, it is possible to prevent corrosion of the electrode layer 21 and the wiring layer 23 caused by contact of moisture, reactive gas, foreign matter, and the like, and to improve the reliability of protection of the electrode layer 21 and the wiring layer 23. The reliability of the liquid crystal display panel 20 can be improved.
[0081]
In order to obtain sufficient moisture resistance and gas barrier property using only the silicon resin, it is necessary to increase the layer thickness of the layer formed of the silicon resin as in the conventional technique. In the second seal portion B, the element-side second protective layer 39 and the drive circuit side second protective layer 40 made of acrylic resin having low moisture permeability are used as the element-side first protective layer 37 and the drive circuit side second made of silicon resin. By providing the protective layer 38 in a laminated manner, it is possible to ensure moisture resistance and gas barrier properties without increasing the layer thickness of the first seal portion A and the second seal portion B.
[0082]
The thermal expansion coefficient of silicon resin is 2 × 10^-FiveThe coefficient of thermal expansion of the acrylic resin is 8 × 10.^-FiveIt is about (1 / ° C). By covering the electrode layer 21 and the wiring layer 23 with layers made of two substances having different coefficients of thermal expansion in this way, heat is applied from the outside, and one layer is peeled off from the liquid crystal display element 31 and the second substrate 24. However, the possibility of the other layer peeling off can be reduced. Therefore, a highly reliable display panel can be manufactured.
[0083]
The display panel 20 further includes a polarizing plate (not shown). The polarizing plate extracts only light having a predetermined vibration direction. The polarizing plate is provided, for example, on the other surface in the thickness direction of the individual electrode forming substrate and on the other surface in the thickness direction of the third substrate 25.
[0084]
The display panel 20 displays various images by controlling the thin film transistor with a driving circuit and applying a voltage between the individual electrode and the common electrode to change the alignment state of the liquid crystal molecules of the liquid crystal layer 27. . For example, the direction of the groove of the alignment film provided on the first substrate 22 and the direction of the groove of the alignment film provided on the common electrode formation substrate are perpendicular to each other, and light from the polarizing plate provided on the first substrate 22 And the vibration direction of light by the polarizing plate provided on the third substrate 25 are perpendicular to each other.
[0085]
In the state where no voltage is applied between the individual electrode and the common electrode, the alignment state of the liquid crystal molecules does not change. For example, the light emitted from the light source to the first substrate 22 and transmitted through the liquid crystal layer 27 is transmitted to the third substrate 25. It passes through the polarizing plate provided in the. In a state where a voltage is applied between the individual electrode and the common electrode, the alignment state of the liquid crystal molecules changes so that the major axis direction of the liquid crystal molecules is parallel to the thickness direction of the first substrate 22. As described above, when the alignment state of the liquid crystal molecules changes, the light irradiated from the light source to the first substrate 22 and transmitted through the liquid crystal layer is blocked by the polarizing plate provided on the third substrate 25. The voltage applied between the individual electrode and the common electrode is controlled for each pixel. Various images are displayed based on light that has passed through a polarizing plate provided on the third substrate 25.
[0086]
FIG. 3 is a flowchart showing a manufacturing process of the first seal portion A of the display panel 20 described above. In a state where the second substrate 24 is bonded to the liquid crystal display element 31, first, in step a 1, the third substrate 22 is exposed to the region where the electrode layer 21 of the first substrate 22 is exposed between the second substrate 24 and the third substrate 25. The first substrate 22, the second substrate 24, and the third substrate 25 are in contact with each other over the one end portion 25 a of the substrate 25 facing the second substrate 24 and the one end portion 25 a of the third substrate 25 facing the second substrate 24. Then, silicon resin is applied using a dispenser, and the process proceeds to step a2. The dispenser is a device that applies a material by discharging a material from a thin nozzle with a gas pressure controlled to a predetermined value. In step a1, the surface of the first substrate 22 on which the electrode layer 21 is provided, the sealing layer 26, the surface of the third substrate 25 facing the first substrate 22, the one end 25a of the third substrate 25 facing the second substrate 24, A silicon resin, which is a first synthetic resin, is applied so as to come into contact with one end portion 24 a of the second substrate 24 facing the third substrate 25 and one surface in the thickness direction of the second substrate 24.
[0087]
  In step a2, the silicon resin applied in step a1 is dried and cured, and the process proceeds to step a3. In step a2, the element-side first protective layer 37 is formed by drying the silicon resin. Silicone resin has a volume shrinkagebigTherefore, there is no gap between the liquid crystal display element 31 and the second substrate 24 in the applied region.
[0088]
In step a3, one end portion 25a of the third substrate 25 facing the second substrate 24 and one end portion 24a of the second substrate 24 facing the third substrate 25 so as to cover the element-side first protective layer 37 again using a dispenser. Then, an acrylic resin, which is a second synthetic resin, is applied so as to be in contact with the first substrate 22, the second substrate 24, and the third substrate 25, and the process proceeds to step a4.
[0089]
  In step a4, the acrylic resin applied in step a3 is dried and cured to finish the process. In step a4, the element side second protective layer 39 is formed by drying the acrylic resin. Acrylic resin has a volumetric shrinkagesmallTherefore, the volume is reduced when dried, but the first substrate 22, the second substrate 24, and the third substrate 22 are applied by being applied in contact with the first substrate 22, the second substrate 24, and the third substrate 25. At least contact with the substrate is maintained. Through the above steps, the first seal portion A is formed.
[0090]
In the first seal portion A formed in this way, it is assumed that the element-side second protective layer 39 is peeled off from the second substrate 24 and a gap is generated between the element-side second protective layer 39 and the second substrate 24. However, since the element-side first protective layer 37 is provided on the inner side, it is possible to prevent moisture, reactive gas and foreign matter entering from the gap from entering the region where the electrode layer 21 is provided. .
[0091]
  The element-side first protective layer 37 has higher moisture permeability than the element-side second protective layer 39, but has a volume shrinkage rate.bigTherefore, there is no gap in the contact portion between the element-side first protective layer 37 and the liquid crystal display element 31 and the second substrate 24 described above. Therefore, it is possible to prevent moisture, reactive gas and foreign matter from entering the region where the electrode layer 21 is provided from between the element side first protective layer 37 and the liquid crystal display element 31 and the second substrate 24.
[0092]
Thus, in the first seal portion A, the element side first protective layer 37 and the element side second protective layer 39 cause moisture, that is, H₂O and reactive gases such as H₂A substance such as S can be reliably prevented from entering the region where the electrode layer 21 is provided, and the moisture resistance and the reliability of the gas barrier can be significantly improved.
[0093]
FIG. 4 is a flowchart showing a manufacturing process of the second seal portion B of the display panel 20 described above. In a state where the second substrate 24 is connected to the liquid crystal display element 31, in step b 1, the one end face 22 C of the first substrate 22 and the second substrate 22 are exposed in a region where the wiring layer 23 of the second substrate 24 is exposed from the first substrate 22. A silicon resin, which is the first synthetic resin, is applied over the other surface in the thickness direction of the substrate 24 using a dispenser, and the process proceeds to step b2.
[0094]
In step b2, the silicon resin applied in step b1 is dried, and the process proceeds to step b3. In step b2, the drive circuit side first protective layer 38 is formed by drying the silicon resin.
[0095]
In step b3, the first protective layer 38 is covered so as to contact the first substrate 22 and the second substrate 24 across the end surface 22C of the first substrate 22 and the other surface in the thickness direction of the second substrate 24. The acrylic resin as the second synthetic resin is applied using a dispenser, and the process proceeds to step b4.
[0096]
  In step b4, the acrylic resin applied in step b3 is dried and cured, and the process ends. In step b4, the acrylic resin is dried to form the drive circuit side second protective layer 40. Acrylic resin has a volumetric shrinkagesmallTherefore, the volume decreases when dried, but the contact with the first substrate 22 and the second substrate 24 is maintained to some extent by being applied in contact with the first substrate 22 and the third substrate 25. Be drunk. Through the above steps, the second seal portion B is formed.
[0097]
In the second seal portion B formed in this way, the drive circuit side second protective layer 40 is temporarily separated from the second substrate 24, and a gap is generated between the drive circuit side second protective layer 40 and the second substrate. However, since the drive circuit side first protective layer 38 is provided on the inner side, moisture, reactive gas and foreign matter entering from the gap are prevented from entering the region where the electrode layer 21 is provided. Can do.
[0098]
The drive circuit side first protective layer 38 has a higher water vapor permeability than the drive circuit side second protective layer 40, but has a small volume change rate. Therefore, the drive circuit side first protective layer 38, the first substrate 22 and the first substrate 22 described above are used. There is no gap in the contact portion with the two substrates 24. Therefore, it is possible to prevent moisture, reactive gas, and foreign matter from entering the region where the wiring layer 23 is provided from between the element-side first protective layer 37 and the first substrate 22 and the second substrate.
[0099]
As described above, in the second seal portion B, moisture, that is, H is generated by the drive circuit side first protective layer 38 and the drive circuit side second protective layer 40.₂O and reactive gases such as H₂A substance such as S can be reliably prevented from entering the region where the wiring layer 23 is provided.
[0100]
The above-described drying of the silicon resin in step a2 and step b2 and the drying of the acrylic resin in step a4 and step b4 may be performed by natural drying that waits for a predetermined time until drying according to the ambient atmosphere, or heating is performed. And may be dried. When heated and dried, the treatment time can be shortened.
[0101]
The moisture permeability of the synthetic resin forming the element-side first protective layer 37 and the drive circuit-side first protective layer 38 is 2.0 × 10 when the thickness is 100 μm.²g / m²・ It is 24 hours or more and 4.0 × 10²g / m²The moisture permeability of the synthetic resin forming the element side second protective layer 39 and the drive circuit side second protective layer 40 is 24 mm or less, the volume shrinkage ratio is 0.8 or more and less than 0.99, 15 g / m when the thickness is 100 μm²・ It is 24 hours or more and 2.0 × 10²g / m²-Less than 24 hr, the volume shrinkage is 0.2 or more and 0.4 or less, preferably 0.27 or more and 0.38 or less. By using such element side first protective layer 37, drive circuit side first protective layer 38, element side second protective layer 39, and drive circuit side second protective layer 40, the electrode layer 21 and the wiring layer 23 are protected. Can be suitably performed.
[0102]
As described above, in the display panel according to the present embodiment, moisture, reactive gas, and foreign matter in the surrounding atmosphere do not come into contact with the electrode layer 21 and the wiring layer 23, so that the electrode layer 21 and the wiring layer 23 are not corroded. Therefore, since the electrode layer 21 and the wiring layer 23 are not cut or short-circuited, the reliability of the display panel 20 is improved.
[0103]
In a display panel using a wiring board protection structure according to still another embodiment of the present invention, the element-side second protective layer 39 and the drive circuit-side second protective layer 40 described above may be formed of urethane resin.
[0104]
The moisture permeability of urethane resin is 45g / m with a thickness of 100μm.²Before drying, it is diluted to about 30% with a solvent and has a volume shrinkage of about 0.3. Compared to the acrylic resin described above, the element-side second protective layer 39, the drive circuit-side first When the two protective layers 40 are formed, moisture resistance and gas barrier properties are further enhanced.
[0105]
Further, when the element-side second protective layer 39 and the drive circuit-side second protective layer 40 are formed of urethane resin, the moisture permeability is smaller than that of acrylic resin, so that the layer thickness is reduced compared to the case of forming with acrylic resin. It is also possible.
[0106]
The coefficient of thermal expansion of the urethane resin is 6.0 to 7.0 × 10.^-FiveSince it is (1 / ° C.), when heat is applied from the outside, the same effect as when an acrylic resin is used can be obtained.
[0107]
The present invention can be applied to any display panel of a simple matrix driving type display panel, an active matrix driving type display panel using two-terminal elements, and a static driving type display panel. It can be suitably used for a flat panel such as a luminescence (EL) panel and also an electric wiring board.
[0108]
In addition, the above-described wiring board protection structure includes the first protective layer and the second protective layer. However, in still another embodiment of the present invention, the third protective layer is covered with the second protective layer. It is good also as composition provided further.
[0114]
【The invention's effect】
  BookAccording to the invention, tableThe wiring of the display panel can be protected from moisture, reactive gas, and foreign matter, and the disconnection and short circuit of the wiring caused by the corrosion of the wiring can be prevented. In particular, it is possible to reliably prevent a migration phenomenon that is likely to occur due to an increase in the electric field applied between the electrodes because the interval between the wirings extending in parallel with the increase in the definition of the display panel is reduced. Therefore, the reliability of the display panel is improved.
[0115]
According to the present invention, the conductive adhesive bonds the second substrate to each other so that the first wiring and the second wiring face each other in a region where the first substrate is exposed to the third substrate. Thus, the first wiring and the second wiring can be electrically connected to each other.
[0116]
The first protective layer covering the first wiring provided on the first substrate is in contact with the first substrate, the end of the second substrate facing the third substrate, and the end of the third substrate facing the second substrate. The second protective layer covers the first protective layer and contacts the first substrate, the end of the second substrate facing the third substrate, and the end of the third substrate facing the second substrate, respectively. Therefore, moisture, reactive gas, and foreign matter can be prevented from entering the area where the wiring is provided from between the first protective layer and the second protective layer and the first to third substrates. By providing the second protective layer having a low humidity outside the first protective layer, it is possible to prevent moisture and reactive gas from entering the region where the wiring is provided directly through the inside of the synthetic resin. Even if one or more of the second protective layer and the first substrate, the second protective layer and the second substrate, and the second protective layer and the third substrate are peeled off, the inner side of the second protective layer Since the first protective layer is provided, moisture and reactive gas entering from between the second protective layer and any of the first to third substrates can be blocked by the first protective layer.
[0117]
In particular, the synthetic resin forming the first protective layer has a lower moisture permeability than that of the synthetic resin forming the second protective layer, but the volume shrinkage is small, so that the interface between the first protective layer and the substrate is low. No gap is formed. Accordingly, it is possible to prevent moisture, reactive gas, and the like from entering the region where the wiring is provided from between the first protective layer and the first to third substrates.
[0118]
Thus, the first protective layer and the second protective layer provide moisture, that is, H₂O and reactive gases such as H₂A substance such as S can be reliably prevented from entering the region where the wiring is provided, and the moisture resistance and the reliability of the gas barrier can be significantly improved. Accordingly, corrosion of the wiring caused by moisture, reactive gas, foreign matter, etc. coming into contact with the wiring can be prevented, and the reliability of the display panel can be improved.
[0119]
Furthermore, even if heat, impact, or the like is applied from the outside and either one of the first protective layer and the second protective layer is peeled off from the first substrate, the second substrate, and the third substrate on which wiring is provided, for example, Either of the second protective layers can maintain the state of being adhered to the substrate, and moisture and reactive gas can enter the region where the wiring is provided from between the first protective layer or the second protective layer and the substrate. Can be prevented. Therefore, the reliability of wiring protection against undesired external stress can be improved. In addition, the conductive adhesive between the first substrate and the second substrate can be covered, and the connection reliability can be improved as well.
[0127]
According to the present invention, when the thickness is 100 μm, the moisture permeability is 2.0 × 10²g / m²-Synthetic resin that is less than 24 hours can pass hydrogen sulfide, which is a reactive gas, which is one of the causes of migration in wiring. Moisture permeability is 4.0 × 10²g / m²-Synthetic resin exceeding 24 hr facilitates the permeation of moisture and reactive gas. The moisture permeability is 15g / m²-With synthetic resin of 24 hours or more, moisture and reactive gas can be sufficiently blocked.
[0128]
Further, the predetermined first volume shrinkage ratio is 0.8 or more and less than 0.99, and the change between the volume before curing and the volume after curing is reduced, whereby the first moisture-proof layer and the substrate are reduced. It is possible to prevent a gap from being formed between the two. The predetermined second volume shrinkage ratio is 0.2 or more and 0.4 or less, and even in the case of such a synthetic resin whose volume is greatly shrunk, the moisture permeability is 4.0 × 10 4 as described above.²g / m²・ It is 24hr or less, 15g / m²-By using a synthetic resin of 24 hours or more, moisture resistance of the wiring and reliability of the gas barrier can be improved.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing a part of a display panel 20 having a wiring board protection structure according to an embodiment of the present invention.
2 is a cross-sectional view of the display panel 20 cut along a plane parallel to the extending direction of each electrode layer 21 between the electrode layer 21 and the electrode layer 21. FIG.
FIG. 3 is a flowchart showing a manufacturing process of the first seal portion A.
FIG. 4 is a flowchart showing a manufacturing process of the second seal portion B.
FIG. 5 is a cross-sectional view showing a part of a connection portion between a liquid crystal display element 2 and a film wiring board 3 of a liquid crystal display panel 1 according to a conventional technique.
6 is a cross-sectional view showing a part of a connection portion between a liquid crystal display element 2 and a film wiring board 3 of a liquid crystal display panel 15 which is another conventional technique. FIG.
[Explanation of symbols]
20 LCD panel
21 Electrode layer
22 First substrate
23 Wiring layer
24 Second substrate
25 Third substrate
28 Adhesive layer
37, 38 First protective layer
39, 40 Second protective layer

Claims (2)

A first substrate provided with a first wiring;
A second substrate provided with a second wiring;
A third substrate formed smaller than the first substrate and facing the first substrate on which the first wiring is provided;
Provided between the peripheral portion of the first substrate and the peripheral portion of the third substrate, and bonds the first substrate and the third substrate to each other and forms a space sandwiched between the first substrate and the third substrate. A sealing layer provided by being retracted from the end of the third substrate;
A conductive adhesive that bonds the second substrate to each other so that the first wiring and the second wiring face each other in a region where the first substrate is exposed to the third substrate;
A first contact portion that is made of a synthetic resin having a predetermined first moisture permeability and a predetermined first volume shrinkage rate, and that comes into contact with the surface of the first substrate on which the first wiring is provided, and a second contact that comes into contact with the seal layer A third contact portion that contacts a surface of the third substrate facing the first substrate, a fourth contact portion that contacts one end surface of the third substrate facing the second substrate, and one end of the second substrate facing the third substrate. A fifth contact portion that contacts the first portion, a sixth contact portion that contacts one surface of the second substrate opposite to the first substrate in the thickness direction of the second substrate, and the first contact between the second substrate and the third substrate. A first protective layer provided in contact with the first to third substrates in a region where the wiring is exposed ;
Consists previously determined first second moisture permeability defining smaller advance than moisture permeability, and pre-defined synthetic resin having a second volumetric shrinkage defining first advance a small than the volume shrinkage ratio, the first protective layer There display panel; and a second protective layer provided in contact to cover the first protective layer so as not to be exposed to the outside, and the first to third substrate. The predetermined first moisture permeability is 2.0 × 10 ² g / m ² · 24 hr or more and 4.0 × 10 ² g / m ² · 24 hr or less when the thickness is 100 μm . When the thickness is 100 μm, the moisture permeability is 15 g / m ² · 24 hr or more and less than 2.0 × 10 ² g / m ² · 24 hr, and the predetermined first volume shrinkage is 0.8 or more. less than enabled with 0.99, pre-determined display panel of claim 1, wherein the second volume shrinkage, characterized in der Rukoto is and 0.4 or less than 0.2.

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