The present invention relates to a liquid crystal element and a display device.
A liquid crystal panel is a component of a liquid crystal display device. Such a liquid crystal panel mainly includes a pair of substrates that are arranged facing each other with a predetermined distance therebetween and a liquid crystal layer and spacers that maintain the distance between the substrates. A periphery of the substrates is sealed with a sealing agent.
Patent Document 1: Japanese Unexamined Patent Publication No. 62-150223
If the environment in which a liquid crystal display panel is used changes from a normal temperature environment to a low temperature environment, volume shrinkage occurs in the liquid crystal layer between the pair of the substrates. If each spacer has an excessive defining force that defines the distance between the substrates, the distance between the substrates does not decrease according to the volume shrinkage of the liquid crystal layer. This may cause vacuum bubbles. On the other hand, if the defining force of the spacers are reduced by, for example, decreasing the number thereof, the spacers may fail to resist an external stress applied to at least one of the substrates and may be excessively deformed. This may damage or break the spacers and may degrade pressure resistance.
The present invention was made in view of the above circumstances, and an object of the present invention is to obtain sufficient pressure resistance with less occurrence of low temperature bubbles.
A liquid crystal element according to the present invention includes a pair of substrates, a liquid crystal layer, a plurality of first spacers, and a plurality of second spacers. The pair of substrates has a normal distance therebetween. The liquid crystal layer is arranged between the substrates. The first spacers have an average particle diameter that is larger than the normal distance between the substrates and are configured to define a distance between the substrates. The second spacers have an average particle diameter that is smaller than the normal distance between the substrates and are configured to define the distance between the substrates.
In this configuration, the average particle diameter of the first spacers is relatively larger than the normal distance between the substrates. Thus, the first spacers almost always define the distance between the substrates in a deformed state. The “normal distance between the substrates” is the distance between the substrates in a normal temperature environment (for example, temperatures of the environment is in a range of 5 to 35° C.) with no external stresses applied to any one of the substrates.
In contrast, the average particle diameter of the second spacer is smaller than the normal distance between the substrates. Thus, the second spacers do not define the distance between the substrates until an external stress is applied to the substrates in the normal temperature environment. If the environment is changed from the normal temperature environment to a low temperature environment (for example, temperature less than 5° C.) and volume shrinkage occurs in the liquid crystal layer, the distance between the substrates may decrease to be smaller than the normal distance. In this case, although the first spacers are further deformed from the state that is in the normal temperature environment, the second spacers are hardly deformed until the distance between the substrates reaches the average particle diameter of the second spacers. This allows the distance between the substrates to easily decrease according to the volume shrinkage of the liquid crystal layer and thus the vacuum bubbles are less likely to be generated. In the normal temperature environment, the second spacers in addition to the first spacers define the distance between the substrates when an external stress is applied to at least one of the substrates and the distance between the substrates decreases from the normal distance and reaches the average particle diameter of the second spacers. Therefore, the first spacers are less likely to be excessively deformed and damaged or broken. As a result, sufficiently high pressure resistance can be obtained.
The following configuration may be preferable as embodiments of the present invention.
(1) The average particle diameter of the second spacers may be in a range of 80 to 95% of the average particle diameter of the first spacers. If the average particle diameter of the second spacers is smaller than 80% of the average particle diameter of the first spacers, the first spacer may be excessively deformed by an external stress that is applied to at least one of the substrates. This may cause damage or breakage of the first spacer. As a result, sufficient pressure resistance may not be obtained. In contrast, if the average particle diameter of the second spacers is larger than 95% of the average particle diameter of the first spacers, that is, the difference between the average particle diameters of the first spacers and the second spacers is quite small, the distance between the substrates hardly decreases according to the volume shrinkage of the liquid crystal layer in the low temperature environment. This may result in generating low temperature bubbles. However, as described above, the average particle diameter of the second spacers that is in a range of 80 to 95% of the average particle diameter of the first spacers is suitable to reduce occurrence of the low temperature bubbles while obtaining pressure resistance.
(2) Each of the second spacers may include an adhering layer that is configured to be adhered to at least one of the substrates. Since the average particle diameter of the second spacers is relatively smaller than the normal distance of the substrates, the second spacers tend to move around compared to the first spacers that are sandwiched and deformed by the substrates in the normal temperature environment. With the adhering layer, the second spacers are firmly attached to at least one of the substrates and less likely to move around and gather one another.
(3) The number of first spacers may be relatively smaller than the number of second spacers. With this configuration, the distance between the substrates easily decreases corresponding to the volume shrinkage in the liquid crystal layer compared to a case in which the number of first spacers is equal to or relatively larger than the number of the second spacers. Thus, vacuum bubbles are less likely to be generated. In addition, if an external stress is applied to at least any one of the substrates, the second spacers that are arranged more than the first spacers properly define the distance between the substrates. Therefore, the first spacers are less likely to be excessively deformed and less likely to have damage or breakage.
(4) A parallax barrier pattern may be arranged on a plate surface of at least one of the substrates. With this configuration, an image seen by a viewer through the liquid crystal element is separated by the parallax barrier pattern, and thus the viewer can recognize a stereoscopic image.
(5) The parallax barrier pattern may include a pair of transparent electrodes arranged on a plate surface of each of the substrates so as to face each other. The plate surface of each substrate faces the liquid crystal layer. The transparent electrodes may be configured to provide a plurality of barrier sections and a barrier opening provided between the barrier sections by controlling a voltage value between the transparent electrodes. The barrier sections are configured to block light and the barrier opening is configured to allow the light to pass therethrough. With this configuration in which the barrier sections and the barrier openings are provided, an image is seen at a specific viewing angle through the barrier openings arranged between the barrier sections via the liquid crystal element. This enables the image to be separated by parallax. In addition, the voltages between the transparent electrodes are controlled to selectively form the barrier sections and the barrier opening. This enables the switching between the stereoscopic image display and a flat image display.
(6) A touch panel pattern may be arranged on another plate surface of one of the substrates. The other plate surface may face a side opposite to the liquid crystal layer. The touch panel pattern may be configured to detect a position input by a user. With this configuration, the position touched by the user can be detected by the touch panel pattern. Such a substrate, on which the touch panel pattern is arranged, frequently receives external stresses and those stresses tend to be strong. However, the liquid crystal element according to the present invention is effective to the above configuration because the first spacers and the second spacers that define the distance between the substrates ensure high pressure resistance.
To solve above problem, a display device according to the present invention may include the above-described liquid crystal element and a display element stacked on the liquid crystal element and configured to display an image.
According to the display device, the liquid crystal element stacked on the display element to display an image has both advantages of reducing low temperature bubbles and having pressure resistance. Therefore, the liquid crystal element has high display quality and an enhanced product lifetime.
The following configuration may be preferable as embodiments of the present invention.
(1) The liquid crystal element may include a parallax barrier pattern configured to separate an image displayed on the display element by parallax. With this configuration, the image displayed on the display element that is seen by a viewer via the liquid crystal element is separated by the parallax barrier pattern. Thus, the viewer of the display device can recognize the stereoscopic image.
(2) The liquid crystal element may be arranged on a side closer to a viewer than the display element. The liquid crystal element arranged closer to the viewer side than the display element easily receives an external stress, for example, a stress touched by a viewer. However, the liquid crystal element according to the present invention is suitable for the above configuration because the first spacers and the second spacers that define the distance between the substrates ensure high pressure resistance.
(3) The display device may include a lighting device configured to apply light to the display element. With this configuration, the display element displays an image using the light applied from the lighting device.
According to the present invention, sufficient pressure resistance is obtained with less occurrence of low temperature bubbles.
A first embodiment of the present invention will be described with reference to
A configuration of the liquid crystal display device 10 is described. As illustrated in
As illustrated in
Next, the liquid crystal display panel 11 is described. As illustrated in
One of the substrates 11a and 11b that is on the front side is a CF substrate 11a and the other one that is on the rear side is an array substrate 11b. As illustrated in
On an inner surface side (the liquid crystal layer 20 side, a surface facing the array substrate 11b) of the CF substrate 11a, as illustrated in
The backlight unit 13 is briefly described first, and then the liquid crystal panel 12 is described. The backlight unit 13 is an edge-light type (a side-light type) backlight unit. The backlight unit 13 includes light sources, a box-like chassis, a light guiding member, and an optical member. The light sources are arranged to face ends of the light guiding member. The chassis has an opening that opens toward the front side (the liquid crystal display panel 11 side, the light exiting side) and houses the light sources. The light guiding member is configured to guide light from the light sources to the opening (a light exiting portion) of the chassis. The optical member is arranged to cover the opening of the chassis. The light emitted from the light sources enters the ends of the light guiding member and travels through the light guiding member to exit from the opening of the chassis. Then, the optical member converts the light into a planar light having an even luminance distribution and the light is applied to the liquid crystal display panel 11. Light transmissivity is selectively changed in the display surface of the liquid crystal display panel 11 by the driving of TFTs 16 included in the liquid crystal display panel 11, and thus a predetermined image is displayed in the display surface. The light sources, the chassis, the light guiding member, and the optical member are not illustrated in detail.
Then, the liquid crystal panel 12 is described in detail. As illustrated in
As illustrated in
The liquid crystal panel 12 includes a parallax barrier pattern 29 and is configured to be a parallax barrier panel. The parallax barrier pattern 29 separates an image to be displayed in the display surface of the liquid crystal display panel 11 by parallax and allows a viewer to recognize the image as a stereoscopic image (3D image, three-dimensional image). The parallax barrier pattern 29 included in the liquid crystal panel 12 is configured to apply predetermined voltages to the liquid crystal layer 27. According to the voltage applied to the liquid crystal layer 27, an alignment of the liquid crystal molecules and light transmissivity of the liquid crystal layer 27 are controlled and barrier sections BA, which will be described in detail later, are provided. The barrier sections BA separate the image on the pixels PX of the liquid crystal display panel 11 by parallax, and thus the viewer can see the stereoscopic image (see
As illustrated in
As illustrated in
As illustrated in
As illustrated in
A normally white type switching liquid crystal panel may be used as the liquid crystal panel 12 of the present embodiment. In such a switching liquid crystal panel, if a potential difference between the first transparent electrode 30A and the second transparent electrode 30B and the third transparent electrode for barrier 30C and the fourth transparent electrode 30D is zero, the liquid crystal layer 27 has the maximum light transmissivity, so that the maximum amount of the light passes through over the entire area of the liquid crystal layer 27. In addition, the liquid crystal panel 12 according to the present embodiment, the driving thereof is controlled by supplying a predetermined potential to the electrodes 30A to 30D, and a viewer can view the stereoscopic image if the liquid crystal display device 10 is placed in both of the portrait orientation and the landscape orientation.
Specifically, if the liquid crystal display device 10 is placed in the portrait orientation, a reference potential is supplied to the second transparent electrode 30B, the third transparent electrode 30C, and the fourth transparent electrode 30D, and a predetermined potential different from the reference potential is supplied to the first transparent electrode 30A. This does not generate a potential difference between the second transparent electrode 30B and the third and fourth transparent electrodes 30C and 30D, but a potential difference is generated between the first transparent electrode 30A and the third and fourth transparent electrodes 30C and 30D. Accordingly, as illustrated in
In contrast, if the liquid crystal display device 10 is placed in the landscape orientation, a reference potential is supplied to the first transparent electrode 30A, the second transparent electrode 30B, and the fourth transparent electrode 30D, and a predetermined potential different from the reference potential is supplied to the third transparent electrode 30C. This does not generate a potential difference between the first and second transparent electrode 30A and 30B and the fourth transparent electrode 30D, but a potential difference is generated between the first and second transparent electrodes 30A and 30B and the third transparent electrode 30C. Accordingly, as illustrated in
The liquid crystal display device 10 that can display the stereoscopic image if it is placed in either the portrait orientation or the landscape orientation may include a gyro scope, which is not illustrated, to detect the orientation of the liquid crystal display device 10 (whether in the portrait orientation or in the landscape orientation). The driving of the liquid crystal display panel 11 and the liquid crystal panel 12 may be automatically switched between a portrait mode and a landscape mode based on a detection signal. If a flat image is required to be seen by the viewer, a reference potential is applied to all of the electrodes 30A to 30D. This does not generate a potential difference between first and second transparent electrodes 30A and 30B and the third and fourth transparent electrodes 30C and 30D and thus the entire area of the liquid crystal layer 27 has the maximum light transmissivity. That is, liquid crystal panel 12 does not include the barrier sections BA that block light. Accordingly, the image displayed on the pixels PX of the liquid crystal display panel 11 does not have the parallax, so that the viewer sees the flat image (the 2D image, the two-dimensional image). No potential may be supplied to all of the electrodes 30A to 30D such that no potential difference is generated between the first and second transparent electrodes 30A and 30B and the third and fourth transparent electrodes 30C and 30D.
The spacers 28 are configured to define the distance (the cell thickness, the gap) between the substrates 12a and 12b of the liquid crystal panel 12. Each spacer 28 is made of a synthetic resin having high light transmissivity (almost transparent) such as inorganic material like silica and organic material such like epoxy resin. The spacers 28 each have a spherical shape and elasticity. As illustrated in
The average particle diameter AD2 of the second spacers 35 is preferably in a range of 80 to 95% of the average particle diameter AD1 of the first spacers 34, and more preferably in a range of 85 to 95%. An external stress applied to at least one of the substrates 12a and 12b keeps deforming the first spacers 34 until the distance between the substrates 12a and 12b decreases to the average particle diameter AD2 of the second spacers 35. If that the average particle diameter AD2 of the second spacers 35 is smaller than 80% of the average particle diameter AD1 of the first diameters 34, the first spacers 34 may be excessively deformed and damaged. As a result, sufficient pressure resistance may not be obtained. On the other hand, if the environment changes from the normal temperature environment to a low temperature environment (for example, temperature of the environment lower than 5° C.), volume shrinkage occurs in each member. Since the liquid crystal layer 27 is made of a material of which thermal expansion ratio is relatively higher than those of the other members (for example, substrates 12a and 12b and spacer 27), the volume shrinkage of the liquid crystal layer 27 is relatively greater than those of other members. If the average particle diameter AD2 of the second spacers 35 is larger than 95% of the average particle diameter AD1 of the first spacers 34, a difference between the average particle diameters AD1 and AD2 is quite small. In this case, if only a slight decrease occurs in the distance between the substrates 12a and 12b according to the volume shrinkage of the liquid crystal layer 27, the second spacers 35 define the distance between the substrates 12a and 12b in addition to the first spacers 34. Accordingly, further decrease in the distance between the substrates 12a and 12b is not caused according to the occurrence of the volume shrinkage in the liquid crystal layer 27. Accordingly, vacuum bubbles may be likely to be generated in the liquid crystal layer 27. However, as described above, with the configuration in which the average particle diameter AD2 of the second spacers 35 is in a range of 80 to 95% of the average particle diameter AD1 of the first spacers 34, low temperature bubbles are less likely to be generated with ensuring sufficient pressure resistance. Furthermore, if the average particle diameter AD2 of the second spacers 35 is in a range of 85 to 95% of the average particle diameter AD1 of the first spacer 34, the above effects can be more surely obtained.
As illustrated in
The number of second spacers 35 is relatively greater than the number of the first spacers 34. Specifically, the second spacers 35 having the average particle diameter AD2 (the number of particles at the peak in
As illustrated in
A ratio of the average particle diameter AD1 of the first spacers 34 to the normal distance SD between the substrates 12a and 12b is in a range of, for example, 1.0 to 1.03 normal distance and a ratio of the average diameter AD2 of the second spacers 35 to the normal distance SD between the substrates 12a and 12b is in a range of, for example, 0.86 to 0.94 normal distance.
The present embodiment has the above-described configuration and the operation of the present embodiment will be described. In manufacturing the liquid crystal display device 10, the flexible printed boards 21 and 33 are respectively connected to the liquid crystal display panel 11 and the liquid crystal panel 12, which are separately manufactured. Then the liquid crystal display panel 11 and the liquid crystal panel 12 are attached together with the photo curable adhesive GL therebetween. A method of manufacturing the liquid crystal panel 12 will be described in detail.
In manufacturing the liquid crystal panel 12, transparent electrodes 30A to 30D are formed on the first substrate 12a and the second substrate 12b by the photolithographic method. Then the alignment films 31 and 32 are provided and alignment treatment is performed. As illustrated in
In attaching the substrates 12a and 12b, the second substrate 12b is arranged so as to face the first substrate 12a and moved close to the first substrate 12a. If the distance between the substrates 12a and 12b reaches equal to normal distance SD, the substrates 12a and 12b are attached together by curing a sealant. In
The liquid crystal display device 10 including the liquid crystal panel 12 manufactured as described above may be used in various temperature environments. If the environment is changed from a normal temperature environment to a low temperature environment, volume shrinkage may occur in each component of the liquid crystal panel 12. The liquid crystal layer 27 has an especially high thermal expansion ratio and thus the volume shrinkage thereof is also large accordingly. The liquid crystal layer 27 is surrounded and sealed by the sealant. Therefore, if the volume shrinkage occurs in the liquid crystal layer 27 according to the temperature change, the distance between the substrates 12a and 12b gradually decreases further from the normal distance SD according to the shrinkage as illustrated in
On the other hand, the liquid crystal panel 12 is a member that is arranged on the user (viewer) side relative to the liquid crystal display panel 11 in the liquid crystal display device 10. Therefore, the liquid crystal panel 12 is more likely to receive an external stress. If an external stress is applied to the second substrate 12b on the front side of the pair of the substrates 12a and 12b, the distance between the substrates 12a and 12b decreases smaller than the normal distance SD. This further deforms the first spacers 34 that resist against the stress. If the distance between the substrates 12a and 12b is equal to the average particle diameter AD2 of the second spacers 35, the second spacers 35 in addition to the first spacers 34 are sandwiched by the substrates 12a and 12b and define the distance. With this configuration, the first spacers 34 are less likely to be excessively deformed over the limit of elasticity and less likely to be damaged or broken. This ensures high pressure resistance. In addition, since the average particle diameter AD2 of the second spacers 35 is 80% or larger than the average particle diameter AD1 of the first spacers 34 in the present embodiment, the first spacers 34 are further less likely to be excessively deformed over the limit of elasticity and high pressure resistance is obtained compared to a case in which the average particle diameter AD2 of the second spacers 35 is smaller than 80% of the average particle diameter AD1 of the first spacers 34.
As described above, the liquid crystal panel (a liquid crystal element) 12 includes a pair of substrates 12a and 12b, the liquid crystal layer 27 arranged between the substrates 12a and 12b, the first spacers 34, and the second spacers 35. The first spacers 34 have the average particle diameter AD1 that is larger than the normal distance SD between the substrates 12a and 12b and are configured to define the distance between the substrates 12a and 12b. The second spacers 35 have the average particle diameter AD2 that is smaller than the normal distance SD between the substrates 12a and 12b and are configured to define the distance between the substrates 12a and 12b.
In this configuration, the average particle diameter AD1 of the first spacers 34 is relatively larger than the normal distance SD between the substrates 12a and 12b. Thus, the first spacer 34 defines the distance between the substrates 12a and 12b with being almost always deformed by the substrates 12a and 12b. The normal distance SD between the substrates 12a and 12b is the distance between the substrates 12a and 12b in a normal temperature environment (for example, temperatures of the environment is in a range of 5 to 35° C.) with no external stresses applied to any one of the substrates 12a and 12b.
In contrast, the average particle diameter AD2 of the second spacer 35 is relatively smaller than the normal distance SD between the substrates 12a and 12b. Thus, the second spacers 35 do not define the distance between the substrates 12a and 12b if no external stress is applied to the substrates 12a and 12b in the normal temperature environment. If the environment is changed from the normal temperature environment to the low temperature environment (for example, temperature less than 5° C.) and volume shrinkage occurs in the liquid crystal layer 27, the distance between the substrates 12a and 12b may decrease to be smaller than the normal distance SD. In this case, although the first spacers 34 are further deformed from the shapes in the normal temperature, the second spacers 35 are hardly deformed until the distance between the substrates 12a and 12b reaches the average particle diameter AD2 of the second spacers 35. This allows the distance between the substrates 12a and 12b to decrease easily according to the volume shrinkage in the liquid crystal layer 27 and thus vacuum bubbles are less likely to be generated. If an external stress is applied to at least one of the substrates 12a and 12b in the normal temperature environment, the distance between the substrates 12a and 12b decreases from the normal distance SD and reaches the average particle diameter AD2 of the second spacers 35 and then the second spacers 35 in addition to the first spacers 34 define the distance between the substrates 12a and 12b. Thus, the first spacers 34 are less likely to be damaged or broken by the excessive deformation. As a result, sufficiently high pressure resistance can be obtained. According to the present embodiment, the low temperature bubbles are less likely to be generated with ensuring sufficient pressure resistance.
The average particle diameter AD2 of the second spacer 35 is in a range of 80 to 95% of the average particle diameter AD1 of the first spacers 34. If the average particle diameter AD2 of the second spacers 35 is smaller than 80% of the average particle diameter AD1 of the first spacers 34 and an external stress is applied to at least one of the substrates 12a and 12b, the first spacers 34 are excessively deformed by the external stress. This may easily cause damage or breakage of the first spacers 34 and sufficient pressure resistance may not be ensured. In contrast, if the average particle diameter AD2 of the second spacers 35 is larger than 95% of the average particle diameter AD1 of the first spacers 34 and the difference between the average particle diameters AD1 and AD2 of the first spacers 34 and the second spacers 35 is quite small, the change in the distance between the substrates 12a and 12b hardly follow according to the volume shrinkage of the liquid crystal layer 27 in the low temperature environment. This may result in easily generating low temperature bubbles. However, as described above, the average particle diameter AD2 of the second spacers 35 that is in a range of 80 to 95% of the average particle diameter AD1 of the first spacers 34 is suitable to reduce occurrence of the low temperature bubbles while ensuring pressure resistance.
The second spacers 35 include the adhering layers 36 that are adhered to at least one of the substrates 12a and 12b. Since the average particle diameter AD2 of the second spacers 35 is relatively smaller than the normal distance SD of the substrates 12a and 12b, the second spacers 35 tend to move around compared to the first spacers 34 that are sandwiched and deformed by the substrates 12a and 12b in the normal temperature environment. With the adhering layers 36 formed on the second spacers 35, the second spacers 35 are firmly attached to at least one of the substrates 12a and 12b and less likely to move around and gather one another.
The number of first spacers 34 is smaller than the number of second spacers 35. With this configuration, the distance between the substrates 12a and 12b easily decreases according to the volume shrinkage in the liquid crystal layer 27 compared to a case in which the number of the first spacers 34 is equal to or larger than the number of the second spacers 35. Thus, vacuum bubbles are less likely to be generated. In addition, if an external stress is applied to at least any one of the substrates 12a and 12b, the second spacers 35 that are greater in number than the first spacers 34 properly define the distance between the substrates 12a and 12b. Therefore, the first spacers 34 are less likely to be excessively deformed and less likely to be damaged or broken.
The parallax barrier pattern 29 is arranged on a plate surface of at least one of the substrates 12a and 12b. With this configuration, the image seen by the viewer through the liquid crystal panel 12 is separated by the parallax barrier pattern 29, and thus the viewer can recognize the stereoscopic image.
The parallax barrier pattern 29 includes a pair of transparent electrodes 30 that are arranged on plate surfaces of the substrates 12a and 12b on the liquid crystal layer 27 side so as to face each other. The transparent electrodes 30 are configured to provide the barrier sections BA and the barrier opening BO between the barrier sections BA by controlling a voltage value between transparent electrodes 30. The barrier sections BA are configured to block light and the barrier openings BO are configured to allow light to pass therethrough. With this configuration in which the barrier sections BA and the barrier opening BO are provided, if an image is seen via the liquid crystal display panel 12, the image is seen at a specific viewing angle through the barrier openings BO arranged between the barrier sections BA. This enables the image to be separated by parallax. In addition, the voltage value between the transparent electrodes 30 is controlled to selectively form the barrier sections BA and the barrier openings BO. This enables the switching between the stereoscopic image display and the flat image display.
The liquid crystal display device (a display device) 10 according to the present embodiment includes the above described liquid crystal panel 12 and the liquid crystal display (a display element) panel 11. The liquid crystal display panel 11 is stacked on the liquid crystal panel 12 and configured to display an image. According to the liquid crystal display device 10 of this embodiment, the liquid crystal panel 12 that is stacked on the liquid crystal display panel 11 for displaying an image has both advantages of reducing occurrence of low temperature bubbles and ensuring pressure resistance. Therefore, the liquid crystal display device 10 has high display quality and an enhanced product lifetime.
The liquid crystal panel 12 included in the liquid crystal display device 10 has the parallax barrier pattern 29 that can separate the image displayed on the liquid crystal display panel 11 by parallax. With this configuration, the image displayed on the liquid crystal display panel 11 that is seen by the viewer via the liquid crystal panel 12 is separated by the parallax barrier pattern 29. Thus, the viewer of the display device can recognize the image as the stereoscopic image.
The liquid crystal panel 12 included in the liquid crystal display device 10 is arranged on a side closer to a viewer than the liquid crystal display panel 11 and therefore easily receives an external stress, for example, the liquid crystal panel 12 may be touched by a user. However, the liquid crystal panel 12 is effective with the above configuration because the first spacers 34 and the second spacers 35 that define the distance between the substrates 12a and 12b ensure high pressure resistance.
The liquid crystal display device 10 includes the backlight unit (lighting device) 12 that is configured to apply light to the liquid crystal display panel 11 included in the liquid crystal display device 10. With this configuration, the liquid crystal display panel 11 displays an image using the light from the backlight unit 12.
The second embodiment of the present invention will be described with reference to
As illustrated in
The touch panel function (position input function) of the liquid crystal panel 112 will be described in detail. As illustrated in
As illustrated in
As illustrated in
As illustrated in
In the liquid crystal display device 110 having the above configuration, the cover glass 37 is frequently touched by the user to use the touch panel function. Even if the cover glass 37 protects the second substrate 112b having the touch panel pattern 38 included in the liquid crystal panel 112, the second substrate 112b is frequently affected by the external stresses and such stresses tend to be strong. The liquid crystal panel 112 according to the present embodiment includes the first spacer 34 that has the average particle diameter AD1 relatively larger than the normal distance SD between the substrates 112a and 112b and the second spacer 35 that has the average particle diameter AD2 relatively larger than the normal distance SD between the substrates 112a and 112b. Since the liquid crystal panel 112 has sufficient pressure resistance as described in the first embodiment, those functions (the parallax barrier function and touch panel function) are performed against the frequent and strong stresses, namely, this enhances pressure resistance and product lifetime.
As described above, according to this embodiment, the touch panel pattern 38 is arranged on the plate surface of one of the substrates 112a and 112b. The plate surface faces a side opposite to the liquid crystal layer 27 side. The touch panel pattern 38 is configured to detect a position input by a user. With this configuration, the position touched by the user can be detected by the touch panel pattern 38. The substrates 112a and 112b on which the touch panel pattern 38 is formed frequently receive external stresses and those stresses tend to be strong. However, the liquid crystal panel 112 is effective in the above configuration because the first spacers 34 and the second spacers 35 that define the distance between the substrates 112a and 112b ensure high pressure resistance.
The present invention is not limited to the embodiments explained in the above description with reference to the drawings. The following embodiments may be included in the technical scope of the present invention, for example.
(1) In the above embodiments, the minimum value of the average particle diameter AD1 in the particle size distribution of the first spacers is smaller than the normal distance SD between the pair of the substrates (refer to
(2) In the above embodiments, the maximum value of the average particle diameter AD2 in the particle size distribution of the second spacers is larger than the normal distance SD between the pair of the substrates (refer to
(3) In the above embodiments, in the particle size distributions of the first spacers and second spacers, the minimum particle diameter of the first spacers is relatively smaller than the maximum particle diameter of the second spacers (refer to
(4) In the above embodiments, the average particle diameter AD2 of the second spacers is in a range of 80 to 95% of the average particle diameter AD1 of the first spacers. However, in the present invention, the average particle diameter of the second spacers may be smaller than 80% of the average particle diameter of the first spacers or larger than 95% of the average particle diameter of the first spacers.
(5) In the above embodiments, the number of the second spacers are relatively larger than the number of the first spacers. However, the number of the first spacers may be substantially equal to or relatively larger than the number of the second spacer.
(6) In the above embodiments, the outer peripheral surfaces of the second spacers are covered by the adhering layers. However, the adhering layers may partially cover the outer peripheral surfaces of the second spacers.
(7) In the above embodiments, only the second spacers include the adhering layers. However, the first spacers may have the adhering layers or none of the first spacers and the second spacers may include the adhering layers.
(8) Other than the above embodiments, the specific aspect of the particle size distribution and the material of each spacer may be suitably changed. For example, the difference between the minimum particle diameter in the particle size distribution of the first spacers and the normal distance SD between the substrates may be relatively smaller than the difference between the maximum particle diameter in the particle size distribution of the second spacers and the normal distance SD between the substrates. Further, the difference between the minimum particle diameter in the particle size distribution of the first spacers and the normal distance SD between the substrates may be substantially equal to the difference between the maximum particle diameter in the particle size distribution of the second spacers and the normal distance SD between the substrates. Other than above, the particle distribution may be modified in various states. For example, an overlapping state of the first and second particle size distributions or the shape (how the particle distributions spread out) of each particle size distribution of each spacer may be variously changed.
(9) In the second embodiment, the protector is the cover glass made of glass. However, the protector made of a synthetic resin may be used.
(10) In the first embodiment, the protector such as the cover glass included in the second embodiment may be used. In such a case, the protector may be made of a synthetic resin as in the above (9).
(11) In the above embodiments, the present invention is applied to the liquid crystal panel having a parallax barrier function. However, the present invention may be applicable to the liquid crystal display panel that is a display element. The present invention may also be applicable to the liquid crystal display device including only a liquid crystal display panel and not including the liquid crystal panel having a parallax barrier function.
(12) In the above (11), the touch panel pattern in the second embodiment may be provided on the outer plate surface of the substrates (the CF substrate, for example) in the liquid crystal display panel.
(13) In the above embodiments, the liquid crystal panel is arranged on the front side relative to the liquid crystal display panel. However, the liquid crystal panel may be arranged on the rear side relative to the liquid crystal display panel.
(14) In the above second embodiment, the projected capacitive type is described as the example type of the touch panel pattern of the liquid crystal panel. Other than the above, the present invention is applicable to a surface capacitive type, a resistive film type, or an electromagnetic induction type touch panel pattern.
(15) In the above embodiments, the liquid crystal display device can display the stereoscopic image when placed in both of the portrait (vertical position) orientation and the landscape (horizontal position) orientation. However, the liquid crystal display device according to the present technology may have a configuration that can display the stereoscopic image only when placed in one of the portrait orientation and the landscape orientation.
(16) The above embodiments use the liquid crystal panel having the function that allows the user to see the stereoscopic image. However, the present invention is applicable to a liquid crystal display device that includes a liquid crystal panel having a multi-view function that allows users at different viewing angles to see different images.
(17) In the above embodiments, the liquid crystal panel is the switching liquid crystal panel that can switch a display mode between the flat image display and the stereoscopic image display. However, the liquid crystal panel that is configured to always have barrier sections and display a stereoscopic image may be used.
(18) Other than the above (17), the liquid crystal panel may be configured to always display a stereoscopic image and may be unable to switch the display mode between to the stereoscopic image display and the flat image display. For example, a mask filter having a specific light blocking pattern may be formed on one of the boards included in the liquid crystal panel.
(19) In the above embodiments, the backlight unit included in the liquid crystal display device is the edge-light type backlight unit. However, the backlight unit may be a direct-type backlight unit.
(20) In the above embodiments, the liquid crystal display device is a transmission type liquid crystal display device including the backlight unit as an external light source. However, the technology may be applied to a reflection type liquid crystal display device configured to display using outside light. In such a case, the liquid crystal display device may not include the backlight unit.
(21) In the above embodiments, the liquid crystal display device includes a display screen having an elongated rectangular shape. However, the liquid crystal display device may include a display screen having a square shape.
(22) In the above embodiments, the TFTs are used as switching components of the liquid crystal display device included in the liquid crystal display device. However, the technology described herein may be applied to liquid crystal display devices including a liquid crystal display panel using switching components other than TFTs (e.g., thin film diodes (TFDs)). Furthermore, the technology may be applied to a liquid crystal display device including a black-and-white liquid crystal display panel other than a liquid crystal display device including a color liquid crystal display panel.
(23) The above embodiments use the liquid crystal display device including the liquid crystal panel as a display panel. However, the technology can be applied to display devices including other types of display panels (such as PDP and an organic EL panel). In such a case, the backlight unit may not be included.
10: liquid crystal display device (display device), 11: liquid crystal display panel (display element), 12: liquid crystal panel (liquid crystal element), 12a: first substrate (substrate), 12b: second substrate (substrate), 13: backlight unit (lighting device), 27: liquid crystal layer, 29: parallax barrier pattern, 30: transparent electrode, 34: first spacer, 35: second spacer, 36: adhering layer, 38: touch panel pattern, AD1, AD2: average particle diameter, BA: barrier section, BO: barrier opening, SD: normal distance.
Number | Date | Country | Kind |
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2011-116977 | May 2011 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2012/062747 | 3/18/2012 | WO | 00 | 11/18/2013 |