JP2007334146A - Liquid crystal display - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid crystal display wherein a visual field angle can be widened and contrast in the normal direction of a screen can be enhanced and which has satisfactory display quality. <P>SOLUTION: The liquid crystal display is provided with: a first optical element OD1 provided on one outer surface of a liquid crystal display panel LPN containing homogeneously aligned liquid crystal molecules and including a first polarizing plate 51, a first retardation plate RF1 as a half-wave plate and a second retardation plate RF2 as a quarter-wave plate having optical anisotropy; and a second optical element OD2 provided on the other outer surface of the liquid crystal display panel and including a second polarizing plate 61, a third retardation plate RF3 as a half-wave plate and a fourth retardation plate RF4 as a quarter-wave plate, wherein the second retardation plate has such wavelength dispersion characteristics that a retardation value specified in 400 nm wavelength is 0.7 to 1.3 and a retardation value specified in 650 nm wavelength is 0.9 to 1.2 when retardations in each wavelength are specified by a retardation in 550 nm wavelength. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a liquid crystal display device, and more particularly to a transmissive or transflective liquid crystal display device including a liquid crystal layer containing homogeneously aligned liquid crystal molecules.

  Similar to a twisted nematic (TN) mode liquid crystal display device, a viewing angle compensation phase difference film is applied to a vertically aligned (VA) mode liquid crystal display device having excellent display characteristics when viewed from the front. Thus, a technique for realizing a wide viewing angle characteristic has been proposed (see, for example, Patent Document 1).

In addition, a technique for manufacturing a biaxial birefringent film that can be applied to a liquid crystal display device such as a super twisted nematic (STN) mode has been proposed (see, for example, Patent Document 2).
Japanese Patent Laid-Open No. 2005-099236 JP-A-2005-181451

  In recent years, liquid crystal display devices configured by holding a liquid crystal layer containing liquid crystal molecules that are homogeneously aligned between a pair of substrates have been required to improve display quality such as further widening the viewing angle and improving contrast. Yes.

  The present invention has been made in view of the above-described problems, and an object thereof is to provide a liquid crystal display device with good display quality.

A liquid crystal display device according to an aspect of the present invention includes:
A liquid crystal display panel holding a liquid crystal layer containing homogeneously aligned liquid crystal molecules between a first substrate and a second substrate disposed to face each other;
Provided on one outer surface of the liquid crystal display panel, disposed between the first polarizing plate, a light having a predetermined wavelength that is disposed between the first polarizing plate and the liquid crystal display panel and transmits the fast axis and the slow axis. Between a first retardation plate that gives a half-wave phase difference, and light of a predetermined wavelength that is disposed between the first retardation plate and the liquid crystal display panel and transmits the fast axis and the slow axis. A first optical element including a second retardation plate that gives a phase difference of ¼ wavelength to and optically anisotropic,
Provided on the other outer surface of the liquid crystal display panel, disposed between the second polarizing plate, light having a predetermined wavelength that is disposed between the second polarizing plate and the liquid crystal display panel and transmits the fast axis and the slow axis. A third retardation plate that gives a half-wave phase difference, and light of a predetermined wavelength that is disposed between the third retardation plate and the liquid crystal display panel and transmits the fast axis and the slow axis. A second optical element including a fourth retardation plate that gives a phase difference of ¼ wavelength to
When the retardation at each wavelength is normalized with a retardation of 550 nm, the second retardation plate has a normalized retardation value at 400 nm of 0.7 to 1.3 and a normalized retardation value at 650 nm of 0.00. It has a wavelength dispersion characteristic of 9 or more and 1.2 or less.

  According to the present invention, a viewing angle can be increased, contrast in the normal direction of the screen can be improved, and a liquid crystal display device with good display quality can be provided.

  A liquid crystal display device according to an embodiment of the present invention will be described below with reference to the drawings. Here, a transflective liquid crystal display device having a reflective portion that displays an image using external light and a transmissive portion that displays an image using backlight light in each pixel will be described as an example. Is not limited to this example. For example, various types of liquid crystals such as a transmissive liquid crystal display device in which each pixel has only a transmissive portion, and a liquid crystal display device in which some pixels constituting the display region have a reflective portion and other pixels have a transmissive portion. Applicable to display devices.

  As shown in FIGS. 1 and 2, the liquid crystal display device is an active matrix type transflective color liquid crystal display device and includes a liquid crystal display panel LPN. The liquid crystal display panel LPN includes an array substrate (first substrate) AR, a counter substrate (second substrate) CT arranged opposite to the array substrate AR, and between the array substrate AR and the counter substrate CT. The liquid crystal layer LQ that is held is provided.

  Further, the liquid crystal display device includes a first optical element OD1 provided on one outer surface of the liquid crystal display panel LPN (that is, the outer surface opposite to the surface holding the liquid crystal layer LQ of the array substrate AR), and the liquid crystal display panel. A second optical element OD2 provided on the other outer surface of the LPN (that is, the outer surface opposite to the surface holding the liquid crystal layer LQ of the counter substrate CT) is provided. Further, the liquid crystal display device having the configuration having the transmission portion as described above includes a backlight unit BL that illuminates the liquid crystal display panel LPN from the first optical element OD1 side.

  Such a liquid crystal display device includes a plurality of pixels PX arranged in a matrix of m × n in a display area DSP that displays an image. Each pixel PX displays (transmits) an image by selectively transmitting backlight light from the backlight unit BL and a reflection unit PR that displays (reflects) an image by selectively reflecting outside light. Display portion).

  The array substrate AR is formed using an insulating substrate 10 having optical transparency such as a glass plate or a quartz plate. That is, the array substrate AR includes m × n pixel electrodes EP arranged for each pixel in the display area DSP, and n scanning lines Y (Y1) respectively formed along the row direction of the pixel electrodes EP. To Yn), m signal lines X (X1 to Xm) respectively formed along the column direction of the pixel electrodes EP, and arranged in the vicinity of the intersection position of the scanning line Y and the signal line X in each pixel PX. There are provided m × n switching elements W (for example, thin film transistors), an auxiliary capacitance line AY that is capacitively coupled to the pixel electrode EP so as to form an auxiliary capacitance CS in parallel with the liquid crystal capacitance CLC.

  The array substrate AR is further connected to at least a part of the scanning line driver YD connected to the n scanning lines Y and the m signal lines X in the driving circuit area DCT around the display area DSP. At least a part of the signal line driver XD. The scanning line driver YD sequentially supplies scanning signals (driving signals) to the n scanning lines Y based on control by the controller CNT. Further, the signal line driver XD supplies video signals (drive signals) to the m signal lines X at the timing when the switching elements W in each row are turned on by the scanning signal based on the control by the controller CNT. Thereby, the pixel electrode EP of each row is set to a pixel potential corresponding to the video signal supplied via the corresponding switching element W.

  Each switching element W is, for example, an N-channel thin film transistor, and includes a semiconductor layer 12 disposed on the insulating substrate 10. The semiconductor layer 12 can be formed of, for example, polysilicon or amorphous silicon, and is formed of polysilicon here. The semiconductor layer 12 has a source region 12S and a drain region 12D on both sides of the channel region 12C. The semiconductor layer 12 is covered with a gate insulating film 14.

  The gate electrode WG of the switching element W is connected to one scanning line Y (or formed integrally with the scanning line Y), and is disposed on the gate insulating film 14 together with the scanning line Y and the auxiliary capacitance line AY. . The gate electrode WG, the scanning line Y, and the auxiliary capacitance line AY are covered with an interlayer insulating film 16.

  The source electrode WS and the drain electrode WD of the switching element W are disposed on both sides of the gate electrode WG on the interlayer insulating film 16. The source electrode WS is connected to one signal line X (or formed integrally with the signal line X) and is in contact with the source region 12S of the semiconductor layer 12. The drain electrode WD is connected to one pixel electrode EP (or formed integrally with the pixel electrode EP) and is in contact with the drain region 12D of the semiconductor layer 12. The source electrode WS, the drain electrode WD, and the signal line X are covered with the organic insulating film 18.

  The pixel electrode EP includes a reflective electrode EPR provided corresponding to the reflective part PR and a transmissive electrode EPT provided corresponding to the transmissive part PT. The reflective electrode EPR is disposed on the organic insulating film 18 and is electrically connected to the drain electrode WD. The reflective electrode EPR is formed of a metal film having light reflectivity such as aluminum. The transmissive electrode EPT is disposed on the interlayer insulating film 16 and is electrically connected to the reflective electrode EPR. The transmissive electrode EPT is formed of a metal film having optical transparency such as indium tin oxide (ITO). The pixel electrodes EP corresponding to all the pixels PX are covered with the alignment film 20.

  On the other hand, the counter substrate CT is formed using an insulating substrate 30 having optical transparency such as a glass plate or a quartz plate. That is, the counter substrate CT includes a black matrix 32 that partitions each pixel PX in the display area DSP, a color filter 34 disposed in each pixel surrounded by the black matrix 32, a counter electrode ET, and the like.

  The black matrix 32 is disposed so as to face wiring portions such as the scanning lines Y and the signal lines X provided on the array substrate AR. The color filter 34 is formed of a plurality of different colors, for example, colored resins colored in three primary colors such as red, blue, and green. The red colored resin, the blue colored resin, and the green colored resin are disposed corresponding to the red pixel, the blue pixel, and the green pixel, respectively.

  The color filter 34 may be formed so that the optical density is different between the reflection part PR and the transmission part PT. That is, outside light that contributes to display passes through the color filter 34 twice in the reflection part PR, whereas backlight light that contributes to display passes only once through the color filter 34 in the transmission part PT. is there. Therefore, in order to adjust the color between the reflection part PR and the transmission part PT, it is desirable that the optical density of the colored resin arranged in the reflection part PR is about half that of the colored resin arranged in the transmission part PT.

  The counter electrode ET is disposed so as to face the pixel electrodes EP of all the pixels PX. The counter electrode ET is formed of a light-transmitting metal film such as indium tin oxide (ITO). The counter electrode ET is covered with an alignment film 36.

  When the counter substrate CT and the array substrate AR as described above are arranged so that the alignment films 20 and 36 face each other, a predetermined gap is formed by a spacer (not shown) arranged therebetween. The At this time, a gap of about half of the transmission part PT is formed in the reflection part PR.

  The liquid crystal layer LQ is composed of a liquid crystal composition including liquid crystal molecules 40 enclosed in a gap formed between the alignment film 20 of the array substrate AR and the alignment film 36 of the counter substrate CT. In this embodiment, the liquid crystal layer LQ includes liquid crystal molecules 40 having a twist angle of 0 deg (homogeneous alignment).

  In the liquid crystal display device according to this embodiment, as shown in FIG. 3, the first optical element OD1 and the second optical element OD2 control the polarization state of the light that has passed through them. That is, the first optical element OD1 controls the polarization state of light passing through the liquid crystal layer LQ so that light having an elliptical polarization state or a circular polarization state is incident on the liquid crystal layer LQ. Therefore, the polarization state of the backlight light incident on the first optical element OD1 is converted into a predetermined state when passing through the first optical element OD1. Thereafter, the backlight light emitted from the first optical element OD1 is incident on the liquid crystal layer LQ while maintaining a predetermined polarization state.

  Similarly, the second optical element OD2 controls the polarization state of light passing through the liquid crystal layer LQ so that light having an elliptical polarization state or a circular polarization state enters the liquid crystal layer LQ. Therefore, the polarization state of the external light incident on the second optical element OD2 is converted into a predetermined polarization state when passing through the second optical element OD1. Thereafter, the external light emitted from the second optical element OD2 is incident on the liquid crystal layer LQ while maintaining a predetermined polarization state.

  The first optical element OD1 includes one first polarizing plate 51, a first retardation plate RF1 disposed between the first polarizing plate 51 and the liquid crystal display panel LPN, a first retardation plate RF1, and a liquid crystal display. And a second retardation plate RF2 disposed between the panel LPN.

  The second optical element OD2 includes one second polarizing plate 61, a third retardation plate RF3 disposed between the second polarizing plate 61 and the liquid crystal display panel LPN, a third retardation plate RF3, and a liquid crystal display. A fourth retardation plate RF4 disposed between the panel LPN and the panel LPN is included.

  The first polarizing plate 51 and the second polarizing plate 61 applied here have an absorption axis and a transmission axis orthogonal to each other in a plane orthogonal to the light traveling direction. Such a polarizing plate extracts light having a vibrating surface in one direction parallel to the transmission axis, that is, light having a linearly polarized light state, from light having a vibrating surface in a random direction.

  The second retardation plate RF2 applied here is a film whose main refractive index in the depth direction is inclined with respect to the normal direction, that is, an optically anisotropic film. As the two phase difference plate RF2, an NH film (manufactured by Nippon Oil Corporation) is applicable. The NH film is a liquid crystal film in which nematic liquid crystal molecules having optically positive uniaxial refractive index anisotropy are fixed in a liquid crystal state in a hybrid alignment along the normal direction.

  Further, as the second retardation plate RF2, a WV film (manufactured by Fuji Photo Film Co., Ltd.) that is an optically anisotropic film can be applied. The WV film is a liquid crystal film in which discotic liquid crystal molecules having optically negative uniaxial refractive index anisotropy are fixed in a liquid crystal state in a hybrid alignment along the normal direction. These anisotropic films correspond to retardation plates having a viewing angle expansion function.

  The first retardation plate RF1 and the second retardation plate RF2 included in the first optical element OD1, and the third retardation plate RF3 and the fourth retardation plate RF4 included in the second optical element OD2 are orthogonal to each other. It has a slow axis and a fast axis. In discussing birefringence, the slow axis corresponds to an axis having a relatively large refractive index, and the fast axis corresponds to an axis having a relatively small refractive index. The slow axis coincides with the vibration plane of the extraordinary ray. The fast axis coincides with the plane of vibration of ordinary rays. When the refractive indexes of ordinary ray and extraordinary ray are respectively no and ne, and the thickness of the retardation plate along the traveling direction of each ray is d, the retardation value Δn · d (nm) of the retardation plate is (Ne · d−no · d) (that is, Δn = ne−no).

  The first retardation plate RF1 and the third retardation plate RF3 are so-called half-wave plates that give a half-wave phase difference between light of a predetermined wavelength that passes through the fast axis and the slow axis. The fourth retardation plate RF4 is a so-called quarter-wave plate that gives a quarter-wave phase difference between light of a predetermined wavelength that passes through the fast axis and the slow axis. Here, in particular, it is desirable to apply a uniaxial retardation plate to the first retardation plate RF1, the third retardation plate RF3, and the fourth retardation plate RF4, and ZEONOR (manufactured by Optes Co., Ltd.). Etc. are applicable.

  The second retardation plate RF2 has a function as a quarter-wave plate that gives a quarter-wave phase difference between light of a predetermined wavelength in addition to the above-described viewing angle expansion function. . In addition, when a WV film is applied as the second retardation plate RF2, the WV film itself does not have a front phase difference equivalent to a quarter wavelength, and therefore has a phase difference equivalent to a quarter wavelength. It is necessary to bond with a phase difference plate, and what was bonded with the base material which consists of a polycarbonate in consideration of wavelength dispersion is applicable.

  In the combination of the first retardation plate RF1 and the second retardation plate RF2, the slow axis of each of them is a predetermined angle with respect to the absorption axis (or transmission axis) of the first polarizing plate 51 in the plane. By arranging so as to form (acute angle), the linearly polarized light transmitted through the first polarizing plate 51 is converted into elliptically polarized light or circularly polarized light having a predetermined ellipticity (= minor axis direction amplitude / major axis direction amplitude). It has a function to convert.

  Similarly, in the combination of the third retardation plate RF3 and the fourth retardation plate RF4, the slow axis of each of them is predetermined with respect to the absorption axis (or transmission axis) of the second polarizing plate 61 in the plane. By arranging so as to form an angle (acute angle), it has a function of converting linearly polarized light transmitted through the second polarizing plate 61 into elliptically polarized light or circularly polarized light having a predetermined ellipticity.

  In general, the birefringent material constituting the retardation plate has characteristics in which the refractive index no for ordinary light and the refractive index ne for extraordinary light depend on the wavelength of light. For this reason, the retardation value Δn · d of the phase difference plate depends on the wavelength of light passing therethrough. Therefore, color display is achieved by combining at least two types of retardation plates (1/2 wavelength plate and ¼ wavelength plate) with the above-described configuration, and relaxing the wavelength dependence of the retardation value of the retardation plate. In all the wavelength ranges used in the above, a predetermined retardation is imparted to form a desired polarization state.

  Next, the wavelength dispersion characteristics of retardation of the second retardation plate RF2 in the configuration of the above-described embodiment will be examined.

  First, each member having a function as a quarter-wave plate applicable as the second retardation plate RF2, that is, a member made of a norbornene polymer (for example, Zeonore (manufactured by Optes Co., Ltd.), Arton (JSR Co., Ltd.) ), Etc.), polycarbonate (PC) bonded with existing WV film (Fuji Photo Film Co., Ltd.), existing NH film (Shin Nippon Petrochemical Co., Ltd.), and reverse wavelength dispersion About each type | mold anisotropic film, the retardation in each wavelength in a visible region (a range from about 380 nm to about 780 nm) was measured.

FIG. 4A shows the chromatic dispersion characteristics of the normalized retardation value (R / R ₅₅₀ ) normalized by the retardation of 550 nm for each member and an ideal quarter-wave plate. As shown in FIG. 4A, an anisotropic film combining a polycarbonate and a WV film and a reverse wavelength dispersion type anisotropic film have a normalized retardation value of less than 1 at a wavelength shorter than 550 nm. In addition, the normalized retardation value on the longer wavelength side than 550 nm exceeds 1. This is the same tendency as an ideal quarter wave plate. On the other hand, for a retardation plate made of a norbornene-based polymer, the normalized retardation value is almost constant for all wavelengths in the visible range. Further, the NH film has a normalized retardation value on the shorter wavelength side of 550 nm exceeding 1 and a normalized retardation value on the longer wavelength side of 550 nm of less than 1.

  Thus, an anisotropic film combining a polycarbonate and a WV film, a retardation film made of a norbornene-based polymer, and an NH film are shorter than 550 nm compared to an ideal quarter-wave plate. Dispersion in which the normalized retardation value at the wavelength exceeds the ideal quarter-wave plate value, and the normalized retardation value at the longer wavelength side than 550 nm is less than the ideal quarter-wave plate value It has characteristics. On the other hand, the reverse wavelength dispersion type anisotropic film has a wavelength dispersion characteristic such that the normalized retardation value is lower than that of an ideal quarter-wave plate for almost all wavelengths in the visible range.

  Further, when these members were applied as the second retardation plate RF2 and transmissive display was performed mainly using the transmissive portion in the liquid crystal display device, the contrast in the normal direction of the screen was measured. Note that ZEONOR was applied to each of the first retardation plate RF1, the third retardation plate RF3, and the fourth retardation plate RF4.

  FIG. 4B shows the front contrast ratio of each member when the front contrast ratio (front CR) is 1 when an anisotropic film combining a polycarbonate and a WV film is applied as the second retardation plate RF2. The value is shown. As shown in FIG. 4B, when an anisotropic film combining a polycarbonate and a WV film is applied as the second retardation plate RF2, the front contrast ratio is the highest, and an inverse wavelength dispersion type anisotropic film is used. When applied, the front contrast ratio was the lowest.

  This is based on the following reasons. That is, the highest front contrast ratio obtained when an anisotropic film in which polycarbonate and a WV film are combined is applied as the first retardation plate RF1 having a phase difference equivalent to λ / 2. This is because the chromatic dispersion characteristic of the ideal λ / 4 plate was brought closest to the combination with ZEONOR. Further, when a norbornene-based polymer was applied, a relatively high front contrast ratio was obtained for the same reason. Even when the NH film was applied, a front contrast ratio of about half that when an anisotropic film in which a polycarbonate and a WV film were combined was applied was obtained.

  That is, the liquid crystal layer LQ also exhibits a wavelength dispersion characteristic such that the retardation varies depending on the wavelength when the retardation at each wavelength is measured. Here, when the above-described member is applied as the second retardation plate, the matching with the wavelength dispersion characteristic of the retardation of the liquid crystal layer LQ is good, and the wavelength dispersion characteristic of the liquid crystal layer LQ is changed to each optical element. In such a case, an effect of compensation is obtained by the wavelength dispersion characteristic of the retardation plate. For this reason, when the light passes through the liquid crystal layer and each optical element, the influence of the retardation received by the light of each wavelength that passes through them is almost the same, and a polarization state with substantially the same ellipticity can be obtained at any wavelength. As a result, when transmissive display is performed, deterioration of the color of black display in particular is suppressed, and a high front contrast ratio is obtained.

  On the other hand, when the reverse wavelength dispersion type anisotropic film is applied, the front contrast ratio obtained is the lowest when ZEONOR applied as the first retardation plate RF1 having a phase difference equivalent to λ / 2 is used. This is because of the most deviating from the wavelength dispersion characteristic of an ideal λ / 4 plate.

  That is, when an inverse wavelength dispersion type anisotropic film is applied as the second retardation plate, the matching with the wavelength dispersion characteristic of the retardation of the liquid crystal layer LQ is poor, and the wavelength dispersion characteristic of the liquid crystal layer LQ It acts in a direction in which the wavelength dispersion characteristics of the phase difference plate in each optical element further deviate (opposite to the compensating direction). For this reason, when passing through the liquid crystal layer and each optical element, the difference in the influence of retardation received by the light of each wavelength that passes through the liquid crystal layer and each optical element is enlarged, and the polarization state has a different ellipticity at each wavelength. As a result, when transmissive display is performed, the color of the black display is particularly deteriorated, resulting in a decrease in the front contrast ratio.

  FIG. 5 shows a TV characteristic (that is, applied to the liquid crystal layer) at wavelengths of 470 nm (B), 550 nm (G), and 610 nm (R) of a liquid crystal display device using an NH film as the second retardation plate RF2. The relationship between voltage and transmittance is shown. FIG. 6 shows TV characteristics at each wavelength of a liquid crystal display device using an inverse wavelength dispersion anisotropic film as the second retardation plate RF2.

  As shown in FIG. 5, for the liquid crystal display device to which the NH film is applied as the second retardation plate RF2, the TV characteristic at each wavelength is 4.5V which is an actual driving voltage at any wavelength. Tmin (= black display state) is shown, and it can be seen that sufficient optical compensation is performed in the entire wavelength region. In other words, as described above, the polarization state having almost the same ellipticity at any wavelength is obtained, so that the variation in voltage for black display is small, and a good front contrast is achieved by the actual driving voltage. A ratio was obtained. This tendency is that the dispersion is large on the shorter wavelength side than 550 nm (that is, the normalized retardation value is larger than that of the quarter wave plate) and longer than 550 nm, compared to the ideal wavelength dispersion characteristic of the quarter wave plate. On the side, the same results were obtained in all cases where a member having a small dispersion was applied.

  On the other hand, as shown in FIG. 6, in the liquid crystal display device to which the reverse wavelength dispersion type anisotropic film is applied, the voltage for performing black display at each wavelength of R, G, and B varies. . That is, at an actual drive voltage of 4.5 V, only 550 nm light is Tmin (= black display state), and only 550 nm light is optically compensated, and optical compensation is performed for light in other wavelength regions. This is inadequate. That is, as described above, since the polarization state has a different ellipticity at each wavelength, the voltage for black display varies greatly. Due to this, when the pixels of each wavelength are driven with an actual drive voltage (4.5 V), the front contrast ratio is lowered.

  Based on such studies, in the liquid crystal display device having the configuration as shown in FIG. 3, the second phase difference plate RF2 has an ideal quarter wavelength retardation dispersion at almost all wavelengths in the visible range. A high front contrast ratio can be obtained by applying a retardation plate that is between the wavelength dispersion characteristic of the plate and the wavelength dispersion characteristic of the NH film.

  That is, for the second retardation plate RF2, the normalized retardation value at 400 nm as a wavelength shorter than 550 nm is 0.7 or more corresponding to the ideal quarter-wave plate value, and 550 nm. A member having a wavelength dispersion characteristic such that a normalized retardation value at 650 nm as a wavelength on a longer wavelength side is 1.2 or less corresponding to an ideal quarter-wave plate value is applied. And about this 2nd phase difference plate RF2, the normalized retardation value in 400 nm as a wavelength of the short wavelength side from 550 nm is 1.3 or less equivalent to the value equivalent to the existing NH film, and from 550 nm A member having a wavelength dispersion characteristic such that a normalized retardation value at 650 nm as a wavelength on the long wavelength side is 0.9 or more corresponding to a value equivalent to that of an existing NH film is applied.

  Examples of retardation plates having wavelength dispersion characteristics in the above-described range include those composed of norbornene polymers, NH films, and combinations of polycarbonate and WV films, but those composed of norbornene polymers. Has no viewing angle expansion function. That is, in order to increase the viewing angle while improving the front contrast ratio, it is necessary not only to have the wavelength dispersion characteristics in the range described above but also to have optical anisotropy. In this embodiment, the NH film and the combination of the polycarbonate and the WV film are exemplified as those applicable as the second retardation plate RF2, but the present invention is not limited to these as long as the above-described conditions are satisfied.

  As described above, the second retardation plate RF2 that gives a quarter-wave phase difference between light of a predetermined wavelength and has optical anisotropy is configured by the member having the above-described wavelength dispersion characteristics. As a result, a wide viewing angle and high contrast can be achieved, and a liquid crystal display device with good display quality can be provided.

  In addition, in consideration of the retardation wavelength dispersion characteristic of the first retardation film RF1 combined with the second retardation film RF2 and the retardation wavelength dispersion characteristic of the liquid crystal layer, a dispersion member as small as a norbornene polymer. Is preferably applied to the second retardation plate RF2. That is, the second retardation plate RF2 has a wavelength dispersion such that the normalized retardation value at 400 nm is 0.8 or more and 1.2 or less and the normalized retardation value at 650 nm is 0.9 or more and 1.1 or less. It is desirable to have characteristics.

  Furthermore, in the case of applying a WV film as an anisotropic film corresponding to the second retardation plate RF2, a combination with a base material having a function as a quarter wavelength plate such as polycarbonate is required. This hinders thinning. For this reason, as the second retardation plate, a liquid crystal film in which nematic liquid crystal molecules are immobilized in a hybrid alignment state along the normal direction (for example, an NH film having a wavelength dispersion lower than that of the existing one) is applied. Is desirable.

(Example)
Next, a configuration example of a liquid crystal display device in which the display mode according to the above-described embodiment is a normally white mode will be described with reference to FIG.

  The R value shown in FIG. 7 indicates a retardation value at a predetermined wavelength, here, a wavelength of 550 nm. The axis angle is an angle formed by the absorption axis of the polarizing plate and the slow axis of the retardation plate counterclockwise with respect to the reference azimuth X-axis, and is defined by FIG. That is, when the liquid crystal display device is observed from the counter substrate CT side, an X axis and a Y axis orthogonal to each other are defined for convenience in a plane parallel to the main surface of the array substrate AR (or the counter substrate CT). The normal direction is defined as the Z axis. In-plane corresponds to a plane defined by the X-axis and the Y-axis. Here, the X axis corresponds to the horizontal direction of the screen, and the Y axis corresponds to the vertical direction of the screen. Further, the positive (+) direction (0 ° azimuth) of the X axis corresponds to the right side of the screen, and the negative (−) direction (180 ° azimuth) of the X axis corresponds to the left side of the screen. Furthermore, the positive (+) direction (90 ° azimuth) of the Y axis corresponds to the upper side of the screen, and the negative (−) direction (270 ° azimuth) of the Y axis corresponds to the lower side of the screen.

  In FIG. 8, A1 and A2 represent absorption axes of the first polarizing plate 51 and the second polarizing plate 61, respectively, and D1 to D4 represent slow axes of the first retardation plate RF1 to the fourth retardation plate RF4, respectively. It represents.

  The second retardation plate RF2 was an existing NH film in Example 1, and the second retardation plate RF2 in Example 2 was a combination of a polycarbonate substrate and a WV film. The Nz coefficient of polycarbonate was 0.1. Since the WV film does not have a front retardation (retardation) equivalent to a quarter wavelength, it is necessary to separately bond with a retardation plate having a retardation equivalent to a quarter wavelength, considering wavelength dispersion. Laminated with a polycarbonate substrate.

  As the first retardation plate RF1, the third retardation plate RF3, and the fourth retardation plate RF4, a film obtained by stretching ZEONOR was applied, and the Nz coefficient thereof was 1.0. Here, the Nz coefficient is defined as Nz = (nx−nz), where nx and ny are the refractive indexes in the directions perpendicular to each other in the plane of the retardation plate, and nz is the refractive index in the normal direction. ) / (Nx−ny).

  The circularly polarized light incident on the liquid crystal display panel LPN can be formed by arranging the absorption axis of the polarizing plate at an angle of 45 ° with respect to the slow axis of the retardation plate having a phase difference corresponding to a quarter wavelength. it can. In order to achieve good optical compensation, uniform circularly polarized light must be formed in the wavelength range of 380 nm to 780 nm, but the wavelength dispersion of the refractive index of the existing retardation plate (polycarbonate, cycloolefin polymer, etc.) The characteristics do not reach the characteristics of an ideal quarter-wave plate. Therefore, a phase difference plate having a phase difference equivalent to a half wavelength and a phase difference plate having a phase difference equivalent to a quarter wavelength are combined. It is necessary to approximate the characteristics of an ideal quarter-wave plate. Therefore, the axis angles of the absorption axis of the polarizing plate (pol), the slow axis of the half-wave plate (λ / 2), and the slow axis of the quarter-wave plate (λ / 4) are as shown below. Designed based on the idea.

  The light that has passed through the polarizing plate is converted into linearly polarized light and is incident on a half-wave plate having a phase difference equivalent to a half-wave plate. The half-wave plate is an optical rotator and has a function of rotating the vibration direction of linearly polarized light by an angle × 2 formed by the absorption axis of the polarizing plate and the slow axis of the half-wave plate. For example, if the angle between the absorption axis of the polarizing plate and the slow axis of the half-wave plate is A, the light after passing through the half-wave plate makes an angle of 2 × A with the absorption axis of the polarizing plate. Converted to linearly polarized light.

  With respect to this linearly polarized light, a circularly polarizing plate can be produced by arranging the slow axis of the quarter wavelength plate in the vicinity of 45 °. Based on this idea, the first optical element OD1 and the second optical element OD2 can be designed, and the liquid crystal display panel LPN can be optimized.

  In the liquid crystal display panel LPN, the liquid crystal layer LQ is composed of a liquid crystal composition including homogeneously aligned liquid crystal molecules 40. For example, MJ041113 (manufactured by Merck, Δn = 0.065) was applied as the liquid crystal composition. At this time, the director (major axis orientation of the liquid crystal molecules) 40D of the liquid crystal molecules 40 was set to form an angle of 225 ° with respect to the X axis. Further, the gap of the transmission part in the liquid crystal layer LQ was set to 4.9 μm.

  According to the first embodiment, when the transmissive display using the transmissive portion is performed, the front contrast ratio in the normal direction of the screen is 180, and according to the second embodiment, the front contrast ratio is 350.

  Further, when the viewing angle dependence of the contrast ratio was simulated, the regions having the contrast ratio of 10: 1 or more are 56 ° and 80 ° in the vertical direction and 80 ° in the horizontal direction according to the first embodiment. And 62 °. Further, according to Example 2, the vertical direction was 60 ° and 80 °, respectively, and the horizontal direction was 80 ° and 80 °, respectively.

  In the first and second embodiments described above, each of the first retardation plate RF1, the third retardation plate RF3, and the fourth retardation plate RF4 employs ZEONOR, which is a uniaxial retardation plate. The same uniaxial retardation plate or biaxial retardation plate can be used as appropriate according to required performance and the phase difference to be compensated. Further, the second retardation plate (anisotropic film) is not limited to an anisotropic film or NH film obtained by bonding a WV film to polycarbonate, and ideal λ / 4 plate wavelength dispersion characteristics and NH An anisotropic film having wavelength dispersion characteristics between the film wavelength dispersion characteristics can be appropriately employed.

  As described above, according to this embodiment, the viewing angle can be enlarged, contrast can be improved, and an image with good display quality can be displayed.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the spirit of the invention in the stage of implementation. In addition, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, you may combine the component covering different embodiment suitably.

  For example, the example in which the switching element W is configured by an N-channel thin film transistor has been described, but other configurations may be used as long as the same various drive signals can be generated.

  In the above-described embodiment, the same effect can be obtained even if the first optical element OD1 is disposed on the outer surface on the counter substrate side in the liquid crystal display panel LPN and the second optical element OD2 is disposed on the outer surface on the array substrate side. .

  At least one of a combination of the first polarizing plate 51 and the first retardation plate RF1 constituting the first optical element OD1, and a combination of the second polarizing plate 61 and the third retardation plate RF3 constituting the second optical element OD2. Is formed of a support layer 101, a polarizer layer 102 disposed on the support layer 101, and a cycloolefin-based polymer disposed on the polarizer layer 102, as shown in FIG. You may comprise with the optical element 100 which has the phase difference layer 103 which gives the phase difference of 1/2 wavelength between the light of the predetermined wavelength which permeate | transmits a fast axis and a slow axis. The support layer 101 can be formed of triacetate cellulose (TAC). The polarizer layer 102 can be formed of dyed polyvinyl alcohol (PVA). By applying such an optical element 100, the number of parts constituting the first optical element OD1 and the second optical element OD2 can be reduced, and the thickness and cost can be reduced.

FIG. 1 schematically shows a configuration of a liquid crystal display device according to an embodiment of the present invention. FIG. 2 is a diagram schematically showing a cross-sectional structure of the liquid crystal display device shown in FIG. FIG. 3 is a diagram schematically showing a configuration of a first optical element and a second optical element applicable to the liquid crystal display device shown in FIG. FIG. 4A is a diagram showing chromatic dispersion characteristics of a normalized retardation value (R / R ₅₅₀ ) normalized by a retardation of 550 nm for each member applicable as a quarter wavelength plate and an ideal quarter wavelength plate. It is. FIG. 4B is a diagram illustrating a comparison result of contrast ratios in the normal direction of the screen when transmissive display using a transmissive portion is performed. FIG. 5 is a diagram illustrating TV characteristics when an NH film is applied as the second retardation plate. FIG. 6 is a diagram showing TV characteristics when an inverse wavelength dispersion type anisotropic film is applied as the second retardation plate. FIG. 7 is a diagram for explaining the configurations and the characteristics of the first and second embodiments. FIG. 8 is a diagram for explaining the orientation of the slow axis of the retardation plate having the configuration of Example 1 and Example 2 and the orientation of the absorption axis of the polarizing plate. FIG. 9 is a diagram schematically showing a configuration of an optical element applicable to the first optical element and the second optical element.

Explanation of symbols

    LPN ... liquid crystal display panel, AR ... array substrate, CT ... counter substrate, LQ ... liquid crystal layer, PT ... transmission part, PR ... reflection part, OD1 ... first optical element, OD2 ... second optical element, 51 ... first polarization Plate, RF1 ... first retardation plate, RF2 ... second retardation plate, 61 ... second polarizing plate, RF3 ... third retardation plate, RF4 ... fourth retardation plate, RF5 ... fifth retardation plate, BL ... Backlight unit, PX ... Pixel

Claims (7)

A liquid crystal display panel holding a liquid crystal layer containing homogeneously aligned liquid crystal molecules between a first substrate and a second substrate disposed to face each other;
Provided on one outer surface of the liquid crystal display panel, disposed between the first polarizing plate, a light having a predetermined wavelength that is disposed between the first polarizing plate and the liquid crystal display panel and transmits the fast axis and the slow axis. Between a first retardation plate that gives a half-wave phase difference, and light of a predetermined wavelength that is disposed between the first retardation plate and the liquid crystal display panel and transmits the fast axis and the slow axis. A first optical element including a second retardation plate that gives a phase difference of ¼ wavelength to and optically anisotropic,
Provided on the other outer surface of the liquid crystal display panel, disposed between the second polarizing plate, light having a predetermined wavelength that is disposed between the second polarizing plate and the liquid crystal display panel and transmits the fast axis and the slow axis. A third retardation plate that gives a half-wave phase difference, and light of a predetermined wavelength that is disposed between the third retardation plate and the liquid crystal display panel and transmits the fast axis and the slow axis. A second optical element including a fourth retardation plate that gives a phase difference of ¼ wavelength to
When the retardation at each wavelength is normalized with a retardation of 550 nm, the second retardation plate has a normalized retardation value at 400 nm of 0.7 to 1.3 and a normalized retardation value at 650 nm of 0.00. A liquid crystal display device having wavelength dispersion characteristics of 9 or more and 1.2 or less.   The second retardation plate has a wavelength dispersion characteristic such that a normalized retardation value at 400 nm is 0.8 or more and 1.2 or less and a normalized retardation value at 650 nm is 0.9 or more and 1.1 or less. The liquid crystal display device according to claim 1, comprising:   2. The liquid crystal display device according to claim 1, wherein the second retardation plate is a liquid crystal film in which nematic liquid crystal molecules are fixed in a hybrid alignment state along a normal direction.   The liquid crystal display device according to claim 1, wherein the first retardation plate, the third retardation plate, and the fourth retardation plate are uniaxial retardation plates.   The liquid crystal display device according to claim 1, further comprising a backlight unit that illuminates the liquid crystal display panel from the first optical element side.   The liquid crystal display device according to claim 1, wherein the display mode is normally white.   At least one of the combination of the first polarizing plate and the first retardation plate and the combination of the second polarizing plate and the third retardation plate is a support layer and a polarizer layer disposed on the support layer. And a retardation layer that is formed by a cycloolefin-based polymer disposed on the polarizer layer and gives a phase difference of ½ wavelength between light of a predetermined wavelength that passes through the fast axis and the slow axis. The liquid crystal display device according to claim 1, comprising an optical element.

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