JP3317846B2 - Liquid crystal display - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a so-called lateral electric field type liquid crystal display device which operates by applying an electric field to a liquid crystal layer in a direction parallel to a substrate, and more particularly to an active matrix suitable for color display. Liquid crystal display device.

[0002]

2. Description of the Related Art A conventional liquid crystal display device uses a transparent electrode as an electrode for driving a liquid crystal layer. This is due to the adoption of a display system represented by a twisted nematic display system in which the operation is performed with the direction of the electric field applied to the liquid crystal substantially perpendicular to the substrate surface.

On the other hand, a lateral electric field type liquid crystal display device in which an electric field applied to a liquid crystal is operated in a direction substantially parallel to a substrate surface has been conventionally known. A liquid crystal display device of a lateral electric field type using an electrode pair is disclosed in, for example, JP-A-63-21907.
Publication, US Patent No. 4,345,249, WO91
/ 10936 or Japanese Patent Application Laid-Open No. 6-222397.

In the case of the lateral electric field type, the electrode does not need to be transparent, and an opaque metal electrode having high conductivity is used. However, in these proposals, there is no mention at all in a horizontal electric field type liquid crystal display device using an active element, of a configuration necessary for suppressing a change in color tone due to voltage application and reducing poor color tone.

[0005]

The above prior art is disadvantageous in the active matrix type lateral electric field type liquid crystal display device, that is, the color tone change due to the magnitude of the driving voltage and the local difference in the thickness of the liquid crystal layer. No consideration was given to the occurrence of uneven color tone, and there was a problem in improving display quality. Hereinafter, this point will be described. The display operation by the in-plane switching mode liquid crystal display device is obtained in the birefringence mode, and the transmittance T at this time is generally expressed by
It can be expressed by an equation.

T = T ₀ · sin ² 2θ · sin ² [(π · d _eff · Δn) / λ] (1) Here, T ₀ is a coefficient, and polarized light mainly used for a liquid crystal panel. The value determined by the transmittance of the plate, θ is the angle between the effective optical axis of the liquid crystal layer and the polarization transmission axis, d _eff is the thickness of the liquid crystal layer,
Δn indicates the refractive index anisotropy of the liquid crystal, and λ indicates the wavelength of light.

Here, the product of the thickness d _eff of the liquid crystal layer and the refractive index anisotropy Δn of the liquid crystal, that is, d _eff · Δn is called retardation. Here, the thickness d of the liquid crystal layer
_eff indicates not the thickness of the entire liquid crystal layer but only the thickness of the liquid crystal layer that actually changes the alignment direction when a voltage is applied.

This is because liquid crystal molecules in the vicinity of the interface of the liquid crystal layer do not change the alignment direction even when a voltage is applied due to the effect of anchoring at the interface. Therefore, assuming that the total thickness of the liquid crystal layer sandwiched between the substrates is d _LC , there is always a relationship of d _eff <d _LC between this thickness d _LC and the thickness d _eff , and the difference is approximately 20 to It can be estimated to be 40 nm.

As is apparent from the above equation (1), the transmittance of the liquid crystal display panel has a maximum value at a certain specific wavelength (peak wavelength), so that the liquid crystal display panel is easily colored, that is, unnecessary coloring occurs. It becomes a liquid crystal display element which is easy.

In a liquid crystal display panel, for example,
The configuration is such that the peak wavelength under zero-order retardation coincides with the maximum luminosity wavelength of 555 nm, that is, the condition (πd · Δn / 555) = π / 2 is satisfied. However, this is a general method for practical use, but in that case, the spectral transmittance of the liquid crystal display panel has a characteristic that it decreases significantly on the short wavelength side of the peak wavelength and gradually decreases on the long wavelength side, The liquid crystal display element is easily colored yellow.

Further, the degree of color change remarkably changes with the application of a voltage to the liquid crystal, and changes from a minimum applied voltage required for display (dark display voltage in a normally closed display mode) to a halftone display voltage, Since the color tone gradually changes as the voltage value changes to the maximum applied voltage (also the bright display voltage), the color display state is significantly deteriorated.

On the other hand, in the display in the birefringence mode, the difference in the thickness of the liquid crystal layer appears as a change in the peak wavelength.
The brightness and color tone at that portion are different from the surroundings, which causes display defects such as uneven brightness and uneven color tone.

However, in the prior art, since no consideration is given to these, there is a problem in that the display quality is improved as described above.

An object of the present invention is to solve the above-mentioned problem, to suppress a change in color tone between a minimum applied voltage and a maximum applied voltage,
Another object of the present invention is to provide a horizontal electric field type liquid crystal display device capable of reducing the occurrence of display failure due to a local difference in thickness of a liquid crystal layer.

[0015]

SUMMARY OF THE INVENTION The object is 400 [n].
m] to 500 [nm] within the emission wavelength range.
It has a maximum value and an emission wavelength range from 500 [nm] to 600.
A second luminance maximum in the range, at which 600 nm
The third luminance maximum within the emission wavelength region from 700 nm to 700 nm.
Light source having a value and a wavelength indicating the first luminance maximum value.
The value of the transmittance at x and the wave representing the second luminance maximum value
The value of the transmittance at the length is y, and the third luminance maximum
When the value of the transmittance at the wavelength indicating the value is z, the transmission
Spectroscopy with the relation x>y> z over the entire range of the rate control range
An active mask that has transmittance characteristics and operates in an in-plane switching method.
A liquid crystal panel of a trix type, and
It is placed on one side of the panel and the image is displayed on the other side.
Is achieved in such a way.

As a result, according to the present invention, a change in color tone due to a change in applied voltage can be suppressed, and a liquid crystal display device having good display characteristics can be obtained.
The reason will be described.

As described above, since the liquid crystal display device of the in-plane switching mode usually operates in the birefringence mode, its transmittance is expressed by the equation (1), and therefore, has a maximum value at a certain wavelength. Has a spectral transmittance characteristic that shows a sharp decrease on the short wavelength side and a gradual decrease on the long wavelength side.

If the peak wavelength is set at around 550 nm, the blue region of 400 to 500
The transmittance in the wavelength range of nm decreases sharply. The wavelength dependence of the transmittance becomes more remarkable as the brightness of the liquid crystal panel increases, which causes a change in color tone due to voltage application.

Further, in the liquid crystal panel, if there is a locally different portion in the thickness of the liquid crystal layer, the transmittance of the blue region in that portion will fluctuate remarkably, causing a poor color tone. From the above, it can be seen that it is important to suppress a sharp drop in transmittance in the short wavelength region of the peak wavelength, that is, in the blue region, to suppress color tone change and poor color tone.

Here, first, in order to suppress a sharp drop in the transmittance in the short wavelength region, the wavelength λ is set to a value in the shorter wavelength region than 550 nm under the condition of d _eff · Δn (λ) = λ / 2. It is effective to shift the peak wavelength to the shorter wavelength side.

That is, the degree of decrease in the transmittance increases as the distance from the peak wavelength increases, so that by setting the peak wavelength to a shorter wavelength, a sharp decrease in the transmittance in the short wavelength region can be suppressed. It is.

However, at this time, it is important to suppress a sharp decrease in the transmittance with respect to the emission wavelength of the light source used. By the way, as a light source used for illuminating such a liquid crystal display panel, a narrow-band light emitting fluorescent tube is often used. Therefore, a description will be given of the narrow-band luminous body type fluorescent tube. This fluorescent tube uses a phosphor having an emission peak in each of the wavelength regions of blue (B), green (G) and red (R), which are the three primary colors of light. It was what was.

As an example, first, 450-
As a phosphor having an emission peak in a region of 490 nm, 3Ca ₃ (P04) ₂ .Ca (F, C1) ₂ : Sb ³ +, Sr
₁₀ (P04) ₆ C ₁₂ : Eu ² +, (Sr, Ca) ₁₀ (P04)
^{_{6 C 12: Eu 2 +,}} (Sr, Ca) 10 (P04) 6 C 1 2 · nB
₂ O ₃ : Eu ² +, (Ba, Ca, Mg) ₁₀ (P04) ₆ C ₁₂ : Eu
^{_{2 +, Sr 2 P 2 O}} 7: Sn 2 +, Ba 2 P 2 O 7: Ti 4 +, 2Sr0
_{· 0.84P 2 O 5 · 0.16B 2} O 3: Eu 2 +, MgWO 4,
BaA ₁₈ O ₁₃ : Eu ² +, BaMg ₂ Al ₁₆ O ₂₇ : Eu ² + Mn ² +,
SrMgAl ₁₀ O ₁₇ : Eu ² + and the like.

Next, as a phosphor having an emission peak in a region of 540 to 550 nm corresponding to green, LaPO ₄ :
^{Ce 3 +, Tb 3 +,} LaO 3 · 0.2SiO 2 · 0.9P 2 O 5: C
e ³ +, Tb ³ +, Y ₂ SiO ₅ : Ce ³ +, Tb ³ +, CeMgAi ₁₁ O
₁₉ : Tb ³ +, GdMgB ₅ O ₁₀ : Ce ³ +, Tb ³ + and the like.

610 to 630 nm corresponding to red color
Phosphors having an emission peak in the region of (Sr, M
_{g) 3 (PO4 4) 2} : Sn 2 +, CaSiO 3: Pb 2 +, Mn 2 +, Y 2
O ₃ : Eu ³ +, Y (P, V) O ₄ : Eu ³ + and the like.

From at least one of these wavelength regions, at least one kind of phosphor is selected, and the emission characteristics of the narrow-band luminous type fluorescent tube formed by using them are such that the spectrum corresponding to blue has a range of 450 to 490 nm and the spectrum corresponding to green corresponds to green. And the spectrum corresponding to red is about 545 nm.
m to 630 nm.

When a narrow-band light emitting fluorescent tube as described above is used as a light source, the spectral transmittance characteristics to be considered in a liquid crystal panel are 450 to 490 nm as a blue region.
Around 545 nm as a green area and 610 as a red area
630 nm.

Therefore, as the liquid crystal panel, the most effective transmittance characteristic for suppressing color tone fluctuation and color tone failure is a characteristic having a maximum value in a wavelength region of 450 to 490 nm. In order to match the peak of the transmittance to this wavelength region, the retardation d _eff · Δn (λ) of the liquid crystal panel is set to 0.3.
It may be 245 μm (λ = 490 nm) or less. In order to reduce the retardation d _eff · Δn, a liquid crystal material having a small refractive index anisotropy Δn may be used, and the thickness d _{eff of the} liquid crystal layer may be reduced.

Here, as described above, it is important to match the light emission characteristics of the light source in the short wavelength region with the peak transmittance of the liquid crystal panel. The spectral transmittance at this time is
This is the transmittance characteristic inherent in the liquid crystal panel, not the spectral characteristic transmitted through a color filter or the like.

At this time, the peak wavelength of the transmittance may be slightly changed depending on the spectral characteristics of the color filter to be used, but the effect due to this can be ignored in practical use. In the present invention, the most important point is the relationship between the peak luminance of the light source and the transmittance of the liquid crystal panel.

On the other hand, since the magnitude of the refractive index anisotropy Δn of the liquid crystal changes with temperature, when the temperature of the liquid crystal panel changes due to the environment in which the liquid crystal display is used, the set value of the retardation d _eff · Δn fluctuates. Resulting in.

Here, when a liquid crystal having a small value of the refractive index anisotropy Δn is used in order to suppress the fluctuation of the retardation d _eff · Δn, the fluctuation rate of the refractive index anisotropy Δn itself due to the temperature is small. And when the thickness d _eff d is small, the retardation d _eff · Δn
Since the variation amount of the liquid crystal display becomes small, an effect of expanding the temperature margin of the liquid crystal display can be expected.

[0033]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a liquid crystal display device according to the present invention will be described with reference to embodiments. First, the angles necessary for describing the configuration and operation principle of the liquid crystal display element of the in-plane switching mode are as shown in FIG.

That is, in FIG. 2, the direction of the electric field is 9 and the angle formed by the polarization transmission axis 11 of the polarizing plate 8 (described later) is Φ _p. The angle formed by the liquid crystal molecule major axis (optical axis) direction 10 in the vicinity is defined as Φ _LC .

At this time, since there are a pair of upper and lower interfaces between the polarizing plate and the liquid crystal, Φ _p1 , Φ _p2 ,
Φ _LC1 and Φ _LC2 are described. In FIG. 2, the major axis direction 10 of the liquid crystal molecules is the same as the rubbing direction of the light distribution film, 1 is a common electrode, 3 is a signal electrode, and 4 is a pixel electrode.

Next, the configuration and operation principle of the liquid crystal display panel of the horizontal electric field type will be described with reference to FIG. 3A and 3B are side sectional views showing one pixel of the in-plane switching mode liquid crystal display panel, and FIGS. 3C and 3D are front views. Here, the active element is omitted, and only the gate insulating film 2 is shown.

FIGS. 3 (a) and 3 (c) show the state when no voltage is applied. The linear electrode 1 is placed inside a pair of transparent substrates 7 such as a glass plate.
Nos. 3 and 4 are formed, and an orientation control film 5 is coated and oriented thereon.

A polarizing plate 8 is provided outside the substrate 7, and the transmission axis 11 of the polarizing plate 8 is as shown in the lower left of the figure. A liquid crystal composition is sandwiched between the alignment control films 5, but only the liquid crystal molecules 6 are shown in the figure. The dielectric anisotropy of the liquid crystal composition at this time is assumed to be positive.

The orientation of these liquid crystal molecules 6 is controlled by the rubbing direction 10 of the orientation control film 5 when no electric field is applied, and the angle Φ _LC is determined in consideration of the above positive dielectric anisotropy. , 45 degrees <| Φ _LC | ≦ 90 degrees. At this time, the liquid crystal molecule alignment direction on each of the upper and lower interfaces is a parallel direction, that is, Φ _LC1 = Φ _LC2 .

Next, assuming that a voltage having a predetermined polarity is applied between the common electrode 1 and the signal electrode 4 of the liquid crystal display element and an electric field 9 is applied, the liquid crystal molecules are converted into the liquid crystal molecules shown in FIGS. The direction is changed to the direction of the electric field 9 as shown in FIG.

As a result, the light transmittance is controlled in accordance with the applied voltage in relation to the polarization transmission axis 11 of the polarizing plate 8, and a display function can be obtained. Note that there is no problem even if the dielectric anisotropy of the liquid crystal composition is negative. That is, in this case, the initial alignment state is 0 degree <|
This is because it is sufficient to set Φ _LC | ≦ 45 degrees.

Next, the structure of the active element (thin film transistor) and various electrodes of the in-plane switching mode liquid crystal display panel will be described.

FIG. 4 and FIG. 5 show unit pixel portions of an in-plane switching mode liquid crystal display panel having two different structures.
A front view as seen from a direction perpendicular to the substrate surface, a side sectional view taken along line AA 'and a side sectional view taken along line BB' of the front view are shown. Note that the glass substrate is omitted.

In these figures, reference numeral 14 denotes a thin film transistor, and the thin film transistor 14 is composed of a pixel electrode (source electrode) 4, a signal electrode (drain electrode) 3, a scanning electrode (gate electrode) 12, and amorphous silicon 13. I have.

Here, the common electrode 1 and the scanning electrode 12 are formed by patterning the same metal layer formed on a glass substrate, respectively. Next, the signal electrode 3 and the pixel electrode 4 are formed by patterning the same metal layer formed on the gate insulating film 2. The capacitive element 16 is formed by forming a structure in which the insulating film 2 is sandwiched between the pixel electrode 4 and the common electrode 1 in a region where the two common electrodes 1 are coupled.

First, in the example of FIG.
Is disposed between the two common electrodes 1 as is apparent from the front view, and the orientation control film 5 also serves as a planarizing film, and is provided directly on the gate insulating film 2. I have.
The pixel pitch in this example is 69 μm in the horizontal direction (that is, between signal wiring electrodes) and 207 μm in the vertical direction. next,
The width of each electrode is determined as follows. First, each electrode used also as a wiring electrode extending over a plurality of pixels, that is, each wiring portion of the scanning electrode 12, the signal electrode 3, and the common electrode 1 (a portion extending in parallel with the scanning electrode (the horizontal direction in FIG. 4)) In order to avoid line defects, the electrode width is widened, for example, to 14 μm.

On the other hand, the width of the pixel electrode 4 and the common electrode 1 which are independently formed in one pixel unit and the width of the signal wiring electrode extending in the longitudinal direction is slightly reduced to 9 μm.
At this time, the common electrode 1 and the signal electrode 3 are slightly overlapped (1 μm) with an insulating film interposed therebetween, so that the black matrix in the direction parallel to the signal electrode 3 can be eliminated.

Accordingly, in this example, a black matrix 22 that shields light only in the scanning electrode direction can be provided as shown. In this case, a color filter 24 may be provided on the surface of one substrate 7 as shown in FIG.

In this example, the black matrix 2
Although 2 is provided on the substrate on which the electrode group is formed, it may be provided on the opposing substrate. In addition, these electrodes need not be formed by a method different from the conventional method, and may be formed by a commonly used method.

Next, in the example of FIG. 5, the common electrode 1 and the pixel electrode 4 are comb-shaped, and two pixel electrodes 4 are arranged between the three common electrodes 1. The pixel pitch is horizontal. It is 100 μm in the direction (horizontal scanning direction) and 300 μm in the vertical direction. Here, insulation is provided by providing an insulating film at a portion where the common electrode 1 and the signal electrode 3 overlap, and the thickness of the insulating film at this time is 2 μm.

Next, in this example, an insulating film 27 for planarization is provided between the gate insulating film 2 and the orientation control film 5. As the material of the insulating film 27, as in the case of the gate insulating film 2, silicon dioxide or silicon nitride may be used, or an appropriate resin may be used.

Next, the electrode width in this example will be described. Also in this example, the scanning electrode 12, the signal electrode 3, and the wiring portion of the common electrode 1 (parallel to the scanning electrode (FIG. 5) In order to avoid line defects, the portion extending in the lateral direction) is made wider, and the width is 1
0 μm, 8 μm, 8 μm.

On the other hand, the widths of the pixel electrode 4 and the common electrode 1 which are independently formed in the unit of one pixel and extend in the longitudinal direction of the signal wiring electrode are slightly reduced to 5 μm and 6 μm, respectively. In this example, by reducing the width of the electrode in this way, the possibility of disconnection due to the incorporation of foreign matter or the like increases, but even in this case, a partial defect of only one pixel is sufficient, and a line defect is generated. There is no danger.

In the example of FIG. 5, the black matrix 2
2 is provided with the color filter 24 on the counter substrate side as shown in FIG. Here, 25 is a protective film and a flattening film.

In this example, the color filter 24
May be formed on the counter substrate side or on the substrate side provided with the electrode group. Also, it is not necessary to use a method different from the conventional method for forming these electrodes, and the electrodes may be formed by a commonly used method.

FIG. 8 shows an example of a driving circuit for a liquid crystal display panel. A driving LSI is connected to the active matrix type liquid crystal display panel 23 shown in the figure, and a vertical scanning circuit is provided on a TFT substrate provided with its electrode group. 20, video signal circuit 2
1. The common electrode drive circuit 26 is connected.

Then, a scanning signal voltage, a video signal voltage, and a timing signal are supplied from a power supply circuit and a controller 19 (not shown), and a display operation by active matrix driving is performed.

Next, embodiments of the present invention will be described with reference to examples. First, as a substrate, a thickness of 1.1
2 mm glass plates are prepared and used as a substrate 7 shown in FIG. A thin film transistor is formed on one of the substrates 7 (the lower substrate in the figure), and the insulating film 2 and the alignment film 5 are further formed on the surface of the thin film transistor. In this embodiment, a rubbing process for aligning the liquid crystal is performed using polyimide as the alignment film 5.

An alignment film 5 is similarly formed on the other substrate (upper substrate in the figure) 7 and rubbing is performed. At this time,
The rubbing directions on the upper and lower interfaces are substantially parallel to each other, and the angle between the rubbing directions and the direction of the applied electric field is 75 degrees. Therefore, in this embodiment, Φ _LC1 = Φ _LC2 = 75 degrees.

Next, a nematic liquid crystal having a positive dielectric anisotropy of 12.0 and a refractive index anisotropy Δn of 0.079 (589 nm, 20 ° C.) is provided between these substrates 7. Enclose the composition.

At this time, the gap between the substrates 7 (cell gap)
d is given by dispersing and sandwiching spherical polymer beads between the substrates so that a gap d = 3.02 μm can be obtained with the liquid crystal sealed. Therefore, the thickness d _{LC of the} entire liquid crystal layer is equal to the gap d (= 3.02 μm).
As a result, d _LC · Δn (589 nm) becomes 0.239 μm, but from the wavelength dispersion characteristic of refractive index anisotropy Δn, d _LC · Δn (490 nm) becomes 0.244 μm.
m, and as a result, d _eff · Δn (490 nm) is 0.2.
It is about 2 μm.

Next, a pair of substrates 7 is sandwiched between two polarizing plates 8, and the polarizing axis Φ _p1 of one of the polarizing plates is set to 75 °, and the polarizing axis Φ _p2 of the other polarizing plate is set to -15 °. Then, the liquid crystal display panel 23 of FIG. 9 is obtained.

Next, as shown in FIG. 9, the liquid crystal display panel 23 includes a fluorescent tube 30, a light cover 31, a light guide 32, and a light diffuser 33 as a light source for transmitted light. A 5885K backlight unit is provided to create a liquid crystal display device.

The backlight unit may be constituted by using a plurality of fluorescent tubes. At this time, a prism sheet is provided between the light diffusion plate 33 and the lower polarizing plate 8. You may.

At this time, from the color characteristics of the liquid crystal display panel 23 itself excluding the color filters, an appropriate
At this time, the color temperature of the light source is selected so that a display closest to an achromatic color is obtained.
Is the color temperature.

The spectral characteristics of the backlight unit at this time are as shown in FIG. 10, and the spectral transmittance characteristics of the liquid crystal display panel 23 in the bright state excluding the color filters are as shown in FIG. And thus meet the requirements of the invention as set forth in the appended claims.

As a result, the voltage dependence of the brightness of the liquid crystal display device according to this embodiment is as shown in FIG. 12, and the result shown in FIG. 1 is obtained as a locus on the chromaticity diagram at this time. Was done. Here, the C light source is a daylight standard light source.

In this embodiment, as is apparent from FIG. 11, since the decrease in the transmittance in the short wavelength region is suppressed, the chromaticity hardly changes from the dark state to the bright state, and the chromaticity is good. It can be seen that the display characteristics are excellent.

Therefore, according to this embodiment, the change in hue due to the luminance control can be sufficiently suppressed, so that there is a risk of coloring in the case of monochrome display and a risk of a decrease in color purity in the case of color display. This can be sufficiently eliminated, and the display quality can be sufficiently improved.

Next, the operation and effect of the above embodiment will be described using a comparative example.

Comparative Example 1 First, as Comparative Example 1, the dielectric anisotropy was positive, the value was 9.0, and the refractive index anisotropy was 0.082 (589 nm,
A liquid crystal display panel was prepared by enclosing a nematic liquid crystal composition (20 ° C.) between substrates. At this time, the cell gap d was 3.83 μm.

Therefore, d _LC · Δn (589
nm) is 0.310 μm and d _LC · Δn (490 nm) is 0.321 μm. As a result, d _eff · Δn (490 nm)
nm) is about 0.30 μm, which is outside the requirement of the present invention.

A liquid crystal display device is manufactured using a backlight unit having a color temperature of 6818K. FIG. 13 shows the spectral transmittance characteristics of the liquid crystal display panel in the bright state excluding the color filters, as shown in FIG. 13, and the transmittance in the short wavelength region is greatly reduced. As a result, the locus on the chromaticity diagram from the application of no voltage to the bright display becomes as shown in FIG. 14, the color tone changes, and the liquid crystal display panel itself is colored.

Therefore, in the liquid crystal display device using the liquid crystal display panel whose transmittance is reduced in the short wavelength region as in Comparative Example 1, as the state shifts from the dark state to the bright state,
It can be seen that the color tone changes. As a result, in this comparative example, it is difficult to suppress the occurrence of coloring in black-and-white display and the occurrence of hue change in color display, and the quality of the displayed image is inevitably reduced. .

Comparative Example 2 Next, as Comparative Example 2, similarly to Comparative Example 1, the dielectric anisotropy was positive, the value was 9.0, and the refractive index anisotropy was 0.08.
A 2 (589 nm, 20 ° C.) nematic liquid crystal composition was sealed between the substrates, and the cell gap d was 4.26 μm.
I made a liquid crystal display panel as m.

Therefore, d _LC · Δn (589 n
m) is 0.345 μm and d _LC · Δn (490 nm) is 0.357
μm. Then, as a result, d _eff · Δn (490n
m) can be estimated to be about 0.33 μm, which also deviates from the requirements of the present invention, and shows that the transmittance for blue light is low.

This liquid crystal display panel has a color temperature of 6818K.
When a liquid crystal display device is prepared by combining the above backlight units, and a locus on the chromaticity diagram of the liquid crystal display device from no voltage application to bright display is obtained, the result is as shown in FIG. , As it transitions from dark to light,
It can be clearly seen that the display becomes yellowish, so it is difficult to improve the display image quality also by this comparative example.

Next, a change in characteristics due to a local change in the thickness of the liquid crystal layer will be described with reference to examples and comparative examples.

Example A Two substrates having a color filter composed of three primary colors of BGR were used on one substrate surface, and between these substrates, the dielectric anisotropy was positive and the value was 12.0. In addition, a nematic liquid crystal composition having a refractive index anisotropy of 0.079 (589 nm, 20 ° C.) is sealed to form a color liquid crystal display panel.

At this time, the cell gap d is given by dispersing and holding spherical polymer beads between the substrates. By selecting the diameter of the polymer beads used here, the cell gap d can be obtained with the liquid crystal sealed. , D = 2.87
μm.

Therefore, d _LC · Δn (589 nm) is 0.2
At 27 μm, d _LC · Δn (490 nm) is 0.232 μm.
m, and therefore, d _eff · Δn (490 nm) is about 0.21 μm.

A backlight unit having a color temperature of 4703K is used as a light source in this color liquid crystal display panel, and a liquid crystal display device of Example A is obtained.

Example B Similarly, two substrates having color filters of three primary colors of BGR were used on one substrate surface, and the dielectric anisotropy was positive between these substrates and the value was 12. The liquid crystal display panel is filled with a nematic liquid crystal composition having a refractive index anisotropy of 0.079 (589 nm, 20 ° C.).

At this time, the diameter of the polymer beads for providing the cell gap d is changed to d = 3.17 μm, which is different from that used in Example A. Therefore, in Example B, the d _LC · Δn (589 nm) is 0.250 μm, and the d _LC · Δn (490 nm) is 0.256 μm.
μm and d _eff · Δn (490 nm) is 0.23 μm
It is about.

The color liquid crystal display panel is combined with a backlight unit having the same color temperature of 4703 K as a light source to obtain a liquid crystal display device of Example B.

Comparative Example C Similarly, two substrates having a color filter composed of the three primary colors of BGR were used on one substrate surface, and the dielectric anisotropy was positive between these substrates and the value was 9.0. A nematic liquid crystal composition having a refractive index anisotropy of 0.082 (589 nm, 20 ° C.) is sealed to form a color liquid crystal display panel.

At this time, the cell gap d is 3.83 μm
So that As a result, d _LC · Δn (589 nm)
Is 0.314 μm and d _LC · Δn (490 nm) is 0.32
1 μm, so that d _eff · Δn (490 nm) is _0.1 μm.
It is about 30 μm, which is outside the requirement of the present invention.

The color liquid crystal display panel has a color temperature of 68.
A liquid crystal display device as Comparative Example C is formed by combining an 18K backlight unit.

Comparative Example D Similarly, two substrates having a color filter composed of the three primary colors of BGR were used on one substrate surface, and the dielectric anisotropy was positive between these substrates and the value was 9.0. A nematic liquid crystal composition having a refractive index anisotropy of 0.082 (589 nm, 20 ° C.) is sealed to form a color liquid crystal display panel.

At this time, the cell gap d is 4.26 μm
So that As a result, d _LC · Δn (589 nm)
Is 0.349 μm and d _LC · Δn (490 nm) is 0.35 μm.
7 μm, so that d _eff · Δn (490 nm) is equal to 0.4 μm.
This is about 33 μm, which is also outside the requirements of the present invention.

The color liquid crystal display panel has a color temperature of 68.
A liquid crystal display device of Comparative Example D is made by combining an 18K backlight unit.

As is apparent from the above description, the gaps of the liquid crystal display panels in Examples A and B and Comparative Examples C and D are different from each other by about 10%. By seeing the difference in color at
A change in color tone due to a difference in the thickness d _eff (≒ d) of the liquid crystal layer, that is, a gap margin can be estimated.

Therefore, the International Commission on Illumination (CIE)
Using the color difference formula of L * u * v * color system proposed in 6 years,
Examples A and B, and Comparative Examples C and D
FIG. 16 shows the characteristics of the color difference ΔE _uv * with respect to the applied voltage. Usually, in such a liquid crystal display device, the value of the color difference ΔE _uv * allowed within the same liquid crystal display panel is about three.

Therefore, when looking at FIG. 16, first, in the case of the embodiment A and the embodiment B, as apparent from the characteristics indicated by the solid line in FIG. Even if it occurs, the value of the color difference ΔE _uv * is kept at 2 or less, and it is understood that the color tone does not become poor in this case.

On the other hand, Comparative Examples C and D
As is clear from the characteristics indicated by the broken line in FIG. 16, a large color difference ΔE _uv * appears in accordance with the applied voltage, and a remarkable poor color tone occurs.

Therefore, in the case of the embodiment of the present invention, 10
It can be seen that when the gap changes by about%, not only the color tone change accompanying the voltage application hardly occurs, but also a sufficient margin for the gap change can be obtained.

In the case of a liquid crystal display panel, from the viewpoint of the production yield, an allowable range of about 10% for the fluctuation of the gap is sufficient for practical use. According to this, it is possible to sufficiently suppress the characteristic change due to the local thickness change of the liquid crystal layer,
It is possible to easily maintain the display quality.

Next, the reason for the occurrence of the color difference between the embodiment of the present invention and the comparative example will be described based on the difference in the pass characteristics between the RGB colors. First, FIG. 17 and FIG. 18 show the characteristics of the brightness with respect to the applied voltage of Example A and Example B using RGB colors as parameters. Next, FIGS. 19 and 20 show Comparative Example C and Comparative Example. D is the same characteristic.

Here, the values of the wavelengths of the respective colors are those obtained by the backlight having the emission wavelength characteristics shown in FIG.
At this time, the wavelength of B (blue) is set to 465 nm by taking an intermediate value of the spectrum of the blue portion.

The following can be understood from these figures. First,
In the case of the embodiment of the present invention shown in FIGS. 17 and 18, the changing tendency of the characteristics of each color is almost the same from dark display to bright display.
It can be seen that the contribution to the brightness is almost equal for all colors. Therefore, in this case, no change in color tone appears. That is, it can be seen that in the embodiment of the present invention, no change in color tone occurs.

Next, in the case of the comparative example of FIGS. 19 and 20,
It can be seen that the change characteristic of the blue characteristic indicated by the solid line is different from the other red and green characteristics in that the contribution to the brightness decreases as the applied voltage increases. Therefore, in the case of this comparative example, the blue component becomes insufficient as the brightness increases, and as a result, the display becomes yellowish and the color tone changes.

FIG. 21 shows the retardation d _eff · Δn (μ
m) as a parameter, showing the transmittance at each wavelength in bright display as brightness, and as apparent from this figure, the setting value of the retardation d _eff · Δn is particularly effective for the short wavelength region having a wavelength of 500 nm or less. It can be seen that the brightness in the (blue region) greatly changes, and a slight change in retardation d _eff · Δn causes a significant decrease in brightness.

In order to obtain a liquid crystal display panel in which a color tone change does not occur, it is important that the relationship between the transmittances at the three wavelengths of RGB is maintained in a predetermined state. The predetermined state means that the transmittance at the wavelength of the longest wave end in the spectrum corresponding to blue in the emission spectrum of the backlight is 545 nm (green) and 630 nm.
This is a state where the transmittance is always higher than the transmittance at the wavelength of (red).

Therefore, in the present invention, it is a condition that this relationship is always maintained, and an example of the liquid crystal display panel which satisfies the condition for defining this relationship is described as the above embodiment. .

[0105]

According to the present invention, the color tone fluctuation due to the voltage application can be suppressed by a simple configuration in which the spectral transmittance of the liquid crystal display panel is set to a predetermined relationship in accordance with the emission spectrum of the light source. Since a display defect due to a local change in the thickness of the liquid crystal layer can be suppressed, a horizontal electric field type liquid crystal display device having good display characteristics can be provided easily and at low cost.

[Brief description of the drawings]

FIG. 1 is a chromaticity diagram for explaining an effect of a liquid crystal display device according to the present invention.

FIG. 2 is an explanatory diagram that defines a rubbing direction and an axial direction of a polarizing plate in a liquid crystal display device.

FIG. 3 is a schematic diagram for explaining the operation of the in-plane switching mode liquid crystal display device according to the present invention.

FIG. 4 is an explanatory example of an electrode structure in a unit pixel in one embodiment of the liquid crystal display device according to the present invention.

FIG. 5 is an explanatory example of an electrode structure in a unit pixel in another embodiment of the liquid crystal display device according to the present invention.

FIG. 6 is an explanatory diagram of a color filter according to an embodiment of the present invention.

FIG. 7 is an explanatory diagram of a color filter according to another embodiment of the present invention.

FIG. 8 is a circuit diagram illustrating an example of a driving circuit of an active matrix type liquid crystal display panel.

FIG. 9 is a schematic configuration diagram showing one embodiment of a liquid crystal display device according to the present invention.

FIG. 10 is an emission spectrum diagram of a light source in one embodiment of the present invention.

FIG. 11 is a spectral transmittance characteristic diagram of the liquid crystal display panel according to one embodiment of the present invention.

FIG. 12 is a characteristic diagram showing voltage dependence of luminance of a liquid crystal display panel according to one embodiment of the present invention.

FIG. 13 is an explanatory diagram of a spectral transmittance characteristic of a conventional liquid crystal display panel.

FIG. 14 is a chromaticity diagram for explaining color tone fluctuation in a conventional example of a liquid crystal display panel.

FIG. 15 is a chromaticity diagram for explaining color tone fluctuation according to another conventional example of the liquid crystal display panel.

FIG. 16 is an explanatory diagram showing a gap margin enlarging effect according to an embodiment of the present invention and a comparative example according to the related art.

FIG. 17 is a transmittance characteristic diagram according to Example A of the present invention.

FIG. 18 is a transmittance characteristic diagram according to Example B of the present invention.

FIG. 19 is a transmittance characteristic diagram of Comparative Example C according to the related art.

FIG. 20 is a transmittance characteristic diagram of Comparative Example D according to the related art.

FIG. 21 is a graph showing transmittance characteristics with respect to wavelength of a liquid crystal display panel, showing retardation as a parameter.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Common electrode 2 Gate insulating film 3 Signal electrode 4 Pixel electrode 5 Alignment film 6 Liquid crystal molecule 7 Substrate 8 Polarizing plate 9 Electric field 10 Rubbing direction 11 Transmission axis of polarizing plate 12 Scanning electrode 13 Amorphous silicon 14 Thin film transistor element 16 Storage capacity 19 Control circuit Reference Signs List 20 vertical scanning circuit 21 video signal circuit 22 black matrix 23 active matrix type liquid crystal display element 24 color filter 25 protective film and flattening film 26 common electrode driving circuit 27 insulating film 30 light source 31 light cover 32 light guide 33 diffusion plate

Continuation of the front page (56) References JP-A-6-160878 (JP, A) JP-A-62-231218 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) G02F 1 / 1368 G02F 1/13357 G02F 1/139

Claims (2)

(57) [Claims] A first luminance maximum value in an emission wavelength region of 400 [nm] to 500 [nm], and 500 [n]
m] to 600 [nm], and has a second maximum luminance value within the emission wavelength range, from 600 [nm] to 700 [n].
m], a light source having a third maximum brightness value in the emission wavelength region, x represents a transmittance value at a wavelength indicating the first brightness maximum value, and x represents a transmittance value at a wavelength indicating the second brightness maximum value. Where y is the value of the transmittance at the wavelength indicating the third luminance maximum value, and z is the spectral transmittance characteristic of x>y> z throughout the transmittance control range.
An active matrix type liquid crystal panel that operates in a lateral electric field mode, wherein the light source is arranged on one surface of the liquid crystal panel, and an image is displayed on the other surface. Liquid crystal display device. 2. The liquid crystal panel according to claim 1, wherein, when the thickness of the liquid crystal layer is d _eff [nm] and the refractive index anisotropy of the liquid crystal is Δn, the product d _eff · Δn is When the wavelength λ is 490 [nm]
In this case, the liquid crystal display device is configured to satisfy a relationship of 200 [nm] ≦ d _eff · Δn ≦ 250 [nm].