TW201331679A - Electrical control birefringence type liquid crystal panel and liquid crystal display - Google Patents
Electrical control birefringence type liquid crystal panel and liquid crystal display Download PDFInfo
- Publication number
- TW201331679A TW201331679A TW101101708A TW101101708A TW201331679A TW 201331679 A TW201331679 A TW 201331679A TW 101101708 A TW101101708 A TW 101101708A TW 101101708 A TW101101708 A TW 101101708A TW 201331679 A TW201331679 A TW 201331679A
- Authority
- TW
- Taiwan
- Prior art keywords
- liquid crystal
- phase difference
- difference compensation
- compensation film
- substrate
- Prior art date
Links
Landscapes
- Liquid Crystal (AREA)
- Polarising Elements (AREA)
Abstract
Description
本發明係有關於一種液晶顯示裝置,特別是有關於一種電場控制雙折射模式之液晶面板。The present invention relates to a liquid crystal display device, and more particularly to a liquid crystal panel having an electric field controlled birefringence mode.
液晶顯示器(LCD)已廣泛地使用於資訊顯示領域。由於液晶材料本身的光學異向性(anisotropy),於不同方向觀看時,造成入射光看到不同的有效雙折射(birefringence)。因此,傳統的液晶顯示器的視角並不如自發光顯示器,例如陰極射線管(CRT)、有機電激發光顯示器(OLED)及電漿顯示器(PDP)的視角廣。Liquid crystal displays (LCDs) have been widely used in the field of information display. Due to the optical anisotropy of the liquid crystal material itself, the incident light sees different effective birefringence when viewed in different directions. Therefore, the viewing angle of a conventional liquid crystal display is not as wide as that of a self-luminous display such as a cathode ray tube (CRT), an organic electroluminescent display (OLED), and a plasma display (PDP).
圖1顯示先前技術之電場控制雙折射(ECB)模式之穿透型式液晶顯示裝置的立體分解圖。一液晶顯示裝置100包含一液晶面板110具有一第一基板112、一第二基板116以及一液晶層115配置於第一基板112與第二基板116之間。一第一偏光板160配置於液晶面板110的外側。一第二偏光板170配置於液晶面板110的外側。一負極性雙折射補償膜120配置於第一偏光板160與液晶面板110之間。一正極性雙折射補償膜130配置於第二偏光板170與液晶面板110之間。一四分之一波板(QWP)140以及一二分之一波板(HWP)145配置於第一偏光板160與負極性雙折射補償膜120之間。一二分之一波板150配置於第二偏光板170與正極性雙折射補償膜130之間。1 shows an exploded perspective view of a prior art electric field controlled birefringence (ECB) mode transmissive liquid crystal display device. A liquid crystal display device 100 includes a liquid crystal panel 110 having a first substrate 112, a second substrate 116, and a liquid crystal layer 115 disposed between the first substrate 112 and the second substrate 116. A first polarizing plate 160 is disposed outside the liquid crystal panel 110. A second polarizing plate 170 is disposed outside the liquid crystal panel 110. A negative polarity birefringence compensation film 120 is disposed between the first polarizing plate 160 and the liquid crystal panel 110. A positive polarity birefringence compensation film 130 is disposed between the second polarizing plate 170 and the liquid crystal panel 110. A quarter-wave plate (QWP) 140 and a half-wave plate (HWP) 145 are disposed between the first polarizing plate 160 and the negative polarity birefringence compensation film 120. The one-half wave plate 150 is disposed between the second polarizing plate 170 and the positive polarity birefringence compensation film 130.
根據本發明實施例,具有兩片不同極性雙折射的光學補償膜。上述兩片不同極性雙折射的光學補償膜彼此之間可相互補償。更明確地說,一入射光LI,例如源自背光模組(BLU),依序穿過第一偏光板160、二分之一波板145、四分之一波板140、負極性雙折射補償膜120、液晶面板110、正極性雙折射補償膜130、二分之一波板150以及第二偏光板170後,而到達觀看者。於液晶面板110中,具有一液晶層115包含電場控制雙折射(electrical control birefringence;ECB)液晶。上述液晶面板110中更包括兩配向層(未圖示),分別位於液晶層115與第一基板112的介面處,以及液晶層115與第二基板116的介面。液晶分子依配向層而排列,使其具一連續的預傾角(pre-tilt angle),介於範圍大約在5度至10度之間。液晶層的間隙厚度範圍大約為4.15微米(μm)。According to an embodiment of the invention, there are two optical compensation films of different polar birefringence. The above two optically compensated films of different polar birefringence can compensate each other. More specifically, an incident light L I , for example, originates from a backlight module (BLU), sequentially passes through the first polarizing plate 160, the half wave plate 145, the quarter wave plate 140, and the negative polarity double The refractive compensation film 120, the liquid crystal panel 110, the positive polarity birefringence compensation film 130, the half-wave plate 150, and the second polarizing plate 170 reach the viewer. In the liquid crystal panel 110, a liquid crystal layer 115 is provided with an electric control birefringence (ECB) liquid crystal. The liquid crystal panel 110 further includes two alignment layers (not shown) located at the interface between the liquid crystal layer 115 and the first substrate 112, and the interface between the liquid crystal layer 115 and the second substrate 116. The liquid crystal molecules are arranged in accordance with the alignment layer to have a continuous pre-tilt angle ranging between about 5 and 10 degrees. The gap thickness of the liquid crystal layer is approximately 4.15 micrometers (μm).
第一光學補償膜,例如具負極性雙折射(△n<0)的補償膜,包含碟狀(disk-like)液晶分子125。較佳的負極性雙折射(△n<0)補償膜的光軸範圍大約介於24度至79度之間。第二光學補償膜,例如具正極性雙折射(△n>0)的補償膜,包含棍狀(rod-like)液晶分子135。較佳的正極性雙折射(△n>0)補償膜的光軸範圍大約介於2度至52度之間。The first optical compensation film, for example, a compensation film having negative polarity birefringence (Δn < 0), includes disk-like liquid crystal molecules 125. The preferred negative polarity birefringence (Δn < 0) compensation film has an optical axis ranging between about 24 and 79 degrees. The second optical compensation film, for example, a compensation film having positive polarity birefringence (Δn>0), includes rod-like liquid crystal molecules 135. The preferred positive polarity birefringence (Δn > 0) compensation film has an optical axis ranging between about 2 and 52 degrees.
圖2顯示先前技術之各補償膜與液晶層間的極性關係圖。經補償後的液晶顯示裝置100利用不同極性的雙折射補償膜120與130,補償液晶面板110中液晶層的雙折射變化。由於負極性雙折射補償膜120與正極性雙折射補償膜130具不同的雙折射補償效果,因此雙折射補償膜120與130之間的雙折射變化亦得以補償,進而使得該液晶顯示器於白底模式(normally white)下,得到較寬廣的視角。Fig. 2 is a view showing the relationship between the polarity of each of the compensation films and the liquid crystal layer of the prior art. The compensated liquid crystal display device 100 compensates for the birefringence change of the liquid crystal layer in the liquid crystal panel 110 by using the birefringence compensation films 120 and 130 of different polarities. Since the negative polarity birefringence compensation film 120 and the positive polarity birefringence compensation film 130 have different birefringence compensation effects, the birefringence variation between the birefringence compensation films 120 and 130 is also compensated, thereby making the liquid crystal display on a white background. Under normal white, a wider viewing angle is obtained.
然而,上述電場控制雙折射(ECB)模式之穿透型式液晶顯示裝置之補償架構使用上下兩組二分之一波板、一組四分之一波板以及不同極性的雙折射補償膜,其製造成本較高。However, the compensation structure of the above-described electric field controlled birefringence (ECB) mode transmissive liquid crystal display device uses two upper and lower two-wave plates, one set of quarter-wave plates, and birefringence compensation films of different polarities. Higher manufacturing costs.
圖3A及3B顯示先前技術之電場控制雙折射(ECB)模式之半穿透半反射型式液晶顯示裝置的剖面分解圖。該液晶顯示裝置包含上下偏光板60、80、上下兩組二分之一波板(HWP)50、70、上下兩組四分之一波板(QWP)52、72及一液晶層40。圖3A顯示當未施加一電壓於電場控制雙折射(ECB)模式之液晶層40時,光線無法由內而外通過上偏光板60,以呈現黑暗畫面;圖3B顯示當施加一電壓於電場控制雙折射(ECB)模式之液晶層40時,光線可由內而外通過上偏光板60,以呈現明亮畫面。然而,上述電場控制雙折射(ECB)模式之穿透半反射型式液晶顯示裝置之補償架構使用上下兩組二分之一波板50、70及上下兩組四分之一波板52、72,其製造成本仍高。3A and 3B are cross-sectional exploded views of a prior art electric field controlled birefringence (ECB) mode transflective liquid crystal display device. The liquid crystal display device includes upper and lower polarizing plates 60 and 80, upper and lower two-part wave plates (HWP) 50 and 70, upper and lower two-quarter wave plates (QWP) 52 and 72, and a liquid crystal layer 40. 3A shows that when a voltage is applied to the liquid crystal layer 40 in the electric field controlled birefringence (ECB) mode, light cannot pass through the upper polarizing plate 60 from inside to outside to present a dark picture; FIG. 3B shows when a voltage is applied to the electric field control. In the liquid crystal layer 40 of the birefringence (ECB) mode, light can pass through the upper polarizing plate 60 from the inside to the outside to present a bright picture. However, the compensation structure of the above-described electric field controlled birefringence (ECB) mode transflective liquid crystal display device uses two upper and lower two-wave plates 50, 70 and two upper and lower quarter wave plates 52, 72, Its manufacturing costs are still high.
因此,便有需要提供一種電場控制雙折射(ECB)模式之液晶面板,能夠解決前述的問題。Therefore, there is a need to provide an electric field controlled birefringence (ECB) mode liquid crystal panel that can solve the aforementioned problems.
本發明提供一種電場控制雙折射模式之液晶面板包含:一彩色濾光基板及一薄膜電晶體基板;一液晶層,配置於該彩色濾光基板與薄膜電晶體基板之間,其中該液晶層包含電場控制雙折射模式之液晶,且該液晶層之上配向方向與該液晶層之下配向方向相反方向且平行;以及一相位差補償膜,配置於該彩色濾光基板之第一表面,其中該相位差補償膜之面內相位延遲值Re須介於190nm與380nm之間,而厚度方向相位延遲值Rth須介於95nm與190nm之間;以及一偏光板,配置於該相位差補償膜之第二表面,其中該偏光板與該彩色濾光基板之間只插置有該相位差補償膜。The present invention provides an electric field control birefringence mode liquid crystal panel comprising: a color filter substrate and a thin film transistor substrate; a liquid crystal layer disposed between the color filter substrate and the thin film transistor substrate, wherein the liquid crystal layer comprises The electric field controls the liquid crystal of the birefringence mode, and the alignment direction of the liquid crystal layer is opposite to the alignment direction of the liquid crystal layer and is parallel; and a phase difference compensation film is disposed on the first surface of the color filter substrate, wherein the The in-plane phase retardation value Re of the phase difference compensation film must be between 190 nm and 380 nm, and the thickness direction phase retardation value Rth must be between 95 nm and 190 nm; and a polarizing plate disposed on the phase difference compensation film The two surfaces, wherein the phase difference compensation film is interposed only between the polarizing plate and the color filter substrate.
由於本發明之液晶面板只需該相位差補償膜之最簡單補償架構,即可達到所需之廣視角的光學表現。相較於先前技術之補償架構,本發明之製造成本較低。Since the liquid crystal panel of the present invention requires only the simplest compensation structure of the phase difference compensation film, the optical performance of the wide viewing angle required can be achieved. The manufacturing cost of the present invention is lower than that of the prior art compensation architecture.
為了讓本發明之上述和其他目的、特徵、和優點能更明顯,下文將配合所附圖示,作詳細說明如下。The above and other objects, features, and advantages of the present invention will become more apparent from the accompanying drawings.
請參考圖4,其顯示本發明之第一實施例之電場控制雙折射(electrical control birefringence;ECB)模式之半穿透半反射型式液晶顯示裝置200。該半穿透半反射型式液晶顯示裝置200包含一液晶面板210及一背光模組290。該液晶面板210包含一彩色濾光基板220、一薄膜電晶體基板230、一液晶層240、一第一相位差補償膜250及一第二相位差補償膜270。該液晶層240配置於該彩色濾光基板220與薄膜電晶體基板230之間。該液晶層240包含電場控制雙折射模式之液晶。Referring to FIG. 4, there is shown a semi-transflective liquid crystal display device 200 of an electric control birefringence (ECB) mode according to a first embodiment of the present invention. The transflective liquid crystal display device 200 includes a liquid crystal panel 210 and a backlight module 290. The liquid crystal panel 210 includes a color filter substrate 220, a thin film transistor substrate 230, a liquid crystal layer 240, a first phase difference compensation film 250, and a second phase difference compensation film 270. The liquid crystal layer 240 is disposed between the color filter substrate 220 and the thin film transistor substrate 230. The liquid crystal layer 240 contains a liquid crystal in an electric field controlled birefringence mode.
就半穿透半反射型式而言,該彩色濾光基板220包含一透明基板222及一透明共同電極224,該透明共同電極224配置於該透明基板222與該液晶層240之間。該薄膜電晶體基板230包含一透明基板232及複數個畫素電極234,該些畫素電極234配置於該透明基板232與該液晶層240之間。每一畫素電極234可定義一畫素(pixel;P),並包含一透明電極234a及一反射電極234b,分別定義穿透區(T)及反射區(R)。換言之,單一畫素可分成兩個次畫素(sub-pixel),分別為穿透區(T)及反射區(R)。該背光模組290配置於該液晶面板210下方,用以提供光源通過該液晶面板之穿透區(T)。In the case of the transflective pattern, the color filter substrate 220 includes a transparent substrate 222 and a transparent common electrode 224 disposed between the transparent substrate 222 and the liquid crystal layer 240. The thin film transistor substrate 230 includes a transparent substrate 232 and a plurality of pixel electrodes 234 disposed between the transparent substrate 232 and the liquid crystal layer 240. Each pixel electrode 234 can define a pixel (pixel; P) and includes a transparent electrode 234a and a reflective electrode 234b, respectively defining a penetration region (T) and a reflection region (R). In other words, a single pixel can be divided into two sub-pixels, a penetration region (T) and a reflection region (R). The backlight module 290 is disposed under the liquid crystal panel 210 to provide a penetration region (T) of the light source through the liquid crystal panel.
該第一相位差補償膜250配置於該彩色濾光基板220之表面226,其中該表面226背對於該液晶層240。該彩色濾光基板220係位於該第一相位差補償膜250與該液晶層240之間。該第二相位差補償膜270配置於該薄膜電晶體基板230之表面236,其中該表面236背對於該液晶層240。該薄膜電晶體基板230係位於該第二相位差補償膜270與該液晶層240之間。The first phase difference compensation film 250 is disposed on the surface 226 of the color filter substrate 220, wherein the surface 226 is opposite to the liquid crystal layer 240. The color filter substrate 220 is located between the first phase difference compensation film 250 and the liquid crystal layer 240. The second phase difference compensation film 270 is disposed on the surface 236 of the thin film transistor substrate 230, wherein the surface 236 is opposite to the liquid crystal layer 240. The thin film transistor substrate 230 is located between the second phase difference compensation film 270 and the liquid crystal layer 240.
一第一偏光板(polarizer)260配置於該相位差補償膜250之表面252,其中該表面252背對於該彩色濾光基板220。該第一相位差補償膜250係位於第一偏光板260與該彩色濾光基板220之間。一第二偏光板(polarizer)280配置於該相位差補償膜270之表面272,其中該表面272背對於該薄膜電晶體基板230。該第二相位差補償膜270係位於第二偏光板280與該薄膜電晶體基板230之間。另外,為了方便該穿透區(T)內之該第二偏光板280及該第二相位差補償膜270的製造,該第二偏光板280及該第二相位差補償膜270亦可延伸至反該反射區(R)內。A first polarizer 260 is disposed on the surface 252 of the phase difference compensation film 250, wherein the surface 252 is opposite to the color filter substrate 220. The first phase difference compensation film 250 is located between the first polarizing plate 260 and the color filter substrate 220. A second polarizer 280 is disposed on the surface 272 of the phase difference compensation film 270, wherein the surface 272 is opposite to the thin film transistor substrate 230. The second phase difference compensation film 270 is located between the second polarizing plate 280 and the thin film transistor substrate 230. In addition, in order to facilitate the manufacture of the second polarizing plate 280 and the second phase difference compensation film 270 in the penetration region (T), the second polarizing plate 280 and the second phase difference compensation film 270 may also extend to Against the reflection zone (R).
應注意的是,該第一偏光板260與該彩色濾光基板220之間只插置有該第一相位差補償膜250;而該第二偏光板280與該薄膜電晶體基板230之間只插置有該第二相位差補償膜270。It should be noted that only the first phase difference compensation film 250 is interposed between the first polarizing plate 260 and the color filter substrate 220; and only between the second polarizing plate 280 and the thin film transistor substrate 230 The second phase difference compensation film 270 is interposed.
請參考圖5,在本實施例中,厚度為d之相位差補償膜的面內相位延遲值Re及厚度方向相位延遲值Rth的公式如下:Referring to FIG. 5, in the present embodiment, the formula of the in-plane phase retardation value Re and the thickness direction phase retardation value Rth of the phase difference compensation film having a thickness d is as follows:
Re=(nx-ny)×dRe=(n x -n y )×d
Rth=[(nx+ny)/2-nz]×dRth=[(n x +n y )/2-n z ]×d
其中:「nx」為面內之折射率為最大之方向(即,慢軸(slow axis)方向)之折射率,「ny」為於面內與慢軸垂直之方向(即,快軸(fast axis)方向)之折射率,「nz」為厚度方向之折射率。Where: "n x " is the refractive index of the direction in which the refractive index is the largest in the plane (ie, the direction of the slow axis), and "n y " is the direction perpendicular to the slow axis in the plane (ie, the fast axis) The refractive index of the (fast axis) direction, and "n z " is the refractive index in the thickness direction.
假設可見光之波長介於380nm與760nm之間,則該第一及第二相位差補償膜250、270之面內相位延遲值Re須介於190nm與380nm之間,而厚度方向相位延遲值Rth須介於95nm與190nm之間。較佳地,該第一及第二相位差補償膜250、270可為二分之一波板。Assuming that the wavelength of the visible light is between 380 nm and 760 nm, the in-plane phase retardation value Re of the first and second phase difference compensation films 250, 270 must be between 190 nm and 380 nm, and the thickness direction phase retardation value Rth is required. Between 95nm and 190nm. Preferably, the first and second phase difference compensation films 250, 270 may be a half wave plate.
請參考圖6,其顯示本發明之第一實施例之電場控制雙折射模式之半穿透半反射型式液晶顯示裝置200之部分立體示意圖,並定義有一XYZ座標軸。Please refer to FIG. 6, which is a partial perspective view of a transflective liquid crystal display device 200 of an electric field controlled birefringence mode according to a first embodiment of the present invention, and defines an XYZ coordinate axis.
就該穿透區(T)而言,沿Z軸正方向依序排列有該第二偏光板280、該第二相位差補償膜270、該液晶層240、該第一相位差補償膜250及該第一偏光板260。該第二偏光板280之吸收軸284與X軸之間夾有60度,該第二相位差補償膜270之慢軸(slow axis)286與X軸之間夾有130度,該液晶層240之上配向方向242與X軸之間夾有90度,該液晶層240之下配向方向244與X軸之間夾有270度(亦即,該液晶層240之上配向方向242與下配向方向244相反且平行),該第一相位差補償膜250之慢軸(slow axis)266與X軸之間夾有130度(亦即,該第一相位差補償膜250與該第二相位差補償膜270以相同方向而平行配置),且該第一偏光板260之吸收軸264與X軸之間夾有60度。In the penetration region (T), the second polarizing plate 280, the second phase difference compensation film 270, the liquid crystal layer 240, the first phase difference compensation film 250, and the second phase difference compensation film 270 are sequentially arranged in the positive direction of the Z axis. The first polarizing plate 260. The absorption axis 284 of the second polarizing plate 280 is sandwiched between 60 degrees and the X axis. The slow axis 286 of the second phase difference compensation film 270 is sandwiched between the X axis and the X axis. The liquid crystal layer 240 is sandwiched between the slow axis 286 and the X axis. The upper alignment direction 242 and the X-axis are sandwiched by 90 degrees, and the alignment direction 244 and the X-axis of the liquid crystal layer 240 are sandwiched by 270 degrees (that is, the alignment direction 242 and the lower alignment direction of the liquid crystal layer 240). 244 is opposite and parallel), the slow axis 266 of the first phase difference compensation film 250 is sandwiched between the X axis and 130 degrees (that is, the first phase difference compensation film 250 and the second phase difference compensation) The films 270 are arranged in parallel in the same direction, and the absorption axis 264 of the first polarizing plate 260 is sandwiched between the X-axis and 60 degrees.
就該反射區(R)而言,沿Z軸正方向依序排列有該反射電極234b、該液晶層240、該第一相位差補償膜250及該第一偏光板260。同樣地,該液晶層240之上配向方向242與X軸之間夾有90度,該液晶層240之下配向方向244與X軸之間夾有270度(亦即,該液晶層240之上配向方向242與下配向方向244相反且平行),該第一相位差補償膜250之慢軸(slow axis)266與X軸之間夾有130度,且該第一偏光板260之吸收軸264與X軸之間夾有60度。In the reflection region (R), the reflective electrode 234b, the liquid crystal layer 240, the first phase difference compensation film 250, and the first polarizing plate 260 are sequentially arranged in the positive direction of the Z axis. Similarly, the alignment direction 242 of the liquid crystal layer 240 is 90 degrees between the X-axis, and the alignment direction 244 of the liquid crystal layer 240 is sandwiched between the X-axis by 270 degrees (that is, above the liquid crystal layer 240). The alignment direction 242 is opposite to and parallel to the lower alignment direction 244. The slow axis 266 of the first phase difference compensation film 250 is sandwiched between the X axis and 130 degrees, and the absorption axis 264 of the first polarizing plate 260 is 264. 60 degrees between the X axis and the X axis.
請再參考圖4,在該反射區(R)(亦即該反射電極位置)的該彩色濾光基板220與薄膜電晶體基板230之間隙為一第一間隙D1,在該穿透區(T)(亦即該透明電極位置)的該彩色濾光基板220與薄膜電晶體基板230之間隙為一第二間隙D2。較佳地,可藉由模擬計算,先假設該第二間隙D2與該第一間隙D1之比例數據關係,計算出該穿透區(T)之電壓與穿透率的曲線和該反射區(R)之電壓與反射率的曲線須相吻合(match),再反推知該第二間隙D2與該第一間隙D1之比例關係,例如在本實施例中,該第二間隙D2可為該第一間隙D1之兩倍。Referring to FIG. 4 again, the gap between the color filter substrate 220 and the thin film transistor substrate 230 in the reflective region (R) (ie, the position of the reflective electrode) is a first gap D1 in which the penetration region (T) The gap between the color filter substrate 220 and the thin film transistor substrate 230 is a second gap D2. Preferably, by calculating a ratio, the relationship between the voltage and the transmittance of the penetration region (T) and the reflection region can be calculated by a simulation calculation. The voltage of R) and the reflectance curve are matched, and the relationship between the second gap D2 and the first gap D1 is inversely inferred. For example, in this embodiment, the second gap D2 may be the first One double of the gap D1.
請參考圖7,其顯示穿透區(T)之施加電壓(applied voltage)與穿透率(Transmittance)和反射區(R)之施加電壓(applied voltage)與反射率(Reflectance)的曲線圖。由於該穿透區(T)之施加電壓與穿透率的曲線和該反射區(R)之施加電壓與反射率的曲線相吻合(match),因此該穿透區(T)和該反射區(R)不需由兩個薄膜電晶體分別驅動,而只需單一薄膜電晶體驅動即可,進而可降低成本。Please refer to FIG. 7 , which shows a graph of applied voltage and transmittance of the penetrating region (T) and applied voltage and reflectance of the reflective region (R). The penetration region (T) and the reflection region are matched by a curve of the applied voltage and the transmittance of the penetration region (T) and a curve of the applied voltage of the reflection region (R) and the reflectance. (R) does not need to be driven by two thin film transistors, but only a single thin film transistor can be driven, thereby reducing the cost.
請參考圖8,其顯示本實施例之具有該第一及第二相位差補償膜之穿透區(T-mode)及反射區(R-mode)之視角圖,其顯示在液晶面板之條件(穿透區之第一間隙D1為3.8 μm,反射區之第二間隙D2為1.9 μm,液晶之預傾角為4度,第一及第二相位差補償膜250、270之面內相位延遲值Re皆為270nm,而厚度方向相位延遲值Rth皆為135nm)下的模擬結果。請參考圖9,其顯示沒有具有相位差補償膜之穿透區(T)及反射區(R)之視角圖。相較於圖9,圖8確實顯示本發明之視角增大。Please refer to FIG. 8 , which shows a perspective view of a T-mode and a reflective region (R-mode) of the first and second phase difference compensation films of the present embodiment, which are displayed on a liquid crystal panel. (The first gap D1 of the penetration region is 3.8 μm, the second gap D2 of the reflection region is 1.9 μm, the pretilt angle of the liquid crystal is 4 degrees, and the in-plane phase retardation values of the first and second phase difference compensation films 250, 270 The simulation results were obtained under the condition that Re is 270 nm and the thickness direction phase retardation value Rth is 135 nm. Please refer to FIG. 9, which shows a perspective view of a penetration region (T) and a reflection region (R) having no phase difference compensation film. Compared to Figure 9, Figure 8 does show an increase in the viewing angle of the present invention.
由於本發明之液晶面板只需該第一及第二相位差補償膜之最簡單補償架構,即可達到所需之廣視角的光學表現。相較於先前技術之補償架構,本發明之製造成本較低。Since the liquid crystal panel of the present invention requires only the simplest compensation structure of the first and second phase difference compensation films, the optical performance of the desired wide viewing angle can be achieved. The manufacturing cost of the present invention is lower than that of the prior art compensation architecture.
請參考圖10,其顯示本發明之第二實施例之電場控制雙折射(electrical control birefringence;ECB)模式之反射型式液晶顯示裝置300。該反射型式液晶顯示裝置300包含一液晶面板310,該液晶面板310包含一彩色濾光基板320、一薄膜電晶體基板330、一液晶層340及一相位差補償膜350。Please refer to FIG. 10, which shows an electric field control birefringence (ECB) mode reflective liquid crystal display device 300 according to a second embodiment of the present invention. The reflective liquid crystal display device 300 includes a liquid crystal panel 310 including a color filter substrate 320, a thin film transistor substrate 330, a liquid crystal layer 340, and a phase difference compensation film 350.
就反射型式而言,單一畫素(pixel;P)只有反射區(R),亦即每一畫素電極334只包含一反射電極334b,定義一反射區(R)。該反射型式液晶顯示裝置300之反射區(R)內的元件(例如反射電極334b、液晶層340、相位差補償膜350及偏光板360)配置大體上類似於該半穿透半反射型式液晶顯示裝置200之反射區(R)內的元件配置,類似的元件標示類似標號。該反射型式液晶顯示裝置300之反射區(R)內的元件(例如反射電極334b、液晶層340、相位差補償膜350及偏光板360)功能及整體功效大體上類似於該半穿透半反射型式液晶顯示裝置200之反射區(R)內的元件功能及整體功效,相同說明毋庸贅述。In the case of the reflection pattern, the single pixel (pixel; P) has only the reflection area (R), that is, each pixel electrode 334 includes only one reflection electrode 334b, defining a reflection area (R). The components (for example, the reflective electrode 334b, the liquid crystal layer 340, the phase difference compensation film 350, and the polarizing plate 360) in the reflective region (R) of the reflective liquid crystal display device 300 are substantially similar in configuration to the transflective liquid crystal display. Component configurations within the reflective region (R) of device 200, like components are numbered similarly. The functions and overall functions of the elements (for example, the reflective electrode 334b, the liquid crystal layer 340, the phase difference compensation film 350, and the polarizing plate 360) in the reflective region (R) of the reflective liquid crystal display device 300 are substantially similar to the transflective reflection. The function of the elements in the reflective region (R) of the type liquid crystal display device 200 and the overall effect are not described in the same description.
請參考圖11,其顯示本發明之第三實施例之電場控制雙折射(electrical control birefringence;ECB)模式之穿透型式液晶顯示裝置400。該穿透型式液晶顯示裝置400包含一液晶面板410及一背光模組490。該液晶面板410包含一彩色濾光基板420、一薄膜電晶體基板430、一液晶層440、一第一相位差補償膜450及一第二相位差補償膜470。Please refer to FIG. 11, which shows an electric field control birefringence (ECB) mode transmissive liquid crystal display device 400 according to a third embodiment of the present invention. The transmissive liquid crystal display device 400 includes a liquid crystal panel 410 and a backlight module 490. The liquid crystal panel 410 includes a color filter substrate 420, a thin film transistor substrate 430, a liquid crystal layer 440, a first phase difference compensation film 450, and a second phase difference compensation film 470.
就穿透型式而言,單一畫素(pixel;P)只有穿透區(T),亦即每一畫素電極434只包含一透明電極434a,定義一穿透區(T)。該反射型式液晶顯示裝置400之穿透區(T)內的元件(例如第二偏光板480、第二相位差補償膜470、液晶層440、第一相位差補償膜450及第一偏光板460)配置大體上類似於該半穿透半反射型式液晶顯示裝置200之穿透區(T)內的元件配置,類似的元件標示相同標號。再者,該反射型式液晶顯示裝置400之穿透區(T)內的元件(例如第二偏光板480、第二相位差補償膜470、液晶層440、第一相位差補償膜450及第一偏光板460)功能及整體功效大體上類似於該半穿透半反射型式液晶顯示裝置200之穿透區(T)內的元件功能及整體功效,相同說明毋庸贅述。In terms of the penetration pattern, the single pixel (pixel; P) has only the penetration region (T), that is, each pixel electrode 434 includes only one transparent electrode 434a, defining a penetration region (T). The components in the penetration region (T) of the reflective liquid crystal display device 400 (for example, the second polarizing plate 480, the second phase difference compensation film 470, the liquid crystal layer 440, the first phase difference compensation film 450, and the first polarizing plate 460) The configuration is substantially similar to the component configuration within the penetration region (T) of the transflective liquid crystal display device 200, like elements being designated by like reference numerals. Furthermore, elements in the penetration region (T) of the reflective liquid crystal display device 400 (for example, the second polarizing plate 480, the second phase difference compensation film 470, the liquid crystal layer 440, the first phase difference compensation film 450, and the first The function and overall efficiency of the polarizing plate 460) are substantially similar to the function of the element and the overall function in the penetration region (T) of the transflective liquid crystal display device 200, and the same description will not be repeated.
綜上所述,乃僅記載本發明為呈現解決問題所採用的技術手段之實施方式或實施例而已,並非用來限定本發明專利實施之範圍。即凡與本發明專利申請範圍文義相符,或依本發明專利範圍所做的均等變化與修飾,皆為本發明專利範圍所涵蓋。In the above, it is merely described that the present invention is an embodiment or an embodiment of the technical means for solving the problem, and is not intended to limit the scope of implementation of the present invention. That is, the equivalent changes and modifications made in accordance with the scope of the patent application of the present invention or the scope of the invention are covered by the scope of the invention.
40...液晶層40. . . Liquid crystal layer
50...二分之一波板50. . . One-half wave plate
52...四分之一波板52. . . Quarter wave plate
60...偏光板60. . . Polarizer
70...二分之一波板70. . . One-half wave plate
72...四分之一波板72. . . Quarter wave plate
80...偏光板80. . . Polarizer
100...液晶顯示裝置100. . . Liquid crystal display device
110...液晶面板110. . . LCD panel
112...第一基板112. . . First substrate
115...液晶層115. . . Liquid crystal layer
116...第二基板116. . . Second substrate
120...負極性雙折射補償膜120. . . Negative polarity birefringence compensation film
125...碟狀液晶分子125. . . Dish liquid crystal molecule
135...棍狀液晶分子135. . . Stick liquid crystal molecule
130...正極性雙折射補償膜130. . . Positive polarity birefringence compensation film
140...四分之一波板140. . . Quarter wave plate
145...二分之一波板145. . . One-half wave plate
150...二分之一波板150. . . One-half wave plate
160...第一偏光板160. . . First polarizer
170...第二偏光板170. . . Second polarizer
200...液晶顯示裝置200. . . Liquid crystal display device
210...液晶面板210. . . LCD panel
220...彩色濾光基板220. . . Color filter substrate
222...透明基板222. . . Transparent substrate
224...透明共同電極224. . . Transparent common electrode
226...表面226. . . surface
230...薄膜電晶體基板230. . . Thin film transistor substrate
232...透明基板232. . . Transparent substrate
234...畫素電極234. . . Pixel electrode
236...表面236. . . surface
234a...透明電極234a. . . Transparent electrode
234b...反射電極234b. . . Reflective electrode
240...液晶層240. . . Liquid crystal layer
242...上配向方向242. . . Upper alignment direction
244...下配向方向244. . . Lower alignment direction
250...相位差補償膜250. . . Phase difference compensation film
252...表面252. . . surface
260...偏光板260. . . Polarizer
264...吸收軸264. . . Absorption axis
266...慢軸266. . . Slow axis
270...相位差補償膜270. . . Phase difference compensation film
272...表面272. . . surface
280...偏光板280. . . Polarizer
284...吸收軸284. . . Absorption axis
286...慢軸286. . . Slow axis
290...背光模組290. . . Backlight module
300...液晶顯示裝置300. . . Liquid crystal display device
310...液晶面板310. . . LCD panel
320...彩色濾光基板320. . . Color filter substrate
330...薄膜電晶體基板330. . . Thin film transistor substrate
334...畫素電極334. . . Pixel electrode
334b...反射電極334b. . . Reflective electrode
340...液晶層340. . . Liquid crystal layer
350...相位差補償膜350. . . Phase difference compensation film
360...偏光板360. . . Polarizer
400...液晶顯示裝置400. . . Liquid crystal display device
410...液晶面板410. . . LCD panel
420...彩色濾光基板420. . . Color filter substrate
430...薄膜電晶體基板430. . . Thin film transistor substrate
434...畫素電極434. . . Pixel electrode
434a...透明電極434a. . . Transparent electrode
440...液晶層440. . . Liquid crystal layer
450...相位差補償膜450. . . Phase difference compensation film
460...偏光板460. . . Polarizer
470...相位差補償膜470. . . Phase difference compensation film
480...偏光板480. . . Polarizer
490...背光模組490. . . Backlight module
D1...第一間隙D1. . . First gap
D2...第二間隙D2. . . Second gap
d...厚度d. . . thickness
LI...入射光L I . . . Incident light
P...畫素P. . . Pixel
R...反射區R. . . Reflection zone
T...穿透區T. . . Penetration zone
圖1顯示先前技術之電場控制雙折射(ECB)模式之穿透型式液晶顯示裝置的立體分解圖;1 shows an exploded perspective view of a prior art electric field controlled birefringence (ECB) mode transmissive liquid crystal display device;
圖2顯示先前技術之各補償膜與液晶層間的極性關係圖;Figure 2 is a view showing the relationship between the polarity of each compensation film and the liquid crystal layer of the prior art;
圖3A及3B顯示先前技術之電場控制雙折射(ECB)模式之半穿透半反射型式液晶顯示裝置的剖面分解圖;3A and 3B are cross-sectional exploded views of a transflective liquid crystal display device of the prior art electric field controlled birefringence (ECB) mode;
圖4為本發明之第一實施例之電場控制雙折射模式之半穿透半反射型式液晶顯示裝置之剖面示意圖;4 is a cross-sectional view showing a transflective liquid crystal display device of an electric field controlled birefringence mode according to a first embodiment of the present invention;
圖5顯示本發明之相位差補償膜的nx、ny及nz之關係;Figure 5 is a view showing the relationship of n x , n y and n z of the phase difference compensation film of the present invention;
圖6為本發明之第一實施例之電場控制雙折射模式之半穿透半反射型式液晶顯示裝置之部分立體示意圖;6 is a partial perspective view of a transflective liquid crystal display device of an electric field controlled birefringence mode according to a first embodiment of the present invention;
圖7顯示穿透區(T)之施加電壓與穿透率和反射區(R)之施加電壓與反射率的曲線圖;Figure 7 is a graph showing the applied voltage and transmittance of the penetration region (T) and the applied voltage and reflectance of the reflection region (R);
圖8顯示本實施例之具有該第一及第二相位差補償膜之穿透區(T)及反射區(R)之視角圖;8 is a perspective view showing a penetration region (T) and a reflection region (R) of the first and second phase difference compensation films of the present embodiment;
圖9顯示沒有具有該第一及第二相位差補償膜之穿透區(T)及反射區(R)之視角圖;Figure 9 is a view showing a perspective view of a penetration region (T) and a reflection region (R) having the first and second phase difference compensation films;
圖10為本發明之第二實施例之電場控制雙折射模式之反射型式液晶顯示裝置之剖面示意圖;以及Figure 10 is a cross-sectional view showing a reflection type liquid crystal display device of an electric field controlled birefringence mode according to a second embodiment of the present invention;
圖11為本發明之第三實施例之電場控制雙折射模式之穿透型式液晶顯示裝置之剖面示意圖。Figure 11 is a cross-sectional view showing a transmission type liquid crystal display device of an electric field controlled birefringence mode according to a third embodiment of the present invention.
200...液晶顯示裝置200. . . Liquid crystal display device
210...液晶面板210. . . LCD panel
220...彩色濾光基板220. . . Color filter substrate
222...透明基板222. . . Transparent substrate
224...透明共同電極224. . . Transparent common electrode
226...表面226. . . surface
230...薄膜電晶體基板230. . . Thin film transistor substrate
232...透明基板232. . . Transparent substrate
234...畫素電極234. . . Pixel electrode
236...表面236. . . surface
234a...透明電極234a. . . Transparent electrode
234b...反射電極234b. . . Reflective electrode
240...液晶層240. . . Liquid crystal layer
250...相位差補償膜250. . . Phase difference compensation film
252...表面252. . . surface
260...偏光板260. . . Polarizer
270...相位差補償膜270. . . Phase difference compensation film
272...表面272. . . surface
280...偏光板280. . . Polarizer
290...背光模組290. . . Backlight module
D1...第一間隙D1. . . First gap
D2...第二間隙D2. . . Second gap
P...畫素P. . . Pixel
R...反射區R. . . Reflection zone
T...穿透區T. . . Penetration zone
Claims (13)
Priority Applications (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| TW101101708A TWI493260B (en) | 2012-01-17 | 2012-01-17 | Electrical control birefringence type liquid crystal panel and liquid crystal display |
| CN201210163096.4A CN103207478B (en) | 2012-01-17 | 2012-05-23 | Liquid crystal panel with electric field controlled birefringence mode and liquid crystal display device thereof |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| TW101101708A TWI493260B (en) | 2012-01-17 | 2012-01-17 | Electrical control birefringence type liquid crystal panel and liquid crystal display |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| TW201331679A true TW201331679A (en) | 2013-08-01 |
| TWI493260B TWI493260B (en) | 2015-07-21 |
Family
ID=48754749
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| TW101101708A TWI493260B (en) | 2012-01-17 | 2012-01-17 | Electrical control birefringence type liquid crystal panel and liquid crystal display |
Country Status (2)
| Country | Link |
|---|---|
| CN (1) | CN103207478B (en) |
| TW (1) | TWI493260B (en) |
Families Citing this family (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN203930105U (en) * | 2014-06-26 | 2014-11-05 | 京东方科技集团股份有限公司 | Flexible membrane, organic LED display panel and display device |
| US9761642B2 (en) | 2015-05-22 | 2017-09-12 | Microsoft Technology Licensing, Llc | Transflective OLED display |
| CN114839815A (en) * | 2021-02-01 | 2022-08-02 | 中强光电股份有限公司 | Display device |
Family Cites Families (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| KR100601916B1 (en) * | 2003-11-21 | 2006-07-14 | 주식회사 엘지화학 | In-plane switching liquid crystal display comprising compensation film for angular field of view using positive biaxial retardation film |
| JP4663285B2 (en) * | 2004-09-22 | 2011-04-06 | 富士フイルム株式会社 | Liquid crystal display device |
| TWI340846B (en) * | 2006-08-04 | 2011-04-21 | Au Optronics Corp | Pixel structure of a transflective liquid crystal panel having a single gap |
| KR20080037801A (en) * | 2006-10-27 | 2008-05-02 | 삼성전자주식회사 | Transflective liquid crystal display and method for manufacturing the same |
| JP2012519886A (en) * | 2009-03-09 | 2012-08-30 | ピクセル チー コーポレイション | Normally black reflective / transmissive LCD |
-
2012
- 2012-01-17 TW TW101101708A patent/TWI493260B/en active
- 2012-05-23 CN CN201210163096.4A patent/CN103207478B/en active Active
Also Published As
| Publication number | Publication date |
|---|---|
| CN103207478B (en) | 2016-02-10 |
| TWI493260B (en) | 2015-07-21 |
| CN103207478A (en) | 2013-07-17 |
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| JP6820417B2 (en) | Display device | |
| US11126042B2 (en) | Horizontal electric field type display panel, method of manufacturing the same, and display device | |
| US7940358B2 (en) | Liquid crystal display device and manufacturing method thereof | |
| US7643116B2 (en) | Liquid crystal display device | |
| US8018553B2 (en) | Liquid crystal display device that includes both a transmissive portion and a reflective portion | |
| KR20090101620A (en) | Polarizer intergally containing view angle compensating film and in plane switching liquid crystal display | |
| JP4566946B2 (en) | Transflective liquid crystal display device with high transmittance and wide viewing angle | |
| JP3538149B2 (en) | Reflection type liquid crystal display device and manufacturing method thereof | |
| US9140937B2 (en) | Display panel | |
| JP6887525B2 (en) | Display device | |
| JP2014215348A (en) | Liquid crystal panel | |
| JP2014215347A (en) | Liquid crystal panel | |
| JP2007163722A (en) | Liquid crystal device, its manufacturing method, optical retardation plate and electronic device | |
| JP2007304498A (en) | Liquid crystal display | |
| JP2009104016A (en) | Liquid crystal display | |
| US7394512B2 (en) | Liquid crystal display device | |
| TWI493260B (en) | Electrical control birefringence type liquid crystal panel and liquid crystal display | |
| JP2010026091A (en) | Circularly polarizing plate and liquid crystal display device | |
| US7382427B2 (en) | Liquid crystal display device | |
| US7787083B2 (en) | Liquid crystal device and electronic apparatus | |
| US9007548B2 (en) | Wide view angle liquid crystal display device operating in normally white mode | |
| US20090147187A1 (en) | Transflective liquid crystal display | |
| US8681294B2 (en) | Optical compensation film for LCD viewing angles reduction | |
| JP2006208531A (en) | Liquid crystal display device | |
| JP2007121490A (en) | Liquid crystal display element |