CN205809480U - A kind of display base plate and display floater - Google Patents

Abstract

The utility model discloses a kind of display base plate, including underlay substrate and the photic zone being arranged on described underlay substrate, wherein, described display base plate also includes antireflection layer, described antireflection layer is made up more than the transparent material of described euphotic refractive index of refractive index, and described antireflection layer is arranged on described euphotic light emission side.This utility model additionally provides a kind of display floater.The display base plate of this utility model offer and display floater improve the display effect of display device.

Description

A kind of display base plate and display floater

Technical field

This utility model relates to Display Technique field, is specifically related to a kind of display base plate and includes the display of this display base plate Panel.

Background technology

At present, due to liquid crystal display, there is the features such as volume is little, low in energy consumption, radiationless, it has also become flat pannel display at present Main product in device.Liquid crystal display mainly includes array base palte and the color membrane substrates arranging box, and backlight etc., Wherein color membrane substrates is the important component part of liquid crystal display, is also the key component affecting display effect.

Fig. 1 show the structural representation of color membrane substrates of the prior art.Generally, the color membrane substrates in liquid crystal display Including RGB (RGB) three primary colors coloured silk film layer.On the one hand, the light that backlight sends is capable of image through after color film layer Colorization；On the other hand, the light that backlight is sent by color film layer the most simultaneously produces color blocking, the light meeting i.e. sent backlight There is obstruction so that the light that backlight sends can not cause light penetration relatively low completely through color film layer, thus affect liquid crystal The display effect of display device.Further, since do not have selectivity when light is through color film layer, the light of each wavelength has certain journey Passing through of degree, has dragged down the colour gamut of liquid crystal display.

Utility model content

The purpose of this utility model is to provide a kind of display base plate and display floater, to solve of the prior art asking Topic.

For achieving the above object, as first aspect of the present utility model, it is provided that a kind of display base plate, including substrate base Plate and the photic zone being arranged on described underlay substrate, wherein, described display base plate also includes antireflection layer, and described antireflection layer is by rolling over Rate of penetrating is made more than the transparent material of described euphotic refractive index, and described antireflection layer be arranged on described euphotic go out light Side.

Preferably, following relation is met between the wavelength of the light of the thickness of described antireflection layer and described photic zone outgoing Formula:

D=n* λ/4,

Wherein, D is the thickness of described antireflection layer；

N is odd number；

λ is the wavelength of the light of described photic zone outgoing.

Preferably, described display base plate is color membrane substrates, and described photic zone is color film layer, and described color film layer is divided into many Individual pixel cell, each described pixel cell is divided into multiple sub-pixel unit, is provided with in each described sub-pixel unit The color of the multiple described color blocking block in one color blocking block, and same described pixel cell is different, described antireflection layer bag Include the multiple and described the most anti-reflection unit of color blocking block.

Preferably, between described color film layer and described underlay substrate or described underlay substrate is positioned at institute to described antireflection layer State between antireflection layer and described color film layer.

Preferably, described color blocking block includes red color resistance block, green color blocking block and blue color blocking block,

Thickness D with the described anti-reflection unit corresponding to described red color resistance block_R=n* λ '_R/ 4, wherein λ '_RFor 690nm；

Thickness D with the described anti-reflection unit corresponding to described green color blocking block_G=n* λ '_G/ 4, wherein λ '_GFor 535.5nm；

Thickness D with the described anti-reflection unit corresponding to described blue color blocking block_B=n* λ '_B/ 4, wherein λ '_BFor 467.5nm。

Preferably, described display base plate also includes the black matrix being arranged on described underlay substrate, the thickness of described antireflection layer Degree is less than or equal to the thickness of described black matrix.

Preferably, the thickness of described black matrix is

Preferably, described display base plate also includes being arranged on the surface deviating from described underlay substrate of described color film layer Protective layer and the chock insulator matter being arranged on described protective layer.

Preferably, described display base plate also includes being arranged on the surface deviating from described color film layer of described underlay substrate Static electricity shield layer, described static electricity shield layer is made up of indium tin oxide material.

Preferably, described display base plate is array base palte, and described photic zone is planarization layer.

As second aspect of the present utility model, it is provided that a kind of display floater, described display floater includes display base plate, Described display base plate includes previously described display base plate.

The display base plate that this utility model provides arranges antireflection layer, and selects refractive index to be more than the material of euphotic refractive index Antireflection layer made by material, can strengthen the transmitance of light according to anti-reflection principle, solve the light that backlight in prior art sends Line is obstructed the problem causing transmitance low, is effectively improved the display effect of liquid crystal indicator.This utility model provides Display floater there is the advantage that colour gamut is high, display effect is good.

Accompanying drawing explanation

Accompanying drawing is used to offer and is further appreciated by of the present utility model, and constitutes a part for description, with following Detailed description of the invention be used for explaining this utility model together, but be not intended that restriction of the present utility model.In the accompanying drawings:

Fig. 1 is the structural representation of color membrane substrates in prior art；

Fig. 2 is fiber-loss occurring principle figure in anti-reflection principle；

Fig. 3 is the anti-reflection phase place schematic diagram of the thin film in this utility model；

Fig. 4 is a kind of structural representation of display base plate of the present utility model；

Fig. 5 be display base plate of the present utility model be the first embodiment structural representation during color membrane substrates；

Fig. 6 be display base plate of the present utility model be the second embodiment structural representation during color membrane substrates；

Fig. 7 be display base plate of the present utility model be the third embodiment structural representation during color membrane substrates；

Fig. 8 is the display base plate of the present utility model a kind of structural representation when being array base palte；

Fig. 9 is the structural representation of display floater of the present utility model.

10, underlay substrate；11, black matrix；12, photic zone；121, color film layer；122, planarization layer；13, antireflection layer；14、 Protective layer；15, chock insulator matter；16, static electricity shield layer；17, upper polaroid；20, light source；21, lower polaroid；22, TFT substrate；23、 Liquid crystal.

Detailed description of the invention

Below in conjunction with accompanying drawing, detailed description of the invention of the present utility model is described in detail.It should be appreciated that herein Described detailed description of the invention is merely to illustrate and explains this utility model, is not limited to this utility model.

It is based on anti-reflection former owing to the display base plate of this utility model offer strengthens the detailed description of the invention of light penetration Reason realizes, and for enabling those skilled in the art's clearer understanding detailed description of the invention of the present utility model, first combines Fig. 2 and Fig. 3 is as follows to anti-reflection principles and methods.

The medium of refractive index less (light spread speed wherein is bigger) is called optically thinner medium, and refractive index is relatively big, and (light is at it Middle spread speed is less) medium be called optically denser medium.When light is entered thin film by air and is entered glass by thin film, i.e. light Line is entered into optically denser medium by optically thinner medium, and front and back incident illumination all can be caused light loss by the luminous reflectance phenomenon of twice, works as thin film The when that thickness being designed as the 1/4 of certain quasi-optical wave length, reflection light 1 in Fig. 2, reflection light 2 will due to phase contrast just The effect cancelled out each other is produced, due to preservation of energy, as it is shown on figure 3, transmission light I correspondence ripple A, transmission light II are corresponding for pi/2 Ripple B, transmission light I and transmission light II can produce complementary effect, thus realize strengthening the purpose of transmitance.

About the explanation of light loss, as in figure 2 it is shown, light S is n by refractive index₀Material to be injected into refractive index be n₁Thing In matter, it can be seen that angle of incidence is i in figure, refraction angle is r, due to the difference of refractive index, light when through both interfaces, Have the reflection of some light, formed such as the reflection light 1 in Fig. 2.When light S is n by refractive index₁Material incide refraction Rate is n₂Material time, be n in refractive index₁Material and refractive index be n₂Material interface on occur secondary reflection, through refraction Rate is n₁Material and refractive index be n₀Material interface refraction after form reflection light 2, reflection light 1 and reflection light 2 The main cause causing light loss, and reflect below light 3 and transmitted ray III etc. have passed through repeatedly reflect and reflect after shape Becoming, its light intensity is the most weak to be negligible.

It is understood that incident ray advances in optically thinner medium, when running into optically denser medium interface, graze or hang down In the case of straight incident two kinds, producing half wave loss in reflection process, this is for the vibration of the electric field vector of light. If incident ray advances in optically denser medium, when running into the interface of optically thinner medium, do not produce half wave loss.Either graze or Person's vertical incidence, the direction of vibration of refraction light will not occur half wave loss relative to the direction of vibration of incident illumination.Therefore, 1/4 ripple Long thickness is just so that light reaches the purpose offset, and according to preservation of energy, the part of counteracting does not disappear but passes through.

Based on principles above, as first aspect of the present utility model, as shown in Figure 4, it is provided that a kind of display base plate, bag Include underlay substrate 10 and the photic zone 12 being arranged on underlay substrate 10, wherein, described display base plate also bag antireflection layer 13, anti-reflection Layer 13 is made up more than the transparent material of refractive indexs of photic zone 12 of refractive index, and antireflection layer 13 be arranged on photic zone 12 go out light Side.

The display base plate that this utility model provides, by arranging antireflection layer, and selects refractive index to be more than euphotic refraction Antireflection layer made by the material of rate, can strengthen the transmitance of light according to anti-reflection principle, solves backlight in prior art and sends out The light gone out is obstructed the problem causing transmitance low, is effectively improved the display effect of liquid crystal indicator.

Antireflection layer 13 is arranged on the light emission side of photic zone 12, according to previously described anti-reflection principle, the thickness of antireflection layer 13 With the wavelength positive correlation of the light that photic zone 12 passes through, i.e. the wavelength of the light that photic zone 12 passes through is the longest, the thickness of antireflection layer 13 Degree needs the thickest of setting.Specifically, below meeting between the wavelength of the light of the thickness of antireflection layer 13 and photic zone 12 outgoing Relational expression:

D=n* λ/4,

Wherein, D is the thickness of antireflection layer 13；

N is odd number；

λ is the wavelength of photic zone 12 emergent ray.

As one specifically embodiment, when described display base plate is color membrane substrates, photic zone 12 can be color film Layer 121, specifically, color film layer 121 is divided into multiple pixel cell, and each described pixel cell is divided into multiple sub-pix Unit, is provided with the multiple described color in a color blocking block, and same described pixel cell in each described sub-pixel unit The color of stop block is different.

It is understood that the refractive index of previously described antireflection layer 13 is more than the refractive index of photic zone 12, specifically, increase The refractive index of permeable layers 13 is more than the refractive index of described color blocking block.

Antireflection layer 13 is arranged on the light emission side of color film layer 121, is preferably carried out mode as one, and antireflection layer 13 is positioned at coloured silk Between film layer 121 and underlay substrate 10, as it is shown in figure 5, the homonymy at the underlay substrate 10 of described color membrane substrates sets gradually increasing Permeable layers 13 and color film layer 121, and antireflection layer 13 selects is that the material of the refractive index that refractive index is more than described color blocking block is made, root According to anti-reflection principle, light is entered optically denser medium by optically thinner medium, is i.e. entered into greatly by the color blocking block of the color medium and small refractive index of film layer 121 In the antireflection layer 13 of refractive index, enhance the transmitance of light.

Being preferably carried out mode as another kind, underlay substrate 10 is between antireflection layer 13 and color film layer 121, such as Fig. 6 Shown in, antireflection layer 13 and color film layer 121 are set in the both sides of described color membrane substrates, the refractive index of antireflection layer 13 is more than color film layer The refractive index of color blocking block described in 121, the most also greater than refractive index of underlay substrate 10, when light by color film layer 121 through substrate When substrate 10 enters into antireflection layer 13, according to anti-reflection principle, light is entered optically denser medium by optically thinner medium, due to antireflection layer 13 Arrange, enhance the transmitance of light.

In actual applications, antireflection layer 13 either arranges with color film layer 121 homonymy or heteropleural is arranged, and can strengthen The transmitance of light.For underlay substrate 10 this embodiment between antireflection layer 13 and color film layer 121, relative to anti-reflection It is low that layer 13 has technology difficulty for this embodiment between color film layer 121 and underlay substrate 10, excellent compared with easy-formation Gesture.

It is understood that the refractive index of described color blocking block is about about 1.6, the refractive index of glass material is typically 1.5 Left and right, it is preferable that antireflection layer 13 should select refractive index material more than 1.6.

It is further preferred that the making material of antireflection layer 13 can select the transparent material of multiple easy molding, such as Translucent effect preferably and the photoresist of affordable, therefore can select the transparent optical photoresist that refractive index is bigger as antireflection layer 13 Making material.The at present refractive index variation of photoresist, the photoresist of big refractive index more typically, such as Germany MicroResis The photoresist refractive index of AZ5214 model about 1.7, use condition can be met.

The most specifically, antireflection layer 13 can include the multiple and described the most anti-reflection unit of color blocking block, described The wavelength positive correlation of the light that the described color blocking block that the thickness of anti-reflection unit is corresponding with described anti-reflection unit passes through.

It should be appreciated that the corresponding described color blocking block of each described anti-reflection unit, due to a described pixel cell In have a described color blocking block of multiple different colours, and according to previously described anti-reflection principle, described anti-reflection unit with thoroughly Cross the wavelength positive correlation of the light of described color blocking block.Wavelength through the light of described color blocking block is the longest, then with this color blocking block pair The thickness that the described anti-reflection unit answered is arranged is the thickest.

Preferably, the described color blocking block outgoing that the thickness of at least one described anti-reflection unit is corresponding with described anti-reflection unit Relationship below is met between the wavelength of light:

D₁=n* λ₁/ 4,

Wherein, D₁Thickness for described anti-reflection unit；

N is odd number；

λ₁Wavelength for the light of described color blocking block outgoing corresponding to described anti-reflection unit.

It is understood that the thickness that can only arrange a described anti-reflection unit meets described relational expression D₁=n* λ₁/ 4, So in described color membrane substrates, the only light through this anti-reflection unit is strengthened, it is also possible to arrange multiple described anti-reflection The thickness of unit meets described relational expression D₁=n* λ₁/ 4, it is also possible to the described of a certain color is only set on described color membrane substrates The described anti-reflection unit that color blocking block is corresponding meets described relational expression D₁=n* λ₁/ 4, or arrange on described color membrane substrates the most described The described anti-reflection unit that color blocking block is corresponding is satisfied by described relational expression D₁=n* λ₁/ 4, wherein, D₁Thickness for described anti-reflection unit Degree, n is odd number, λ₁Wavelength for the light of described color blocking block outgoing corresponding to described anti-reflection unit.

It is further preferred that described color blocking block includes red color resistance block, green color blocking block and blue color blocking block.

The color of the described color blocking block on usual described color membrane substrates is red, green and blue, the most described color blocking block Can be divided into described red color resistance block, green color blocking block and blue color blocking block, corresponding with described red color resistance block is described anti-reflection The thickness of unit meets relational expression D_R=n* λ_R/ 4, wherein D_RThickness for the described anti-reflection unit corresponding with described red color resistance block Degree, n is odd number, λ_RFor the wavelength of the light through red filter unit, λ_RIn the range of more than or equal to 620nm and be less than Or equal to 760nm；The thickness of the described anti-reflection unit corresponding with described green color blocking block meets relational expression D_G=n* λ_G/ 4, its Middle D_GFor the thickness of the described anti-reflection unit corresponding with described green color blocking block, n is odd number, λ_GFor through green filter unit The wavelength of light, λ_GIn the range of more than or equal to 505nm and less than or equal to 566nm；With described blue color blocking block pair The thickness of the described anti-reflection unit answered meets relational expression D_B=n* λ_B/ 4, wherein D_BDescribed in corresponding with described blue color blocking block The thickness of anti-reflection unit, n is odd number, λ_BFor the wavelength of the light through blue filter unit, λ_BIn the range of being more than or equal to 460nm and less than or equal to 475nm.

In order to make the light through described color blocking block all have well through effect in its wave-length coverage, generally Select centre wavelength.

Such as, with the thickness D of the described anti-reflection unit corresponding to described red color resistance block_R=n* λ '_R/ 4, wherein λ '_RFor 690nm, λ '_RCentral value for the wavelength of light through described red color resistance block.

Thickness D with the described anti-reflection unit corresponding to described green color blocking block_G=n* λ '_G/ 4, wherein λ '_GFor 535.5nm, λ '_GCentral value for the wavelength of light through described green color blocking block.

Thickness D with the described anti-reflection unit corresponding to described blue color blocking block_B=n* λ '_B/ 4, wherein λ '_BFor 467.5nm, λ '_BCentral value for the wavelength of light through described blue color blocking block.

The preferred implementation arranged as described anti-reflection element thickness by the central value selecting wavelength of light, can be made The transmitance obtaining light is best, and it is also possible that the light being positioned at the wavelength of the central value both sides of wavelength of light also has preferably Transmitance.

Being preferably carried out mode as another, described color membrane substrates also includes the black matrix being arranged on underlay substrate 10 11, the thickness of antireflection layer 13 is less than or equal to the thickness of black matrix 11.

It is understood that the metal on the array base palte arranged box with described color membrane substrates can be walked by black matrix 11 Line blocks, and raising displays contrast, when arranging antireflection layer 13 between underlay substrate 10 and color film layer 121, in order to anti- Leak-stopping light, needs the thickness higher than antireflection layer 13 arranged by the thickness of black matrix 11.

It is further preferred that the thickness of black matrix 11 generally could be arranged to

As it is shown in fig. 7, described color membrane substrates also includes being arranged on the surface of the away from substrate substrate 10 of color film layer 121 Protective layer 14 and the chock insulator matter 15 being arranged on protective layer 14.Wherein, the refractive index of protective layer 14 is about about 1.5.

Preferably, what described color membrane substrates also included being arranged on the surface deviating from color film layer 121 of underlay substrate 10 is quiet Electricity overcoat 16, static electricity shield layer 16 is made up of indium tin oxide material.

It should be noted that be provided with one layer of static electricity shield layer 16 on the underlay substrate 10 of the color membrane substrates shown in Fig. 6, This static electricity shield layer 16 is generally made up of tin indium oxide (ITO) material, this described color membrane substrates with static electricity shield layer 16 Structure be particularly suited for IPS (In-Plane Switching, plane conversion) show pattern, the work that static electricity shield layer 16 is risen With mainly preventing electrostatic, liquid crystal cell is exerted an adverse impact.Fig. 6 only changing for ease of the color membrane substrates under description IPS pattern Enter the structural representation provided, it should be appreciated that for the color membrane substrates of other display patterns, electrostatic can be not provided with completely Overcoat 16.

Processing technology about described color membrane substrates can be briefly described as follows:

Underlay substrate 10 is formed black matrix 11；

The region being correspondingly formed color film layer 121 on underlay substrate 10 and the light emission side being positioned at color film layer 121 make anti-reflection Layer 13；

Form color film layer 121；

The surface of color film layer 121 away from substrate substrate 10 forms protective layer 14.

Wherein, when antireflection layer 13 is arranged between color film layer 121 and underlay substrate 10, color film layer 121 is formed at anti-reflection Above Ceng；When underlay substrate 10 is arranged on color film layer 121 and antireflection layer 13, color film layer 121 is formed on underlay substrate 10.

As another kind specifically embodiment, when described display base plate is array base palte, as shown in Figure 8, photic zone 12 can be planarization layer 122.

Specifically, when described display base plate is described array base palte, photic zone 12 can be planarization layer 122, now, Antireflection layer 13 is arranged on the light emission side of planarization layer 122, and the refractive index of antireflection layer 13 is more than the refractive index of planarization layer 122, The wavelength positive correlation of the light of the thickness of antireflection layer 13 and planarization layer 122 outgoing, and meet relationship below:

D₂=n* λ₂/ 4,

Wherein, D₂Thickness for antireflection layer 13；

N is odd number；

λ₂Wavelength for the light of planarization layer 122 outgoing.

It should be noted that when described display base plate is described array base palte, and coloured silk film layer is arranged on described array base Time on plate, described antireflection layer can be arranged on the light emission side of described color film layer.The thickness of described antireflection layer still meets institute above State the thickness of antireflection layer 13 on color membrane substrates and through the relational expression between the wavelength of the light of color film layer 121.Described antireflection layer Concrete arrange and and described color blocking block between relation with reference to the foregoing when described display base plate be described color film base Detailed description of the invention during plate, here is omitted.

The display base plate that this utility model provides, by increasing the setting of antireflection layer, by antireflection layer according to anti-reflection principle The wavelength to the light through color blocking block that thickness is arranged is relevant or relevant to the wavelength of the light through planarization layer, anti-reflection The setting of layer reduces the loss of the light that display base plate passes through, and effectively enhances passing through of the light through display base plate Rate, and color domain also has good castering action.

As second aspect of the present utility model, it is provided that a kind of display floater, described display floater includes display base plate, Described display base plate is previously described display base plate.

From the foregoing it will be appreciated that described display base plate can be color membrane substrates, it is also possible to be array base palte.

Preferably, as a example by display base plate described earlier is described color membrane substrates, it is right that the display floater shown in Fig. 9 includes The color membrane substrates of box setting and array base palte, be provided with liquid crystal 23, Qi Zhongguang between described color membrane substrates and described array base palte The light that source 20 sends enters into the antireflection layer 13 in described color membrane substrates after first passing through lower polaroid 21, TFT substrate 22, owing to increasing The setting of permeable layers 13, light transmitance after antireflection layer 13 penetrates strengthens, and finally penetrates from upper polaroid 17.

It is understood that embodiment of above be merely to illustrate that principle of the present utility model and use exemplary Embodiment, but this utility model is not limited thereto.For those skilled in the art, without departing from this In the case of the spirit of utility model and essence, can make various modification and improvement, these modification and improvement are also considered as this reality With novel protection domain.

Claims (11)

1. a display base plate, including underlay substrate and the photic zone being arranged on described underlay substrate, it is characterised in that described Display base plate also includes antireflection layer, and described antireflection layer is made up more than the transparent material of described euphotic refractive index of refractive index, And described antireflection layer is arranged on described euphotic light emission side.

Display base plate the most according to claim 1, it is characterised in that the thickness of described antireflection layer and described photic zone outgoing Light wavelength between meet relationship below:

D=n* λ/4,

Wherein, D is the thickness of described antireflection layer；

N is odd number；

λ is the wavelength of the light of described photic zone outgoing.

Display base plate the most according to claim 2, it is characterised in that described display base plate is color membrane substrates, described printing opacity Layer is color film layer, and described color film layer is divided into multiple pixel cell, and each described pixel cell is divided into multiple sub-pix Unit, is provided with the multiple described color in a color blocking block, and same described pixel cell in each described sub-pixel unit The color of stop block is different, and described antireflection layer includes the multiple and described the most anti-reflection unit of color blocking block.

Display base plate the most according to claim 3, it is characterised in that described antireflection layer is positioned at described color film layer and described lining Between substrate or described underlay substrate is between described antireflection layer and described color film layer.

5. according to the display base plate described in claim 3 or 4, it is characterised in that described color blocking block includes red color resistance block, green Color blocking block and blue color blocking block,

Thickness D with the described anti-reflection unit corresponding to described red color resistance block_R=n* λ '_R/ 4, wherein λ '_RFor 690nm；

Thickness D with the described anti-reflection unit corresponding to described green color blocking block_G=n* λ '_G/ 4, wherein λ '_GFor 535.5nm；

Thickness D with the described anti-reflection unit corresponding to described blue color blocking block_B=n* λ '_B/ 4, wherein λ '_BFor 467.5nm.

Display base plate the most according to claim 3, it is characterised in that described display base plate also includes being arranged on described substrate Black matrix on substrate, the thickness of described antireflection layer is less than or equal to the thickness of described black matrix.

Display base plate the most according to claim 6, it is characterised in that the thickness of described black matrix is

Display base plate the most according to claim 3, it is characterised in that described display base plate also includes being arranged on described color film Protective layer on the surface deviating from described underlay substrate of layer and the chock insulator matter being arranged on described protective layer.

Display base plate the most according to claim 3, it is characterised in that described display base plate also includes being arranged on described substrate Static electricity shield layer on the surface deviating from described color film layer of substrate, described static electricity shield layer is made up of indium tin oxide material.

Display base plate the most according to claim 2, it is characterised in that described display base plate is array base palte, described printing opacity Layer is planarization layer.

11. 1 kinds of display floaters, described display floater includes display base plate, it is characterised in that described display base plate includes right Require the display base plate described in any one in 1-10.