CN105679232A - Touch control-type 3D organic light emitting display (OLED) device - Google Patents

Abstract

The invention discloses a touch control-type 3D organic light emitting display (OLED) device, which belongs to the technical field of 3D display. The touch control-type 3D organic light emitting display device comprises a 2D display module and a 3D light splitting device, wherein the 2D display module comprises a substrate and a packaging cover plate, the side, facing the packaging cover plate, of the substrate is provided with an OLED device, a packaging layer covers the OLED device, and a touch panel is arranged between the packaging layer and the packaging cover plate; and the substrate is provided with multiple pixels, each pixel comprises R, G and B subpixels, and the R, G and B subpixels are arranged along the diagonal line of the pixel. The touch control-type 3D organic light emitting display (OLED) device provided by the invention has the advantages that the thickness of the display device can be reduced; the opening rate is improved; moire is reduced; and a clear 3D display effect can be provided.

Description

Touch solid organic electroluminescence display device and method of manufacturing same

Technical field

The present invention relates to Display Technique field, particularly relate to a kind of touch solid organic electroluminescence display device and method of manufacturing same.

Background technology

In recent years, liquid crystal display (LiquidCrystalDisplay, LCD) device and Organic Light Emitting Diode (OrganicLightEmittingDiode, OLED) panel display apparatus such as display device has progressively replaced CRT monitor, becomes the main product in display device market. Wherein, OLED display has self-luminous, driving voltage is low, luminous efficiency is high, response time is short, definition and contrast 180 ° of visual angles high, nearly, use temperature range width, the plurality of advantages such as Flexible Displays and large area total colouring can be realized, be known as the display device being there is development potentiality most by industry.

OLED display generally includes: the encapsulation cover plate that substrate and substrate are oppositely arranged, the anode being located on substrate, the hole injection layer being located on anode, the hole transmission layer being located on hole injection layer, the luminescent layer being located on hole transmission layer, the electron transfer layer being located on luminescent layer, the electron injecting layer being located on electron transfer layer and be located at the negative electrode on electron injecting layer. Launch hole and electronics during OLED display work to luminescent layer, these electronics and hole combination are produced excitability electron-hole pair, and excitability electron-hole pair is converted to ground state realization luminescence from excited state.

Along with the development of portable electronic display device, touch screen (Touchpanel) provides a kind of new man-machine interaction interface, and it is more direct, more humane on using. Touch screen and flat display apparatus are combined, forms touch control display apparatus, it is possible to make flat display apparatus have touch controllable function, finger, pointer etc. can be passed through and perform input, operate more directly perceived, easy.

Current OLED touch control display apparatus generally adopts to separate OLED display and touch screen and does, then again the two is combined, so the OLED touch control display apparatus of routine is thicker, generally include four-layer structure, be oled substrate, OLED cover plate, touch screen base plate and touch screen cover plate respectively.

3D, D are the abbreviations of English Dimension, and 3D refers to three dimensions. It is understood that, in daily life, people observe the external scene around with space multistory sense with two eyes, 3D Display Technique utilizes binocular stereo vision principle to make people obtain three dimensions sense exactly, and current 3D Display Technique has bore hole formula and the big class of spectacle two;So-called bore hole 3D, it is through carrying out on a display panel special process, the 3D video image of encoded process is independently sent into the right and left eyes of people, thus making user without bore hole stereoperception can be experienced by anaglyph spectacles, the compatible 2D picture of energy simultaneously, bore hole 3D is currently used primarily in public business situations, and in domestic consumer field, Ge great producer also strengthens the R&D intensity that bore hole 3D is shown. Technically, existing bore hole 3D technology mainly has optical barrier type (Barrier) 3D technology.

Optical barrier type 3D technology is also referred to as disparity barrier or parallax barrier technology, the method that it realizes mainly uses a switching Liquid Crystal screen, polarizing coating and high molecule liquid crystal layer, utilize liquid crystal layer and polarizing coating to produce vertical stripes that a series of direction is 90 °, it is the formation of vertical slice grid pattern by the light of these stripeds, it is referred to as " parallax barrier ", under the 3D pattern shown, during the content that display should be seen by left eye, opaque striped i.e. " parallax barrier " will block right eye, in like manner, during the picture that display should be seen by right eye, left eye will be blocked, by the picture of the left eye of beholder with right eye is separated, reach the effect of stereo display.

The existing 3D Display Technique based on OLED mainly has following problem: owing to backlight suffers the stop of parallax barrier, so display brightness also can decrease, causes the reduction of display effect.

Summary of the invention

The present invention is based on above one or more problem, it is provided that a kind of touch solid organic electroluminescence display device and method of manufacturing same. The thickness of display device can be reduced, and 3D display effect clearly is provided.

The present invention solves above-mentioned technical problem by following technical proposals:

A kind of touch solid organic electroluminescence display device and method of manufacturing same, including: 2D display module, is arranged on the 3D light-splitting device above described 2D display module,

Described 2D display module includes: the encapsulation cover plate that substrate and described substrate are oppositely arranged, described substrate are provided with OLED towards described encapsulation cover plate side, described OLED is coated with encapsulated layer, between described encapsulated layer and described encapsulation cover plate, is provided with touch screen;

Including multiple pixel on described substrate, each pixel includes R, G, B sub-pixel, and described R, G, B sub-pixel is along the diagonal row of described pixel;

Described display device also includes: the 2D driver module that is connected with described 2D display module, the 3D light splitting being connected with described 3D light-splitting device drive module, drives the control module that module is connected with described 2D driver module and 3D light splitting; Described control module, is used for controlling described 2D driver module and drives described 2D display module luminous, and controls 3D light-splitting device display occlusion state described in described 3D light splitting driving module drive.

Further, described touch screen includes the first conductive layer being arranged on described encapsulated layer, it is arranged on the described encapsulation cover plate antiglare layer towards substrate-side, is arranged on the second conductive layer below described antiglare layer, be arranged on the isolating points layer below described second conductive layer.

Further, described encapsulated layer includes: the organic planarization layer of be located at the first inorganic passivation layer in described OLED, being located on described first inorganic passivation layer and be located at the second inorganic passivation layer on described organic planarization layer.

Further, each described that pixel is included size is identical, and nine sub-pixels of three row three row arrangements, described R, G, B sub-pixel is three sub-pixels of same diagonal traverse.

Further, in each described pixel, other six sub-pixels except R, G, B sub-pixel are black matrix.

Optionally, described 3D light-splitting device is liquid crystal lens, described liquid crystal lens includes upper substrate, infrabasal plate and the liquid crystal layer being filled between described upper substrate and described infrabasal plate, described upper substrate is provided with the first strip electrode, described infrabasal plate is provided with the second strip electrode, angle theta is formed between described first strip electrode and described second strip electrode, 0 °≤θ≤90 °.

Optionally, described 3D light-splitting device is liquid crystal lens, described liquid crystal lens includes upper substrate, infrabasal plate and the liquid crystal layer being filled between described upper substrate and described infrabasal plate, described upper substrate is provided with the first strip electrode, described infrabasal plate is provided with the second strip electrode, and described first strip electrode forms angle theta with X-axis₁, 0 °≤θ₁≤ 90 °, described second strip electrode forms angle theta with Y-axis₂, 0 °≤θ₂≤90°。

Further, sending in two adjacent periods of vertical synchronizing signal at described 2D driver module, described control module controls described 2D driver module and drives described 2D display module alternately to show right eye/left eye picture and left-eye/right-eye picture;

Described control module controls adjacent described first strip electrode of described 3D light splitting driving module drive and the second adjacent strip electrode alternates energising, and each conduction time is the cycle corresponding with described vertical synchronizing signal.

Optionally, described 3D light-splitting device is liquid crystal slit grating, described slit grating sets gradually lower glass substrate from top to bottom, infrabasal plate COM electrode, infrabasal plate SEG electrode, liquid crystal layer, upper substrate SEG electrode, upper substrate COM electrode, top glass substrate, insulating barrier is had to separate between described infrabasal plate COM electrode and described infrabasal plate SEG electrode, insulating barrier is had to separate between described upper substrate SEG electrode and described upper substrate COM electrode, described infrabasal plate COM electrode and described upper substrate COM electrode are whole ITO electrode, described infrabasal plate SEG electrode is strip electrode parallel to each other, the strip electrode of described infrabasal plate SEG electrode forms θ angle with x-axis, 0 °≤θ≤90 °, described upper substrate SEG electrode is strip electrode parallel to each other, the strip electrode of described upper substrate SEG electrode forms θ ' angle with y-axis, 0 °≤θ '≤90 °.

Further, when the first state, described control module controls 3D light splitting and drives the voltage that module is applied on liquid crystal slit grating upper substrate COM electrode to be 0V, and the voltage being applied on infrabasal plate SEG electrode is V1, and infrabasal plate COM electrode and upper substrate SEG electrode are all set to 0V voltage; When the second state, it is 0V that the control 3D light splitting of described control module drives module to be applied to liquid crystal slit grating infrabasal plate COM electrode voltage, and the voltage being applied on upper substrate SEG electrode is V1, upper substrate COM electrode and infrabasal plate SEG electrode are all set to 0V voltage, V1 > 0.

The touch solid organic electroluminescence display device and method of manufacturing same that the embodiment of the present invention provides, compared to prior art, has the advantages that

1, described touch screen is integrated between substrate and encapsulation cover plate, it is not necessary to be separately provided touch screen cover plate, it is possible to reduce the thickness of touch solid organic electroluminescence display device and method of manufacturing same.

2, by R, G, B sub-pixel diagonal row along pixel. On the one hand, it is possible to improve color blocking district aperture opening ratio; On the other hand, it is ensured that display device resolution when transverse screen is placed and placed with perpendicular screen is identical.

3, OLED itself has self-luminous character, without being equipped with the drive circuit of extra backlight and backlight in use procedure, therefore, compared to existing technologies, reduce the thickness of system, power consumption and cost, and due to the advantage of OLED itself so that the advantage such as system has visual angle width, the corresponding time is fast, brightness is high, energy-conservation and technique is simple.

4,3D light-splitting device adopts liquid crystal lens, and forms angle between the first strip electrode of liquid crystal lens and the second strip electrode, can effectively reduce the moire fringes that 3D display produces.

Accompanying drawing explanation

Fig. 1 is the structural representation that the embodiment of the present invention one provides a kind of touch solid organic electroluminescence display device and method of manufacturing same;

Fig. 2 is the embodiment of the present invention one dot structure schematic diagram;

Fig. 3 is that the embodiment of the present invention one provides 3D light-splitting device structural representation;

Fig. 4 is that the embodiment of the present invention two provides 3D light-splitting device structural representation.

Detailed description of the invention

Below in conjunction with drawings and Examples, the present invention is described in detail. If it should be noted that do not conflict, the embodiment of the present invention and each feature in embodiment can be combined with each other, all within protection scope of the present invention.

Embodiment one

Referring to the overall structure profile that Fig. 1 is the present invention, the embodiment of the present invention one provides a kind of touch solid organic electroluminescence display device and method of manufacturing same, including: 2D display module 1,3D light-splitting device 2, described 2D display module 1 is arranged on above described 3D light-splitting device 2. Also include the 2D driver module being connected with described 2D display module 1, the 3D light splitting driving module being connected with described 3D light-splitting device 2, drive the control module that module is connected with described 2D driver module and 3D light splitting; Described control module, is used for controlling described 2D driver module and drives described 2D display module 1 luminous, and controls described 3D light splitting and drive 3D light-splitting device 2 described in module drive to show occlusion state.

Described 2D display module 1 includes: encapsulation cover plate 12, described substrate 11 that substrate 11 and described substrate 11 are oppositely arranged are provided with OLED 13 towards described encapsulation cover plate 12 side, described OLED 13 is coated with encapsulated layer 14, between described encapsulated layer 14 and described encapsulation cover plate 12, is provided with touch screen 10. In the present embodiment, described touch screen 10 includes the first conductive layer 101 being arranged on described encapsulated layer 14, it is arranged on the described encapsulation cover plate 12 antiglare layer 102 towards substrate 11 side, it is arranged on described antiglare layer 102 the second conductive layer 103 below, is arranged on described second conductive layer 103 isolating points layer 104 below. Described touch screen 10 is integrated between substrate 11 and encapsulation cover plate 12 by the present embodiment, it is not necessary to be separately provided touch screen cover plate, it is possible to reduce the thickness of touch solid organic electroluminescence display device and method of manufacturing same.

In the present embodiment, described OLED 13 includes: reflective anode metal layer, transparent cathode metal level and be located at the organic material layer between described reflective anode metal layer and transparent cathode metal level. Further, described organic material layer includes again hole injection layer, hole transmission layer, luminescent layer, electron transfer layer and electron injecting layer.

Described encapsulated layer 14 includes: the organic planarization layer of be located at the first inorganic passivation layer in described OLED 13, being located on described first inorganic passivation layer and be located at the second inorganic passivation layer on described organic planarization layer.

Further, described substrate 11 including multiple pixel, pixel can arrange with fundamental matrix pattern, but is not limited to matrix pattern.Pixel can be controlled by different way, and can be luminous by different way, to show image on the whole surface of 2D display module 1. In the present invention, each pixel includes R, G, B sub-pixel, and described R, G, B sub-pixel is along the diagonal row of described pixel. Wherein, each sub-pixel includes organic luminous layer and thin film transistor (TFT) (hereinafter referred to as TFT), it is luminous that organic luminous layer can pass through self, TFT can send the scanning cut-in voltage of scanning signal in response to 2D driver module and control sub-pixel and receive or do not receive data signal, thus controlling the brightness of organic luminous layer.

Concrete, as in figure 2 it is shown, each, described that pixel is included size is identical, and nine sub-pixels of three row three row arrangements, described R, G, B sub-pixel is three sub-pixels of same diagonal traverse. In each described pixel, six sub-pixels of other except R, G, B sub-pixel are black matrix. Wherein, TFT-R, TFT-G, TFT-B respectively R, G, G sub-pixel TFT switch placement location. BM (BlackMatrix) is black matrix, and effect is the metal wire of transmission data and switching signal in the region blocked and do not have color blocking and pixel. The TFT of the present invention drives the position of the switch to be placed in color blocking overlay area, it is possible to be placed in not by color blocking overlay area. Do so has the advantage that the pixel aperture ratio that can improve color blocking district. Generally for the small sizes such as mobile phone (such as 3.5 inches to 6.5 inches), if PPI(Pixelsperinch per inch pixel count) higher (as more than 300PPI) pixel aperture ratio generally all less (such as less than 30%). Although present invention color blocking district only has about 1/3 size of prior art, but by being arranged on outside color blocking district by the placement location of TFT can to ensure the aperture opening ratio of at least 33%, aperture opening ratio is even better than the prior art pixel design in high PPI situation.

As one preferably embodiment, described 3D light-splitting device 3 is liquid crystal lens, as shown in Figure 3, described liquid crystal lens includes upper substrate 31, infrabasal plate 32 and the liquid crystal layer 33 being filled between described upper substrate 31 and described infrabasal plate 32, described upper substrate 31 is provided with the first strip electrode 311, described infrabasal plate 32 is provided with the second strip electrode 322, forms angle theta between described first strip electrode 311 and described second strip electrode 322,0 °≤θ≤90 °.

As another kind preferably embodiment, described 3D light-splitting device 3 is liquid crystal lens, described liquid crystal lens includes upper substrate, infrabasal plate and the liquid crystal layer being filled between described upper substrate and described infrabasal plate, described upper substrate is provided with the first strip electrode, described infrabasal plate is provided with the second strip electrode, and described first strip electrode forms angle theta with X-axis₁, 0 °≤θ₁≤ 90 °, described second strip electrode forms angle theta with Y-axis₂, 0 °≤θ₂≤90°。

When a stereoscopic image is displayed, the frequency of 2D display module 1 need to reach 120HZ, sending in two adjacent periods of vertical synchronizing signal at described 2D driver module, described control module controls described 2D driver module and drives described 2D display module 1 alternately to show right eye/left eye picture and left-eye/right-eye picture;

Described control module controls adjacent described first strip electrode 311 of described 3D light splitting driving module drive and the second adjacent strip electrode 322 alternates energising, and each conduction time is the cycle corresponding with described vertical synchronizing signal.

The touch solid organic electroluminescence display device and method of manufacturing same that the embodiment of the present invention provides, compared to prior art, has the advantages that

1, described touch screen is integrated between substrate and encapsulation cover plate, it is not necessary to be separately provided touch screen cover plate, it is possible to reduce the thickness of touch solid organic electroluminescence display device and method of manufacturing same.

2, by R, G, B sub-pixel diagonal row along pixel. On the one hand, it is possible to improve color blocking district aperture opening ratio; On the other hand, it is ensured that display device resolution when transverse screen is placed and placed with perpendicular screen is identical.

3, OLED itself has self-luminous character, without being equipped with the drive circuit of extra backlight and backlight in use procedure, therefore, compared to existing technologies, reduce the thickness of system, power consumption and cost, and due to the advantage of OLED itself so that the advantage such as system has visual angle width, the corresponding time is fast, brightness is high, energy-conservation and technique is simple.

4,3D light-splitting device adopts liquid crystal lens, and forms angle between the first strip electrode of liquid crystal lens and the second strip electrode, can effectively reduce the moire fringes that 3D display produces.

Embodiment two

The embodiment of the present invention two provides a kind of touch solid organic electroluminescence display device and method of manufacturing same, different from embodiment one are in that: described 3D light-splitting device 3 is liquid crystal slit grating, described slit grating sets gradually lower glass substrate 301 from top to bottom, infrabasal plate COM electrode 302, infrabasal plate SEG electrode 303, liquid crystal layer 33, upper substrate SEG electrode 304, upper substrate COM electrode 305, top glass substrate 306, insulating barrier is had to separate between described infrabasal plate COM electrode 302 and described infrabasal plate SEG electrode 303, insulating barrier is had to separate between described upper substrate SEG electrode 304 and described upper substrate COM electrode 305, described infrabasal plate COM electrode 302 and described upper substrate COM electrode 305 are whole ITO electrode, described infrabasal plate SEG electrode 303 is strip electrode parallel to each other, the strip electrode of described infrabasal plate SEG electrode 303 forms θ angle with x-axis, 0 °≤θ≤90 °, described upper substrate SEG electrode 304 is strip electrode parallel to each other, the strip electrode of described upper substrate SEG electrode 304 forms θ ' angle with y-axis, 0 °≤θ '≤90 °.

In control process, when the first state, when placing such as display device transverse screen, the voltage that module is applied on liquid crystal slit grating upper substrate COM electrode 305 is driven to be 0V if controlling module control 3D light splitting described in a certain moment, and it being applied to the square wave that voltage is +/-V1 on infrabasal plate SEG electrode 303 to prevent liquid crystal material from polarizing, the size of voltage V1 and square wave frequency/cycle etc. determine according to characteristics such as liquid crystal materials. Other two-layer electrodes and infrabasal plate COM electrode 302 and upper substrate SEG electrode 304, due to inoperative, are all set to COM voltage and 0V. Owing to defining certain voltage difference between upper substrate COM electrode 305 and infrabasal plate SEG electrode 303, form chequered with black and white striped, namely can form 3D within region and show.

When the second state, when screen as vertical in display device is placed, the voltage that module is applied on liquid crystal slit grating infrabasal plate COM electrode 302 is driven to be 0V if controlling module control 3D light splitting described in a certain moment, and it being applied to the square wave that voltage is +/-V1 on upper substrate SEG electrode 304 to prevent liquid crystal material from polarizing, the size of voltage V1 and square wave frequency/cycle etc. determine according to characteristics such as liquid crystal materials. Other two-layer electrodes and upper substrate COM electrode 305 and infrabasal plate SEG electrode 303, due to inoperative, are all set to COM voltage and 0V. Owing to defining certain voltage difference between infrabasal plate COM electrode 302 and upper substrate SEG electrode 304, form chequered with black and white striped, namely can form 3D within region and show.

The dot structure so coordinating above type of drive and the present invention to propose, can be implemented without re-designing light-splitting device and both can reach the dynamic changeable light-splitting device of the needs according to display direction and realize both direction anyhow and all can realize bore hole 3D and show.

The foregoing is only embodiments of the present invention; not thereby the scope of the claims of the present invention is limited; every equivalent structure utilizing description of the present invention and accompanying drawing content to make or equivalence flow process conversion; or directly or indirectly it is used in other relevant technical fields, all in like manner include in the scope of patent protection of the present invention.

Claims (10)

1. a touch solid organic electroluminescence display device and method of manufacturing same, it is characterized in that, including: 2D display module, it is arranged on the 3D light-splitting device above described 2D display module, described 2D display module includes: the encapsulation cover plate that substrate and described substrate are oppositely arranged, described substrate are provided with OLED towards described encapsulation cover plate side, described OLED is coated with encapsulated layer, between described encapsulated layer and described encapsulation cover plate, is provided with touch screen;

Including multiple pixel on described substrate, each pixel includes R, G, B sub-pixel, and described R, G, B sub-pixel is along the diagonal row of described pixel;

Described display device also includes: the 2D driver module that is connected with described 2D display module, the 3D light splitting being connected with described 3D light-splitting device drive module, drives the control module that module is connected with described 2D driver module and 3D light splitting; Described control module, is used for controlling described 2D driver module and drives described 2D display module luminous, and controls 3D light-splitting device display occlusion state described in described 3D light splitting driving module drive.

2. touch solid organic electroluminescence display device and method of manufacturing same according to claim 1, it is characterized in that: described touch screen includes the first conductive layer being arranged on described encapsulated layer, it is arranged on the described encapsulation cover plate antiglare layer towards substrate-side, it is arranged on the second conductive layer below described antiglare layer, is arranged on the isolating points layer below described second conductive layer.

3. touch solid organic electroluminescence display device and method of manufacturing same according to claim 2, it is characterised in that: described encapsulated layer includes: the organic planarization layer of be located at the first inorganic passivation layer in described OLED, being located on described first inorganic passivation layer and be located at the second inorganic passivation layer on described organic planarization layer.

4. touch solid organic electroluminescence display device and method of manufacturing same according to claim 1, it is characterized in that: each described that pixel is included size is identical, nine sub-pixels of three row three row arrangements, described R, G, B sub-pixel is three sub-pixels of same diagonal traverse.

5. touch solid organic electroluminescence display device and method of manufacturing same according to claim 4, it is characterised in that: in each described pixel, six sub-pixels of other except R, G, B sub-pixel are black matrix.

6. touch solid organic electroluminescence display device and method of manufacturing same according to claim 4, it is characterized in that: described 3D light-splitting device is liquid crystal lens, described liquid crystal lens includes upper substrate, infrabasal plate and the liquid crystal layer being filled between described upper substrate and described infrabasal plate, described upper substrate is provided with the first strip electrode, described infrabasal plate is provided with the second strip electrode, angle theta is formed between described first strip electrode and described second strip electrode, 0 °≤θ≤90 °.

7. touch solid organic electroluminescence display device and method of manufacturing same according to claim 4, it is characterized in that: described 3D light-splitting device is liquid crystal lens, described liquid crystal lens includes upper substrate, infrabasal plate and the liquid crystal layer being filled between described upper substrate and described infrabasal plate, described upper substrate is provided with the first strip electrode, described infrabasal plate is provided with the second strip electrode, and described first strip electrode forms angle theta with X-axis₁, 0 °≤θ₁≤ 90 °, described second strip electrode forms angle theta with Y-axis₂, 0 °≤θ₂≤90°。

8. the touch solid organic electroluminescence display device and method of manufacturing same according to claim 6 or 7, it is characterized in that: send in two adjacent periods of vertical synchronizing signal at described 2D driver module, described control module controls described 2D driver module and drives described 2D display module alternately to show right eye/left eye picture and left-eye/right-eye picture;

Described control module controls adjacent described first strip electrode of described 3D light splitting driving module drive and the second adjacent strip electrode alternates energising, and each conduction time is the cycle corresponding with described vertical synchronizing signal.

9. touch solid organic electroluminescence display device and method of manufacturing same according to claim 4, it is characterized in that: described 3D light-splitting device is liquid crystal slit grating, described slit grating sets gradually lower glass substrate from top to bottom, infrabasal plate COM electrode, infrabasal plate SEG electrode, liquid crystal layer, upper substrate SEG electrode, upper substrate COM electrode, top glass substrate, insulating barrier is had to separate between described infrabasal plate COM electrode and described infrabasal plate SEG electrode, insulating barrier is had to separate between described upper substrate SEG electrode and described upper substrate COM electrode, described infrabasal plate COM electrode and described upper substrate COM electrode are whole ITO electrode, described infrabasal plate SEG electrode is strip electrode parallel to each other, the strip electrode of described infrabasal plate SEG electrode forms θ angle with x-axis, 0 °≤θ≤90 °, described upper substrate SEG electrode is strip electrode parallel to each other, the strip electrode of described upper substrate SEG electrode forms θ ' angle with y-axis, 0 °≤θ '≤90 °.

10. touch solid organic electroluminescence display device and method of manufacturing same according to claim 9, it is characterized in that: when the first state, described control module controls 3D light splitting and drives the voltage that module is applied on liquid crystal slit grating upper substrate COM electrode to be 0V, and the voltage being applied on infrabasal plate SEG electrode is V1, infrabasal plate COM electrode and upper substrate SEG electrode are all set to 0V voltage; When the second state, it is 0V that the control 3D light splitting of described control module drives module to be applied to liquid crystal slit grating infrabasal plate COM electrode voltage, and the voltage being applied on upper substrate SEG electrode is V1, upper substrate COM electrode and infrabasal plate SEG electrode are all set to 0V voltage, V1 > 0.