CN204302632U - Liquid crystal grating and mosaic screen - Google Patents
Liquid crystal grating and mosaic screen Download PDFInfo
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- CN204302632U CN204302632U CN201420860779.XU CN201420860779U CN204302632U CN 204302632 U CN204302632 U CN 204302632U CN 201420860779 U CN201420860779 U CN 201420860779U CN 204302632 U CN204302632 U CN 204302632U
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Abstract
The utility model provides a kind of liquid crystal grating and mosaic screen, comprise the first substrate and second substrate that are oppositely arranged, and the liquid crystal molecule be filled between first substrate and second substrate, first substrate is provided with the first electrode layer, second substrate is provided with the second electrode lay, liquid crystal grating comprises at least one raster unit, and raster unit comprises a viewing area, and surrounds the rim area of viewing area; First electrode layer comprises the first border electrode that corresponding rim area is arranged; The second electrode lay comprises the second border electrode that corresponding rim area is arranged; Wherein to be used for the coating-forming voltage when carrying out 3D and 2D display poor for the first border electrode and the second border electrode, to control turning to of liquid crystal molecule in rim area, makes scattering enter the rim area outgoing of the light in rim area from second substrate.Above-mentioned liquid crystal grating can make the seam of mosaic screen have certain display brightness, drastically increases the display effect of mosaic screen.
Description
Technical field
The utility model relates to display technique field, particularly relates to a kind of liquid crystal grating and mosaic screen.
Background technology
Along with the development of flat panel display, large screen splicing technology is widely used in the fields such as security protection, monitoring, medical treatment, radio and television, advertisement media.
In large screen splicing technology, need by display module complete for polylith according to X × Y (wherein, X represents the columns of the display module that mosaic screen comprises, Y represents the line number of the display module that mosaic screen comprises) form, utilize outside support structures to form to be combined into large-sized mosaic screen.The frame that a complete display module generally includes display screen, backlight and the two is fixed together, due to the existence of frame, can there is splicing seams in the mosaic screen finally combined, the width of splicing seams depends on the border width sum of adjacent two pieces of display modules.Splicing seams causes display frame divided, destroys continuity and the integrality of picture, and for large scale mosaic screen, the width of its splicing seams should be less than 5mm, just can have good display effect.
Usually the mode reducing display module border width is adopted to reduce splicing seams width in prior art.But, owing to being subject to the restriction of material thickness, structural strength etc., reducing border width and there is the limit.At present, the border width of display module can accomplish 6mm ~ 10mm, and therefore the splicing seams width of mosaic screen can reach 12mm ~ 20mm usually, and this can not meet the requirement of high-quality display picture far away.
Utility model content
For overcoming above-mentioned defect of the prior art, technical problem to be solved in the utility model is: provide a kind of liquid crystal grating and mosaic screen, to improve the picture display effect of mosaic screen.
For achieving the above object, the utility model adopts following technical scheme:
The utility model provides a kind of liquid crystal grating, comprise the first substrate and second substrate that are oppositely arranged, and the liquid crystal molecule be filled between described first substrate and described second substrate, described first substrate is provided with the first electrode layer, described second substrate is provided with the second electrode lay, it is characterized in that, described liquid crystal grating comprises at least one raster unit, described raster unit comprises a viewing area, and surrounds the rim area of described viewing area; Described first electrode layer comprises the first border electrode that corresponding described rim area is arranged; Described the second electrode lay comprises the second border electrode that corresponding described rim area is arranged; Wherein, it is poor that described first border electrode and described second border electrode are used for the coating-forming voltage when carrying out 3D and 2D display, to control turning to of liquid crystal molecule in described rim area, scattering is made to enter the rim area outgoing of the light in described rim area from described second substrate.
Preferably, described first electrode layer also comprises the first show electrode that corresponding described viewing area is arranged; Described the second electrode lay also comprises the second show electrode that corresponding described viewing area is arranged; It is poor that described first show electrode and described second show electrode are used for carrying out coating-forming voltage when 3D shows at needs, to control turning to of liquid crystal molecule in described viewing area, grating is formed in described viewing area, keep voltage identical when needs carry out 2D display, be in initial orientation state with the liquid crystal molecule controlled in described viewing area, allow light all to pass through in described viewing area.
Preferably, the formation material of described first border electrode is metal, and the formation material of described second border electrode, described first show electrode and described second show electrode is transparent conductive material.
Preferably, described first border electrode and described first show electrode are electrically insulated, and described second border electrode and described second show electrode are electrically insulated.
Preferably, described first border electrode is face electrode, and described second border electrode is frame-shaped electrode, and described first show electrode is gate-shaped electrode, and described second show electrode is face electrode.
Preferably, described first border electrode is the face electrode extended in the corresponding region of described rim area; Described second border electrode comprises at least one frame-shaped electrode; When described second border electrode comprises multiple frame-shaped electrode, described multiple frame-shaped electrode is according to the descending order of size around distribution, and described multiple frame-shaped electrode is electrically insulated each other; Described first show electrode comprises the sub-gate electrode of multiple strip be arranged in parallel; Described second show electrode is the face electrode extended in the corresponding region of described viewing area.
Preferably, described first border electrode is applied in rim area public electrode voltages signal; Described first electrode layer also comprises: the gate-shaped electrode voltage signal line being arranged at described first border electrode periphery, described gate-shaped electrode voltage signal line is electrical connected by via hole and described first show electrode, for applying gate-shaped electrode voltage signal to described first show electrode; Described the second electrode lay also comprises: the frame-shaped electrode voltage signal line being arranged at described second border electrode periphery, described frame-shaped electrode voltage signal line is electrical connected by via hole and described second border electrode, for applying frame-shaped electrode voltage signal to described second border electrode; The viewing area public electrode voltages signal wire of described second border electrode periphery is extended to through described viewing area, described viewing area public electrode voltages signal wire is electrical connected by via hole and described second show electrode, for applying viewing area public electrode voltages signal to described second show electrode; Wherein, between described rim area public electrode voltages signal and described frame-shaped electrode voltage signal, there is voltage difference, between described gate-shaped electrode voltage signal and described viewing area public electrode voltages signal, there is voltage difference.
Preferably, the formation material of described gate-shaped electrode voltage signal line, described viewing area public electrode voltages signal wire and described frame-shaped electrode voltage signal line is metal.
Preferably, when described liquid crystal grating is superimposed with display module, the vertical projection of described viewing area public electrode voltages signal wire on described first substrate is overlapping with a part for the vertical projection of black matrix on described first substrate of described display module.
Preferably, described first substrate and described second substrate are flexible base, board.
The utility model additionally provides a kind of mosaic screen, comprising: the multiple display modules be stitched together, and described multiple display module is matrix form arrangement; Above-described liquid crystal grating, described liquid crystal grating covers on the display surface of described multiple display module, and described liquid crystal grating comprises multiple raster unit, and described multiple raster unit is overlapping with described multiple display module one_to_one corresponding.
Preferably, the rim area of described raster unit is overlapping with the rim area of described display module, and the viewing area of described raster unit is overlapping with the viewing area of described display module.
Preferably, in described multiple display module, the substrate of close described liquid crystal grating is the first substrate of described liquid crystal grating.
Preferably, described mosaic screen is flexible mosaic screen.
Liquid crystal grating provided by the utility model and mosaic screen, by covering a liquid crystal grating on spliced multiple display module, this liquid crystal grating comprises and multiple display modules raster unit one to one, each raster unit is divided into viewing area and rim area, and the liquid crystal both sides of viewing area are provided with the first border electrode and the second border electrode.When showing, between first border electrode and the second border electrode, the poor liquid crystal molecule controlled in rim area of coating-forming voltage turns to, the light path that the light in rim area is entered in scattering can be changed, make this some light from the rim area outgoing of second substrate, thus make the seam of mosaic screen (seam causes primarily of frame) have certain display brightness, during the display frame of eye-observation mosaic screen, seam becomes not obvious, drastically increases the display effect of mosaic screen.
Accompanying drawing explanation
In order to be illustrated more clearly in the utility model embodiment or technical scheme of the prior art, be briefly described to the accompanying drawing used required in embodiment or description of the prior art below, apparently, accompanying drawing in the following describes is only embodiments more of the present utility model, for those of ordinary skill in the art, under the prerequisite not paying creative work, other accompanying drawing can also be obtained according to these accompanying drawings.
The schematic diagram of the cross-section structure of the liquid crystal grating that Fig. 1 provides for the utility model embodiment one;
The plane structure chart of the liquid crystal grating that Fig. 2 provides for the utility model embodiment one;
The plane structure chart of the first electrode layer of the liquid crystal grating that Fig. 3 provides for the utility model embodiment one;
The plane structure chart of the second electrode lay of the liquid crystal grating that Fig. 4 provides for the utility model embodiment one;
The concrete sectional structure chart of the liquid crystal grating that Fig. 5 provides for the utility model embodiment one;
The making step figure of the first electrode layer of the liquid crystal grating that Fig. 6 a ~ Fig. 6 c provides for the utility model embodiment two;
The making step figure of the second electrode lay of the liquid crystal grating that Fig. 7 a ~ Fig. 7 c provides for the utility model embodiment two;
Description of reference numerals: 11-first substrate; 12-second substrate; 13-first electrode layer; 131-first border electrode; 132-first show electrode; 133-gate-shaped electrode voltage signal line; 135-the first frame-chip lead; 136-first shows-chip lead; 14-the second electrode lay; 141-second border electrode; 142-second show electrode; 143-frame-shaped electrode voltage signal line; 144-viewing area public electrode voltages signal wire; 15-liquid crystal molecule;
2-raster unit; 21-rim area; 22-viewing area;
6-via hole; 7-via hole;
A-light.
Embodiment
For enabling above-mentioned purpose of the present utility model, feature and advantage become apparent more, below in conjunction with the accompanying drawing in the utility model embodiment, are clearly and completely described the technical scheme in the utility model embodiment.Obviously, described embodiment is only the utility model part embodiment, instead of whole embodiments.Based on the embodiment in the utility model, other embodiments all that those of ordinary skill in the art obtain under the prerequisite of not making creative work, all belong to the scope of the utility model protection.
Embodiment one
Present embodiments provide a kind of liquid crystal grating, as shown in Figure 1, comprise the first substrate 11 and second substrate 12 that are oppositely arranged, and the liquid crystal molecule 15 be filled between first substrate 11 and second substrate 13, first substrate 11 is provided with the first electrode layer 13, second substrate 14 is provided with the second electrode lay 14.
As shown in Figure 2, this liquid crystal grating comprises at least one raster unit 2, and each raster unit 2 comprises a viewing area 22, and surrounds the rim area 21 of viewing area 22.
With reference to Fig. 3, Fig. 4 and Fig. 5, the first electrode layer 13 of above-mentioned liquid crystal grating comprises the first border electrode 131 of corresponding rim area 21 setting, and the second electrode lay 14 comprises the second border electrode 141 that corresponding rim area 21 is arranged.First border electrode 131 and the second border electrode 141 are poor for the coating-forming voltage when carrying out 3D and 2D display, to control turning to of liquid crystal molecule 15 in rim area 21, make scattering enter rim area 21 outgoing of the light A in rim area 21 from second substrate 12.
The liquid crystal grating of said structure in use, by applying different voltage respectively to the first border electrode 131 and the second border electrode 141, make to there is voltage difference therebetween, thus turning to of the liquid crystal molecule 15 of the rim area 21 of each raster unit 2 of liquid crystal grating can be controlled, change the light path that the light in rim area is entered in scattering, make this some light from rim area 21 outgoing of second substrate 12, rim area 21 has certain display brightness.When on the display surface this liquid crystal grating being covered mosaic screen, the rim area with certain display brightness of each raster unit of liquid crystal grating can cover in the seam of mosaic screen, thus during the display frame of eye-observation mosaic screen, seam becomes not obvious, drastically increases the display effect of mosaic screen.
First electrode layer 13 of each raster unit of the liquid crystal grating provided described in the present embodiment preferably also can comprise the first show electrode 132 of corresponding viewing area 22 setting, and the second electrode lay 14 preferably also can comprise the second show electrode 142 that corresponding viewing area 22 is arranged.
First show electrode 132 and the second show electrode 142 poor for carrying out coating-forming voltage when 3D shows at needs, to control turning to of liquid crystal molecule in viewing area 22, form grating in viewing area 22.Namely in viewing area 22, the transmission region be alternately arranged and lightproof area is formed, by making in the displaying time of a frame, one half-pix display left-eye image, second half pixel reality eye image, and the pixel of display left-eye image and display eye image is alternately arranged, owing to there is parallax between right and left eyes, through same transmission region, left eye only can see the pixel of display left-eye image, right eye only can see the pixel of display eye image, and left-eye image superposes the effect forming 3D and show with eye image.
First show electrode 132 and the second show electrode 142 also keep voltage identical for carrying out at needs when 2D shows, and be in initial orientation state, allow light all to pass through in viewing area 22 with the liquid crystal molecule controlled in viewing area 22.When the first show electrode 132 is identical with the voltage of the second show electrode 142, do not have voltage difference therebetween, liquid crystal molecule by the impact of voltage difference, can not deflect, therefore can keep initial orientation state.It should be noted that, liquid crystal molecule can make when the initial orientation state described in the present embodiment through light all pass through.
Visible, by arranging the first show electrode 141 and the second show electrode 142 in viewing area 22 correspondence of liquid crystal grating in this enforcement, meet the demand that display device shows 3D display and 2D.
It should be noted that, the first show electrode 132 shown in Fig. 3, its live width being positioned at the part of viewing area 22 is wider, to ensure that the grating formed meets the requirements, the live width exceeding the part of viewing area 22 is thinner, with on the basis realizing electrical connection, that reduces with other live components is overlapping as far as possible, reduces the generation of unnecessary stray capacitance.Based on the consideration of Simplified flowsheet, in other embodiment of the present utility model, the first show electrode 132 also can be made to be positioned at the part of viewing area 22 identical with the live width of the part exceeding viewing area 22.Second border electrode 141 surrounds the live width of the frame-shaped part of viewing area 22 can slightly wider than for the live width of part of frame-shaped part conveying voltage signal of surrounding viewing area 22, both to ensure that the electric field formed between the second border electrode 141 and the first border electrode 131 meets the requirements, that reduces again with other live components is overlapping, the live width that second border electrode 141 surrounds the frame-shaped part of viewing area 22 is identical with for what carry the live width of the part of voltage signal also can arrange to the frame-shaped part of surrounding viewing area 22, to simplify preparation technology.
In the present embodiment, the formation material of the first border electrode 131 preferably can be metal, the preferred metal material selecting high reflectance, reflect with the direction of the light that will enter in rim area 21 towards second substrate 12, reduce the loss of the light entered in rim area 21, improve the brightness of rim area 21 further.
The formation material of the second border electrode 141, first show electrode 132 and the second show electrode 142 preferably can be transparent conductive material, such as, can be indium tin oxide, with the light penetration that the viewing area 22 and second substrate 12 that ensure first substrate 11 are good.
In the present embodiment, the first border electrode 131 and the first show electrode 132 preferably can be made to be electrically insulated, second border electrode 141 and the second show electrode 142 are electrically insulated, to realize the independent control to the first border electrode 131, first show electrode 132, second border electrode 141 and the second show electrode 142, strengthen the flexibility and changeability of the drived control to liquid crystal grating.
The concrete shape of the present embodiment to the first border electrode 131, second border electrode 141, first show electrode 132 and the second show electrode 142 does not limit, such as can be: the first border electrode 131 is face electrode, second border electrode 141 is frame-shaped electrode, first show electrode 132 is gate-shaped electrode, and the second show electrode is face electrode.It should be noted that, the face electrode described in the present embodiment specifically refers to extension in whole rim area 21 or viewing area 22 and does not have the electrode of figure.
Wherein, the first border electrode 131 specifically can be the face electrode extended in the corresponding region of rim area 21; Second border electrode 141 can comprise at least one frame-shaped electrode, when the second border electrode 141 comprises multiple frame-shaped electrode, the plurality of frame-shaped electrode according to the descending order of size around distribution, and multiple frame-shaped electrode is electrically insulated each other, thus meticulousr control can be carried out to the liquid crystal molecule in rim area 21; First show electrode 132 specifically can for arrange by multiple strip electrode runs parallel the gate-shaped electrode formed; Second show electrode 142 specifically can be the face electrode extended in the corresponding region of viewing area 22.
As shown in Figure 3, first border electrode 131 can be used as the public electrode controlling rim area 21 liquid crystal molecule, be applied in rim area public electrode voltages signal, preferred by arranging the first frame-chip lead 135 at the edge of the first border electrode 131, first border electrode 131 is connected to driving chip, realizes the applying of rim area public electrode voltages signal.In order to apply gate-shaped electrode voltage signal to the first show electrode 132, first electrode layer 13 preferably also can comprise: the gate-shaped electrode voltage signal line 133 being arranged at the first border electrode 131 periphery, itself and the first show electrode 132 are electrical connected, also the first display-chip lead 136 can be set in the end of gate-shaped electrode voltage signal line 133, first show electrode 132 is connected to driving chip, realizes the applying of gate-shaped electrode voltage signal.
In the present embodiment, transparent conductive material preferably can be adopted to form the first show electrode 132, the first frame-chip lead 135 and the first display-chip lead 136 with layer, metal is adopted to form the first border electrode 131 and gate-shaped electrode voltage signal line 133 with layer, therefore the first show electrode 132 can be made to be electrical connected by via hole and gate-shaped electrode voltage signal line 133, first frame-chip lead 135 is electrical connected by via hole and the first border electrode 131, the first display-chip lead 136 is electrical connected by via hole and gate-shaped electrode voltage signal line 133.
It should be noted that, first show electrode 132 of the palisade in the first electrode layer comprises multiple sub-gate electrode side by side in the row direction, for the liquid crystal grating comprising multiple raster units that matrix form is arranged, first show electrode 132 of one row raster unit comprises the sub-gate electrode of multiple row, preferably the sub-gate electrode of row can be connected in series, adopt same gate-shaped electrode voltage signal line 133 to carry gate-shaped electrode voltage signal simultaneously, now need the number of gate-shaped electrode voltage signal line 133 arranged should be identical with the number of the sub-gate electrode included by the first show electrode 132 in a raster unit.
As shown in Figure 4, in order to apply voltage respectively to the second border electrode 141 and the second show electrode 142, the second electrode lay 14 preferably also can comprise: the frame-shaped electrode voltage signal line 143 being arranged at the second border electrode 141 periphery, this frame-shaped electrode voltage signal line 143 and the second border electrode 141 are electrical connected, for applying frame-shaped electrode voltage signal to the second border electrode 141; The viewing area public electrode voltages signal wire 144 of the second border electrode 141 periphery is extended to through viewing area 22, this viewing area public electrode voltages signal wire 144 and the second show electrode 142 are electrical connected, for applying viewing area public electrode voltages signal to the second show electrode 142.
In the present embodiment, metal preferably can be adopted to form frame-shaped electrode voltage signal line 143 and viewing area public electrode voltages signal wire 144 with layer, transparent conductive material is adopted to form the second border electrode 141 and the second show electrode 142 with layer, therefore frame-shaped electrode voltage signal line 143 can be made to be electrical connected by via hole and the second border electrode 141, and viewing area public electrode voltages signal wire 144 is electrical connected by via hole and the second show electrode.In addition, while formation second border electrode 141 and the second show electrode 142, by filling transparent conductive material in via hole, frame-shaped electrode voltage signal line 143 and viewing area public electrode voltages signal wire 144 can be led to driving chip.
It should be noted that, when the second border electrode 141 of the frame-shaped in the second electrode lay comprise multiple size order according to size around multiple frame-shaped electrode time, for the liquid crystal grating comprising multiple raster units that matrix form is arranged, measure-alike frame-shaped electrode in second show electrode 141 of one row raster unit can be connected in series, same frame-shaped electrode voltage signal line 143 is adopted to carry frame-shaped electrode voltage signal, now need the number of frame-shaped electrode voltage signal line 143 arranged should be identical with the number of the frame-shaped electrode included by the second show electrode 141 in a raster unit.
In addition, in order to improve the voltage uniformity on the second show electrode 142, viewing area public electrode voltages signal wire 144 for carrying from viewing area public electrode voltages signal to the second show electrode 142 can be all set vertical and horizontal above the second show electrode 142, to take into account the regional of the second show electrode 142.
Between above-mentioned rim area public electrode voltages signal and frame-shaped electrode voltage signal, there is voltage difference, to control turning to of the liquid crystal molecule of rim area 21; Between gate-shaped electrode voltage signal and viewing area public electrode voltages signal, there is voltage difference, to control turning to of the liquid crystal molecule of viewing area 22.
Superincumbent describe in, the formation material of gate-shaped electrode voltage signal line 133, viewing area public electrode voltages signal wire 144 and frame-shaped electrode voltage signal line 141 is metal, in other embodiment of the present utility model, aforementioned three also can adopt other conductive material to be formed.
When adopting the lighttight materials such as metal to be formed when viewing area public electrode voltages signal wire 144, can produce light and certain block effect, because viewing area public electrode voltages signal wire 144 is through viewing area 22, therefore for avoiding its shading to cause adverse effect to display effect, arranging of public electrode voltages signal wire 144 position, viewing area preferably can be: when liquid crystal grating is superimposed with display module, the vertical projection of viewing area public electrode voltages signal wire 144 on first substrate 11 is overlapping with a part for the vertical projection of black matrix on first substrate 11 of display module.
In the present embodiment, flexible base, board can be selected as the first substrate 11 of liquid crystal grating and second substrate 12, thus make whole liquid crystal grating have flexibility, meet the demand of Flexible Displays module or mosaic screen.
Embodiment two
Present embodiments provide a kind of method for making of liquid crystal grating, for making the liquid crystal grating described in embodiment one, this method for making comprises the following steps: on first substrate 11, form the first electrode layer 13, and this first electrode layer 13 comprises the first border electrode 131 that corresponding rim area 21 is arranged; Second substrate 12 is formed the second electrode lay 14, and this second electrode lay 14 comprises the second border electrode 141 that corresponding rim area 21 is arranged.
When carrying out 3D and 2D display, between first border electrode 131 and the second border electrode 141, coating-forming voltage is poor, control turning to of the liquid crystal molecule in rim area 21, scattering is enable to enter the rim area outgoing of the light in rim area 21 from second substrate 12, the rim area 21 of liquid crystal grating is made to have certain display brightness, therefore, after made liquid crystal grating superposed with mosaic screen using, the rim area 21 of liquid crystal grating covers in the seam of mosaic screen, seam can be made to become not obvious, improve the display quality of mosaic screen.
The display module applied to make liquid crystal grating had both possessed 3D Presentation Function, possesses again 2D Presentation Function, first electrode layer 13 of made liquid crystal grating preferably also can comprise the first show electrode 132 of corresponding viewing area 22 setting, and the second electrode lay 14 preferably also can comprise the second show electrode 142 that corresponding viewing area 22 is arranged.When needs carry out 3D display, poor by coating-forming voltage between the first show electrode 132 and the second show electrode 142, control turning to of the liquid crystal molecule in viewing area 22, form grating in viewing area 22; When needs carry out 2D display, keep the first show electrode 132 identical with the second show electrode 142 voltage, the liquid crystal molecule controlled in viewing area 22 is in initial orientation state, allows light all to pass through in viewing area 22.
Below for the first electrode layer 13 illustrated in fig. 3 and the second electrode lay illustrated in fig. 4 14, respectively the process of preparation first electrode layer 13 and the second electrode lay 14 is specifically described.
As shown in Fig. 6 a ~ Fig. 6 c, first substrate 11 is formed the first electrode layer 13 and specifically comprises:
Step S11: form the figure comprising the first show electrode 132 on first substrate 11, this first show electrode 132 is gate-shaped electrode, see Fig. 6 a.
In this step, also can be formed with layer with the first show electrode 132 and be used for the first frame-chip lead 135 of being connected with external drive core by the first border electrode of follow-up formation and be used for that the gate-shaped electrode voltage signal line of follow-up formation is connected first with external drive core showing-chip lead 136.First show electrode 132, the first frame-chip lead 135 and first show-and the formation material of chip lead 136 can select transparent conductive material, and formation process adopts patterning processes.
Step S12: form insulation course on the first substrate 11 being formed with the first show electrode 132.
Insulation course is electrically insulated with the first border electrode of follow-up formation for keeping the first show electrode 132.
Step S13: form via hole 6 on the insulating layer, to expose the first show electrode 132, see Fig. 6 b.
Concrete, the region that via hole 6 comes out comprises the first show electrode 132 for the end be electrically connected with the gate-shaped electrode voltage signal line of follow-up formation, also can comprise the two ends of the first frame-chip lead 135 and the first display-chip lead 136.
Step S14: form the figure comprising the first border electrode 131 and gate-shaped electrode voltage signal line 133 on the insulating layer, first border electrode 131 is face electrode, gate-shaped electrode voltage signal line 133 is positioned at the periphery of the first border electrode 131, and gate-shaped electrode voltage signal line 133 is electrical connected, see Fig. 6 c by via hole 6 and the first show electrode 132.
In this step, the formation material of the first border electrode 131 and gate-shaped electrode voltage signal line 133 can select metal material, and to ensure good electric conductivity, formation process adopts patterning processes.
While gate-shaped electrode voltage signal line 133 realizes being electrically connected with the first show electrode 132, gate-shaped electrode voltage signal line 133 shows with first-and chip lead 136, first border electrode 131 also achieves with the first frame-chip lead 135 and is electrically connected.
As shown in Fig. 7 a ~ Fig. 7 c, second substrate 12 is formed the second electrode lay 14 and specifically comprises:
Step S21: form the figure comprising frame-shaped electrode voltage signal line 143 and viewing area public electrode voltages signal wire 144 on second substrate 12, wherein, frame-shaped electrode voltage signal line 143 is positioned at the periphery of the second frame electrode zone to be formed, when liquid crystal grating is superimposed with display module, the vertical projection of viewing area public electrode voltages signal wire 144 on first substrate 11 is overlapping with a part for the black matrix vertical projection on the first substrate of display module, see Fig. 7 a.
In this step, the formation material of frame-shaped electrode voltage signal line 143 and viewing area public electrode voltages signal wire 144 preferably can adopt metal material, and formation process adopts patterning processes.
Step S22: form insulation course on the second substrate 12 being formed with frame-shaped electrode voltage signal line 143 and viewing area public electrode voltages signal wire 144.
Step S23: form via hole 7 on the insulating layer, this via hole 7 exposes frame-shaped electrode voltage signal line 143 and viewing area public electrode voltages signal wire 144, see Fig. 7 b.
In this step, in the black matrix that the vertical projection of via hole on first substrate 11 exposing viewing area public electrode voltages signal wire 144 drops on display module vertical projection on the first substrate, thus can not impact display frame.
Via hole 7 also can expose frame-shaped electrode voltage signal line 143 and the end of viewing area public electrode voltages signal wire 144 outside liquid crystal grating, with in subsequent step, external drive chip is electrically connected with frame-shaped electrode voltage signal line 143 and viewing area public electrode voltages signal wire 144 respectively by this via hole.
Step S24: form the second border electrode 141 and the second show electrode 142 on the insulating layer, wherein, second border electrode 141 is frame-shaped electrode, and the second border electrode 141 is electrical connected by via hole 7 and frame-shaped electrode voltage signal line 143, second show electrode 142 is face electrode, and the second show electrode 142 is electrical connected, see Fig. 7 c by via hole 7 and viewing area public electrode voltages signal wire 144.
In this step, the second border electrode 141 and the second show electrode 142 preferably can adopt transparent conductive material, utilize patterning processes to be formed simultaneously.Meanwhile, the via hole 7 being positioned at frame-shaped electrode voltage signal line 143 and the end of viewing area public electrode voltages signal wire 144 outside liquid crystal grating is also filled by transparent conductive material, make driving chip by this via hole electrical connection frame-shaped electrode voltage signal line 143 and viewing area public electrode voltages signal wire 144, and then carry corresponding signal to the second border electrode 141 and the second show electrode 142.
It should be noted that, below only with step S11 ~ step S14, step S21 ~ step S24 is illustrated the method for making of the first electrode layer 13 and the second electrode lay 14 respectively, in actual design and production run, those skilled in the art also can according to the first border electrode 131 of required preparation, first show electrode 132, the concrete structure of the second border electrode 141 and the second show electrode 142, material, the difference of type of drive etc., by to step S11 ~ step S14, step S21 ~ step S24 carries out being out of shape and obtains the first required border electrode 131, first show electrode 132, second border electrode 141 and the second show electrode 142.
Embodiment three
Present embodiments provide a kind of driving method of liquid crystal grating, for driving embodiment with described liquid crystal grating, this driving method comprises: when needs carry out 3D and 2D display, different voltage signals is applied respectively to the first border electrode 131 and the second border electrode 141, make coating-forming voltage between the first border electrode 131 and the second border electrode 141 poor, to control turning to of liquid crystal molecule in rim area 21, scattering is made to enter rim area 21 outgoing of the light A in rim area 21 from second substrate 12.
In the present embodiment, by applying different voltage signals respectively to the first border electrode 131 and the second border electrode 141, make coating-forming voltage therebetween poor, reach the object turned to of the liquid crystal molecule controlled in rim area 21, thus scattering can be made to enter the rim area outgoing of the light in rim area 21 from second substrate 12, rim area 21 has certain display brightness, after made liquid crystal grating superposed with mosaic screen using, the rim area 21 of liquid crystal grating covers in the seam of mosaic screen, seam can be made to become not obvious, thus improve the display quality of mosaic screen.
If the first electrode layer 13 of the liquid crystal grating driven also comprises the first show electrode 132 that corresponding viewing area 22 is arranged, when the second electrode lay 14 also comprises the second show electrode 142 of corresponding viewing area 22 setting, this liquid crystal grating can realize 3D and 2D display, and concrete driving method is:
When needs carry out 3D display, different voltage signals is applied respectively to the first show electrode 132 and the second show electrode 142, make coating-forming voltage between the first show electrode 132 and the second show electrode 142 poor, to control turning to of liquid crystal molecule in viewing area 22, form grating in viewing area 22.After forming grating, utilize the parallax existed between right and left eyes, in the displaying time of a frame, through the same lightproof area of grating, left eye only can see the pixel for showing left-eye image, right eye only can see the pixel for showing eye image, and because left-eye image and eye image are the picture taken from different perspectives, therefore left-eye image there will be 3D effect after superposing with eye image.
When needs carry out 2D display, apply identical voltage signal respectively to the first show electrode 132 and the second show electrode 142 or do not apply voltage signal, the first show electrode 132 is made to keep voltage identical with the second show electrode 142, be in initial orientation state with the liquid crystal molecule controlled in viewing area 22, allow light all to pass through in viewing area 22.When carrying out 2D display, not need viewing area 22 in formation grating, only need the viewing area 22 of liquid crystal grating can allow light all by.
More specifically, if the first border electrode 131 is face electrode, second border electrode 141 is frame-shaped electrode, first show electrode 132 is gate-shaped electrode, second show electrode 142 is face electrode, then above-mentionedly apply different voltage signals respectively to the first border electrode 131 and the second border electrode 141 and be specially: apply rim area public electrode voltages signal to the first border electrode 131, and apply frame-shaped electrode voltage signal to the second border electrode 141; Apply different voltage signals respectively to the first show electrode 132 and the second show electrode 142 to be specially: apply gate-shaped electrode voltage signal to the first show electrode 132, and apply viewing area public electrode voltages signal to the second show electrode 142, with respectively in rim area 21 and viewing area 22 coating-forming voltage poor, the liquid crystal molecule controlled in respective region carries out different deflection.
Embodiment four
Present embodiments provide a kind of mosaic screen, comprising: the multiple display modules be stitched together, the plurality of display module is matrix form arrangement; Liquid crystal grating described in embodiment one, this liquid crystal grating covers on the display surface of multiple display module, and liquid crystal grating comprises multiple raster unit 2, and multiple raster unit is overlapping with multiple display module one_to_one corresponding.
From describing above, when showing, the rim area 21 of liquid crystal grating provided by the utility model has certain brightness, when this liquid crystal grating covers on spliced display module, the rim area 21 of liquid crystal grating just in time can hide the splicing seams that tiled display module is formed, user is when watching the display frame of mosaic screen, and the brightness of the rim area 21 of seam crossing liquid crystal grating makes splicing seams become not obvious, thus drastically increases the display quality of splicing picture.
In the present embodiment, the rim area 21 of the raster unit 2 of liquid crystal grating is overlapping with the rim area of display module, the viewing area of raster unit 2 is overlapping with the viewing area of display module, to ensure that the splicing seams that the frame of display module is formed can hide by the rim area 21 of liquid crystal grating completely.
Preferably can be the first substrate 11 of liquid crystal grating near the substrate of liquid crystal grating in multiple display module, namely the joint of multiple display module and liquid crystal grating can common substrate, the figure of the first electrode layer 13 of liquid crystal grating directly can be prepared in the substrate of multiple display module near liquid crystal grating towards the side of liquid crystal grating, thus reaches the object reduced costs.
The mosaic screen that this enforcement provides preferably can be flexible mosaic screen, namely shows the substrate that module and liquid crystal grating adopt and all selects flexible base, board to make.
It should be noted that, the display module in the present embodiment can be liquid crystal panel, Electronic Paper or OLED (Organic Light-Emitting Diode, Organic Light Emitting Diode) panel.
The foregoing is only embodiment of the present utility model; but protection domain of the present utility model is not limited thereto; anyly be familiar with those skilled in the art in the technical scope that the utility model discloses; the change that can expect easily or replacement, all should be encompassed within protection domain of the present utility model.Therefore, protection domain of the present utility model should be as the criterion with the protection domain of described claim.
Claims (14)
1. a liquid crystal grating, comprise the first substrate and second substrate that are oppositely arranged, and the liquid crystal molecule be filled between described first substrate and described second substrate, described first substrate is provided with the first electrode layer, described second substrate is provided with the second electrode lay, it is characterized in that, described liquid crystal grating comprises at least one raster unit, described raster unit comprises a viewing area, and surrounds the rim area of described viewing area;
Described first electrode layer comprises the first border electrode that corresponding described rim area is arranged;
Described the second electrode lay comprises the second border electrode that corresponding described rim area is arranged;
Wherein, it is poor that described first border electrode and described second border electrode are used for the coating-forming voltage when carrying out 3D and 2D display, to control turning to of liquid crystal molecule in described rim area, scattering is made to enter the rim area outgoing of the light in described rim area from described second substrate.
2. liquid crystal grating according to claim 1, is characterized in that, described first electrode layer also comprises the first show electrode that corresponding described viewing area is arranged;
Described the second electrode lay also comprises the second show electrode that corresponding described viewing area is arranged;
It is poor that described first show electrode and described second show electrode are used for carrying out coating-forming voltage when 3D shows at needs, to control turning to of liquid crystal molecule in described viewing area, grating is formed in described viewing area, keep voltage identical when needs carry out 2D display, be in initial orientation state with the liquid crystal molecule controlled in described viewing area, allow light all to pass through in described viewing area.
3. liquid crystal grating according to claim 2, is characterized in that, the formation material of described first border electrode is metal, and the formation material of described second border electrode, described first show electrode and described second show electrode is transparent conductive material.
4. liquid crystal grating according to claim 3, is characterized in that, described first border electrode and described first show electrode are electrically insulated, and described second border electrode and described second show electrode are electrically insulated.
5. liquid crystal grating according to claim 4, is characterized in that, described first border electrode is face electrode, and described second border electrode is frame-shaped electrode, and described first show electrode is gate-shaped electrode, and described second show electrode is face electrode.
6. liquid crystal grating according to claim 5, is characterized in that, described first border electrode is the face electrode extended in the corresponding region of described rim area;
Described second border electrode comprises at least one frame-shaped electrode; When described second border electrode comprises multiple frame-shaped electrode, described multiple frame-shaped electrode is according to the descending order of size around distribution, and described multiple frame-shaped electrode is electrically insulated each other;
Described first show electrode comprises the sub-gate electrode of multiple strip be arranged in parallel;
Described second show electrode is the face electrode extended in the corresponding region of described viewing area.
7. liquid crystal grating according to claim 5, is characterized in that, described first border electrode is applied in rim area public electrode voltages signal; Described first electrode layer also comprises: the gate-shaped electrode voltage signal line being arranged at described first border electrode periphery, described gate-shaped electrode voltage signal line is electrical connected by via hole and described first show electrode, for applying gate-shaped electrode voltage signal to described first show electrode;
Described the second electrode lay also comprises: the frame-shaped electrode voltage signal line being arranged at described second border electrode periphery, described frame-shaped electrode voltage signal line is electrical connected by via hole and described second border electrode, for applying frame-shaped electrode voltage signal to described second border electrode; The viewing area public electrode voltages signal wire of described second border electrode periphery is extended to through described viewing area, described viewing area public electrode voltages signal wire is electrical connected by via hole and described second show electrode, for applying viewing area public electrode voltages signal to described second show electrode;
Wherein, between described rim area public electrode voltages signal and described frame-shaped electrode voltage signal, there is voltage difference, between described gate-shaped electrode voltage signal and described viewing area public electrode voltages signal, there is voltage difference.
8. liquid crystal grating according to claim 7, is characterized in that, the formation material of described gate-shaped electrode voltage signal line, described viewing area public electrode voltages signal wire and described frame-shaped electrode voltage signal line is metal.
9. liquid crystal grating according to claim 7, it is characterized in that, when described liquid crystal grating is superimposed with display module, the vertical projection of described viewing area public electrode voltages signal wire on described first substrate is overlapping with a part for the vertical projection of black matrix on described first substrate of described display module.
10. the liquid crystal grating according to any one of claim 1 ~ 9, is characterized in that, described first substrate and described second substrate are flexible base, board.
11. 1 kinds of mosaic screens, is characterized in that, comprising:
The multiple display modules be stitched together, described multiple display module is matrix form arrangement;
Liquid crystal grating described in any one of claim 1 ~ 10, described liquid crystal grating covers on the display surface of described multiple display module, and described liquid crystal grating comprises multiple raster unit, and described multiple raster unit is overlapping with described multiple display module one_to_one corresponding.
12. mosaic screens according to claim 11, is characterized in that, the rim area of described raster unit is overlapping with the rim area of described display module, and the viewing area of described raster unit is overlapping with the viewing area of described display module.
13. mosaic screens according to claim 11, is characterized in that, are the first substrate of described liquid crystal grating in described multiple display module near the substrate of described liquid crystal grating.
14. mosaic screens according to claim 11, is characterized in that, described mosaic screen is flexible mosaic screen.
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104460136A (en) * | 2014-12-30 | 2015-03-25 | 京东方科技集团股份有限公司 | Liquid crystal optical grating, manufacturing and drive methods thereof and spliced screen |
CN111427114A (en) * | 2020-04-30 | 2020-07-17 | 京东方科技集团股份有限公司 | Image transfer module, display device and control method |
US10885875B2 (en) | 2018-03-29 | 2021-01-05 | Au Optronics Corporation | Seamless or frameless display device having lens layer |
-
2014
- 2014-12-30 CN CN201420860779.XU patent/CN204302632U/en not_active Withdrawn - After Issue
Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
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CN104460136A (en) * | 2014-12-30 | 2015-03-25 | 京东方科技集团股份有限公司 | Liquid crystal optical grating, manufacturing and drive methods thereof and spliced screen |
WO2016107027A1 (en) * | 2014-12-30 | 2016-07-07 | 京东方科技集团股份有限公司 | Liquid crystal grating and manufacturing method and drive method therefor, and splicing screen |
CN104460136B (en) * | 2014-12-30 | 2017-06-23 | 京东方科技集团股份有限公司 | Liquid crystal grating and preparation method thereof and driving method, mosaic screen |
US10241358B2 (en) | 2014-12-30 | 2019-03-26 | Boe Technology Group Co., Ltd. | Liquid crystal grating and manufacturing method and driving method therefor, and spliced screen |
US10885875B2 (en) | 2018-03-29 | 2021-01-05 | Au Optronics Corporation | Seamless or frameless display device having lens layer |
CN111427114A (en) * | 2020-04-30 | 2020-07-17 | 京东方科技集团股份有限公司 | Image transfer module, display device and control method |
CN111427114B (en) * | 2020-04-30 | 2022-10-28 | 京东方科技集团股份有限公司 | Image transfer module, display device and control method |
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