CN203606600U - Naked-eye 3D display - Google Patents

Abstract

The utility model discloses a naked-eye 3D display. The naked-eye 3D display comprises a TFT display module and a light modulation device. The light modulation device is arranged in a path for transmitting image signal light generated by the TFT display module, and fits completely to the TFT display module. The light modulation device comprises an electrochromatic device which has a functional circuit for a touch screen. By adopting the above structure, the naked-eye 3D display provided by the utility model is capable of not only displaying two-dimensional planar images in both the vertical direction and the horizontal direction, but also displaying three-dimensional stereoscopic images; besides, the thickness of the modules of the naked-eye 3D display is reduced, the cost of the substrate is lowered, and the transmitance of light is increased.

Description

Bore hole 3D display

Technical field

The utility model relates to stereo display technique field, relates in particular to a kind of bore hole 3D display.

Background technology

In the current 3D display technology with touch-screen, included TFT module, grating module and the touch screen module of 3D display normally independently made, and TFT module, grating module and the touch screen module of finished product forms 3D display through rationally arranging.So design, makes the module thickness of whole 3D display larger, and then transmittance reduction, the substrate cost of 3D display are improved.

Therefore, need to provide a kind of bore hole 3D display to solve the problems of the technologies described above.

Utility model content

The technical problems to be solved in the utility model is to provide a kind of bore hole 3D display.

The purpose of this utility model is to provide a kind of bore hole 3D display, comprising: TFT display module, light modulating device;

Described TFT display module, for synthetic image signal light;

Described light modulating device, be arranged on the bang path of the picture signal light that described TFT display module generates, and the full laminating of described light modulating device and TFT display module is set together, comprise: image display format command reception device, display direction pick-up unit, the first electric field generator, the second electric field generator, the 3rd electric field generator, electrochromic device;

Described image display format command reception device, for receiving the instruction of image display format, receives image and is shown as the format order that two-dimentional plane shows the format order of image or the stereoscopically displaying images of three-dimensional;

Described display direction pick-up unit, for detection of the display direction of described TFT display module, the display direction that detects described TFT display module is vertical direction or horizontal direction;

Described the first electric field generator, with the first electrode on the first conductive layer in described electrochromic device, the 4th electrode on the second conductive layer is electrically connected, be used for according to the received image display format instruction of described image display format command reception device, and the display direction of the described TFT display module detecting according to described display direction pick-up unit, receive image at described image display format command reception device and be shown as display direction that two-dimentional plane shows that the format order of image and described display direction pick-up unit detect described TFT display module while being vertical direction or horizontal direction, not to the first electrode on described the first conductive layer, the 4th electrode on described the second conductive layer provides electric field,

Receive image at described image display format command reception device and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and described display direction pick-up unit detect described TFT display module while being vertical direction, provide electric field to the first electrode on described the first conductive layer, the 4th electrode on described the second conductive layer;

Receive image at described image display format command reception device and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and described display direction pick-up unit detect described TFT display module while being horizontal direction, provide electric field to the first electrode on described the first conductive layer, the 4th electrode on described the second conductive layer;

Described the second electric field generator, with the second electrode on described the first conductive layer in described electrochromic device, the 5th electrode on described the second conductive layer is electrically connected, be used for according to the received image display format instruction of described image display format command reception device, and the display direction of the described TFT display module detecting according to described display direction pick-up unit, receive image at described image display format command reception device and be shown as display direction that two-dimentional plane shows that the format order of image and described display direction pick-up unit detect described TFT display module while being vertical direction or horizontal direction, not to the second electrode on described the first conductive layer, the 5th electrode on described the second conductive layer provides electric field,

Receive image at described image display format command reception device and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and described display direction pick-up unit detect described TFT display module while being vertical direction, provide electric field to the second electrode on described the first conductive layer, the 5th electrode on described the second conductive layer;

Receive image at described image display format command reception device and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and described display direction pick-up unit detect described TFT display module while being horizontal direction, do not provide electric field to the second electrode on described the first conductive layer, the 5th electrode on described the second conductive layer;

Described the 3rd electric field generator, with the third electrode on the first conductive layer described in described electrochromic device, the 6th electrode on described the second conductive layer is electrically connected, be used for according to the received image display format instruction of described image display format command reception device, and the display direction of the described TFT display module detecting according to described display direction pick-up unit, receive image at described image display format command reception device and be shown as display direction that two-dimentional plane shows that the format order of image and described display direction pick-up unit detect described TFT display module while being vertical direction or horizontal direction, not to the third electrode on described the first conductive layer, the 6th electrode on described the second conductive layer provides electric field,

Receive image at described image display format command reception device and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and described display direction pick-up unit detect described TFT display module while being vertical direction, do not provide electric field to the third electrode on described the first conductive layer, the 6th electrode on described the second conductive layer;

Receive image at described image display format command reception device and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and described display direction pick-up unit detect described TFT display module while being horizontal direction, provide electric field to the third electrode on described the first conductive layer, the 6th electrode on described the second conductive layer;

Described electrochromic device, comprising: risen by described TFT display module side, be arranged in order first substrate, the first conductive layer, electrochromic layer, dielectric substrate, the second conductive layer, the second substrate of setting;

Or risen by described TFT display module side, be arranged in order first substrate, the first conductive layer, dielectric substrate, electrochromic layer, the second conductive layer, the second substrate of setting;

Described first substrate, the picture signal light generating for seeing through described TFT display module;

Described the first conductive layer, comprising:

The first current-carrying part of multiple square shapes, the electrode of the first current-carrying part of described multiple square shapes is in parallel, and obtains the first electrode, and the first current-carrying part of described multiple square shapes is for seeing through described first substrate institute transmitted light;

The second current-carrying part of multiple square shapes, the electrode of the second current-carrying part of described multiple square shapes is in parallel, and obtains the second electrode, and the second current-carrying part of described multiple square shapes is for seeing through described first substrate institute transmitted light;

The 3rd current-carrying part of multiple square shapes, the electrode of the 3rd current-carrying part of described multiple square shapes is in parallel, and obtains third electrode, and the 3rd current-carrying part of described multiple square shapes is for seeing through described first substrate institute transmitted light;

The first light transmission part of multiple square shapes, for seeing through described first substrate institute transmitted light;

The 3rd current-carrying part of the first current-carrying part of described square shape and described square shape is arranged at same a line and alternately; The second current-carrying part of described square shape and the first light transmission part of described square shape are arranged at same a line and alternately; The first current-carrying part of described square shape and the second current-carrying part of described square shape are arranged at same row and alternately; The 3rd current-carrying part of described square shape and the first light transmission part of described square shape are arranged at same row and alternately;

Described electrochromic layer, it is according to described the first conductive layer, described the second electrically conducting of conductive layer and produce change color, comprising discolors becomes pellucidity, or the painted opaque state that becomes, for at described the first electric field generator not to the first electrode on described the first conductive layer, the 4th electrode on described the second conductive layer provides electric field, and described the second electric field generator is not to the second electrode on described the first conductive layer, the 5th electrode on described the second conductive layer provides electric field, and described the 3rd electric field generator is not to the third electrode on described the first conductive layer, when the 6th electrode on described the second conductive layer provides electric field, become pellucidity, see through the light that described the first conductive layer sees through, obtain two-dimentional plane and show image,

At described the first electric field generator to the first electrode on described the first conductive layer, the 4th electrode on described the second conductive layer provides electric field, and described the second electric field generator is to the second electrode on described the first conductive layer, the 5th electrode on described the second conductive layer provides electric field, and described the 3rd electric field generator is not to the third electrode on described the first conductive layer, when the 6th electrode on described the second conductive layer provides electric field, become partially transparent state, part opaque state, part sees through the light that described the first conductive layer sees through, part does not see through the light that described the first conductive layer sees through, form slit grating, the 3 D stereo that obtains Glassless shows image,

At described the first electric field generator to the first electrode on described the first conductive layer, the 4th electrode on described the second conductive layer provides electric field, and described the second electric field generator is not to the second electrode on described the first conductive layer, the 5th electrode on described the second conductive layer provides electric field, and described the 3rd electric field generator is to the third electrode on described the first conductive layer, when the 6th electrode on described the second conductive layer provides electric field, become partially transparent state, part opaque state, part sees through the light that described the first conductive layer sees through, part does not see through the light that described the first conductive layer sees through, form slit grating, the 3 D stereo that obtains Glassless shows image,

Described dielectric substrate, for providing ion to described electrochromic layer, makes described electrochromic layer produce the reversible reaction of oxidation or reduction and produces change color, and comprising discolors becomes pellucidity, or the painted opaque state that becomes;

Described the second conductive layer comprises:

The 4th current-carrying part of multiple square shapes, the electrode of the 4th current-carrying part of described multiple square shapes is in parallel, and obtains the 4th electrode, and the 4th current-carrying part of described multiple square shapes is for seeing through described electrochromic layer institute transmitted light;

The 5th current-carrying part of multiple square shapes, the electrode of the 5th current-carrying part of described multiple square shapes is in parallel, and obtains the 5th electrode, and the 5th current-carrying part of described multiple square shapes is for seeing through described electrochromic layer institute transmitted light;

The 6th current-carrying part of multiple square shapes, the electrode of the 6th current-carrying part of described multiple square shapes is in parallel, and obtains the 6th electrode, and the 6th current-carrying part of described multiple square shapes is for seeing through described electrochromic layer institute transmitted light;

The second light transmission part of multiple square shapes, for seeing through described electrochromic layer institute transmitted light;

The 4th current-carrying part of described square shape and the 6th current-carrying part of described square shape are arranged at same a line and alternately; The 5th current-carrying part of described square shape and the second light transmission part of described square shape are arranged at same a line and alternately; The 4th current-carrying part of described square shape and the 5th current-carrying part of described square shape are arranged at same row and alternately; The 6th current-carrying part of described square shape and the second light transmission part of described square shape are arranged at same row and alternately;

Described second substrate, the light seeing through for seeing through described the second conductive layer;

Wherein, have the functional circuit of touch-screen to be arranged on first substrate towards the surface of the first conductive layer or dorsad on the surface of the first conductive layer, or have the functional circuit of touch-screen be arranged on second substrate towards the surface of the second conductive layer or dorsad on the surface of the second conductive layer.

Wherein, described the first conductive layer, comprising: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass;

Described the second conductive layer, comprising: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass.

Wherein, the first current-carrying part of described multiple square shapes, comprising: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass;

The second current-carrying part of described multiple square shapes, comprising: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass;

The 3rd current-carrying part of described multiple square shapes, comprising: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass;

The 4th current-carrying part of described multiple square shapes, comprising: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass;

The 5th current-carrying part of described multiple square shapes, comprising: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass;

The 6th current-carrying part of described multiple square shapes, comprising: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass.

Wherein, described electrochromic layer, comprising: printable electrochromism ink, or electrochomeric films, or electrochomeric glass, or automatically controlled light transmission film;

Described dielectric substrate, comprising: printable electrolyte ink.

Wherein, described the first electric field generator, comprising: power supply, or the dutycycle square wave driving voltage that is 50%;

Described the second electric field generator, comprising: power supply, or the dutycycle square wave driving voltage that is 50%;

Described the 3rd electric field generator, comprising: power supply, or the dutycycle square wave driving voltage that is 50%.

Wherein, the electrode relation of described the first electrode, described the 4th electrode, comprising: described the first electrode is positive source, described the 4th electrode supply negative pole, or described the first electrode is that power cathode, described the 4th electrode are positive source;

The electrode relation of described the second electrode, described the 5th electrode, comprising: described the second electrode is that positive source, described the 5th electrode are power cathode, or described the second electrode is that power cathode, described the 5th electrode are positive source;

The electrode relation of described third electrode, described the 6th electrode, comprising: described third electrode is that positive source, described the 6th electrode are power cathode, or described third electrode is that power cathode, described the 6th electrode are positive source.

Wherein, the size of the first light transmission part of the size of the 3rd current-carrying part of the size of the first current-carrying part of described square shape and the size of the second current-carrying part of described square shape, described square shape, described square shape is identical;

The size of the 4th current-carrying part of described square shape is identical with the size of the second light transmission part of the size of the 6th current-carrying part of the size of the 5th current-carrying part of described square shape, described square shape, described square shape;

The size of the first current-carrying part of described square shape is identical with the size of the 4th current-carrying part of described square shape.

Wherein, it is identical with electric field level that described the 3rd electric field generator offers described third electrode, described the 6th electrode that the electric field level that described the first electric field generator offers described the first electrode, described the 4th electrode and described the second electric field generator offer the electric field level of described the second electrode, described the 5th electrode.

Wherein, described TFT display module, comprising: TV, or computer, or projector, or navigating instrument, or mobile phone, or camera.

Wherein, described touch-screen comprises resistive touch screen or capacitive touch screen.

The beneficial effects of the utility model are: bore hole 3D display of the present utility model by forming electrochromic device by the functional circuit of touch-screen and the design of electrochromism grating on same substrate, and then do full laminating design with TFT indicating template, the reduced thickness of whole 3D display module, required substrate cost and light penetration are improved, and the bore hole 3D display that provides of the utility model effect that can realize two-way bore hole and watch 3D rendering.

Accompanying drawing explanation

Fig. 1 is the structural representation of the utility model bore hole 3D display;

Fig. 2 is the perspective exploded view of the utility model bore hole 3D display;

Fig. 3 is the structural representation of the utility model the first conductive layer;

Fig. 4, the perspective exploded view while forming in vertical direction slit grating for the utility model bore hole 3D display;

Fig. 5, the perspective exploded view while forming in the horizontal direction slit grating for the utility model bore hole 3D display;

Fig. 6 is the structural representation of the utility model the second conductive layer;

Fig. 7 is the perspective exploded view of the second structure of the utility model electrochromic device;

Fig. 8, the perspective exploded view while forming in vertical direction slit grating for the second structure of the utility model electrochromic device;

Fig. 9, the perspective exploded view while forming in the horizontal direction slit grating for the second structure of the utility model electrochromic device.

Embodiment

Refer to Fig. 1 and Fig. 2, Fig. 1, is the structural representation of the utility model bore hole 3D display, and Fig. 2 is the perspective exploded view of the utility model bore hole 3D display, and this bore hole 3D display comprises: TFT display module 1, light modulating device 2;

TFT display module 1, for synthetic image signal light;

Light modulating device 2, be arranged on the bang path of the picture signal light that TFT display module 1 generates, and light modulating device 2 is set together with the full laminating of TFT display module 1, comprise: image display format command reception device 21, display direction pick-up unit 22, the first electric field generator 23, the second electric field generators 24, the 3rd electric field generator 25, electrochromic device 26;

Image display format command reception device 21, for receiving the instruction of image display format, receives image and is shown as the format order that two-dimentional plane shows the format order of image or the stereoscopically displaying images of three-dimensional;

Display direction pick-up unit 22, for detection of the display direction of TFT display module 1, the display direction that detects TFT display module 1 is vertical direction or horizontal direction;

The first electric field generator 23, with in the first electrode 2625(figure on the first conductive layer 262 in electrochromic device 26, do not indicate), in the 4th electrode 2655(figure on the second conductive layer 265, do not indicate) be electrically connected, be used for according to the received image display format instruction of image display format command reception device 21, and the display direction of the TFT display module 1 detecting according to display direction pick-up unit 22, receive image at image display format command reception device 21 and be shown as display direction that two-dimentional plane shows that the format order of image and display direction pick-up unit 22 detect TFT display module 1 while being vertical direction, not to the first electrode 2625 on the first conductive layer 262, the 4th electrode 2655 on the second conductive layer 265 provides electric field,

Receive image at image display format command reception device 21 and be shown as display direction that two-dimentional plane shows that the format order of image and display direction pick-up unit 22 detect TFT display module 1 while being horizontal direction, do not provide electric field to the first electrode 2625 on the first conductive layer 262, the 4th electrode 2655 on the second conductive layer 265;

Receive image at image display format command reception device 21 and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and display direction pick-up unit 22 detect TFT display module 1 while being vertical direction, provide electric field to the first electrode 2625 on the first conductive layer 262, the 4th electrode 2655 on the second conductive layer 265;

Receive image at image display format command reception device 21 and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and display direction pick-up unit 22 detect TFT display module 1 while being horizontal direction, provide electric field to the first electrode 2625 on the first conductive layer 262, the 4th electrode 2655 on the second conductive layer 265;

The second electric field generator 24, with in the second electrode 2626(figure on the first conductive layer 262 in electrochromic device 26, do not indicate), in the 5th electrode 2656(figure on the second conductive layer 265, do not indicate) be electrically connected, be used for according to the received image display format instruction of image display format command reception device 21, and the display direction of the TFT display module 1 detecting according to display direction pick-up unit 22, receive image at image display format command reception device 21 and be shown as display direction that two-dimentional plane shows that the format order of image and display direction pick-up unit 22 detect TFT display module 1 while being vertical direction, not to the second electrode 2626 on the first conductive layer 262, the 5th electrode 2656 on the second conductive layer 265 provides electric field,

Receive image at image display format command reception device 21 and be shown as display direction that two-dimentional plane shows that the format order of image and display direction pick-up unit 22 detect TFT display module 1 while being horizontal direction, do not provide electric field to the second electrode 2626 on the first conductive layer 262, the 5th electrode 2656 on the second conductive layer 265;

Receive image at image display format command reception device 21 and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and display direction pick-up unit 22 detect TFT display module 1 while being vertical direction, provide electric field to the second electrode 2626 on the first conductive layer 262, the 5th electrode 2656 on the second conductive layer 265;

Receive image at image display format command reception device 21 and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and display direction pick-up unit 22 detect TFT display module 1 while being horizontal direction, do not provide electric field to the second electrode 2626 on the first conductive layer 262, the 5th electrode 2656 on the second conductive layer 265;

The 3rd electric field generator 25, with in third electrode 2627(figure on the first conductive layer 262 in electrochromic device 26, do not indicate), in the 6th electrode 2657(figure on the second conductive layer 265, do not indicate) be electrically connected, be used for according to the received image display format instruction of image display format command reception device 21, and the display direction of the TFT display module 1 detecting according to display direction pick-up unit 22, receive image at image display format command reception device 21 and be shown as display direction that two-dimentional plane shows that the format order of image and display direction pick-up unit 22 detect TFT display module 1 while being vertical direction, not to the third electrode 2627 on the first conductive layer 262, the 6th electrode 2657 on the second conductive layer 265 provides electric field,

Receive image at image display format command reception device 21 and be shown as display direction that two-dimentional plane shows that the format order of image and display direction pick-up unit 22 detect TFT display module 1 while being horizontal direction, do not provide electric field to the third electrode 2627 on the first conductive layer 262, the 6th electrode 2657 on the second conductive layer 265;

Receive image at image display format command reception device 21 and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and display direction pick-up unit 22 detect TFT display module 1 while being vertical direction, do not provide electric field to the third electrode 2627 on the first conductive layer 262, the 6th electrode 2657 on the second conductive layer 265;

Receive image at image display format command reception device 21 and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and display direction pick-up unit 22 detect TFT display module 1 while being horizontal direction, provide electric field to the third electrode 2627 on the first conductive layer 262, the 6th electrode 2657 on the second conductive layer 265;

Electrochromic device 26, comprising: risen by TFT display module 1 side, be arranged in order first substrate 261, the first conductive layer 262, electrochromic layer 263, dielectric substrate 264, the second conductive layer 265, the second substrate 266 of setting;

First substrate 261, the picture signal light generating for seeing through TFT display module 1;

Referring to Fig. 3, is the structural representation of the utility model the first conductive layer 262, and this first conductive layer 262 comprises:

The first current-carrying part 2621 of multiple square shapes, the electrode of the first current-carrying part 2621 of the plurality of square shape is in parallel, and obtains the first electrode 2625, and the first current-carrying part 2621 of the plurality of square shape is for seeing through 261 transmitted lights of first substrate;

The second current-carrying part 2622 of multiple square shapes, the electrode of the second current-carrying part 2622 of the plurality of square shape is in parallel, and obtains the second electrode 2626, and the second current-carrying part 2622 of the plurality of square shape is for seeing through 261 transmitted lights of first substrate;

The 3rd current-carrying part 2623 of multiple square shapes, the electrode of the 3rd current-carrying part 2623 of the plurality of square shape is in parallel, and obtains third electrode 2627, and the 3rd current-carrying part 2623 of the plurality of square shape is for seeing through 261 transmitted lights of first substrate;

The first light transmission part 2624 of multiple square shapes, for seeing through 261 transmitted lights of first substrate;

The first current-carrying part 2621 of the party's bulk and the 3rd current-carrying part 2623 of the party's bulk are arranged at same a line and alternately;

The second current-carrying part 2622 of the party's bulk and the first light transmission part 2624 of the party's bulk are arranged at same a line and alternately;

The first current-carrying part 2621 of the party's bulk and the second current-carrying part 2622 of the party's bulk are arranged at same row and alternately;

The 3rd current-carrying part 2623 of the party's bulk and the first light transmission part 2624 of the party's bulk are arranged at same row and alternately;

The size of the size of the size of the size of the first current-carrying part 2621 of the party's bulk and the second current-carrying part 2622 of square shape, the 3rd current-carrying part 2623 of the party's bulk, the first light transmission part 2624 of the party's bulk can be identical, also can be not identical;

Electrochromic layer 263, it produces change color according to the first conductive layer 262, electrically conducting of the second conductive layer 265, and comprising discolors becomes pellucidity, or the painted opaque state that becomes, for

Do not provide electric field to the first electrode 2625 on the first conductive layer 262, the 4th electrode 2655 on the second conductive layer 265 at the first electric field generator 23, and

The second electric field generator 24 does not provide electric field to the second electrode 2626 on the first conductive layer 262, the 5th electrode 2656 on the second conductive layer 265, and

When the 3rd electric field generator 25 does not provide electric field to the third electrode 2627 on the first conductive layer 262, the 6th electrode 2657 on the second conductive layer 265, become pellucidity, see through the light that the first conductive layer 262 sees through, obtain two-dimentional plane and show image;

Provide electric field at the first electric field generator 23 to the first electrode 2625 on the first conductive layer 262, the 4th electrode 2655 on the second conductive layer 265, and

The second electric field generator 24 provides electric field to the second electrode 2626 on the first conductive layer 262, the 5th electrode 2656 on the second conductive layer 265, and

The 3rd electric field generator 25 is not to the third electrode 2627 on the first conductive layer 262, when the 6th electrode 2657 on the second conductive layer 265 provides electric field, become partially transparent state, part opaque state, part sees through the light that the first conductive layer 262 sees through, part does not see through the light that the first conductive layer 262 sees through, form slit grating, the 3 D stereo that obtains Glassless shows image, refer to Fig. 4, perspective exploded view while forming in vertical direction slit grating for the utility model bore hole 3D display, the 3 D stereo that obtains in vertical direction Glassless for the utility model bore hole 3D display shows schematic diagram when image, wherein, the black part in Fig. 4 on electrochromic layer 263 represents the first lightproof part 2631, does not see through the light that the first conductive layer 262 sees through, and white portion represents the 3rd light transmission part 2632, sees through the light that the first conductive layer 262 sees through,

Provide electric field at the first electric field generator 23 to the first electrode 2625 on the first conductive layer 262, the 4th electrode 2655 on the second conductive layer 265, and

The second electric field generator 24 does not provide electric field to the second electrode 2626 on the first conductive layer 262, the 5th electrode 2656 on the second conductive layer 265, and

The 3rd electric field generator 25 is to the third electrode 2627 on the first conductive layer 262, when the 6th electrode 2657 on the second conductive layer 265 provides electric field, become partially transparent state, part opaque state, part sees through the light that the first conductive layer 262 sees through, part does not see through the light that the first conductive layer 262 sees through, form slit grating, the 3 D stereo that obtains Glassless shows image, refer to Fig. 5, perspective exploded view while forming in the horizontal direction slit grating for the utility model bore hole 3D display, the 3 D stereo that obtains in the horizontal direction Glassless for the utility model bore hole 3D display shows schematic diagram when image, wherein, the black part in Fig. 5 on electrochromic layer 263 represents the second lightproof part 2633, does not see through the light that the first conductive layer 262 sees through, and white portion represents the 4th light transmission part 2634, sees through the light that the first conductive layer 262 sees through,

Dielectric substrate 264, for providing ion to electrochromic layer 263, makes electrochromic layer 263 produce the reversible reaction of oxidation or reduction and produces change color, and comprising discolors becomes pellucidity, or the painted opaque state that becomes;

Referring to Fig. 6, is the structural representation of the utility model the second conductive layer 265, and this second conductive layer 265 comprises:

The 4th current-carrying part 2651 of multiple square shapes, the electrode of the 4th current-carrying part 2651 of the plurality of square shape is in parallel, and obtains the 4th electrode 2655, and the 4th current-carrying part 2651 of the plurality of square shape is for seeing through 263 transmitted lights of electrochromic layer;

The 5th current-carrying part 2652 of multiple square shapes, the electrode of the 5th current-carrying part 2652 of the plurality of square shape is in parallel, and obtains the 5th electrode 2656, and the 5th current-carrying part 2652 of the plurality of square shape is for seeing through 263 transmitted lights of electrochromic layer;

The 6th current-carrying part 2653 of multiple square shapes, the electrode of the 6th current-carrying part 2653 of the plurality of square shape is in parallel, and obtains the 6th electrode 2657, and the 6th current-carrying part 2653 of the plurality of square shape is for seeing through 263 transmitted lights of electrochromic layer;

The second light transmission part 2654 of multiple square shapes, for seeing through 263 transmitted lights of electrochromic layer;

The 4th current-carrying part 2651 of the party's bulk and the 6th current-carrying part 2653 of the party's bulk are arranged at same a line and alternately;

The 5th current-carrying part 2652 of the party's bulk and the second light transmission part 2654 of the party's bulk are arranged at same a line and alternately;

The 4th current-carrying part 2651 of the party's bulk and the 5th current-carrying part 2652 of the party's bulk are arranged at same row and alternately;

The 6th current-carrying part 2653 of the party's bulk and the second light transmission part 2654 of the party's bulk are arranged at same row and alternately;

The size of the size of the size of the size of the 4th current-carrying part 2651 of the party's bulk and the 5th current-carrying part 2652 of square shape, the 6th current-carrying part 2653 of the party's bulk, the second light transmission part 2654 of the party's bulk can be identical, also can be not identical;

Second substrate 266, the light seeing through for seeing through the second conductive layer 265.

Wherein, electrochromic device 26 also comprises the second structure, refer to Fig. 7, for the perspective exploded view of the second structure of the utility model electrochromic device 26, the second structure of this electrochromic device 26 comprises: risen by TFT display module 1 side, be arranged in order first substrate 261, the first conductive layer 262, dielectric substrate 264, electrochromic layer 263, the second conductive layer 265, the second substrate 266 of setting;

First substrate 261, the picture signal light generating for seeing through TFT display module 1;

The first conductive layer 262, comprising:

The first current-carrying part 2621 of multiple square shapes, the electrode of the first current-carrying part 2621 of the plurality of square shape is in parallel, and obtains the first electrode 2625, and the first current-carrying part 2621 of the plurality of square shape is for seeing through 261 transmitted lights of first substrate;

The second current-carrying part 2622 of multiple square shapes, the electrode of the second current-carrying part 2622 of the plurality of square shape is in parallel, and obtains the second electrode 2626, and the second current-carrying part 2622 of the plurality of square shape is for seeing through 261 transmitted lights of first substrate;

The 3rd current-carrying part 2623 of multiple square shapes, the electrode of the 3rd current-carrying part 2623 of the plurality of square shape is in parallel, and obtains third electrode 2627, and the 3rd current-carrying part 2623 of the plurality of square shape is for seeing through 261 transmitted lights of first substrate;

The first light transmission part 2624 of multiple square shapes, for seeing through 261 transmitted lights of first substrate;

The first current-carrying part 2621 of the party's bulk and the 3rd current-carrying part 2623 of the party's bulk are arranged at same a line and alternately;

The second current-carrying part 2622 of the party's bulk and the first light transmission part 2624 of the party's bulk are arranged at same a line and alternately;

The first current-carrying part 2621 of the party's bulk and the second current-carrying part 2622 of the party's bulk are arranged at same row and alternately;

The 3rd current-carrying part 2623 of the party's bulk and the first light transmission part 2624 of the party's bulk are arranged at same row and alternately;

The size of the size of the size of the size of the first current-carrying part 2621 of the party's bulk and the second current-carrying part 2622 of square shape, the 3rd current-carrying part 2623 of the party's bulk, the first light transmission part 2624 of the party's bulk can be identical, also can be not identical;

Dielectric substrate 264, for providing ion to electrochromic layer 263, makes electrochromic layer 263 produce the reversible reaction of oxidation or reduction and produces change color, and comprising discolors becomes pellucidity, or the painted opaque state that becomes;

Electrochromic layer 263, it produces change color according to the first conductive layer 262, electrically conducting of the second conductive layer 265, and comprising discolors becomes pellucidity, or the painted opaque state that becomes, for

Do not provide electric field to the first electrode 2625 on the first conductive layer 262, the 4th electrode 2655 on the second conductive layer 265 at the first electric field generator 23, and

The second electric field generator 24 does not provide electric field to the second electrode 2626 on the first conductive layer 262, the 5th electrode 2656 on the second conductive layer 265, and

When the 3rd electric field generator 25 does not provide electric field to the third electrode 2627 on the first conductive layer 262, the 6th electrode 2657 on the second conductive layer 265, become pellucidity, see through the light that the first conductive layer 262 sees through, obtain two-dimentional plane and show image;

Provide electric field at the first electric field generator 23 to the first electrode 2625 on the first conductive layer 262, the 4th electrode 2655 on the second conductive layer 265, and

The second electric field generator 24 provides electric field to the second electrode 2626 on the first conductive layer 262, the 5th electrode 2656 on the second conductive layer 265, and

The 3rd electric field generator 25 is not to the third electrode 2627 on the first conductive layer 262, when the 6th electrode 2657 on the second conductive layer 265 provides electric field, become partially transparent state, part opaque state, part sees through the light that the first conductive layer 262 sees through, part does not see through the light that the first conductive layer 262 sees through, form slit grating, the 3 D stereo that obtains Glassless shows image, refer to Fig. 8, perspective exploded view while forming in vertical direction slit grating for the second structure of the utility model electrochromic device 26, the 3 D stereo that obtains Glassless for the second structure of the utility model electrochromic device 26 shows schematic diagram when image, wherein, the black part in Fig. 8 on electrochromic layer 263 represents the first lightproof part 2631, does not see through the light that the first conductive layer 262 sees through, and white portion represents the 3rd light transmission part 2632, sees through the light that the first conductive layer 262 sees through,

Provide electric field at the first electric field generator 23 to the first electrode 2625 on the first conductive layer 262, the 4th electrode 2655 on the second conductive layer 265, and

The second electric field generator 24 does not provide electric field to the second electrode 2626 on the first conductive layer 262, the 5th electrode 2656 on the second conductive layer 265, and

The 3rd electric field generator 25 is to the third electrode 2627 on the first conductive layer 262, when the 6th electrode 2657 on the second conductive layer 265 provides electric field, become partially transparent state, part opaque state, part sees through the light that the first conductive layer 262 sees through, part does not see through the light that the first conductive layer 262 sees through, form slit grating, the 3 D stereo that obtains Glassless shows image, refer to Fig. 9, perspective exploded view while forming in the horizontal direction slit grating for the second structure of the utility model electrochromic device 26, the 3 D stereo that obtains in the horizontal direction Glassless for the second structure of the utility model electrochromic device 26 shows schematic diagram when image, wherein, the black part in Fig. 9 on electrochromic layer 263 represents the second lightproof part 2633, does not see through the light that the first conductive layer 262 sees through, and white portion represents the 4th light transmission part 2634, sees through the light that the first conductive layer 262 sees through,

The second conductive layer 265, comprising:

The 4th current-carrying part 2651 of multiple square shapes, the electrode of the 4th current-carrying part 2651 of the plurality of square shape is in parallel, and obtains the 4th electrode 2655, and the 4th current-carrying part 2651 of the plurality of square shape is for seeing through 263 transmitted lights of electrochromic layer;

The 5th current-carrying part 2652 of multiple square shapes, the electrode of the 5th current-carrying part 2652 of the plurality of square shape is in parallel, and obtains the 5th electrode 2656, and the 5th current-carrying part 2652 of the plurality of square shape is for seeing through 263 transmitted lights of electrochromic layer;

The 6th current-carrying part 2653 of multiple square shapes, the electrode of the 6th current-carrying part 2653 of the plurality of square shape is in parallel, and obtains the 6th electrode 2657, and the 6th current-carrying part 2653 of the plurality of square shape is for seeing through 263 transmitted lights of electrochromic layer;

The second light transmission part 2654 of multiple square shapes, for seeing through 263 transmitted lights of electrochromic layer;

The 4th current-carrying part 2651 of the party's bulk and the 6th current-carrying part 2653 of the party's bulk are arranged at same a line and alternately;

The 5th current-carrying part 2652 of the party's bulk and the second light transmission part 2654 of the party's bulk are arranged at same a line and alternately;

The 4th current-carrying part 2651 of the party's bulk and the 5th current-carrying part 2652 of the party's bulk are arranged at same row and alternately;

The 6th current-carrying part 2653 of the party's bulk and the second light transmission part 2654 of the party's bulk are arranged at same row and alternately;

The size of the size of the size of the size of the 4th current-carrying part 2651 of the party's bulk and the 5th current-carrying part 2652 of square shape, the 6th current-carrying part 2653 of the party's bulk, the second light transmission part 2654 of the party's bulk can be identical, also can be not identical;

Second substrate 266, the light seeing through for seeing through the second conductive layer 265.Wherein, the first conductive layer 262 comprises: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide (ITO) electro-conductive glass.

Wherein, the second conductive layer 265 comprises: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass.

Wherein, the first current-carrying part 2621 of multiple square shapes comprises: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass.

Wherein, the second current-carrying part 2622 of multiple square shapes comprises: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass.

Wherein, the 3rd current-carrying part 2623 of multiple square shapes comprises: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass.

Wherein, the 4th current-carrying part 2651 of multiple square shapes comprises: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass.

Wherein, the 5th current-carrying part 2652 of multiple square shapes comprises: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass.

Wherein, the 6th current-carrying part 2653 of multiple square shapes comprises: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass.

Wherein, electrochromic layer 263 comprises: printable electrochromism ink, or electrochomeric films, or electrochomeric glass, or automatically controlled light transmission film.

Wherein, dielectric substrate 263 comprises: printable electrolyte ink.

Wherein, first substrate 261 comprises clear glass or transparent membrane.。

Wherein, second substrate 266 comprises transparent membrane or clear glass.。

Wherein, the first electric field generator 23 comprises: power supply, or the dutycycle square wave driving voltage that is 50%.

Wherein, the second electric field generator 24 comprises: power supply, or the dutycycle square wave driving voltage that is 50%.

Wherein, the 3rd electric field generator 25 comprises: power supply, or the dutycycle square wave driving voltage that is 50%.

Wherein, the size of the first current-carrying part 2621 of the plurality of square shape can be identical with the size of the 4th current-carrying part 2651 of the plurality of square shape, also can be not identical.

Wherein, TFT display module 1 comprises TV, or computer, or projector, or navigating instrument, or mobile phone, or camera.

Wherein, the electrode relation of the first electrode 2625, the 4th electrode 2655, can be that the first electrode 2625 is that positive source, the 4th electrode 2655 are power cathode, can be also that the first electrode 2625 is that power cathode, the 4th electrode 2655 are positive source.

Wherein, the electrode relation of the second electrode 2626, the 5th electrode 2656, can be that the second electrode 2626 is that positive source, the 5th electrode 2656 are power cathode, can be also that the second electrode 2626 is that power cathode, the 5th electrode 2656 are positive source.

Wherein, the electrode relation of third electrode 2627, the 6th electrode 2657, can be that third electrode 2627 is that positive source, the 6th electrode 2657 are power cathode, can be also that third electrode 2627 is that power cathode, the 6th electrode 2657 are positive source.

Wherein, the electric field level that the first electric field generator 23 offers the first electrode 2625, the 4th electrode 2655 and the second electric field generator 24 offer the electric field level of the second electrode 2626, the 5th electrode 2656 and the 3rd electric field generator 25, and to offer the electric field level of third electrode 2627, the 6th electrode 2657 identical or not identical.

Wherein, be arranged at same a line and the line width summation of the plurality of the first current-carrying part 2621 alternately and the line width summation of the plurality of the 3rd current-carrying part 2623 and, equate with the line width of this TFT display module 1.

Wherein, be arranged at same a line and the line width summation of the plurality of the second current-carrying part 2622 alternately and the line width summation of the plurality of the first light transmission part 2624 and, equate with the line width of this TFT display module 1.

Wherein, be arranged at the high summation of row of same row and the plurality of the first current-carrying part 2621 alternately and the high summation of row of the plurality of the second current-carrying part 2622 and, with high the equating of row of this TFT display module 1.

Wherein, be arranged at the high summation of row of same row and the plurality of the 3rd current-carrying part 2623 alternately and the high summation of row of the plurality of the first light transmission part 2624 and, with high the equating of row of this TFT display module 1.

Wherein, be arranged at same a line and the line width summation of the plurality of the 4th current-carrying part 2651 alternately and the line width summation of the plurality of the 6th current-carrying part 2653 and, equate with the line width of this TFT display module 1.

Wherein, be arranged at same a line and the line width summation of the plurality of the 5th current-carrying part 2652 alternately and the line width summation of the plurality of the second light transmission part 2654 and, equate with the line width of this TFT display module 1.

Wherein, be arranged at the high summation of row of same row and the plurality of the 4th current-carrying part 2651 alternately and the high summation of row of the plurality of the 5th current-carrying part 2652 and, with high the equating of row of this TFT display module 1.

Wherein, be arranged at the high summation of row of same row and the plurality of the 6th current-carrying part 2653 alternately and the high summation of row of the plurality of the second light transmission part 2654 and, with high the equating of row of this TFT display module 1.

The utility model bore hole 3D display application TFT display module 1 synthetic image signal light, first substrate 261 sees through the picture signal light that TFT display module 1 generates, the first conductive layer 262 sees through the light that first substrate 261 sees through, dielectric substrate 264 provides ion to electrochromic layer 263, make electrochromic layer 263 produce the reversible reaction of oxidation or reduction and produce change color, comprising discolors becomes pellucidity, or the painted opaque state that becomes;

Receive image at image display format command reception device 21 and be shown as display direction that two-dimentional plane shows that the format order of image and display direction pick-up unit 22 detect TFT display module 1 while being vertical direction or horizontal direction, the first electric field generator 23 is not to the first electrode 2625 on the first conductive layer 262, the 4th electrode 2655 on the second conductive layer 265 provides electric field, the second electric field generator 24 is not to the second electrode 2626 on the first conductive layer 262, the 5th electrode 2656 on the second conductive layer 265 provides electric field, the 3rd electric field generator 25 is not to the third electrode 2627 on the first conductive layer 262, the 6th electrode 2657 on the second conductive layer 265 provides electric field, electrochromic layer 263 becomes pellucidity, see through the light that the first conductive layer 262 sees through, the image that now makes image that left eye is seen see with right eye is identical, obtain two-dimentional plane and show image,

Receive image at image display format command reception device 21 and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and display direction pick-up unit 22 detect TFT display module 1 while being vertical direction, the first electric field generator 23 is to the first electrode 2625 on the first conductive layer 262, the 4th electrode 2655 on the second conductive layer 265 provides electric field, the second electric field generator 24 is to the second electrode 2626 on the first conductive layer 262, the 5th electrode 2656 on the second conductive layer 265 provides electric field, the 3rd electric field generator 25 is not to the third electrode 2627 on the first conductive layer 262, the 6th electrode 2657 on the second conductive layer 265 provides electric field, electrochromic layer 263 becomes partially transparent state, part opaque state, part sees through the light that the first conductive layer 262 sees through, part does not see through the light that the first conductive layer 262 sees through, form slit grating, now make left eye see left image, right eye is seen right image, left image is not identical with right image, after brain is synthetic, will produce stereo perception, the 3 D stereo that obtains Glassless shows image,

Receive image at image display format command reception device 21 and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and display direction pick-up unit 22 detect TFT display module 1 while being horizontal direction, the first electric field generator 23 is to the first electrode 2625 on the first conductive layer 262, the 4th electrode 2655 on the second conductive layer 265 provides electric field, the second electric field generator 24 is not to the second electrode 2626 on the first conductive layer 262, the 5th electrode 2656 on the second conductive layer 265 provides electric field, the 3rd electric field generator 25 is to the third electrode 2627 on the first conductive layer 262, the 6th electrode 2657 on the second conductive layer 265 provides electric field, electrochromic layer 263 becomes partially transparent state, part opaque state, part sees through the light that the first conductive layer 262 sees through, part does not see through the light that the first conductive layer 262 sees through, form slit grating, now make left eye see left image, right eye is seen right image, left image is not identical with right image, after brain is synthetic, will produce stereo perception, the 3 D stereo that obtains Glassless shows image,

Thereby reaching to realize makes bore hole 3D displaying appliance for showing that in vertical direction two-dimentional plane shows image, the 3 D stereo that also can show Glassless shows image, can show that in the horizontal direction two-dimentional plane shows image, also can show that the 3 D stereo of Glassless shows the function of image, realizing beholder can be reached and be viewed and admired the object that 3 D stereo shows image by bore hole.

In embodiment of the present utility model, there is the functional circuit of touch-screen to be arranged on towards the surface of the first conductive layer 262 or dorsad on the surface of the first conductive layer 262 of first substrate 261, or have the functional circuit of touch-screen to be arranged on towards the surface of the second conductive layer 266 or dorsad surface of the second conductive layer 266 of second substrate 266.Make electrochromic device 26 not only there is the function of electrochromism grating, and gather the function of touch-screen, compared to electrochromism grating and the touch-screen of finished product are combined simply, not only reduce number of substrates, and reduce the module quantity of bore hole 3D display, improved the transmitance of light.Wherein, first substrate 261 and second substrate 262 comprise: transparent film or glass.

In a preferred embodiment of the present utility model, touch-screen comprises resistive touch screen, and in another preferred embodiment of the present utility model, touch-screen comprises capacitive touch screen.Bore hole 3D display of the present utility model is owing to having the function of touch-screen, therefore, and touch that can sensing staff, and then calculate operational order corresponding to staff touch point, realize by staff and touches the object that operates bore hole 3D display.

Than existing by TFT module, grating module and the touch screen module of finished product are formed to 3D display through rationally arranging, in the present embodiment, described light modulating device 2 arranges with the full laminating of TFT display module 1 and the functional circuit of touch-screen and electrochromism grating common substrate and form electrochromic device, the not only thin thickness of bore hole 3D display that the utility model is provided, substrate cost is low, and light penetration is high.

By the way, the bore hole 3D display that the utility model provides by forming electrochromic device by touch-screen and the design of electrochromism grating in same substrate, and then do full laminating design with TFT display module, the reduced thickness of whole 3D display module, required substrate cost and light penetration are improved, and the bore hole 3D display that provides of the utility model effect that can realize bore hole and watch 3D rendering.

For the utility model bore hole 3D display, the form of realization is diversified.All within spirit of the present utility model and principle, any modification of doing, be equal to replacement, improvement etc., within all should being included in protection domain of the present utility model.

Claims (10)

1. a bore hole 3D display, is characterized in that, comprising: TFT display module, light modulating device;

Described TFT display module, for synthetic image signal light;

Described light modulating device, be arranged on the bang path of the picture signal light that described TFT display module generates, and the full laminating of described light modulating device and TFT display module is set together, comprise: image display format command reception device, display direction pick-up unit, the first electric field generator, the second electric field generator, the 3rd electric field generator, electrochromic device;

Described image display format command reception device, for receiving the instruction of image display format, receives image and is shown as the format order that two-dimentional plane shows the format order of image or the stereoscopically displaying images of three-dimensional;

Described display direction pick-up unit, for detection of the display direction of described TFT display module, the display direction that detects described TFT display module is vertical direction or horizontal direction;

Described the first electric field generator, with the first electrode on the first conductive layer in described electrochromic device, the 4th electrode on the second conductive layer is electrically connected, be used for according to the received image display format instruction of described image display format command reception device, and the display direction of the described TFT display module detecting according to described display direction pick-up unit, receive image at described image display format command reception device and be shown as display direction that two-dimentional plane shows that the format order of image and described display direction pick-up unit detect described TFT display module while being vertical direction or horizontal direction, not to the first electrode on described the first conductive layer, the 4th electrode on described the second conductive layer provides electric field,

Receive image at described image display format command reception device and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and described display direction pick-up unit detect described TFT display module while being vertical direction, provide electric field to the first electrode on described the first conductive layer, the 4th electrode on described the second conductive layer;

Receive image at described image display format command reception device and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and described display direction pick-up unit detect described TFT display module while being horizontal direction, provide electric field to the first electrode on described the first conductive layer, the 4th electrode on described the second conductive layer;

Described the second electric field generator, with the second electrode on described the first conductive layer in described electrochromic device, the 5th electrode on described the second conductive layer is electrically connected, be used for according to the received image display format instruction of described image display format command reception device, and the display direction of the described TFT display module detecting according to described display direction pick-up unit, receive image at described image display format command reception device and be shown as display direction that two-dimentional plane shows that the format order of image and described display direction pick-up unit detect described TFT display module while being vertical direction or horizontal direction, not to the second electrode on described the first conductive layer, the 5th electrode on described the second conductive layer provides electric field,

Receive image at described image display format command reception device and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and described display direction pick-up unit detect described TFT display module while being vertical direction, provide electric field to the second electrode on described the first conductive layer, the 5th electrode on described the second conductive layer;

Receive image at described image display format command reception device and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and described display direction pick-up unit detect described TFT display module while being horizontal direction, do not provide electric field to the second electrode on described the first conductive layer, the 5th electrode on described the second conductive layer;

Described the 3rd electric field generator, with the third electrode on the first conductive layer described in described electrochromic device, the 6th electrode on described the second conductive layer is electrically connected, be used for according to the received image display format instruction of described image display format command reception device, and the display direction of the described TFT display module detecting according to described display direction pick-up unit, receive image at described image display format command reception device and be shown as display direction that two-dimentional plane shows that the format order of image and described display direction pick-up unit detect described TFT display module while being vertical direction or horizontal direction, not to the third electrode on described the first conductive layer, the 6th electrode on described the second conductive layer provides electric field,

Receive image at described image display format command reception device and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and described display direction pick-up unit detect described TFT display module while being vertical direction, do not provide electric field to the third electrode on described the first conductive layer, the 6th electrode on described the second conductive layer;

Receive image at described image display format command reception device and be shown as display direction that the format order of three-dimensional stereoscopically displaying images and described display direction pick-up unit detect described TFT display module while being horizontal direction, provide electric field to the third electrode on described the first conductive layer, the 6th electrode on described the second conductive layer;

Described electrochromic device, comprising: risen by described TFT display module side, be arranged in order first substrate, the first conductive layer, electrochromic layer, dielectric substrate, the second conductive layer, the second substrate of setting;

Or risen by described TFT display module side, be arranged in order first substrate, the first conductive layer, dielectric substrate, electrochromic layer, the second conductive layer, the second substrate of setting;

Described first substrate, the picture signal light generating for seeing through described TFT display module;

Described the first conductive layer, comprising:

The first current-carrying part of multiple square shapes, the electrode of the first current-carrying part of described multiple square shapes is in parallel, and obtains the first electrode, and the first current-carrying part of described multiple square shapes is for seeing through described first substrate institute transmitted light;

The second current-carrying part of multiple square shapes, the electrode of the second current-carrying part of described multiple square shapes is in parallel, and obtains the second electrode, and the second current-carrying part of described multiple square shapes is for seeing through described first substrate institute transmitted light;

The 3rd current-carrying part of multiple square shapes, the electrode of the 3rd current-carrying part of described multiple square shapes is in parallel, and obtains third electrode, and the 3rd current-carrying part of described multiple square shapes is for seeing through described first substrate institute transmitted light;

The first light transmission part of multiple square shapes, for seeing through described first substrate institute transmitted light;

The 3rd current-carrying part of the first current-carrying part of described square shape and described square shape is arranged at same a line and alternately; The second current-carrying part of described square shape and the first light transmission part of described square shape are arranged at same a line and alternately; The first current-carrying part of described square shape and the second current-carrying part of described square shape are arranged at same row and alternately; The 3rd current-carrying part of described square shape and the first light transmission part of described square shape are arranged at same row and alternately;

Described electrochromic layer, it is according to described the first conductive layer, described the second electrically conducting of conductive layer and produce change color, comprising discolors becomes pellucidity, or the painted opaque state that becomes, for at described the first electric field generator not to the first electrode on described the first conductive layer, the 4th electrode on described the second conductive layer provides electric field, and described the second electric field generator is not to the second electrode on described the first conductive layer, the 5th electrode on described the second conductive layer provides electric field, and described the 3rd electric field generator is not to the third electrode on described the first conductive layer, when the 6th electrode on described the second conductive layer provides electric field, become pellucidity, see through the light that described the first conductive layer sees through, obtain two-dimentional plane and show image,

At described the first electric field generator to the first electrode on described the first conductive layer, the 4th electrode on described the second conductive layer provides electric field, and described the second electric field generator is to the second electrode on described the first conductive layer, the 5th electrode on described the second conductive layer provides electric field, and described the 3rd electric field generator is not to the third electrode on described the first conductive layer, when the 6th electrode on described the second conductive layer provides electric field, become partially transparent state, part opaque state, part sees through the light that described the first conductive layer sees through, part does not see through the light that described the first conductive layer sees through, form slit grating, the 3 D stereo that obtains Glassless shows image,

At described the first electric field generator to the first electrode on described the first conductive layer, the 4th electrode on described the second conductive layer provides electric field, and described the second electric field generator is not to the second electrode on described the first conductive layer, the 5th electrode on described the second conductive layer provides electric field, and described the 3rd electric field generator is to the third electrode on described the first conductive layer, when the 6th electrode on described the second conductive layer provides electric field, become partially transparent state, part opaque state, part sees through the light that described the first conductive layer sees through, part does not see through the light that described the first conductive layer sees through, form slit grating, the 3 D stereo that obtains Glassless shows image,

Described dielectric substrate, for providing ion to described electrochromic layer, makes described electrochromic layer produce the reversible reaction of oxidation or reduction and produces change color, and comprising discolors becomes pellucidity, or the painted opaque state that becomes;

Described the second conductive layer comprises:

The 4th current-carrying part of multiple square shapes, the electrode of the 4th current-carrying part of described multiple square shapes is in parallel, and obtains the 4th electrode, and the 4th current-carrying part of described multiple square shapes is for seeing through described electrochromic layer institute transmitted light;

The 5th current-carrying part of multiple square shapes, the electrode of the 5th current-carrying part of described multiple square shapes is in parallel, and obtains the 5th electrode, and the 5th current-carrying part of described multiple square shapes is for seeing through described electrochromic layer institute transmitted light;

The 6th current-carrying part of multiple square shapes, the electrode of the 6th current-carrying part of described multiple square shapes is in parallel, and obtains the 6th electrode, and the 6th current-carrying part of described multiple square shapes is for seeing through described electrochromic layer institute transmitted light;

The second light transmission part of multiple square shapes, for seeing through described electrochromic layer institute transmitted light;

The 4th current-carrying part of described square shape and the 6th current-carrying part of described square shape are arranged at same a line and alternately; The 5th current-carrying part of described square shape and the second light transmission part of described square shape are arranged at same a line and alternately; The 4th current-carrying part of described square shape and the 5th current-carrying part of described square shape are arranged at same row and alternately; The 6th current-carrying part of described square shape and the second light transmission part of described square shape are arranged at same row and alternately;

Described second substrate, the light seeing through for seeing through described the second conductive layer;

Wherein, have the functional circuit of touch-screen to be arranged on towards the surface of the first conductive layer or dorsad on the surface of the first conductive layer of first substrate, or have the functional circuit of touch-screen be arranged on second substrate towards the surface of the second conductive layer or dorsad on the surface of the second conductive layer.

2. bore hole 3D display as claimed in claim 1, is characterized in that, described the first conductive layer, comprising: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass;

Described the second conductive layer, comprising: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass.

3. bore hole 3D display as claimed in claim 1, is characterized in that, the first current-carrying part of described multiple square shapes, comprising: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass;

The second current-carrying part of described multiple square shapes, comprising: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass;

The 3rd current-carrying part of described multiple square shapes, comprising: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass;

The 4th current-carrying part of described multiple square shapes, comprising: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass;

The 5th current-carrying part of described multiple square shapes, comprising: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass;

The 6th current-carrying part of described multiple square shapes, comprising: printable electrically conducting transparent ink, or conductive plastic sheeting, or tin indium oxide ITO electro-conductive glass.

4. bore hole 3D display as claimed in claim 1, is characterized in that, described electrochromic layer, comprising: printable electrochromism ink, or electrochomeric films, or electrochomeric glass, or automatically controlled light transmission film;

Described dielectric substrate, comprising: printable electrolyte ink.

5. bore hole 3D display as claimed in claim 1, is characterized in that, described the first electric field generator, comprising: power supply, or the dutycycle square wave driving voltage that is 50%;

Described the second electric field generator, comprising: power supply, or the dutycycle square wave driving voltage that is 50%;

Described the 3rd electric field generator, comprising: power supply, or the dutycycle square wave driving voltage that is 50%.

6. bore hole 3D display as claimed in claim 1, it is characterized in that, the electrode relation of described the first electrode, described the 4th electrode, comprise: described the first electrode is positive source, described the 4th electrode supply negative pole, or described the first electrode is that power cathode, described the 4th electrode are positive source;

The electrode relation of described the second electrode, described the 5th electrode, comprising: described the second electrode is that positive source, described the 5th electrode are power cathode, or described the second electrode is that power cathode, described the 5th electrode are positive source;

The electrode relation of described third electrode, described the 6th electrode, comprising: described third electrode is that positive source, described the 6th electrode are power cathode, or described third electrode is that power cathode, described the 6th electrode are positive source.

7. bore hole 3D display as claimed in claim 1, it is characterized in that, the size of the first current-carrying part of described square shape is identical with the size of the first light transmission part of the size of the 3rd current-carrying part of the size of the second current-carrying part of described square shape, described square shape, described square shape;

The size of the 4th current-carrying part of described square shape is identical with the size of the second light transmission part of the size of the 6th current-carrying part of the size of the 5th current-carrying part of described square shape, described square shape, described square shape;

The size of the first current-carrying part of described square shape is identical with the size of the 4th current-carrying part of described square shape.

8. bore hole 3D display as claimed in claim 1, it is characterized in that, it is identical with electric field level that described the 3rd electric field generator offers described third electrode, described the 6th electrode that the electric field level that described the first electric field generator offers described the first electrode, described the 4th electrode and described the second electric field generator offer the electric field level of described the second electrode, described the 5th electrode.

9. bore hole 3D display as claimed in claim 1, is characterized in that, described TFT display module, comprising: TV, or computer, or projector, or navigating instrument, or mobile phone, or camera.

10. bore hole 3D display as claimed in claim 1, is characterized in that, described touch-screen comprises resistive touch screen or capacitive touch screen.

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