CN208537851U - A kind of glasses - Google Patents
A kind of glasses Download PDFInfo
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- CN208537851U CN208537851U CN201821329066.5U CN201821329066U CN208537851U CN 208537851 U CN208537851 U CN 208537851U CN 201821329066 U CN201821329066 U CN 201821329066U CN 208537851 U CN208537851 U CN 208537851U
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- display panel
- glasses
- electrode layer
- transparency electrode
- eyeglass
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Abstract
The utility model embodiment provides a kind of glasses, is related to intelligence and dresses technical field, the transmitance of eyeglass can change into arbitrary value according to the intensity of illumination of varying environment in glasses, more to meet actual demand of the user under different light intensity environment.A kind of glasses, including eyeglass and mirror holder, the eyeglass includes substrate, the electrochromic device that is set on the substrate, the surface of the mirror holder or is internally provided with driving circuit;The electrochromic device includes the first transparency electrode layer, electrochromic material layer and second transparency electrode layer being cascading;The driving circuit, for inputting the first current potential to the first transparency electrode layer, inputting the second current potential to the second transparency electrode layer;First current potential of the first transparency electrode layer and the second current potential of the second transparency electrode layer, for changing the extent of reaction of redox reaction in the electrochromic material layer, to change the light transmission rate of the eyeglass.
Description
Technical field
The utility model relates to intelligence wearing technical field more particularly to a kind of glasses.
Background technique
In traditional light-sensitive sunglasses, common eyeglass is needed in process by deepening to dye, for blocking sunlight, and
Weaken irradiation of the sunlight to human eye;Polarized sunglasses piece weakens sunlight and reflected light using polarisation effect, and effect is better than common
Eyeglass.
However, whether common eyeglass or polarized sunglasses piece, shaded effect are fixed, it cannot be with the external world
The variation of light intensity is to adjust coverage extent of the eyeglass to the light for being incident on eyeglass, it is difficult to meet user in different light intensity rings
Actual demand in border.
Utility model content
The embodiments of the present invention provide a kind of glasses, and the transmitance of eyeglass can be according to varying environment in the glasses
Intensity of illumination changes into arbitrary value, more to meet actual demand of the user under different light intensity environment.
In order to achieve the above objectives, the embodiments of the present invention adopt the following technical scheme that
There is provided a kind of glasses, including eyeglass and mirror holder, the eyeglass includes substrate, the electroluminescent change that is set on the substrate
Color device, the surface of the mirror holder or is internally provided with driving circuit;The electrochromic device includes being cascading
First transparency electrode layer, electrochromic material layer and second transparency electrode layer;The driving circuit is used for described first
Transparent electrode layer inputs the first current potential, inputs the second current potential to the second transparency electrode layer;The first transparency electrode layer
Second current potential of first current potential and the second transparency electrode layer, also for changing oxidation in the electrochromic material layer
The extent of reaction of original reaction, to change the light transmission rate of the eyeglass.
Optionally, the direction of the electrochromic material layer, the electrochromism are directed toward along the first transparency electrode layer
Device further includes the ion storage being cascadingly set between the first transparency electrode layer and the electrochromic material layer
Layer and electrolyte layer.
Optionally, the eyeglass further includes the display panel being stacked with the electrochromic device.
Further alternative, the display panel is set to the electrochromic device close to the one side of substrate.
Optionally, the display panel includes multiple subpixel areas, and the electrochromic device includes multiple electroluminescent changes
Color element, the projection of the electrochromic cells on said display panel is between the subpixel area.
Further alternative, the shapes of the electrochromic cells is circle, rectangle, triangle, diamond shape, trapezoidal;With/
Or, the shape of the subpixel area be circle, it is rectangle, triangle, diamond shape, trapezoidal.
Optionally, the display panel is OLED display panel, alternatively, the display panel is LCD display panel.
Further alternative, the OLED display panel is that bilateral is shown or unilateral side is shown.
Optionally, when the display panel is unilateral display, the display light of the display panel is along described in wearing
The user of glasses is directed toward the direction outgoing of the glasses.
It optionally, further include the control switch for being set to the mirror holder surface, the control switch is for adjusting described the
The size of one current potential and second current potential.
The utility model embodiment provides a kind of glasses, and the glasses include eyeglass and mirror holder, and eyeglass includes electrochromism
Material layer, mirror holder are equipped with driving circuit, it is only necessary to adjust that driving circuit in the glasses inputs to first transparency electrode layer the
The size of the size of one current potential, the second current potential inputted to second transparency electrode layer, that is, can be changed the electrochromic material layer
The extent of reaction of middle redox reaction, so change eyeglass light transmission rate so that in the glasses eyeglass transmission
Rate can change into arbitrary value according to the intensity of illumination of varying environment, and the shading degree of eyeglass is one fixed compared to the prior art
It is worth, glasses described in the utility model embodiment more meet actual demand of the user under different light intensity environment.
Detailed description of the invention
In order to illustrate the embodiment of the utility model or the technical proposal in the existing technology more clearly, below will be to embodiment
Or attached drawing needed to be used in the description of the prior art is briefly described, it should be apparent that, the accompanying drawings in the following description is only
It is some embodiments of the utility model, for those of ordinary skill in the art, in the premise not made the creative labor
Under, it is also possible to obtain other drawings based on these drawings.
Fig. 1 is a kind of structural schematic diagram of glasses provided by the embodiment of the utility model;
Fig. 2 is a kind of structural schematic diagram of eyeglass provided by the embodiment of the utility model;
Fig. 3 is a kind of structural schematic diagram of eyeglass provided by the embodiment of the utility model;
Fig. 4 is a kind of structural schematic diagram of eyeglass provided by the embodiment of the utility model;
Fig. 5 is a kind of structural schematic diagram of eyeglass provided by the embodiment of the utility model;
Fig. 6 is a kind of structural schematic diagram of eyeglass provided by the embodiment of the utility model;
Fig. 7 is a kind of structural schematic diagram of eyeglass provided by the embodiment of the utility model;
Fig. 8 is a kind of schematic top plan view of eyeglass provided by the embodiment of the utility model;
Fig. 9 is a kind of schematic top plan view of eyeglass provided by the embodiment of the utility model;
Figure 10 is a kind of structural schematic diagram of glasses provided by the embodiment of the utility model.
Appended drawing reference:
10- eyeglass;11- substrate;12- electrochromic device;120- electrochromic cells;121- first transparency electrode layer;
122- electrochromic material layer;123- second transparency electrode layer;124- ion storage;125- electrolyte layer;13- protective layer;
14- display panel;141- subpixel area;20- mirror holder;21- driving circuit;22- control switch.
Specific embodiment
The following will be combined with the drawings in the embodiments of the present invention, carries out the technical scheme in the embodiment of the utility model
Clearly and completely describe, it is clear that the described embodiments are only a part of the embodiments of the utility model, rather than whole
Embodiment.Based on the embodiments of the present invention, those of ordinary skill in the art are without making creative work
Every other embodiment obtained, fall within the protection scope of the utility model.
The utility model embodiment provides a kind of glasses, as depicted in figs. 1 and 2, including eyeglass 10 and mirror holder 20, the mirror
Piece 10 include substrate 11, be set on substrate 11 electrochromic device 12, the surface of mirror holder 20 or be internally provided with driving electricity
Road 21;Electrochromic device 12 include be cascading first transparency electrode layer 121, electrochromic material layer 122 and
Second transparency electrode layer 123;Driving circuit 21, for inputting the first current potential, to the second transparent electricity to first transparency electrode layer 121
Pole layer 123 inputs the second current potential;First current potential of first transparency electrode layer 121 and the second current potential of second transparency electrode layer 123,
For changing the extent of reaction of redox reaction in electrochromic material layer 122, to change the light transmission rate of eyeglass 10.
Herein, under the first current potential and the different situation of the second current potential, first transparency electrode layer 121 and the second transparent electricity
Pole layer 123 forms electric field, under the action of the electric field, by the way that ion or electricity are injected or extracted to electrochromic material layer 122
Son, so that oxidation reaction or reduction reaction occur for electrochromic material layer 122, further, so that electrochromic material layer
122 switch between the colored state of low transmission and the colour killing state of high transmittance.Wherein, first transparency electrode layer 121 with
Potential difference between second transparency electrode layer 123 is different, injects to electrochromic material layer 122 or the ion that extracts or electronics
Quantity is different, and the extent of reaction of redox reaction is different in electrochromic material layer 122, further, electrochromic material
The transmitance of layer 122 is not identical, therefore, can be by between control first transparency electrode layer 121 and second transparency electrode layer 123
The size of potential difference changes the transmitance of electrochromic material layer 122.
Specifically, the transmitance of electrochromic material layer 122 is raised and lowered, with the material of electrochromic material layer 122,
And the reaction occurred is that oxidation reaction or reduction reaction are related.
It wherein, it will be appreciated by those skilled in the art that, include substrate 11 and electrochromic device 12, electroluminescent change in eyeglass
Color device 12 includes the case where first transparency electrode layer 121, second transparency electrode layer 123 and electrochromic material layer 122
Under, the transmitance of eyeglass 10 is not only related with the transmitance of electrochromic material layer 122, also with substrate 11, first transparency electrode
Layer 121, the transmitance of second transparency electrode layer 123 are related, therefore, in order to better by control electrochromic material layer 122
Transmitance, to control the transmitance of eyeglass 10, the utility model embodiment preferred substrate 11, first transparency electrode layer 121,
The material of two transparent electrode layers 123 is the higher material of transmitance.
Exemplary, the material of substrate 11 is transparent glass;First transparency electrode layer 121 and second transparency electrode layer 123
Material is transparent conductive materials such as tin indium oxide (Indium tin oxide, abbreviation ITO).
On this basis, as shown in figure 3, being directed toward the direction of electrochromic material layer 122 along first transparency electrode layer 121,
Electrochromic device 12 can also include be cascadingly set on first transparency electrode layer 121 and electrochromic material layer 122 it
Between ion storage 124 and electrolyte layer 125.
Wherein, electrolyte layer 125 is for providing ion (example needed for redox reaction occurs for electrochromic material layer 122
Such as H+、Li+、Na+) transmission channel.When electrochromic material layer 122 is by injection ion, ion storage 124 is used for electricity
It solves matter layer 125 and ion is provided;When ion in electrochromic material layer 122 is extracted, ion storage 124 is used for ion
It stores.
It should be noted that first, the surface of mirror holder 20 is divided into inner surface and outer surface, described in viewer's wearing
It is inner surface close to the side of viewer, the other side is outer surface when glasses.Driving circuit 21 can be set in mirror holder 20
Inner surface, the outer surface in mirror holder 20 also can be set, certainly, driving circuit 21 also can be set in mirror holder 20
Portion.
Wherein, it will be appreciated by those skilled in the art that, mirror holder 20 includes frame, nose support, temple etc..
Second, the material of electrochromic material layer 122 is not defined, as long as electrochromic material layer 122 is occurring
When redox reaction, transmitance can change as the concentration of the product of redox reaction is different.
Specifically, the material of electrochromic material layer 122 can be inorganic electrochromic material, it is also possible to organic electroluminescence
Off-color material, organic electrochromic material are divided into small organic molecule electrochromic material and conducting polymer electrochromic material.
Wherein, when the material of electrochromic material layer 122 is inorganic electrochromic material, the material of electrochromic material 122 is for example
It can be WO3、MoO3、V2O5、Nb2O5、BiO3、NiO、IrOx、CoO3、Rh2O3, MnO etc.;When the material of electrochromic material layer 122
When material is organic electrochromic material, it is (organic small that the material of electrochromic material layer 22 for example can be purple sieve essence class compound
Molecule electrochromic material) etc. or polyaniline compound conducting polymer, polypyrrole conducting polymer, polythiophene conductive polymerization
Object (conducting polymer electrochromic material) etc..
It is exemplary, with WO3For, the chemical equation of redox reaction are as follows:
Wherein, x is constant, M+For can be H+、Li+、Na+;WO3To be transparent, MxWO3(tungsten bronze) is blue.
When reduction reaction occurs, reactant WO3, product MxWO3, with increasing for reduction reaction product, electricity
The color of mutagens color material layer 122 gradually deepens (that is, colored state of low transmission), and then the transmitance of eyeglass 10 gradually drops
It is low;When oxidation reaction occurs, reactant MxWO3, product WO3, with increasing for oxidation reaction product, electroluminescent change
The color of color material layer 122 gradually becomes shallower as (that is, colour killing state of high transmittance), and then the transmitance of eyeglass 10 gradually rises.
Herein, only with WO3Citing, for the electrochromic material layer 122 of above-mentioned other materials, can also pass through redox
Reaction so that the color of electrochromic material layer 122 changes, and then changes the transmitance of eyeglass 10.
Third is not defined the size of the first current potential and the second current potential, as long as the potential difference formed therebetween, foot
So that the materials from oxidizing reduction reaction of electrochromic material layer 122, and the transmitance of eyeglass 10 is made to be adjusted to ideal
Value.
Exemplary, the value of the first current potential and the second current potential is equal, at this point, first transparency electrode layer 121 and the second transparent electricity
Potential difference between pole layer 123 is 0, and redox reaction does not occur in electrochromic material layer 122;First current potential and the second electricity
The value of position is unequal, and the potential difference between first transparency electrode layer 121 and second transparency electrode layer 123 is not 0, electrochromism material
Redox reaction occurs in the bed of material 122.
4th, it is contemplated that first transparency electrode layer 121 and second transparency electrode layer 123 in electrochromic device 12 are connecing
In the case where touching air, it is easily oxidized corrosion, therefore, as shown in figure 4, eyeglass 10 further includes the guarantor for covering electrochromic device 12
Sheath 13.
5th, the structure of electrochromic device 12 is not defined, as shown in Figures 2 and 3, electrochromic device 12 can
With the flood that tiles;As shown in figure 5, electrochromic device 12 also may include multiple block-like electrochromic cells 120.
Wherein, electrochromic device 12 be include multiple block-like electrochromic cells 120 in the case where, first is transparent
Electrode layer 121 and second transparency electrode layer 123 can tile a flood, also may include multiple blocky transparent electrodes.But ability
The technical staff in domain should be understood that only first transparency electrode layer 121, second transparency electrode layer 123 and electrochromic material
The part of 122 overlapping of layer, is only effective one electrochromic cells 120.
Further, electrochromic device 12 be include multiple block-like electrochromic cells 120 in the case where, it is multiple
The shape of block-like electrochromic cells 120 can be circle, rectangle, triangle, diamond shape, trapezoidal.
6th, when the user dons the glasses, the side in eyeglass 10 close to user can be substrate 11 away from electrochromism
12 side of device is also possible to electrochromic device 12 away from 11 side of substrate.
The utility model embodiment provides a kind of glasses, and the glasses include eyeglass 10 and mirror holder 20, and eyeglass 10 includes electricity
Mutagens color material layer 12, mirror holder 20 are equipped with driving circuit 21, it is only necessary to it is transparent to adjust driving circuit 21 to first in the glasses
The size of the size for the first current potential that electrode layer 121 inputs, the second current potential inputted to second transparency electrode layer 123, Ji Kegai
The extent of reaction of redox reaction in power transformation mutagens color material layer 122, and then change the light transmission rate of eyeglass 10, so that
The transmitance of eyeglass 10 can change into arbitrary value according to the intensity of illumination of varying environment in the glasses, compared to the prior art mirror
The shading degree of piece 10 is a fixed value, and glasses described in the utility model embodiment more meet user in different light intensity environment
Under actual demand.
Optionally, as shown in Figure 6 and Figure 7, eyeglass 10 further includes the display panel being stacked with electrochromic device 12
14。
Wherein, as shown in fig. 6, display panel 14 is set to the side that electrochromic device 12 deviates from substrate 11, that is, first exist
Electrochromic device 12 is formed on substrate 11, and then display panel 14 is formed on the substrate, and so, can avoid being formed
The light-emitting function of display panel 14 is caused to damage when electroluminescent device 12;As shown in fig. 7, display panel 14 be set to it is electroluminescent
Electrochromic device 12 is close to the side of substrate 11, so, display panel 14 can be directly arranged in flat 11 surface of substrate,
It no longer needs to that flatness layer is arranged to form display panel 14, to can avoid increasing the thickness of eyeglass 10.
It should be noted that first, display panel 14 can be OLED display panel, be also possible to LCD display panel.Its
In, OLED display panel can use light needed for its own provides display, and it is aobvious that LCD display panel can use natural light offer
Show required light.
Wherein, when display panel 14 be LCD display panel when, LCD display panel include array substrate, with array substrate phase
Pair to box substrate and positioned at array substrate and to the liquid crystal layer between box substrate, on this basis, eyeglass 10 further includes setting
It is placed in the light-emitting surface side of LCD display panel and the polaroid of incidence surface side.
When display panel 14 is OLED display panel, OLED display panel includes array substrate, encapsulation cover plate.Wherein,
Array substrate is equipped with light needed for OLED luminescent device provides display for OLED display panel, and OLED luminescent device includes sun
Pole, cathode and the light emitting functional layer between anode and cathode.
Second, display panel 14 is that bilateral is shown or unilateral side is shown, that is, close to the wearing glasses in display panel 14
User and/or away from wear the glasses user while be light-emitting surface, that is, the display light of display panel 14
The direction outgoing for wearing the user of the glasses is directed toward along the glasses, and/or, the display light of display panel 14 is along described in wearing
The user of glasses is directed toward the direction outgoing of the glasses.
Specifically, when display panel is liquid crystal (Liquid Crystal Display, abbreviation LCD) display panel, alternatively,
Display panel be organic electroluminescent LED (Organic Light-Emitting Diode, abbreviation OLED) display panel,
And OLED display panel is when being that top shines or bottom shines, in display panel 14 close to user or away from user while be
Light-emitting surface;When display panel is OLED display panel and OLED display panel is double-side, close to use in display panel 14
Family and away from user while be light-emitting surface.
On this basis, it is contemplated that the distance of distinct vision of human eye is about 25 centimetres, in the case where user wears the glasses,
The distance between eyeglass 10 and the eyes of user are much smaller than 25 centimetres, therefore, the utility model embodiment preferred display panel 14
In be only light-emitting surface away from the one side for the user for wearing the glasses, so, the picture that display panel 14 is shown is for removing
Other users viewing other than the user of wearing spectacles, and the other users can watch display picture within the scope of the distance of distinct vision
Face.
Certainly, in the case where user does not wear the glasses, close to the user for wearing the glasses in display panel 14
One side may be display surface, as long as the eyes of user are at a distance from eyeglass 10 within the scope of the distance of distinct vision.
Whether third whether the display of display panel 14, is sent out with the electrochromic material layer 122 in electrochromic device 12
Raw redox reaction is unrelated.
In the utility model embodiment, eyeglass 10 includes display panel 14, and eyeglass 10 may make to have the function of display picture
Energy.
Further alternative, as shown in Figure 8 and Figure 9, display panel 14 includes multiple subpixel areas 141, electrochromism
Device 120 includes multiple electrochromic cells 120, and projection of the electrochromic cells 120 on display panel 14 is located at sub-pixel
Between region 141.
Herein, in order to neither influence the display effect of display panel 14, may make the transmitance of eyeglass 10 according to electroluminescent again
The transmitance of Electrochromic device 12 changes and changes, and the gross area of the preferably multiple subpixel areas 141 of the utility model embodiment accounts for
The 20%~50% of 10 gross area of eyeglass.
It should be noted that first, since electrochromic cells 120 are arranged in block distribution, it is only set in eyeglass 10
The part for being equipped with electrochromic cells 120 just can be by the transmitance of change electrochromic device 12, to change the saturating of eyeglass 10
Rate is crossed, however, since electrochromic cells 120 are between subpixel area 141, the area of electrochromic cells 120
Spacing between small and adjacent electrochromic unit 120 is smaller, therefore, can regard the whole transmitance of eyeglass 10 as with electroluminescent
The transmitance of Electrochromic device 12 and change.
Second, the shape of subpixel area 141 is not defined, the shape of subpixel area can be circle, rectangle,
Triangle, diamond shape, trapezoidal etc..
In the utility model embodiment, by making projection of the electrochromic cells 120 on display panel 14 be located at sub- picture
Between plain region 141, it can avoid influencing each other when electrochromic device 12 and the work of display panel 14.
Aiming at the problem that glasses that the prior art proposes are difficult to meet actual demand of the user in different light intensity environment, phase
Pass technology proposes automatic color regulating sunglasses, and automatic color regulating sunglasses can adjust the face of eyeglass according to the light intensity of external environment
Color depth, still, this automatic color regulating sunglasses are that the simple color for adjusting eyeglass according to the light intensity of external environment is deep
Degree, and do not consider the sense of reality of user for example, even if light is very strong, but somebody and does not think bright and clear;Alternatively,
There is the user of obstacle for eyesight, even if light is very strong, but its light seen is very faint.That is, existing automatic color regulating ink
Mirror can not mix colours according to the subjective feeling of user, and then can not accomplish really intelligence toning.
Based on this, optionally, as shown in Figure 10, the glasses further include the control switch 22 for being set to 20 surface of mirror holder,
Control switch 22 is used to adjust the size of the first current potential and the second current potential.
Herein, the size of the first current potential and the second current potential can be adjusted, to change electrochromism by adjusting control switch 22
The extent of reaction of 122 redox reaction of electrochromic material layer in device 12, and then change the transmission of electrochromic device 12
Rate, so that the transmitance of eyeglass 10 changes.
It should be noted that first, control switch 22 can be button switch, rotary switch, be also possible to voice control
Switch etc..
Second, the specific location of control switch 22 is not defined, it is contemplated that control switch 22 is arranged in mirror holder 20
Outer surface, facilitate user to adjust the transmitance of eyeglass 10 in the case where wearing the glasses, therefore, the utility model is real
The outer surface that mirror holder 20 is preferably arranged in control switch 22 by example is applied, such as control switch 22 is arranged in the outside table of temple
Face.
In the utility model embodiment, user can be by adjusting control switch 22, to change the transmitance of eyeglass 10, operation
Simply;Also, user can also arbitrarily adjust the transmitance of eyeglass 10 according to the subjective feeling of itself under different light intensity environment,
The suitable light intensity of the light for seeing eyes, so that the glasses are more intelligent.
Above description is only a specific implementation of the present invention, but the protection scope of the utility model is not limited to
In this, anyone skilled in the art within the technical scope disclosed by the utility model, can readily occur in variation
Or replacement, it should be covered within the scope of the utility model.Therefore, the protection scope of the utility model should be with the power
Subject to the protection scope that benefit requires.
Claims (13)
1. a kind of glasses, including eyeglass and mirror holder, which is characterized in that the eyeglass includes substrate, is set on the substrate
Electrochromic device, the surface of the mirror holder or is internally provided with driving circuit;
The electrochromic device includes the first transparency electrode layer being cascading, electrochromic material layer and second
Transparent electrode layer;
The driving circuit, for inputting the first current potential, defeated to the second transparency electrode layer to the first transparency electrode layer
Enter the second current potential;
First current potential of the first transparency electrode layer and the second current potential of the second transparency electrode layer, for changing institute
The extent of reaction of redox reaction in electrochromic material layer is stated, to change the light transmission rate of the eyeglass.
2. glasses according to claim 1, which is characterized in that be directed toward the electrochromism along the first transparency electrode layer
The direction of material layer, the electrochromic device further include be cascadingly set on the first transparency electrode layer with it is described electroluminescent
Ion storage and electrolyte layer between discoloration material layer.
3. glasses according to claim 1 or 2, which is characterized in that the eyeglass further includes and the electrochromic device
The display panel being stacked.
4. glasses according to claim 3, which is characterized in that the display panel is set to the electrochromic device and leans on
The nearly one side of substrate.
5. glasses according to claim 3, which is characterized in that the display panel includes multiple subpixel areas, described
Electrochromic device includes multiple electrochromic cells, and the projection of the electrochromic cells on said display panel is located at institute
It states between subpixel area.
6. glasses according to claim 5, which is characterized in that the shape of the electrochromic cells is circle, rectangle, three
It is angular, diamond shape, trapezoidal;And/or the shape of the subpixel area be circle, it is rectangle, triangle, diamond shape, trapezoidal.
7. glasses according to claim 3, which is characterized in that the display panel is OLED display panel, alternatively, described
Display panel is LCD display panel.
8. according to the described in any item glasses of claim 4-6, which is characterized in that the display panel is OLED display panel,
Alternatively, the display panel is LCD display panel.
9. glasses according to claim 7, which is characterized in that the OLED display panel is that bilateral is shown or unilateral side is aobvious
Show.
10. glasses according to claim 8, which is characterized in that the OLED display panel shows for bilateral or unilateral side
Display.
11. according to claim 7 or the described in any item glasses of 9-10, which is characterized in that shown in the display panel to be unilateral
In the case of showing, the display light of the display panel is directed toward the direction outgoing of the glasses along the user for wearing the glasses.
12. glasses according to claim 8, which is characterized in that described when the display panel is unilateral display
The display light of display panel is directed toward the direction outgoing of the glasses along the user for wearing the glasses.
13. glasses according to claim 1, which is characterized in that it further include the control switch for being set to the mirror holder surface,
The control switch is used to adjust the size of first current potential and second current potential.
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN111308832A (en) * | 2020-03-31 | 2020-06-19 | 优奈柯恩(北京)科技有限公司 | Lens, camera and intelligent glasses |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN111308832A (en) * | 2020-03-31 | 2020-06-19 | 优奈柯恩(北京)科技有限公司 | Lens, camera and intelligent glasses |
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