CN212031896U - Light adjusting film - Google Patents

Abstract

The utility model relates to a light adjusting film, light adjusting film includes two-layer transparent conductive electrode, transparent conductive electrode includes: the substrate comprises a light adjusting area and a wiring area; the working electrode is positioned on the substrate and consists of a nano metal wire, a nano metal rod or a nano metal film, and the structure of the working electrode positioned in the wiring area is provided with a lapping groove exposing the section of the working electrode; the protective layer is positioned on one side of the working electrode, which is far away from the substrate, and a conductive channel communicated with the lap joint groove is arranged on the protective layer; the electric connecting piece is positioned in the lapping groove and the conductive channel and is solidified conductive slurry; the conductive electrode is positioned on one side of the protective layer, which is far away from the working electrode, and the conductive electrode is electrically connected with the working electrode through the electric connecting piece; wherein the PDLC film is positioned between the protective layers of the two transparent conductive electrodes.

Description

Light adjusting film

Technical Field

The utility model relates to a membrane field of adjusting luminance especially relates to a membrane of adjusting luminance.

Background

The conducting film made of metal nano materials such as nano silver wires and the like is a basic material for manufacturing electronic products such as nano silver wire large-size touch screens, light-adjustable films, flexible touch screens and the like.

Taking a nano silver wire conductive film as an example, the basic structure of the nano silver wire conductive film comprises a substrate, a nano silver wire working electrode and a protective layer, wherein the protective layer has the main functions of improving the structural strength of the nano silver wire layer, avoiding scratching, blocking external corrosive substances and improving the stability of a nano silver wire material. However, in the existing application, the electrical signal of the nano silver wire layer is led out from the right top of the working electrode of the nano silver wire, and contact conduction is formed after silver paste printing, so that the surface conductivity of the nano silver wire needs to be emphasized, and the contact resistance of the silver paste in an area of about 1 square millimeter is required to be less than 100 ohms.

The conventional implementation methods include two methods, one is that the protective layer is thin enough, the conductive grid formed by the nano silver wires has points exposed out of the protective layer, and after the silver paste is printed, conductive filler particles in the silver paste can be in direct contact with the nano silver wires; the other is that after the silver paste is printed by silk, after a solvent in the silver paste is dissolved to destroy a surface protection layer, the conductive filler particles in the silver paste and the nano silver wire are in close contact for conduction, wherein the contact comprises direct contact and quantum tunneling type contact, namely when the distance between two conductive particles is in a nano level, electrons can jump between two conductors for conduction.

The conduction of the two modes limits the thickness of the surface protective layer of the nano silver wire, so that the nano silver wire is difficult to form real effective protection. Particularly, when the nano silver wire is applied to a light-adjustable film, the nano silver wire needs to be in close contact with Polymer Dispersed Liquid Crystal (PDLC), the requirement on the stability of the nano silver wire is high, and the requirement cannot be met by the current process.

In view of the above, it is desirable to provide a light adjusting film to solve the above problems.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a membrane of adjusting luminance.

In order to realize the purpose of the utility model, the utility model adopts the following technical scheme:

a light modulation film comprises two layers of transparent conductive electrodes and a PDLC film positioned between the two layers of transparent conductive electrodes; the transparent conductive electrode includes:

the substrate comprises a dimming area and a wiring area, wherein the wiring area is positioned on the outer periphery side of the dimming area;

the working electrode is positioned on the substrate and consists of a nano metal wire, a nano metal rod or a nano metal film, a lapping groove exposing the section of the working electrode is arranged on the working electrode positioned in the wiring area, the depth of the lapping groove is not less than two thirds of the thickness of the working electrode, or the lapping groove penetrates through the working electrode along the thickness direction;

the protective layer is positioned on one side of the working electrode, which is far away from the substrate, and a conductive channel communicated with the lap joint groove is arranged on the protective layer;

the electric connecting piece is positioned in the lapping groove and the conductive channel and is solidified conductive slurry;

the conductive electrode is positioned on one side of the protective layer, which is far away from the working electrode, and the conductive electrode is electrically connected with the working electrode through the electric connecting piece;

the PDLC film is positioned between the protective layers of the two transparent conductive electrodes, or the PDLC film is positioned between the substrates of the two transparent conductive electrodes; or the PDLC film is positioned between the protective layer of one transparent conductive electrode and the substrate of the other transparent conductive electrode.

Further, the nano metal wire is a nano silver wire with the diameter of 5 nm-100 nm and the length of 15 mu m-25 mu m.

Further, the thickness of the protective layer is not less than 10 nm.

Further, the sheet resistance of the side, away from the working electrode, of the protective layer is 0.1-500 ohm/sq measured by using an eddy current sheet resistance meter, and the resistance cannot be measured by using a four-probe sheet resistance meter.

Further, the overlapping groove is a groove or the overlapping groove comprises several independent subslots.

Further, the conductive channel is a channel or the conductive channel includes several independent sub-channels.

Further, the working electrode comprises a patterned sub-working electrode, a lapping groove which is positioned on the sub-working electrode in the wiring area and is exposed out of the section of the sub-working electrode is arranged, the depth of the lapping groove is not less than two thirds of the thickness of the sub-working electrode, or the lapping groove penetrates through the sub-working electrode along the thickness direction; the protective layer is provided with conductive channels which are correspondingly communicated with the lap joint grooves one by one; and the transparent conductive electrode also comprises electric connection pieces positioned in the conductive channels and the lap joint grooves which are communicated in a one-to-one correspondence manner, and electric connection conductive electrodes which are in one-to-one correspondence with the electric connection pieces.

Compared with the prior art, the beneficial effects of the utility model reside in that: the utility model discloses the used transparent conductive electrode of membrane of adjusting luminance is through seting up the section that the overlap joint groove outwards exposes working electrode on working electrode, and this section passes through electric connector and conductive electrode and realizes electric contact, has changed surface electric connection's in the past mode, not only can adopt transparent conductive materials such as the great nano-metal wire of surface insulation or contact resistance preparation working electrode, can also strengthen the thickness of protective layer obtains stable transparent conductive electrode.

Drawings

FIG. 1 is a schematic structural diagram of a substrate, a working electrode and a protective layer;

FIG. 2 is a schematic illustration of the protective layer of FIG. 1 after screen printing of a plurality of silver paste segments thereon;

FIG. 3 is a schematic view of the protective layer of FIG. 1 after forming a plurality of breaking points and then screen printing silver paste blocks;

FIG. 4 is a schematic view of the structure of FIG. 1 after forming a conductive via and a landing slot;

FIG. 5 is a schematic illustration of the addition of conductive paste into the conductive vias and landing pads of FIG. 4;

FIG. 6 is a schematic illustration of a transparent conductive electrode formed after disposing a conductive electrode onto the protective layer of FIG. 5;

fig. 7 is a schematic view of a light adjusting film according to a preferred embodiment of the present invention.

100-transparent conductive electrode, 1-substrate, 2-working electrode, 21-lapping groove, 3-protective layer, 31-conductive channel, 4-electric connector, 5-conductive electrode, 6-silver paste block, 7-breaking point, 8-PDLC film and 200-light adjusting film.

Detailed Description

The present application will now be described in detail with reference to specific embodiments thereof as illustrated in the accompanying drawings. These embodiments are not intended to limit the present application, and structural, methodological, or functional changes made by those skilled in the art according to these embodiments are included in the scope of the present application.

In the various illustrations of the present application, certain dimensions of structures or portions may be exaggerated relative to other structures or portions for ease of illustration and, thus, are provided to illustrate only the basic structure of the subject matter of the present application.

Referring to fig. 1 and fig. 4 to fig. 6, the transparent conductive electrode 100 of the present invention includes a substrate 1, a working electrode 2 located on the substrate 1, a protective layer 3 located on one side of the working electrode 2 departing from the substrate 1, and a conductive electrode 5 located on one side of the protective layer 3 departing from the working electrode 2.

The substrate may be a substrate used in a manufacturing process or a resin layer coated on the substrate, and the substrate is transparent and includes, but is not limited to, glass, a plastic plate, and a transparent film including, but not limited to, a PET film. The substrate is positioned on the outermost layer of the light adjusting film and plays a role in protecting other film layers.

In addition, the substrate comprises a dimming area and a wiring area positioned on the outer periphery side of the dimming area.

The working electrode 2 is composed of a nano metal wire, a nano metal rod or a nano metal film, and the thickness is generally 30 nm-100 nm. The nano metal wire, the nano metal rod or the nano metal rod can be coated on the surface of the substrate 1 in a solution form to form a continuous conductive film layer, and preferably, the nano metal wire is a nano silver wire with the diameter of 5 nm-100 nm and the length of 15 μm-25 μm, has high conductivity and high transparency. Alternatively, the working electrode 2 is a nano metal film formed by magnetron sputtering, vacuum deposition, or the like, and has reliable conductivity.

The working electrode 2 located in the wiring area is provided with a lap joint groove exposing the cross section of the working electrode 2, the lap joint groove 21 is opened back to the substrate 1, and the cross section forms at least part of the groove wall of the lap joint groove 21.

The cross section extends from the side of the working electrode 2 departing from the substrate 1 to the side of the substrate 1, and the projection of the cross section on the surface perpendicular to the working electrode 2 is a straight line, an arc line or other irregular lines as long as the nano metal wire, the nano metal rod or the nano metal film can be exposed or protruded from the cross section into the overlapping groove 21.

Further, the depth of the overlapping groove 21 is not less than two thirds of the thickness of the working electrode to form an effective conductive surface; preferably, the overlapping groove 21 penetrates through the working electrode along the thickness direction, has a large cross-sectional area, and can form effective and stable electrical connection with the conductive electrode 5 to enhance the conductivity.

In addition, the overlapping groove 21 may be a single groove, or the overlapping groove 21 may include several independent sub-grooves.

The bridging groove 21 is located at the middle position of the working electrode 2, is an internal groove, and is generally a closed figure, such as a circle, when viewed from the top of the transparent conductive electrode; or the overlapping groove 21 is opened at the edge of the working electrode 2, and is an edge groove, and is generally in an open pattern, such as a semicircular arc, when viewed from the top of the transparent conductive electrode.

The protective layer is usually a transparent resin layer, which can improve the structural strength of the working electrode 2, isolate external corrosive substances, improve the stability of the nano metal wire, the nano metal rod or the nano metal film, and is used for insulating the working electrode 2 from other film layers when being applied to other battery products. The sheet resistance of the side of the protective layer, which is far away from the working electrode 2, measured by using an eddy current sheet resistance meter is 0.1-500 ohm/sq, and the resistance cannot be measured by using a four-probe sheet resistance meter, which indicates that the protective layer does not have conductivity.

The protective layer 3 is provided with a conductive channel 31 communicated with the overlapping groove 21, and preferably, the conductive channel 31 and the overlapping groove 21 are positioned on the same straight line, so that synchronous formation is facilitated, and conductive filler is filled conveniently.

In addition, the conductive channel 31 is a single channel, or the conductive channel 31 includes several independent sub-channels. Any form of the said overlapping slot 21 can communicate with any form of conductive path 31; preferably, when the overlapping groove 21 is a groove, the conductive channel 31 is a channel; when the overlapping groove 21 is formed by several sub-grooves, the conductive channel 31 is formed by several sub-channels, and the sub-channels correspond to the sub-grooves one to one.

Filling conductive slurry into the conductive channel 31 and the overlapping groove 21 and solidifying the conductive slurry to form an electric connecting piece, wherein the electric connecting piece 4 is directly contacted with the section of the working electrode 2 exposed in the overlapping groove 21 and is electrically connected with the section of the working electrode 2 so as to lead out an electric signal of the section of the working electrode 2 to one side of the protective layer 3, which is far away from the working electrode 2; the traditional surface electrical connection mode is changed, the working electrode can be made of transparent conductive materials such as nano metal wires with large surface insulation or contact resistance, the thickness of the protective layer 3 can be increased, for example, the thickness of the protective layer 3 is not less than 10nm, preferably, the thickness of the protective layer is not less than 1 μm, and the stable transparent conductive electrode is obtained.

The electric conduction mechanism of the electric connection piece 4 and the section comprises: the end part of the nano metal wire or the nano metal rod extends out of the cross section into the lapping groove 21 and is electrically connected with the electric connector 4; or after the overlapping groove 21 is formed, a conductive film layer made of metal nano materials including a nano metal wire or a nano metal rod and the like or the nano metal film is turned outwards at the overlapping groove 21 to form a micron-sized conductive surface which is electrically connected with the electric connecting piece 4; or after the conductive paste is filled into the lapping groove 21, the cross section has better side invasion, so that the electric connector 4 is electrically connected with the working electrode 2.

The conductive paste includes, but is not limited to, conductive carbon paste and conductive silver paste. The conductive electrode is a copper foil electrode.

As shown in fig. 7, for the light modulation film 200 of the present invention, including two layers of any one of the above transparent conductive electrodes, the PDLC film 8 located between the two layers of transparent conductive electrodes, the PDLC film is located between the protective layers of the two layers of transparent conductive electrodes, i.e. two layers the protective layer 3 of the transparent conductive electrode is disposed face to face, and the two protective layers 3 are respectively located on two opposite sides of the PDLC film 8. In addition, the PDLC film can also be positioned between the substrates of the two layers of transparent conductive electrodes; or the PDLC film may also be located between the protective layer of one transparent conductive electrode and the substrate of another transparent conductive electrode.

After the two layers of transparent conductive electrodes are connected to a low-voltage alternating-current power supply, the arrangement state of liquid crystals in the PDLC film 8 is controlled through an electric field, so that the refractive index of the liquid crystals is changed, the light transmittance of the light modulation film 200 is changed, and the light transmission state and the light scattering state are switched.

The PDLC film 8 adopts the prior art, the PDLC film 8 corresponds to the dimming area of the substrate, and the wiring area is exposed, preferably, the conductive electrodes 2 of the two layers of transparent conductive electrodes are positioned on different sides, preferably two opposite sides, of the PDLC film 8, so that the lead wires can be conveniently arranged and the connection with a power supply can be conveniently realized.

Further, according to the light modulation film 200 of any one of the above embodiments, the working electrode includes a patterned sub-working electrode, and a overlapping groove having a cross section exposing the sub-working electrode is formed on the sub-working electrode in the wiring region, and a depth of the overlapping groove is not less than two thirds of a thickness of the sub-working electrode, or the overlapping groove penetrates the sub-working electrode in a thickness direction; the protective layer is provided with conductive channels which are correspondingly communicated with the lap joint grooves one by one; and the transparent conductive electrode also comprises electric connection pieces positioned in the conductive channels and the lap joint grooves which are communicated in a one-to-one correspondence manner, and electric connection conductive electrodes which are in one-to-one correspondence with the electric connection pieces. Each working electrode is independently connected with the conductive electrode, and the light transmittance of the patterned partial area can be adjusted, so that characters, patterns and the like are presented. The connection mode of the working electrode and the conductive electrode is the same as the connection mode of the continuous working electrode and the conductive electrode, and the description is omitted here.

The utility model also provides a preparation method of membrane of adjusting luminance, including following step:

s1 preparing the transparent conductive electrode, comprising the following steps: s1.1, forming a working electrode 2 on a substrate 1, wherein the working electrode 2 is composed of a nano metal wire, a nano metal rod or a nano metal film; s1.2, a cross section of the working electrode 1 is exposed by forming a lapping groove 21 on the working electrode 2 positioned in a wiring area of the substrate 1, wherein the depth of the lapping groove 21 is not less than two thirds of the thickness of the working electrode 2, or the lapping groove 21 penetrates through the working electrode 2 along the thickness direction; s1.3, forming a protective layer 3 on one side of the working electrode 2, which is far away from the substrate 1; s1.4, arranging a conductive channel 31 on the protective layer 3 in the wiring area of the substrate 1; s1.5, filling conductive slurry into the conductive channel 31 and the lapping groove 21, and solidifying the conductive slurry to form an electric connector 4; s1.6, arranging a conductive electrode 5 on one side of the protective layer 3, which is far away from the working electrode 2, wherein the conductive electrode 5 is electrically connected with the working electrode 3 through the electric connecting piece 4;

s2, compounding a PDLC film 8 between the two protective layers 3 of the transparent conductive electrode or compounding the PDLC film 8 between the two substrates 1 of the transparent conductive electrode; or the PDLC film 8 is compounded between the protective layer 3 of one transparent conductive electrode and the substrate 1 of the other transparent conductive electrode.

Wherein, S1.1 to S1.6 are only for convenience of description and do not emphasize the sequence of steps. For example, according to the different specific processes, the sequence relationship between steps S1.1 and S1.2 is: the overlap groove 21 may be formed simultaneously with the formation of the working electrode, or may be formed after the formation of the working electrode; the sequence relationship between step S1.3 and step S1.4 is: the conductive path 31 may be formed at the same time as the formation of the protective layer 3, or the conductive path 31 may be formed after the formation of the protective layer 3; step S1.2 and step S1.4 may be implemented separately or may be implemented synchronously after step S1.3.

Moreover, in the method, the process and the sequence of the steps are mainly described, and the positions, forms, and configurations of the substrate 1, the working electrode 2, the bonding groove 21, the protective layer 3, the conductive channel 31, the electrical connection member 4, and the conductive electrode 5 are the same as those described in the transparent conductive film 100, and are not described in detail.

Specifically, step S1.1 coats a conductive film on the substrate 1 using a nano-wire or nano-metal rod material, the coating process including but not limited to using a high precision slot extrusion coating apparatus, the nano-wire or nano-metal rod material being typically a solution.

In a preferred embodiment, the nano metal wire is a nano silver wire with the diameter of 5 nm-100 nm and the length of 15 μm-25 μm, and the thickness of wet films coated by various processes is 2 μm-10 μm so as to ensure continuous and stable conductivity.

Or, in the step S1.1, a patterned nano metal film may be directly formed by means of a mask by means of magnetron sputtering or vacuum evaporation to form the working electrode 2; or a nano metal film is firstly formed on the substrate 1 by adopting a magnetron sputtering or vacuum evaporation mode, and then the patterned working electrode 2 is formed by etching.

In the present invention, the overlapping groove 21 and the conductive channel 31 can be formed independently.

Preferably, after the working electrode 2 is formed, the conductive path 31 and the overlapping groove 21 are formed at the same time; the process is briefly described, and the conductive channel 31 is connected with the lap joint groove 21 in an alignment way, so that the subsequent filling of the conductive slurry is facilitated. Simultaneous formation here means that the same process step is used for completion.

Further, the utility model discloses the people discovers in the research, working electrode 2 be nanometer level, and the inevitable fluting technology can lead to the section nonconducting, through many ways of thinking and improving, forms the temperature is not higher than 300 ℃ in the overlap joint groove 21 process, and/or, forms the temperature is not higher than 300 ℃ in the electrically conductive passageway 31 process to avoid causing because of the thermal effect the non-conductive phenomenon of section of working electrode 2. Preferably, the temperature is not higher than 180 ℃, so that the nano metal wire or the nano metal rod can be prevented from being broken, and the conductive stability is ensured.

The method for forming the conductive channel 31 and/or the overlap groove 21 comprises mechanical damage, ultrasonic wave, laser etching, plasma ablation, shock wave, hole preparation and chemical etching, wherein the mechanical damage comprises scratching, scraping, drilling, cutting, grinding and vibration, and the laser etching process is preferably femtosecond laser to ensure the conductivity of the section.

In step S1.6, a copper foil electrode is attached to the electrical connector 4, and is electrically connected to the working electrode 2 through the electrical connector.

The transparent conductive electrode of the present invention and the method for manufacturing the same will be described below with reference to detailed examples.

Comparative example 1

Coating a coating liquid containing a nano silver wire on the surface of a transparent PET film by using high-precision slit extrusion coating equipment, wherein the diameter of the nano silver wire in the coating liquid is about 5-100 nm, the length is 15-25 mu m, and the solid content is 0.5%; the thickness of the coated wet film is 2 mu m-10 mu m, a metal grid layer containing nano silver wires is formed, the sheet resistance is 50ohm/sq after drying, and the visible light transmittance is not lower than 85%.

The protective layer 3 was prepared by coating a transparent UV curable resin solution using a high precision slit extrusion coating apparatus at a coating thickness of 1um, at which time the resistance could not be measured with a four probe sheet resistance meter, which was measured with an eddy current sheet resistance meter at 50 ohm/sq.

As shown in fig. 3, conductive silver paste is screen-printed on the protective layer 3 to form silver paste blocks 6 with a thickness of about 5 μm to 10um and a size of 2mm, the interval between each edge of a silver paste block 6 and an adjacent silver paste block 6 is 5mm, after drying and curing, the resistance between each silver paste block 6 is measured to show that the circuit is open, and the silver paste blocks 6 are not conductive.

Example 1, the difference from comparative example 1 is that:

as shown in fig. 4, after the protective layer 3 is formed, in a set silk-screen silver paste area, a tungsten needle is used to impact and destroy the protective layer 3 and the metal mesh layer, so as to form a plurality of destruction points 7 with a depth of about 1 μm to 50um and a diameter of 0.2mm, and the plurality of destruction points 7 are uniformly distributed in the overlapping area, as shown in fig. 4, 10 destruction points 7 are formed in this embodiment. And each breaking point 7 forms one sub-channel and one sub-groove on the protective layer 3, and the sub-groove breaks a part of the metal grid layer close to the protective layer 3 or penetrates through the metal grid layer according to the depth of the breaking point 7.

The conductive silver paste is printed on the screen in the set screen printing silver paste area to form silver paste blocks 6 with the thickness of 5 mu m-10 um and the size of 1mm, and the intervals between each edge of each silver paste block 6 and the adjacent silver paste blocks 6 are 2mm, so that the conductive channel 31 and the lap joint groove 21 are filled with the silver paste due to the adhesion and the flowability of the silver paste.

After drying and curing, the resistance between the silver paste blocks 6 is measured, and the measured value is less than 50 ohms, which indicates that the silver paste blocks 6 are conducted with the metal grid layer formed by the nano silver wires.

Comparing comparative example 1 with example 1, it can be seen that, when the bridging groove 21 is formed on the nano silver wire conductive film, the cross section has conductive performance, and the silver paste flowing into the bridging groove 21 and the cross section of the metal mesh layer can be effectively electrically connected.

The sequence relationship between step S2 and steps S1.1 to S1.6 includes but is not limited to: firstly, preparing a complete transparent conductive electrode through the steps S1.1-S1.6, and then compounding the protective layer 3 of the transparent conductive electrode on one side of the PDLC film 8, wherein the compounding method can adopt optical transparent adhesive bonding; the PDLC film 8 may be formed on the protective layer 3 after any of steps S1.3 to S1.6 of preparing a transparent conductive electrode; and the two methods can be selected according to the combination mode of the two transparent conductive electrodes and the PDLC film 8.

In a reference embodiment, the method for manufacturing a light-adjusting film includes the steps of: 1) coating a coating liquid containing nano silver wires and transparent UV curing resin on a PET film in sequence to form a working electrode 2 and a protective layer 3, and manufacturing two transparent conductive electrodes; coating a polymer dispersed liquid crystal coating liquid on the protective layer of one of the transparent conductive electrodes to form a PDLC layer; compounding another transparent conductive electrode on the PDLC layer; 2) die-cutting into a designated shape, and reserving a conducting electrode leading-out position, wherein the electrode leading-out position is consistent with the wiring area of the substrate; 3) wiping off the PDLC film 8 at the electrode leading position by using a solvent; 4) slightly polishing the electrode leading-out position by using sand paper to form a microscopic section of a nano metal wire layer or a nano metal rod layer or a nano metal film; 5) brushing conductive slurry on the polishing area, enabling the conductive slurry to flow to be in contact with the microscopic section, and drying and curing the conductive slurry; 6) attaching a conductive copper foil electrode to the surface of the conductive slurry layer to form the light adjusting film 200; and (3) carrying out external packaging on the dimming film 200, and connecting the copper foil electrode into a low-voltage alternating current power supply to obtain the dimming liquid crystal screen.

Further, in order to obtain a patterned sub-working electrode, step S1.1, a conductive film is coated on the substrate by using nano-materials such as nano-metal wires or nano-metal rods, and the coating process includes, but is not limited to, using a high-precision slit extrusion coating device; s1.12, etching the conductive film to form a patterned sub-working electrode, wherein the etching process comprises but is not limited to laser thin film etching, gas etching, discharge etching, chemical etching, physical etching and mechanical etching.

Depending on the specific process, the etching process of step S1.12 and the step S1.2 of forming the overlapping groove may be performed simultaneously when the same process is used; of course, the two steps can be carried out, and the sequence can be interchanged. Furthermore, after the protective layer is formed in step S1.3, the etching process in step S1.12 may be performed to form the patterned protective layer 3 corresponding to the sub-working electrode; of course, step S1.3 may be performed after step S1.12 to form the entire protective layer 3.

Or step S1.1 comprises: the patterned electrodes of the nanowires or the nanowires rods are screen printed or sprayed directly on the substrate 1 according to a predetermined pattern. Based on the method, after the step S1.1, the step S1.3 can form a whole protective layer 3, or form a patterned protective layer 3 by a mask method.

Or, in the step S1.1, a patterned nano metal film may be directly formed by means of a mask by means of magnetron sputtering or vacuum evaporation to form the working electrode 2; or a nano metal film is firstly formed on the substrate 1 by adopting a magnetron sputtering or vacuum evaporation mode, and then the patterned working electrode 2 is formed by etching.

Step S1.2 is to form a lap joint groove on the sub-working electrode located in the wiring region of the substrate.

Step S1.4 is specifically to form conductive channels on the protective layer located in the routing area of the substrate, where the conductive channels are in one-to-one correspondence with the lap joint grooves.

And S1.5, filling conductive slurry into the conductive channels and the lap joint grooves which are communicated in a one-to-one correspondence mode, and solidifying the conductive slurry to form an electric connector.

And S1.6, specifically, arranging a plurality of conductive electrodes on one side of the protective layer, which is far away from the sub-working electrodes, wherein the conductive electrodes are electrically connected with the corresponding sub-working electrodes through the electric connecting pieces.

The utility model discloses a membrane 200 of adjusting luminance through set up overlap joint groove 21 on working electrode 2 and outwards expose working electrode 2's section, and this section passes through electric connector 4 and conductive electrode 5 and realizes electric contact, has changed surface electric connection's mode in the past, not only can adopt transparent conducting material preparation working electrode 2 such as the great nano-metal wire of surface insulation or contact resistance, can also strengthen protective layer 3's thickness obtains stable transparent conductive electrode.

It should be understood that although the present description refers to embodiments, not every embodiment contains only a single technical solution, and such description is for clarity only, and those skilled in the art should make the description as a whole, and the technical solutions in the embodiments can also be combined appropriately to form other embodiments understood by those skilled in the art.

The above list of details is only for the feasible embodiments of the present invention, and is not intended to limit the scope of the present invention, and all equivalent embodiments or modifications that do not depart from the technical spirit of the present invention are intended to be included within the scope of the present invention.

Claims (7)

1. A light modulation film comprises two layers of transparent conductive electrodes and a PDLC film positioned between the two layers of transparent conductive electrodes; characterized in that the transparent conductive electrode comprises:

the substrate comprises a dimming area and a wiring area, wherein the wiring area is positioned on the outer periphery side of the dimming area;

the working electrode is positioned on the substrate and consists of a nano metal wire, a nano metal rod or a nano metal film, a lapping groove exposing the section of the working electrode is arranged on the structure of the working electrode positioned in the wiring area, the depth of the lapping groove is not less than two thirds of the thickness of the working electrode, or the lapping groove penetrates through the working electrode along the thickness direction;

the protective layer is positioned on one side of the working electrode, which is far away from the substrate, and a conductive channel communicated with the lap joint groove is arranged on the protective layer;

the electric connecting piece is positioned in the lapping groove and the conductive channel and is solidified conductive slurry;

the conductive electrode is positioned on one side of the protective layer, which is far away from the working electrode, and the conductive electrode is electrically connected with the working electrode through the electric connecting piece;

the PDLC film is positioned between the protective layers of the two transparent conductive electrodes, or the PDLC film is positioned between the substrates of the two transparent conductive electrodes; or the PDLC film is positioned between the protective layer of one transparent conductive electrode and the substrate of the other transparent conductive electrode.

2. The light-adjusting film according to claim 1, wherein the nano metal wire is a nano silver wire having a diameter of 5nm to 100nm and a length of 15 μm to 25 μm.

3. The light adjusting film according to claim 1, wherein a thickness of the protective layer is not less than 10 nm.

4. The film of claim 1, wherein the sheet resistance of the protective layer on the side facing away from the working electrode is from 0.1 to 500ohm/sq as measured using an eddy current sheet resistance meter, and wherein the resistance cannot be measured using a four-probe sheet resistance meter.

5. The light adjusting film according to claim 1, wherein the overlapping groove is one groove or the overlapping groove includes several independent sub grooves.

6. The light modulating film of claim 1 wherein said conductive channel is a channel or said conductive channel comprises several independent sub-channels.

7. The light-adjusting film according to any one of claims 1 to 6, wherein the working electrode comprises a patterned sub-working electrode, and a lap joint groove having a cross section exposing the sub-working electrode is provided on the sub-working electrode in the wiring region, and a depth of the lap joint groove is not less than two thirds of a thickness of the sub-working electrode, or the lap joint groove penetrates the sub-working electrode in a thickness direction; the protective layer is provided with conductive channels which are correspondingly communicated with the lap joint grooves one by one; and the transparent conductive electrode also comprises electric connection pieces positioned in the conductive channels and the lap joint grooves which are communicated in a one-to-one correspondence manner, and electric connection conductive electrodes which are in one-to-one correspondence with the electric connection pieces.

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