阅读说明：本技术 一种变色器件及其控制方法 (Color changing device and control method thereof ) 是由 王巍舒 于 2020-12-08 设计创作，主要内容包括：本发明提供了一种变色器件及其控制方法。所述变色器件包括依次层叠设置的第一基底层、第一导电层、变色层、第二导电层和第二基底层；所述变色器件中包括至少一个隔断结构,所述隔断结构包括至少两条边界汇流条和位于所述两条边界汇流条之间的至少一条隔断汇流条,所述隔断汇流条和边界汇流条分别位于不同的导电层上。本发明通过所述变色器件的导电层上增加由隔断汇流条和边界汇流条组成的隔断结构,通过对汇流条上电压的调控,实现了根据实际应用对变色器件分区变色区域的调整,同时还实现了渐变和分区结合的效果,减少了电流损耗导致的器件的损坏。(The invention provides a color changing device and a control method thereof. The color-changing device comprises a first substrate layer, a first conductive layer, a color-changing layer, a second conductive layer and a second substrate layer which are sequentially stacked; the color-changing device comprises at least one partition structure, the partition structure comprises at least two boundary bus bars and at least one partition bus bar positioned between the two boundary bus bars, and the partition bus bars and the boundary bus bars are respectively positioned on different conducting layers. According to the invention, the partition structure consisting of the partition bus bar and the boundary bus bar is added on the conductive layer of the color-changing device, and the adjustment of the color-changing area of the color-changing device in a partition mode according to practical application is realized by regulating and controlling the voltage on the bus bar, and meanwhile, the effect of combination of gradual change and partition is realized, and the damage of the device caused by current loss is reduced.)

1. The color-changing device is characterized by comprising a first substrate layer, a first conducting layer, a color-changing layer, a second conducting layer and a second substrate layer which are sequentially stacked;

a first bus bar and a second bus bar are respectively arranged at the edges of two ends of the first conducting layer;

a third bus bar and a fourth bus bar are respectively arranged at the edges of two ends of the second conducting layer;

the color-changing device comprises at least one partition structure, the partition structure comprises at least two boundary bus bars and at least one partition bus bar positioned between the two boundary bus bars, and the partition bus bars and the boundary bus bars are respectively positioned on different conducting layers.

2. Color changing device according to claim 1, characterized in that the width of the partition structure is less than 5 cm.

3. The color-changing device according to claim 1 or 2, wherein the first conductive layer and the second conductive layer are provided with positioning holes;

preferably, the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the partition bus bar, and the boundary bus bar are parallel to each other.

4. Color change device according to any of claims 1-3, characterized in that the projections of the first and third bus bars on the plane of the color change device coincide with each other and/or the projections of the second and fourth bus bars on the plane of the color change device coincide with each other.

5. The color changing device according to any one of claims 1 to 4, wherein the thicknesses of the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the partition bus bar, and the boundary bus bar are independently 10nm to 5 μm;

preferably, the widths of the first, second, third, fourth, partition and border bus bars are independently less than 20mm, preferably less than 2 mm;

preferably, the first, second, third, fourth, partition and boundary bus bars each have a conductivity greater than the first and second conductive layers.

6. The color changing device according to any one of claims 1 to 5, wherein at least one end of each of the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the partition bus bar, and the boundary bus bar is provided with a lead-out structure;

preferably, the two ends of the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the partition bus bar and the boundary bus bar are provided with leading-out structures.

7. The color changing device of claim 6, wherein the lead out structures of the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the partition bus bar, and the boundary bus bar are staggered.

8. The color changing device according to any one of claims 1 to 6, wherein the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the partition bus bar and the boundary bus bar do not contact each other.

9. The color-changing device according to any one of claims 1 to 7, wherein a protective layer and/or an insulating layer is independently provided on the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the partition bus bar, and the boundary bus bar.

10. A control method of a color-changing device for controlling the transmittance state of the color-changing device according to any one of claims 1 to 9,

applying a color change control signal to the color change device, and determining a target voltage according to the transmittance state type carried by the color change control signal received by the color change device, wherein the target voltage at least comprises voltage values respectively corresponding to the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the boundary bus bar and the partition bus bar;

and adjusting the transmittance state of the color-changing device by the target voltage.

Technical Field

The invention belongs to the technical field of electrochromism, and relates to a color-changing device and a control method thereof.

Background

How to control the zonal color change of the electrochromic device (i.e. the situation that the transmittance of different areas is not consistent) is a key concern of electrochromic products. Control of the different regions is typically achieved by separating the conductive layers of the different regions. However, in the prior art, once the conductive layers are separated, the color-changing areas are fixed and cannot be adjusted according to the requirements of practical application.

Meanwhile, the electrochromic device can further realize the adjustment of light intensity by adjusting the transmittance of the device. Generally, the whole electrochromic device is in a specific transmittance state, that is, the transmittance of each point on the device is the same, and the gradual change state cannot be realized.

Generally, different voltages are applied to specific positions on the bus bars to control the overall potential distribution of the electrochromic device, so that a gradual change effect is realized, wherein the color change direction is changed from two sides of the bus bars to the middle. But this results in a very visually non-uniform discoloration of the device and a slow discoloration time. Meanwhile, the current loss of different voltages directly applied to the same bus bar is also large, and the excessive current loss can be converted into heat energy, so that the damage of the electrochromic device is accelerated, and particularly the damage of the device at the bus bar is accelerated.

CN108761952A discloses a color-changing light-adjusting glass capable of displaying patterns in a partitioned manner, wherein a first bus bar and a second bus bar are arranged on a second conductive layer and an EC stacked layer in a penetrating manner, a third bus bar is arranged on one side of the second conductive layer away from the first bus bar, at least two fourth bus bars are arranged on one side of the second conductive layer away from the second bus bar, at least two pattern regions are formed on the second conductive layer through laser grooving insulating partitions, and the pattern regions are connected with the fourth bus bars through connection regions; and the second conducting layer and the EC stacking layer are provided with a first laser notch groove for insulating and separating the first bus bar and the third bus bar and a second laser notch groove for insulating and separating the second bus bar and the fourth bus bar. The problem with this document is that the laser grooving method is used to separate the conductive layers and fix the areas of zonal discoloration, which cannot be adjusted to the needs of the application.

CN105324708A discloses a bus bar arrangement and manufacturing method for non-rectangular shaped (e.g. triangular, trapezoidal, circular, pentagonal, hexagonal, arcuate, etc.) optical devices. The optical device includes a first side, a second side, and a third side adjacent to the second side, and two bus bars spanning a portion of the optical device. The optical transitions in this document are typically driven by applying appropriate potentials to the two thin conductive layers of the optically switchable device. Thus, the current loss of different voltages directly applied to the same bus bar is also large, and the excessive current loss can be converted into heat energy, so that the damage of the electrochromic device is accelerated, and particularly the damage of the device at the bus bar is accelerated.

Therefore, how to realize the effect of adjusting the regional division of the regional color change and simultaneously combining the regional division and the gradual change is a technical problem which needs to be solved urgently at present.

Disclosure of Invention

The invention aims to provide a color-changing device and a control method thereof. According to the invention, the partition structure consisting of the partition bus bar and the boundary bus bar is added on the conductive layer of the color-changing device, and the adjustment of the color-changing area of the color-changing device in a partition mode according to practical application is realized by regulating and controlling the voltage on the bus bar, and meanwhile, the effect of combination of gradual change and partition is realized, and the damage of the device caused by current loss is reduced.

In order to achieve the purpose, the invention adopts the following technical scheme:

in a first aspect, the present invention provides a color changing device, including a first substrate layer, a first conductive layer, a color changing layer, a second conductive layer, and a second substrate layer, which are sequentially stacked;

a first bus bar and a second bus bar are respectively arranged at the edges of two ends of the first conducting layer;

a third bus bar and a fourth bus bar are respectively arranged at the edges of two ends of the second conducting layer;

the color-changing device comprises at least one partition structure, the partition structure comprises at least two boundary bus bars and at least one partition bus bar positioned between the two boundary bus bars, and the partition bus bars and the boundary bus bars are respectively positioned on different conducting layers.

According to the invention, the partition structure consisting of the partition bus bar and the boundary bus bar is added on the conducting layer of the color changing device, and voltage mutation is realized at the partition structure through regulating and controlling the voltage on the bus bar, so that the adjustment of the color changing area of the color changing device in a partition mode according to practical application can be realized without partitioning the conducting layer, meanwhile, the effect of combination of gradual change and partition is realized, and the damage of the device caused by current loss is reduced.

In the present invention, the shape of the bus bar is not particularly limited, and may be linear or curved depending on the shape of the color changing device.

It should be noted that, the materials of the conductive layer, the substrate layer and the bus bar are not specifically required and limited, and those skilled in the art can reasonably select the materials of the conductive layer, the substrate layer and the bus bar according to actual requirements, for example, the substrate layer may be a transparent substrate, and may be an optical-grade transparent material, specifically, a flexible substrate material, including Polyester Film (PET), cyclic olefin copolymer or cellulose triacetate;

the conductive layer can be selected from indium-tin oxide (ITO), Aluminum Zinc Oxide (AZO), fluorine doped tin oxide (FTO), silver nanowire, graphene, carbon nanotube, metal mesh, silver nanoparticle, and other conductive materials;

the bus bar can be made of any one or the combination of at least two of conductive materials such as conductive silver paste, conductive copper paste, conductive carbon paste, nano-silver conductive ink, copper foil, copper wire or conductive adhesive film and the like; the material the same as the conducting layer can be directly adopted, the thickness of the material at the bus bar is larger, and the resistance is smaller, so that the visual consistency of the product can be increased due to the fact that the material is transparent while the conducting function is guaranteed.

Meanwhile, the positional relationship of the bus bar with the conductive layer and the base layer may be arbitrary, but the bus bar must be in contact with the conductive layer, but the position thereof with the base layer may be arbitrary.

Preferably, the partition structure has a width of less than 5cm, such as 4.9cm, 4.7cm, 4.5cm, 4.3cm, 4cm, 3.5cm or 3cm, etc.

The width of the partition structure in the invention specifically refers to the maximum distance between two boundary bus bars in the partition structure.

At the partition structure, if the width of the partition structure is too large, the color change condition at the partition structure and the color change condition of the whole device are inconsistent, because the voltage abrupt change occurs at the partition structure.

Further preferably, the surface resistance of the conductive layer inside the partition structure is greater than the surface resistance of the conductive layer outside the partition structure, wherein inside the partition structure refers to the area between the two boundary bus bars of the partition structure. By increasing the surface resistance of the conducting layer in the partition structure, when the voltage difference of the boundary bus bars at two ends of the partition structure is larger, the local heat generation in the partition structure can be reduced. In particular, the conductive layer within the partition structure may be scribed, etched, etc. to increase the local area resistance of the conductive layer within the partition structure.

Preferably, the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the partition bus bar, and the boundary bus bar are parallel to each other.

The bus bars are parallel to each other, so that the uniformity of the color changing device during color changing is improved.

Preferably, the first conductive layer and the second conductive layer are both provided with positioning holes.

The positioning hole is beneficial to accurate positioning when the first conducting layer and the second conducting layer are opposite.

The locating hole is used for the position of fixed conducting layer, can not be located the regional work that influences the color changer that discolours, and the position and the quantity of locating hole can rationally set up according to the installation requirement, for example, the locating hole is located the both ends of conducting layer. Preferably, the projections of the first and third bus bars on the plane of the color changing device coincide with each other, and/or the projections of the second and fourth bus bars on the plane of the color changing device coincide with each other.

Because the color of the bus bar and the color/transmittance of the bus bar area are not different, for example, the color of the bus bar can be displayed at the bus bar area, and the transmittance of the bus bar area can be changed along with the voltage, the two opposite bus bars are overlapped, which is beneficial to improving the overall visual consistency of the color changing device as much as possible.

Preferably, the thicknesses of the first, second, third, fourth, partition and boundary bus bars are independently 10nm to 5 μm, for example 10nm, 50nm, 100nm, 200nm, 500nm, 800nm, 1 μm, 2 μm, 3 μm, 3.5 μm, 4 μm, 4.5 μm or 5 μm, and the like.

Preferably, the widths of the first, second, third, fourth, partition and border bus bars are independently less than 20mm, such as 19.5mm, 19mm, 18mm, 15mm, 13mm, 10mm, 8mm, 5mm, 1mm, 0.5mm, 0.4mm, 0.3mm, etc., preferably less than 2 mm.

The width of the bus bar cannot be too wide, because too wide can lead to the bus bar being too obtrusive in visual effect, the aesthetic property of the whole device is reduced, and when the width of the bus bar is larger than 5mm, a shielding layer can be added on the part corresponding to the bus bar to shield the bus bar.

Preferably, the first, second, third, fourth, partition and boundary bus bars each have a conductivity greater than the first and second conductive layers.

The conductivity of the bus bar material is greater than that of the conductive layer material, so that the voltage drop along the bus bar direction (namely the transverse direction of the color changing device) is reduced, the voltage uniformity of each point of the color changing device in the transverse direction is improved, the color changing uniformity of the color changing device is improved, and the color changing speed is accelerated.

Preferably, at least one end of each of the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the partition bus bar and the boundary bus bar is provided with a leading-out structure.

The lead-out structure is used for connecting an external power supply, and the lead-out structure is arranged on the bus bar, so that the bus bar is usually made of a material with high conductivity, and the color change response speed of the color change device can be improved.

Preferably, the two ends of the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the partition bus bar and the boundary bus bar are provided with leading-out structures.

The two ends of the bus bar are respectively provided with the leading-out structure, namely two electrodes are led out from one bus bar, so that the phenomenon that when voltage is applied to one side only, the potential distribution caused by the voltage drop of the bus bar is uneven, and the color change effect is influenced can be avoided.

Preferably, the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the partition bus bar and the boundary bus bar are provided with positioning holes at two ends.

The positioning holes are arranged, so that the first conducting layer and the second conducting layer can be accurately aligned when being sequentially stacked.

Preferably, the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the partition bus bar and the boundary bus bar are arranged in a staggered manner.

In order to prevent the problem that the lead-out structures of two bus bars at the same position overlap each other when the first conductive layer and the second conductive layer face each other, leading-out is inconvenient and short-circuited easily, the lead-out structures are designed to be in a staggered relationship.

Preferably, the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the partition bus bar, and the boundary bus bar are not in contact with each other.

Preferably, a protective layer and/or an insulating layer is independently disposed on the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the partition bus bar, and the boundary bus bar.

The protective layer and/or the insulating layer can be an insulating glue layer, an insulating gloss oil, and the like.

The protective layer is arranged on the bus bar, so that the bus bar material can be protected from being corroded or oxidized by water vapor, oxygen and other environmental factors, and the insulating layer is arranged on the bus bar, so that the bus bar on the first conducting layer can be prevented from being contacted with the second conducting layer or the bus bar on the second conducting layer, or the bus bar on the second conducting layer can be prevented from being contacted with the first conducting layer or the bus bar on the first conducting layer. Thereby being beneficial to improving the stability and the service life of the color-changing device.

In a second aspect, the present invention also provides a method for controlling a color-changing device, for controlling the transmittance state of the color-changing device according to the first aspect,

applying a color change control signal to the color change device, and determining a target voltage according to the transmittance state type carried by the color change control signal received by the color change device, wherein the target voltage at least comprises voltage values respectively corresponding to the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the boundary bus bar and the partition bus bar;

and adjusting the transmittance state of the color-changing device by the target voltage.

By applying different voltages to the bus bars, voltage jump can be effectively realized at the partition structure consisting of the boundary bus bars and the partition bus bars. The voltage difference of different areas of the color-changing device can be realized by applying voltage on the bus bar, and the color change of the color-changing device in a subarea mode can be realized by matching with the voltage mutation at the position of the partition structure. Meanwhile, the gradual change effect can be realized through the adjustment of the voltage, or the effect of combining the partition and the gradual change is realized.

Exemplarily, a method for preparing the color-changing device is provided, and the method specifically includes:

(1) forming a conductive layer on a substrate: the first conductive layer and the second conductive layer are respectively prepared by forming the conductive layers on the substrate through a magnetron sputtering method (or a vacuum evaporation deposition method, a sol-gel method, a chemical vapor deposition method and the like).

(2) Forming a bus bar and a partition structure on the first conductive layer and the second conductive layer, respectively: and forming a bus bar and a partition structure on the preset positions of the first conducting layer and the second conducting layer respectively in a silver paste silk-screen printing mode.

(3) Coating an electrochromic layer on the first conductive layer: 500mg of poly (3-hexylthiophene) (P3HT) was dissolved in 10mL of o-xylene, magnetically stirred for 10 hours, and then the resulting solution was dropped onto an ITO layer (first conductive layer) plated on the first substrate layer, and spin-coated to form an electrochromic layer.

(4) Coating an ion storage layer on the second conductive layer: after 500mg of tungsten trioxide was dissolved in 20mL of deionized water and stirred and filtered, the resulting solution was dropped onto an ITO layer (second conductive layer) plated on the second substrate layer, and spin-coated to form a tungsten trioxide coating layer, thereby obtaining an ion storage layer.

(5) Preparing the whole color-changing device: mixing 20 wt% of lithium perchlorate, 59.9 wt% of methyl methacrylate, 20 wt% of propylene carbonate and 0.1 wt% of azodiisobutyronitrile, and coating the mixture on an ion storage layer to form an ion transfer layer; and then covering the electrochromic material layer (together with the first substrate layer) on the ion transfer layer, and carrying out ultraviolet curing to form the ion transfer layer.

Compared with the prior art, the invention has the following beneficial effects:

(1) according to the invention, different voltages are applied to different bus bars, so that the effects of quick color change and uniform color change can be achieved while gradient color change is realized, the current loss is reduced, and the damage of devices is effectively avoided.

(2) According to the invention, different voltages are applied to the boundary bus bar and the partition bus bar, so that voltage mutation is realized at the partition structure consisting of the boundary bus bar and the partition bus bar, namely different voltages of different areas of the color-changing device can be realized, and the color change of the color-changing device in a subarea manner can be realized by matching with the voltage mutation at the partition structure.

(3) By applying different voltages to the bus bars, voltage jump can be effectively realized at the partition structure consisting of the boundary bus bars and the partition bus bars. The voltage difference of different areas of the color-changing device can be realized by applying voltage on the bus bar, and the color change of the color-changing device in a subarea mode can be realized by matching with the voltage mutation at the position of the partition structure. Meanwhile, the effect of combining partitioning and gradual change can be realized by adjusting the voltage.

Drawings

Fig. 1 is a distribution diagram of all bus bars on the first conductive layer and a distribution diagram of voltages applied to the bus bars in example 1.

Fig. 2 is a distribution diagram of all the bus bars on the second conductive layer and a distribution diagram of voltages applied to the bus bars in example 1.

Fig. 3 is a distribution diagram of all bus bars on the first conductive layer and the second conductive layer in planar projection and a distribution diagram of voltages applied to the bus bars in example 1, and further includes two separated discolored regions a and B.

Fig. 4 is a distribution diagram of the lead structure and the positioning hole structure on the first conductive layer in example 1.

Fig. 5 is a distribution diagram of the lead structure and the positioning hole structure on the second conductive layer in example 1.

Fig. 6 is a distribution diagram of all the lead structures and positioning holes on the first conductive layer and the second conductive layer in planar projection in example 1.

Fig. 7 is a distribution diagram of all the bus bars on the first conductive layer and the second conductive layer in planar projection and a distribution diagram of voltages applied to the bus bars in example 3, and further includes three separated discolored regions C and E and D.

1-a first bus bar, 2-a second bus bar, 3-a third bus bar, 4-a fourth bus bar, 51-a first boundary bus bar, 52-a second boundary bus bar, 53-a third boundary bus bar, 54-a fourth boundary bus bar, 61-a first partition bus bar, 62-a second partition bus bar, 7-a first partition structure, 8-a second partition structure, 9-a third partition structure, 11-a lead-out structure on a first conductive layer, 12-a positioning hole on the first conductive layer, 21-a lead-out structure on a second conductive layer, and 22-a positioning hole on the second conductive layer.

Detailed Description

The technical solution of the present invention is further explained by the following embodiments. It should be understood by those skilled in the art that the examples are only for the understanding of the present invention and should not be construed as the specific limitations of the present invention.

It is to be understood that in the description of the present invention, the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be taken as limiting the present invention. Furthermore, the terms "first", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first," "second," etc. may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

It should be noted that, in the description of the present invention, unless otherwise explicitly specified or limited, the terms "disposed," "connected" and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art through specific situations.

Example 1

The present embodiment provides a color changing device. The color-changing device can realize the effect of color change in a subarea manner and also can realize the effect of color change in a gradual change manner.

The color-changing device comprises a first substrate layer, a first conductive layer, a color-changing layer, a second conductive layer and a second substrate layer which are sequentially stacked;

the color changing layer includes: an ion storage layer, an ion transfer layer, and an electrochromic layer laminated in this order, the electrochromic layer being laminated to the first conductive layer;

as shown in fig. 4, two ends of the first conductive layer are provided with positioning holes 12 on the first conductive layer; as shown in fig. 5, two ends of the second conductive layer are provided with positioning holes 22 on the second conductive layer;

as shown in fig. 1, a first bus bar 1 and a second bus bar 2 are respectively arranged at two end edges of the first conductive layer;

as shown in fig. 2, a third bus bar 3 and a fourth bus bar 4 are respectively arranged at two end edges of the second conductive layer;

as shown in fig. 1 to 3, the color changing device includes a first blocking structure 7, and the first blocking structure 7 includes a first boundary bus bar 51 on the first conductive layer, a second boundary bus bar 52, and a first blocking bus bar 61 on the second conductive layer. The first partition bus bar 61 is positioned between the first boundary bus bar 51 and the second boundary bus bar 52. Two different areas are separated by the first partition structure 7.

The projections of the first bus bar 1 and the third bus bar 3 on the plane of the color changing device coincide with each other, and the projections of the second bus bar 2 and the fourth bus bar 4 on the plane of the color changing device coincide with each other.

And one end of each bus bar of the color changing device is provided with a leading-out structure, and the projections of the leading-out structures 11 on the first conducting layer and the leading-out structures 21 on the second conducting layer on a plane are arranged in a staggered mode. Meanwhile, each bus bar is not in contact with each other.

The width of the first partition structure 7 in the color changing device is 2cm, the width of the bus bar is 0.5mm, and the thickness of the bus bar is 3 micrometers.

As shown in fig. 3, a distribution diagram of all the bus bars on the first conductive layer and the second conductive layer in the planar projection and a distribution diagram of voltages applied to the bus bars in this embodiment are shown. As can be seen from the figure, only the first bus bar 1 and the second bus bar 2 can be seen from the planar projection, because the projections of the first bus bar 1 and the third bus bar 3 on the plane of the color changing device coincide with each other, and the projections of the second bus bar 2 and the fourth bus bar 4 on the plane of the color changing device coincide with each other. And the first partition structure 7 comprises a first boundary busbar 51, a second boundary busbar 52 and a first partition busbar 61, while the projection of the first partition busbar 61 on the plane is located between the projections of the first and second boundary busbars 51 and 52 on the plane. Two areas A and B are separated by the first partition structure 7, and the transmittance of different areas can be different by regulating and controlling the voltage on the bus bar, so that the color change effects of partition color change and gradual color change are realized.

As shown in fig. 6, it can be seen that the lead-out structure 11 disposed at one end of the bus bar on the first conductive layer and the lead-out structure 21 disposed at one end of the bus bar on the second conductive layer are disposed in a staggered manner, and do not contact with each other, and the first conductive layer and the second conductive layer can be precisely aligned through the positioning hole 12 and the positioning hole 22.

Example 2

The present embodiment provides a control method of a color changing device, which may be performed by a controller controlling transmittance of the color changing device. Specifically, the method comprises the following steps:

s1, applying a color change control signal to the color change device, and determining target voltages according to the transmittance state type carried by the color change control signal received by the color change device, wherein the target voltages at least comprise voltage values corresponding to the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the boundary bus bar and the partition bus bar respectively;

and S2, adjusting the transmittance state of the color-changing device by the target voltage.

In step S1, the color-changing control signal may be applied by the user, or may be triggered by a specific condition (e.g., temperature, light, etc.). The color-changing control signal at least carries a transmittance state type, specifically, the transmittance state type includes a subarea color-changing type, a gradual color-changing type, other types preset by a user, and the like. The color-change control signal may be, for example, [ zone color change ], [ gradation color change ], or the like.

Furthermore, the color-changing control signal can also carry position information of the color-changing area and a transmittance state corresponding to each position. Specifically, the color changing device may be divided into a plurality of regions, each region having its corresponding code. For example, for the color changing device of example 1, the color changing device may be divided into an a region located above the first partition structure 7 and a B region located below the first partition structure 7. The color-change control signal may be, for example, [ zone color change; region A, faded state; b region, colored state, [ gradient discoloration; region a, colored state; b region, a gradual change from a colored state to a faded state ], and the like.

The target voltage lists corresponding to different transmittance state types are prestored in a controller/processor of the color-changing device. When the transmittance state type of the color-changing device is determined, the voltage value corresponding to each bus bar can be determined from the target voltage list. Then, the corresponding voltage value is respectively applied to each bus bar, so that the transmittance state of the color-changing device can be adjusted to the expected state.

The following describes the implementation of the control method in detail by taking the color-changing device of example 1 as an example.

An exemplary target voltage list 1 is as follows:

TABLE 1

Bus bar	Voltage numbering	Color change by partition	Gradual color change
				First bus bar 1	U1	2V	1V
Second bus bar 2	U2	0V	2V
				First boundary bus bar 51	U5	2V	1V
Second boundary bus bar 52	U6	0V	1V
				Third bus bar 3	U3	1V	2V
Fourth bus bar 4	U4	1V	1V
				First partition bus bar 61	U7	1V	2V

The implementation of zone-wise color change can be understood by the following description:

for region a, U1-U3-U5-U7-1V; for region B, U2-U4-U6-U7-1V; the color-changing effect that the area A is in a fading state and the area B is in a coloring state is realized.

For the color-changing device of example 1, when the voltage difference between the two conductive layers in the a region is 1V, the material of the color-changing layer will fade at the voltage, the transmittance will become high (for example, the transmittance is increased to 60%), and the a region is visually transparent and colorless; when the voltage difference between the two conductive layers in the B region is-1V, the material of the color-changing layer is colored at the voltage, and the transmittance becomes low (e.g., the transmittance decreases to 5%), and the B region is visually dark and opaque.

The implementation of the gradual change in color can be understood by the following description:

for region a, U1-U3-U5-U7-1V; for region B, U6-U7-1V, U2-U4-1V; the color change effect that the area A is in a colored state and the area B is in a gradual change state from the colored state to a faded state is realized.

For the color-changing device of example 1, when the voltage difference between the two conductive layers in the region a is-1V, the material of the color-changing layer will be colored at this voltage, the transmittance becomes low (e.g., the transmittance decreases to 5%), and the region a is dark and opaque visually; the voltage difference between the two conductive layers in the B area is gradually changed from-1V to 1V, and the material of the color changing layer fades under the condition that the voltage difference is 1V, the transmittance is high (for example, the transmittance is improved to 60 percent), and the material is colorless and transparent in vision, so when the voltage difference between the two conductive layers in the B area is gradually changed from-1V to 1V, the B area is in a color changing effect of gradually changing from a colored state to a faded state in vision.

It will be appreciated that when it is desired that the device as a whole assume a certain state, for example a faded state, this can be achieved by applying voltage regulation across the device only (for example applying a voltage across the first bus bar 1 and the fourth bus bar 4 so that the voltage difference is 1V); if the device is discolored gradually as a whole, for example, the entire device is changed from the colored state to the discolored state from top to bottom, voltage regulation may be applied only across the device (for example, U1-U3 is-1V, and U2-U4 is 1V).

It is to be understood that the specific voltage values in the present embodiment are specific examples given for the convenience of explaining the present invention, and the voltage of each bus bar is not particularly limited, and those skilled in the art may modify this according to the inventive concept of the present invention.

Example 3

The embodiment provides a color-changing device capable of simultaneously realizing color change in a subarea and color change in a gradual change mode.

The color-changing device comprises a first substrate layer, a first conductive layer, a color-changing layer, a second conductive layer and a second substrate layer which are sequentially stacked;

a first bus bar 1 and a second bus bar 2 are respectively arranged at the edges of two ends of the first conducting layer;

a third bus bar 3 and a fourth bus bar 4 are respectively arranged at the edges of two ends of the second conducting layer;

as shown in fig. 7, the color-changing device comprises a second partition structure 8 and a third partition structure 9, wherein the second partition structure 8 comprises a first boundary bus bar 51 located on the first conductive layer, a second boundary bus bar 52 and a first partition bus bar 61 located on the second conductive layer; the first partition bus bar 61 is between the first boundary bus bar 51 and the second boundary bus bar 52, the second partition structure 8 partitions the regions C and D, and the third partition structure 9 partitions the regions D and E.

The third partition structure 9 includes a third boundary bus bar 53, a fourth boundary bus bar 54 on the second conductive layer, and a second partition bus bar 62 on the first conductive layer; the second partition bus bar 62 is between the third boundary bus bar 53 and the fourth boundary bus bar 54.

The projections of the first bus bar 1 and the third bus bar 3 on the plane of the color changing device coincide with each other, and the projections of the second bus bar 2 and the fourth bus bar 4 on the plane of the color changing device coincide with each other.

Each bus bar both ends on the color-changing device are provided with leading-out structures and locating holes, and the leading-out structures are arranged in a staggered mode. Meanwhile, each bus bar is not in contact with each other.

The width of a second partition structure 8 in the color-changing device is 5cm, and the width of a third partition structure 9 in the color-changing device is 5 cm; the first, second, third and fourth bus bars have a width of 15mm, and the first, second, third and fourth partition bus bars 61, 62, 53 and 54 have a width of 1mm and a thickness of 5 μm.

As can be seen from fig. 7, the second partition structure 8 and the third partition structure 9 partition the color-changing device into three regions, and the transmittances of the three regions are regulated and controlled by controlling the voltage on the bus bar, so that the entire color-changing device realizes the color-changing effects of color change in different regions and color change in gradual change.

Example 4

The present embodiment provides a control method of a color changing device, which may be performed by a controller controlling transmittance of the color changing device. Specifically, the method comprises the following steps:

s1, applying a color change control signal to the color change device, and determining target voltages according to the transmittance state type carried by the color change control signal received by the color change device, wherein the target voltages at least comprise voltage values corresponding to the first bus bar, the second bus bar, the third bus bar, the fourth bus bar, the boundary bus bar and the partition bus bar respectively;

and S2, adjusting the transmittance state of the color-changing device by the target voltage.

In step S1, the color-changing control signal may be applied by the user, or may be triggered by a specific condition (e.g., temperature, light, etc.). The color-changing control signal at least carries a transmittance state type, specifically, the transmittance state type includes a subarea color-changing type, a gradual color-changing type, other types preset by a user, and the like. The color-change control signal may be, for example, [ zone color change ], [ gradation color change ], or the like.

Furthermore, the color-changing control signal can also carry position information of the color-changing area and a transmittance state corresponding to each position. Specifically, the color changing device may be divided into a plurality of regions, each region having its corresponding code. For example, for the color changing device of example 3, the color changing device may be divided into a C region located above the second partition structure 8, a D region located between the second partition structure 8 and the third partition structure 9, and an E region located below the third partition structure 9. The color-change control signal may be, for example, [ zone color change; region C, faded state; region D, colored state; region E, faded state, [ fade; region C, colored state; region D, gradual change state from coloring state to fading state; zone E, faded state ], etc.

The target voltage lists corresponding to different transmittance state types are prestored in a controller/processor of the color-changing device. When the transmittance state type of the color-changing device is determined, the voltage value corresponding to each bus bar can be determined from the target voltage list. Then, the corresponding voltage value is respectively applied to each bus bar, so that the transmittance state of the color-changing device can be adjusted to the expected state.

The following describes the implementation of the control method in detail by taking the color changing device of example 3 as an example.

An exemplary target voltage list 2 is as follows:

TABLE 2

Bus bar	Voltage numbering	Gradual color change
			First bus bar 1	U1	1V
Second bus bar 2	U2	0V
			First boundary bus bar 51	U5	0.5V
Second boundary bus bar 52	U6	0.5V
			Third bus bar 3	U3	0V
Fourth bus bar 4	U4	-1V
			First partition bus bar 61	U7	1.5V
Second partition bus bar 62	U8	0V
			Third boundary bus bar 53	U9	1V
Fourth boundary bus bar 54	U10	-1V

The implementation of the gradual change in color can be understood by the following description:

for region C, U1-U3-1V, U5-U7-1V; for region D, U6-U7-U8-U9-1V; for region E, U8-U10-U2-U4-1V; the color change effect that the area C is in a fade state to a coloring state, the area D is in a coloring state and the area E is in a fade state is realized.

For the color-changing device of this embodiment, when the voltage difference between the two conductive layers in the E region is 1V, the material of the color-changing layer will fade at a voltage of 1V, and the transmittance becomes high (for example, the transmittance increases to 60%), and the E region is visually colorless and transparent; when the voltage difference between the two conductive layers in the D region is-1V, the material of the color-changing layer is colored under the voltage, the transmittance is low (for example, the transmittance is reduced to 5%), and the D region is dark and impermeable visually; the voltage difference between the two conductive layers in the C area is gradually changed from 1V to-1V from top to bottom, so that the C area has a color change effect of gradually changing from a colored state to a faded state in visual perception.

It will be appreciated that when it is desired that the device as a whole assume a certain state, for example a faded state, this can be achieved by applying voltage regulation across the device only (for example applying a voltage across the first bus bar 1 and the fourth bus bar 4 so that the voltage difference is 1V); if the device is discolored gradually as a whole, for example, the entire device is changed from the colored state to the discolored state from top to bottom, voltage regulation may be applied only across the device (for example, U1-U3 is-1V, and U2-U4 is 1V).

It is to be understood that the specific voltage values in the present embodiment are specific examples given for the convenience of explaining the present invention, and the voltage of each bus bar is not particularly limited, and those skilled in the art may modify this according to the inventive concept of the present invention.

It can be seen from the embodiments 2 and 4 that the present invention can simultaneously achieve the effect of the zonal discoloration and the gradual change, and does not need to completely separate the conductive layers, so that the present invention can be adjusted according to the actual situation when adjusting the zonal discoloration area.

It is understood that one skilled in the art can also disconnect the conductive layer between two boundary bus bars in a partition structure of the present invention (e.g., scribe the conductive layer between two boundary bus bars of the partition structure, so that there is an open circuit between the two boundary bus bars), where the overall color change of the device cannot be adjusted by simply applying a voltage across the device.

The applicant declares that the above description is only a specific embodiment of the present invention, but the scope of the present invention is not limited thereto, and it should be understood by those skilled in the art that any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention are within the scope and disclosure of the present invention.