KR20160127849A - Self-powered electrochromic device - Google Patents

Abstract

A self-powered electrochromic device is suggested. The self-powered electrochromic device suggested in the present invention includes a color element and a nanowire where power color are automatically adjusted according to the brightness of surrounding light, and a nanowire. The nanowire which partially passes ultraviolet rays as well as visible light may include a transparent solar cell capable of self-power generation by using the ultraviolet rays. So, the self-powered electrochromic device capable of self-power generation can be provided.

Description

[0001] Self-powered electrochromic device [0002]

The present invention relates to a self-powered electrochromic device in which an electrochromic device and a transparent solar cell are fused.

[0002] The phenomenon in which the color reversibly changes in the direction of the electric field when a voltage is applied is called electrochromism, and a material capable of reversibly changing the optical characteristics of the material by an electrochemical redox reaction having such characteristics It is called electrochromic material. That is, when the electric field is not applied from the outside, the electrochromic material is not colored, but when the electric field is applied, it is colored. On the contrary, when the electric field is not applied from the outside, the electrochromic material is colored. Has the extinction characteristic.

The electrochromic device using such an electrochromic principle does not require an external light source, has excellent reflectivity, is excellent in flexibility and portability, can be lightened, and is expected to be widely used in various flat panel displays. In particular, the application of electronic paper (E-paper), which is an electronic medium for replacing paper, has recently been actively pursued.

As such electrochromic materials, inorganic compounds such as tungsten oxide and molybdenum oxide and organic compounds such as pyridine-based compounds, aminoquinone-based compounds and azine-based compounds are known.

Particularly, the organic electrochromic materials have a lower long-term stability than the inorganic electrochromic materials, but they are being actively studied because they can be applied to a flexible substrate and can form a thin film by a wet process.

Transparent conductive films are used as core materials for large area electronic devices including solar cells and displays, and future research and development tasks of this technology can be summarized by reducing material cost and securing durability. In the case of ITO (indium tin oxide, In2O3: Sn) thin film, which is a typical transparent conductive film material, it is difficult to reduce the material cost due to the rarity of indium (In), which is one of raw materials. On the other hand, the existing ITO thin film is not suitable for transparent electrodes of flexible electronic devices due to limit of flexibility durability of material itself in the realization of flexible electronic device technology which is emerging recently. Therefore, it is expected that the research and development of material structure and manufacturing method to reduce the raw material and manufacturing cost and to ensure the flexibility durability of the material will have a great influence on the future development of the large area electronic device field. ZnO, which is another typical transparent conductive film material, is mainly applied to the limited use in the photovoltaic field, but it is suitable as a transparent conductive film for flexible electronic devices because it has a lower price of raw materials than ITO. Commercial manufacturing methods of ZnO are generally vacuum evaporation methods such as sputtering or chemical vapor deposition 9). However, for a wide range of applications to future large area electronic devices, development using a sol-gel method that can reduce the manufacturing cost is appropriate.

An object of the present invention is to provide an electrochromic device capable of supplying a self-power by fusing an electrochromic device and a transparent solar cell.

In one aspect, the self-power-supply electrochromic element proposed in the present invention includes a color element and a nanowire that are automatically adjusted in power generation according to the brightness of the surrounding light, and the nanowire not only passes visible light but also partially passes ultraviolet And a transparent solar cell capable of self-power generation using the ultraviolet rays.

Wherein the color development element automatically adjusts the power generation of the power source to a predetermined color when the brightness of the ambient light is equal to or greater than a predetermined brightness, and when the brightness of the ambient light is equal to or lower than a predetermined brightness, Can be adjusted.

The illumination of the predetermined color may be automatically adjusted according to the degree of brightness of the surrounding light.

The solar cells are stacked in a plurality of layers and connected in series so that the voltage can be adjusted.

The transparent solar cell uses an electrode including a nanowire passing through a part of ultraviolet rays, so that the intensity of the transmitted light can be constantly adjusted through power generation by natural light without a separate power source.

The transparent solar cell may include an ultraviolet ray blocking function by absorbing ultraviolet rays.

The self-power-on-electrochromic element can be applied to a flexible substrate and can be attached to any surface.

According to the embodiments of the present invention, the proposed self-power-supply electrochromic element can be used for a detachable window in which transmitted light intensity is constant through power generation by natural light without a separate power source. In addition, due to ultraviolet absorption of the transparent solar cell layer, ultraviolet ray blocking function can be included.

1 is a view showing the structure of a self-powered electrochromic device according to an embodiment of the present invention.
2 is a view showing a structure of an electrochromic device according to an embodiment of the present invention.
3 is a view illustrating a transparent solar cell according to an embodiment of the present invention.

The present invention proposes a self-powered electrochromic device by fusing an electrochromic device with a transparent solar cell. A self-powered electrochromic device capable of generating electricity by natural light without using a separate power supply using ultraviolet rays is proposed. In addition, the intensity of the transmitted light is constant and can be used for removable windows. In addition, due to ultraviolet absorption of the transparent solar cell layer, ultraviolet ray blocking function can be included. In addition, although the self-power-supply electrochromic element according to the related art is applied to a glass window, the present invention has an advantage of applying a self-power-consuming electrochromic element to a flexible substrate. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing the structure of a self-powered electrochromic device according to an embodiment of the present invention.

The proposed self - powered electrochromic device consists of an electrochromic device and a solar cell to form a self - powered electrochromic device. The proposed self - powered electrochromic device has the possibility of detachable window with constant intensity of transmitted light through power generation by a natural pipe without a separate power source. In addition, ultraviolet ray blocking function can be included due to ultraviolet absorption of the transparent solar cell layer.

The proposed self-powered electrochromic device includes a coloring device that automatically adjusts the color of the power source according to the brightness of the surrounding light, and nanowires. The nanowires pass a part of ultraviolet rays as well as visible light, And the like.

More specifically, a self-powered electrochromic device can include a metal NW, a buffer layer, a nano transparent junction, a ZnO / metal NW composite TCO, & Flexible & transparent substrate, Electrochromic electrode, Ion conductor, Ion storage electrode.

When light, in other words ultraviolet and visible light, passes through a proposed transparent solar cell, ultraviolet light is absorbed and used for self-generation, and part of visible light is passed through.

At this time, when the brightness of the surrounding light exceeds the predetermined brightness, the power generation color is automatically adjusted to a predetermined color. On the other hand, when the brightness of the ambient light is equal to or lower than a predetermined brightness, the power supply color can be adjusted to a predetermined color. The illumination of the predetermined color may be automatically adjusted according to the degree of brightness of the surrounding light.

For example, when the applicant applies a power-source color element to an automobile glass, when the automobile comes on with a high beam, the color of the automobile window is automatically adjusted according to the brightness of the light, Can be blocked.

The transparent solar cell of the proposed self-powered electrochromic device can be stacked in a plurality of layers, and the voltage can be changed by connecting them in series. In addition, since the transparent solar cell uses an electrode including a visible ray as well as a nanowire through which a part of ultraviolet rays pass, power of transmitted light can be adjusted constantly through power generation by natural light without a separate power source. Thus, the ultraviolet ray shielding function is included by absorbing ultraviolet rays. Or ZnO / silver nanowires composite membrane TCO. And, the proposed self-powered electrochromic device can be applied to flexible substrates and can be attached to arbitrary surfaces.

2 is a view showing a structure of an electrochromic device according to an embodiment of the present invention.

The electrochromic device of the self-powered electrochromic device includes a flexible substrate 210, a TCO 220, an electrochromic device 230, an ion electrolyte 240, Ion storage 250, and a flexible substrate TCO 270.

An electrochromic layer 230 and an ion storage layer 250 are formed on the flexible substrate TCO 270 coated with the TCO 220 by the sol-gel method. Then, a sealing material is adhered to both substrates, and then an ion electrolyte (240) is injected into an empty space using a vacuum device, and then the injection port is sealed.

For example, the materials of an electrochromic device may be as follows.

- Ion storage electrode: V2O5

- Ion conductor: LiCIO

- Electrochromic electrode: WO3

3 is a view illustrating a transparent solar cell according to an embodiment of the present invention.

The transparent solar cell of the self-powered electrochromic device of the present invention includes a buffer layer 310, a nano transparent 320, a TCO 330, a flexible substrate 340).

For example, materials of a transparent solar cell may be as follows.

- ZnO nanopillar

- Cu2Ox nanoparticles (nanoparticles)

When the self-power-applied electrochromic element using the transparent solar cell according to the embodiment is applied to a sunroof for a vehicle installed on the roof of a vehicle, ventilation and openness of the interior of the vehicle can be enhanced.

The transparent solar cell according to the embodiment automatically adjusts the power supply color to a predetermined color when the brightness of the ambient light is equal to or higher than a predetermined brightness and when the brightness of the ambient light is lower than a predetermined brightness, It can be adjusted brightly with the specified color. Therefore, the sunroof can control the transmittance of sunlight entering the interior of the vehicle. In the case of a sunroof applied with a self-power-applied electrochromic element, which is proposed in an area where the solar irradiation amount is drastically increased in summer such as Korea, or in an excessive sunlight area such as a tropical area, Can be adjusted to ensure safe operation can help.

Accordingly, the present invention can adjust the solar light transmittance of the sunroof by applying an electrochromic material. The electrochromic device is an electrochromic material that exhibits a reversible redox reaction when an electric field or an electric current is passed therethrough to form a color absorption band, thereby reversibly changing the transmittance of the electrochromic device.

An object of the present invention is to provide an electrochromic device capable of supplying a self-power by fusing an electrochromic device and a transparent solar cell. According to the embodiments of the present invention, the proposed self-power-supply electrochromic element can be used for a detachable window in which transmitted light intensity is constant through power generation by natural light without a separate power source. In addition, due to ultraviolet absorption of the transparent solar cell layer, ultraviolet ray blocking function can be included.

Claims (7)

A coloring element that automatically adjusts the color of the power source according to the brightness of the surrounding light; And
Wherein the nanowire includes a transparent solar cell capable of self-development using the ultraviolet rays by partially passing not only visible light but also ultraviolet light;
Wherein the electrochromic device further comprises: The method according to claim 1,
The color-
When the brightness of the surrounding light is equal to or greater than a predetermined brightness, the power generation color is automatically adjusted to a predetermined color,
When the brightness of the ambient light is equal to or less than a predetermined brightness, the power generation is brightened to a predetermined color
Characterized in that the device is a self-powered electrochromic device. 3. The method of claim 2,
Wherein the predetermined color is automatically adjusted in accordance with the degree of brightness of the surrounding light
Characterized in that the device is a self-powered electrochromic device. The method according to claim 1,
In the transparent solar cell,
Voltage adjustable by stacking in multiple layers and serially connected
Characterized in that the device is a self-powered electrochromic device. The method according to claim 1,
In the transparent solar cell,
By using an electrode including a nanowire passing through not only visible light but also ultraviolet light, the strength of transmitted light can be adjusted constantly by power generation by natural light without a separate power source
Characterized in that the device is a self-powered electrochromic device. The method according to claim 1,
In the transparent solar cell,
Including ultraviolet ray blocking function by absorbing ultraviolet ray
Characterized in that the device is a self-powered electrochromic device. The method according to claim 1,
The self-powered electrochromic device may further comprise:
Applicable to flexible substrates and attachable to any surface
Characterized in that the device is a self-powered electrochromic device.

Images