CN212271463U - Mosaic decorative board - Google Patents

Abstract

The utility model discloses a mosaic decorative board, heated board, sealing glue piece, mosaic clear glass board from bottom to top range upon range of in proper order is provided with sealed chamber between heated board, mosaic clear glass board and the sealing glue piece, fills the electrolyte that contains electrochromic material in the sealed chamber, and sealing connection is first to lead electrical pillar in the heated board, and sealed intracavity is arranged in to first leading electrical pillar one end, and the other end extends to deviating from the electrolyte direction to extend the heated board, makes first leading electrical pillar can be connected to the power. The utility model provides a mosaic decorative board utilizes electrochromic material, when circular telegram and outage, demonstrates the effect of different patterns.

Description

Mosaic decorative board

Technical Field

The utility model relates to a mosaic decorative board.

Background

Electrochromic (eletrochromim) refers to a phenomenon in which when an electric field is applied to a color changeable material or a current is applied thereto, the optical properties (transmittance, reflectance, or absorption rate of light) of the material are changed reversibly and stably in a certain wavelength range including visible light wavelengths. In appearance, electrochromism shows reversible changes in color and transparency. When a voltage of a certain polarity is applied to the electrochromic material, the visible light transmittance of the material increases, which is called "discoloration", and when the polarity of the voltage is reversed, the light transmittance of the material decreases, which appears as a deepening color, which is called "coloring".

Electrochromic materials can be divided into two broad classes, inorganic materials and organic materials. Organic substances commonly used as electrochromic materials are amethyst compounds, thiopyrans, polyaniline, PEDOT and the like; inorganic electrochromic materials can also be classified into three groups, i.e., a material which is colorless in a high-valence oxidation state and colored in a low-valence reduction state, and such a material is called a cathodic electrochromic material, for example, WO₃，MoO₃，TiO₂，Nb₂O₅And the like. The second class, colorless in the reduced state and colored in the higher state, is known as anodic electrochromic materials, such as NiO_x，Rh₂O₃And the like. The third class, having different colors in two different valence states, is known as bicolor electrochromic materials, e.g. V₂O₅Etc.; at present, there are a variety of electrochromic materials, a variety of electrolytes containing these electrochromic materials, and discoloration is also different.

Mosaic decorative boards are also called mosaic bricks or leatheroid bricks and originate from ancient greeks. The small ceramic tile is used for splicing various decorative patterns in buildings. The blank is formed by semi-dry pressing and baked in a kiln to form the mosaic brick. CaO, Fe2O3, etc. are sometimes used as a coloring agent in the sludge. The decorative board is mainly used for paving or decorating inner walls and can also be used for decorating outer wall surfaces. At present, the mosaic decorative plate is generally a ceramic tile plate, and the color can not be changed, so that the application range and the application mode of the mosaic decorative plate are limited.

SUMMERY OF THE UTILITY MODEL

The utility model provides a mosaic decorative board can utilize electrochromic material to can reach when circular telegram and outage, strengthen or weaken the effect of mosaic pattern, with the mode different with conventional mosaic decorative board, demonstrate the mosaic pattern, because electrochromic material's the colouring that fades makes the utility model discloses certain dynamic effect still has.

The purpose of the utility model is realized like this:

the utility model provides a mosaic decorative board, from bottom to top stacks gradually heated board, sealed gluey piece, mosaic clear glass board, the heated board mosaic clear glass board with be provided with sealed chamber between the sealed gluey piece, fill the electrolyte that contains electrochromic material in the sealed chamber, the first electric pillar that leads of sealing connection in the heated board, sealed intracavity is arranged in to first electric pillar one end of leading, and the other end extends to deviating from the electrolyte direction to extend the heated board, make first leading electric pillar can be connected to the power.

Preferably, a first conductive film is disposed between the first conductive pillar and the electrolyte.

Preferably, at least two first conductive columns are connected to the heat insulation board.

Preferably, a plurality of separated first conductive films are arranged in the sealing cavity, the first conductive films are attached to the heat insulation board, one side of each first conductive film is in contact with the electrolyte, and the other side of each first conductive film is in contact with the first conductive column.

Furthermore, the first conductive film is in contact with a plurality of the first conductive columns which are separately arranged, and the first conductive columns connected with the same first conductive film are connected to the same electrode of a power supply.

Preferably, the side, facing the electrolyte, of the mosaic transparent glass plate is coated with a second conductive film.

Furthermore, a second conductive column is arranged on one side, away from the electrolyte, of the second conductive film, the second conductive column is connected with the mosaic transparent glass plate in a sealing mode, one end of the second conductive column is connected with the second conductive film, the other end of the second conductive column extends in the direction away from the electrolyte and extends out of the mosaic transparent glass plate, and therefore the second conductive column can be connected to a power supply.

Furthermore, the mosaic transparent glass plate is hermetically connected with a plurality of second conductive columns, and the second conductive columns are connected to the same electrode of the power supply.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model provides a mosaic decorative board utilizes electrochromic material, when circular telegram and outage, demonstrates the effect of different patterns.

Drawings

Fig. 1 is a schematic structural view of a mosaic decoration board of the present invention;

the mosaic transparent glass plate comprises a 1-mosaic transparent glass plate, a 2-first conductive film, a 3-sealing glue block, a 4-heat insulation plate, a 5-first conductive column, a 6-second conductive column and a 7-sealing cavity.

Detailed Description

The present invention will be further described with reference to the following specific embodiments, but the present invention is not limited to these specific embodiments. It will be recognized by those skilled in the art that the present invention encompasses all alternatives, modifications, and equivalents as may be included within the scope of the claims.

In the utility model, if not, the adopted raw materials and equipment can be purchased from the market or commonly used in the field. The methods in the following examples are conventional in the art unless otherwise specified.

As shown in fig. 1, a mosaic decorative board, heated board 4, sealing rubber piece 3, the transparent glass plate of mosaic 1 that stack gradually from bottom to top, heated board 4 the transparent glass plate of mosaic 1 with be provided with sealed chamber 7 between the sealing rubber piece 3, fill the electrolyte that contains electrochromic material in the sealed chamber, the first conductive pillar 5 of sealing connection in the heated board, sealed intracavity is arranged in to first conductive pillar 5 one end, and the other end extends to deviating from the electrolyte direction to extend the heated board, make first conductive pillar 5 can be connected to the power.

The utility model provides a mosaic decorative board utilizes electrochromic material, when circular telegram and outage, demonstrates the effect of different patterns.

The electrolyte 3 is composed of one or more of propylene carbonate, ethylene carbonate, fluoroethylene carbonate, gamma-butyrolactone and N-methyl pyrrolidone, and contains conductive particles. The electrochromic material is a cathodic electrochromic material, which may be bipyridylfluoroborate, and the anodic electrochromic material may be a phenazine hydride. The conductive particles are selected from one of fullerene, carbon nano tube, conductive carbon black and conductive fiber. The electrolyte is uniformly dispersed in the electrolyte by adopting a mechanical dispersion mode, or a ball milling dispersion mode or an ultrasonic dispersion mode, so that the particle size of the electrolyte is in a nano-scale range and the electrolyte does not settle; through the first conductive column 5, the electrolyte is connected with a direct current power supply with the voltage of 0.5-5V, the color changing time is 1.2-10 s, the power supply is disconnected, and the color fading time is 2-15 s.

Preferably, a first conductive film 2 is arranged between the first conductive pillar 5 and the electrolyte; the contact area between the first conductive film 2 and the electrolyte is large, so that the contact area between the first conductive column 5 and the electrolyte is enlarged, and on the other hand, the first conductive column 5 is prevented from being corroded by the electrolyte and the electrolyte is polluted by the first conductive column 5 by avoiding the direct contact between the first conductive column 5 and the electrolyte.

Preferably, at least two first conductive pillars 5 are connected to the heat-insulating plate 4; preferably, a plurality of first conductive films 2 which are separated from each other are arranged in the sealing cavity, the first conductive films 2 are attached to the heat insulation board, one surface of each first conductive film is in contact with the electrolyte, and the other surface of each first conductive film is in contact with the first conductive column 5; make on the one hand the mosaic decorative board can be in 4 face connection power supplies of thermal insulation board, on the other hand can be through the quantity of the first conductive pillar 5 of control circular telegram, control input current's intensity to control final pattern effect.

Further, the first conductive film 2 is in contact with a plurality of the first conductive pillars 5 separately arranged, and the first conductive pillars 5 connected to the same first conductive film 2 are connected to the same electrode of a power supply; the intensity of the input current, and thus the final pattern effect, can be controlled by controlling the number of energized first conductive pillars 5.

Preferably, the side of the mosaic transparent glass plate 1 facing the electrolyte is coated with a second conductive film; further, a second conductive column 6 is arranged on one side, away from the electrolyte, of the second conductive film, the second conductive column 6 is hermetically connected with the mosaic transparent glass plate 1, one end of the second conductive column 6 is connected with the second conductive film, and the other end of the second conductive column extends in a direction away from the electrolyte and extends out of the mosaic transparent glass plate, so that the second conductive column 6 can be connected to a power supply; further, the mosaic transparent glass plate is connected with a plurality of second conductive columns in a sealing mode, and the second conductive columns 6 are connected to the same electrode of the power supply.

The above description is only for the preferred embodiment of the present invention, and is not intended to limit the present invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. The utility model provides a mosaic decorative board, its characterized in that, heated board (4), sealant block (3), mosaic clear glass board (1) from bottom to top stack gradually, heated board (4) mosaic clear glass board (1) with be provided with sealed chamber (7) between sealant block (3), fill the electrolyte that contains electrochromic material in the sealed chamber, sealing connection first leads electrical pillar (5) in the heated board, first lead electrical pillar (5) one end and arrange sealed chamber (7) in, the other end deviates from the electrolyte direction and extends the heated board.

2. The mosaic decorative board according to claim 1, wherein a first conductive film (2) is disposed between said first conductive post and the electrolyte.

3. Mosaic decorative board according to claim 1, characterized in that at least two first conductive columns (5) are connected in said insulating board (4).

4. The mosaic decorative plate according to claim 1, wherein a plurality of separated first conductive films (2) are arranged in the sealing cavity, the first conductive films (2) are attached to the insulation plate, one side of each first conductive film is in contact with the electrolyte, and the other side of each first conductive film is in contact with the first conductive columns (5).

5. The mosaic decorative plate according to claim 4, wherein said first conductive film (2) is in contact with a plurality of said first conductive posts (5) separately provided, and said first conductive posts (5) connected to the same one of said first conductive films (2) are connected to the same electrode of a power supply.

6. Mosaic decorative panel according to claim 1, characterized in that the mosaic transparent glass panel (1) side facing the electrolyte is coated with a second conductive film.

7. The mosaic decorative plate according to claim 6, wherein a second conductive film (6) is arranged on one side of the second conductive film, which faces away from the electrolyte, the second conductive film (6) is hermetically connected with the mosaic transparent glass plate (1), one end of the second conductive film (6) is connected with the second conductive film, and the other end extends in a direction away from the electrolyte and extends out of the mosaic transparent glass plate.

8. The mosaic decorative plate according to claim 7, wherein said mosaic transparent glass plate is hermetically connected with a plurality of said second conductive columns, and said second conductive columns (6) are connected to the same electrode of a power supply.

Images