JPH11109422A - Electrochromic antidazzle mirror - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make it possible to rapidly evaporate the water drops sticking to a mirror finished surface by constituting a first layer of an electrochromic(EC) layer or exothermic layer and a second layer of the exothermic layer or EC layer and disposing an insulating layer therebetween. SOLUTION: This mirror has a light reflector 110, the first layer 120, the second layer 130, an insulating layer 140 and a protective layer 150. The first layer 120 consists of the EC layer which is disposed on the visible recognition side of the reflected light of the light reflector 110 and is reversibly changed in translucency by impressed voltage. The second layer 130 consists of the exothermic layer which is disposed on the visible recognition side of the reflected light with respect to the first layer 120 and is transparent. The insulating layer 140 consists of a transparent insulator which is disposed between the first layer 120 and the second layer 130. The protective layer 150 is disposed on the visible recognition side of the reflected light with respect to the second layer 130 and is transparent and thin. Then, the heat generated in the exothermic layer of the second layer is transmitted to the mirror finished surface without via the light reflector 110. Since the protective layer 150 is thin, the heat is liable to be transferred from the rear surface to the front surface and the temp. of its front surface may be rapidly elevated.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention has an anti-glare function,
The present invention relates to an anti-glare mirror that can be used for a vehicle door mirror or the like, and more particularly, to an electrochromic anti-glare mirror that exhibits an anti-glare function by using electrochromism.

[0002]

2. Description of the Related Art Electrochromism is a phenomenon in which the color of a substance is reversibly changed by an oxidation-reduction reaction caused by application of a voltage. Conventionally, there is a mirror provided with an electrochromic (hereinafter, referred to as EC) element capable of causing this phenomenon, and E is provided on the front side of a light reflector that reflects light.
In general, a C layer and a transparent glass for protecting the EC layer from external mechanical stress are sequentially provided. This mirror is called an EC anti-glare mirror, and the color of the EC layer is turned on and off by a voltage application / removal operation, thereby reversibly changing its translucency, and exhibiting an anti-glare effect as required. However, if water droplets such as raindrops adhere to the mirror surface of the EC anti-glare mirror, the water droplets scatter the incident light incident on the mirror or the reflected light reflected by the mirror, and the reflected image can be clearly seen. I can no longer do it.

[0003] To cope with such a problem, there has been proposed an EC anti-glare mirror provided with a heating element (heater) behind a light reflector (Japanese Patent Application Laid-Open No. 6-84437). In this EC anti-glare mirror, water droplets adhering to the mirror surface can be removed by evaporation due to heat generated from the heating element. However, since the light reflector and the transparent glass for protecting the EC anti-glare layer are interposed between the heating element and the surface of the EC anti-glare mirror, the heat generated from the heating element is transmitted to the mirror surface. Hateful. Also, if the temperature of the heat generated from the heating element is too high, the EC anti-glare layer may be thermally degraded.
The heating value of the heating element cannot be increased. For these reasons, the EC anti-glare mirror disclosed in this publication cannot quickly evaporate water droplets attached to the mirror surface.

[0004]

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and has as its object to provide an EC anti-glare mirror capable of quickly evaporating water droplets attached to a mirror surface.

[0005]

According to a first aspect of the present invention, there is provided an EC anti-glare mirror, comprising: a light reflector for reflecting light; A first layer composed of one of an EC layer whose translucency reversibly changes and a transparent heat generating layer through which a current flows to generate heat, and a first layer provided on the side on which reflected light is viewed with respect to the first layer; A second layer comprising the EC layer and the other of the heat generating layer, the first layer and the second layer.
An insulating layer made of a transparent insulator, provided between the first and second layers,
A transparent and thin protective layer provided on the reflected light viewing side with respect to the second layer.

[0006] The EC according to claim 2, which solves the above problem.
The anti-glare mirror is a heat-generating light reflector that reflects light and generates heat when a current flows, and is provided on the side of the reflected light with respect to the heat-generating light reflector. An EC layer to be formed, an insulating layer made of a transparent insulator provided between the heating light reflector and the EC layer, and a transparent and thin protective layer provided on the side where the reflected light is viewed with respect to the EC layer. , Is provided.

[0007] The EC according to claim 3, which solves the above problem.
The anti-glare mirror is the EC anti-glare mirror according to claim 1 or 2, wherein the protective layer comprises a titanium oxide layer made of titanium oxide and a silicon dioxide layer made of silicon dioxide. I do. Claim 4 for solving the above problem
An EC anti-glare mirror according to claim 3, wherein the surface of the protective layer is covered with a noble metal layer in the EC anti-glare mirror according to claim 3.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS First, an embodiment of an EC anti-glare mirror according to claim 1 will be described. The EC anti-glare mirror is roughly classified into two types depending on the configuration of the first layer and the second layer. One is a mode in which the first layer is constituted by an EC layer and the second layer is constituted by a heating layer. And
The other is a mode in which the first layer is composed of a heat generating layer and the second layer is composed of an EC layer.

The light reflector is not particularly limited as long as it can reflect light, and a known light reflector can be used. For example, a light reflector having a reflective layer made of an alloy such as a nickel-chromium alloy in addition to a metal such as aluminum or silver on a surface of a transparent plate such as a transparent glass or a transparent resin can be used. The EC layer is not particularly limited as long as the translucency is reversibly changed by an applied voltage, and a known EC layer can be used. For example, an oxidization layer between a pair of transparent electrode layers can be used. An EC layer having a multilayer structure in which a coloring layer, a solid electrolyte layer, and a reducing coloring layer are sequentially arranged can be used. In this example, the transparent electrode layer can be made of ITO (indium tin oxide), tin dioxide (SnO ₂ ), or the like. The oxidized coloring layer is made of iridium oxide (Ir).
O _X) and nickel oxide (NiO) can be constituted by a. On the other hand, the reduction coloring layer is made of tungsten oxide (WO).
₃ ), molybdenum oxide (MoO ₃ ), vanadium oxide (V
_X O _Y ). Note that “coloring” includes transparency. The solid electrolyte layer is a solid-state layer having an electrolytic component such as a water component. For example, tantalum pentoxide (T
a ₂ O ₅ ), silicon oxide (SiO ₂ ), chromium oxide (C
r ₂ O ₃ ) can be used as a matrix. In addition,
The arrangement direction of the layers constituting the EC anti-glare layer may be either the direction on the viewing side of the reflected light or the opposite direction.

The thickness of each layer constituting the EC layer can be appropriately selected according to each material. In order to form these layers, known thin film forming means such as an electron beam evaporation method, a heating evaporation method, a sputtering method, and an ion plating method can be used. The order of forming each EC layer is not particularly limited.

The coloration of the EC layer can be performed by applying and removing a voltage between the pair of transparent electrode layers so that the oxidized coloring layer and the reduced coloring layer are colored. The operation of adding and removing the voltage can be performed by providing a power supply capable of arbitrarily controlling the voltage outside the mirror. The heat generating layer is made of a transparent material that generates heat when an electric current is applied. As such materials,
For example, ITO, ZnO, AZO (Al-added ZnO),
SnO ₂ , CdO, Au or the like can be used.
The heating layer does not necessarily have to be a layer having a uniform thickness over the entire surface, and may take a form such as a lattice shape or a mesh shape.

The heat generating layer can generate heat by passing an electric current from a power supply installed outside. The calorific value can be changed as parameters such as the conductivity of the heating layer and the thickness of the layer, and the magnitude of the current flowing through the heating layer.
If the calorific value is too large, the function of the EC layer may be reduced by the high-temperature heat. Therefore, it is preferable to appropriately select each of the parameters of the calorific value and select a calorific value that can raise the surface of the mirror to an appropriate temperature without deteriorating the function of the EC layer.

The insulating layer is not particularly limited as long as it is made of a transparent insulator. For example, Al ₂ O ₃ ,
SiC, SiN, Ta ₂ O ₅ , SiO ₂ , ZrO ₂ and Y ₂
O ₃ can be used made of. The thickness of this layer can be appropriately selected depending on the insulating property, thermal conductivity, and the like. The protective layer is a transparent and thin layer that protects the heat generating layer, the EC layer, and the insulating layer from external mechanical stress, external moisture, and the like. The material of this layer is not particularly limited, and may be a hard material such as silicon dioxide or a soft material having cushioning properties.

In particular, when the protective layer is made of a material having excellent hydrophilicity such as silicon dioxide, when water droplets adhere to the mirror surface, the water droplets spread. As a result, the contact area of the water droplet with respect to the mirror surface increases, and the heat generated from the heating element is easily transmitted to the water droplet. In addition, the maximum total amount of water droplets that can adhere to the mirror surface is reduced by the formation of the water film. Therefore, water droplets adhering to the mirror surface can be quickly evaporated, the amount of water droplets adhering to the mirror surface can be reduced, and the efficiency of removing water droplets adhering to the mirror surface increases.

As described above, the heat generating layer, the EC layer, the insulating layer, and the protective layer can be respectively constituted, but it is preferable that each layer is in close contact with each other. This not only increases the mechanical strength of the mirror, but also facilitates the transfer of heat generated in the heating element layer to the mirror surface. As described above, the EC anti-glare mirror in which the heating layer, the EC layer, the insulating layer, and the protective layer are in close contact with each other can be formed by a known thin film forming means such as an electron beam evaporation method, a heating evaporation method, a sputtering method, and an ion plating method. Each layer can be formed by utilizing the same. The order of forming the heat generating layer, the EC layer, the insulating layer, and the protective layer is not particularly limited.

In the EC anti-glare mirror according to the first aspect, heat generated in the heat generating layer is transmitted to the mirror surface without passing through the light reflector. Further, since the protective layer is thin, heat is easily transmitted from the back surface to the front surface, and the temperature of the front surface can be quickly increased. For these reasons, the E according to claim 1
The C anti-glare mirror can evaporate water droplets attached to the mirror surface more quickly than a conventional EC anti-glare mirror.

By the way, depending on the type of the EC layer, there is a case where the response time of color erasing / decoloring becomes slow in cold weather. When such an EC layer is used, the heat generated in the heat generating layer can be used to heat the EC layer to a temperature at which the EC layer can operate properly. An embodiment of the EC anti-glare mirror according to claim 2 will be described below. The heat generating light reflector is not particularly limited as long as it reflects light and generates heat when an electric current is applied. For example, a substrate having a smooth surface formed with a film layer made of a metal such as aluminum, silver, chromium, or titanium, or an alloy of nickel and chromium, or an alloy of nickel and titanium, can be used.
In this example, the surface on which the coating layer is formed is arranged so as to face the reflected light viewing side. The coating layer provided on the substrate reflects light and generates an electric current when heated. The substrate used in this example is not particularly limited as long as it has excellent mechanical strength such as metal and glass. The heating light reflector can generate heat by passing an electric current from a power supply installed outside.

The insulating layer, the EC layer and the protective layer can be configured in the same manner as the EC anti-glare mirror according to the first aspect. In the EC anti-glare mirror according to the second aspect, for the same reason as the EC anti-glare mirror according to the first aspect, it is possible to evaporate water droplets attached to the surface of the mirror more quickly than in the conventional EC anti-glare mirror. it can. Further, the number of constituent layers of the mirror can be reduced by one layer as compared with the EC anti-glare mirror according to the first aspect.

Next, an embodiment of the EC anti-glare mirror according to the third aspect will be described. This EC anti-glare mirror is the same as the EC anti-glare mirror according to claim 1 except that the protective layer is made of a titanium oxide layer made of titanium oxide and a silicon dioxide layer made of silicon dioxide. It has the form of In this EC anti-glare mirror, it is preferable that the silicon dioxide layer is arranged so as to have a mirror surface. The protective layer is 2
It can have a structure of layers or more, and in addition to a titanium oxide layer and a silicon dioxide layer, can also be provided with a silicon dioxide layer, a titanium oxide layer and a silicon dioxide layer. Further, it is preferable that the titanium oxide layer and the silicon dioxide layer are in close contact with each other. This not only increases the mechanical strength of the mirror, but also facilitates the transfer of heat generated in the heating element layer to the surface of the mirror.

In the EC anti-glare mirror according to the third aspect, since the silicon dioxide layer having excellent hydrophilicity is exposed, the reason is that, as described above, water droplets adhering to the mirror surface can be easily evaporated and the mirror surface can be easily removed. The amount of water droplets adhering to the surface can be reduced. By the way, when an organic substance such as hydrocarbons floating in the air adheres to the surface of the silicon dioxide layer, the hydrophilicity thereof is reduced. However, in this protective layer, the organic matter attached to the surface of the mirror by the titanium oxide layer can be removed by decomposing it to water, carbon dioxide, or the like by photocatalysis. Therefore, even if organic substances such as hydrocarbons floating in the air are attached to the surface of the silicon dioxide layer to lower its hydrophilicity, it can be restored to the original hydrophilicity by irradiating light to a mirror surface. .

Next, an embodiment of the EC anti-glare mirror according to the present invention will be described. This EC anti-glare mirror has the same form as the EC anti-glare mirror according to claim 3 except that the surface of the protective layer is coated with a noble metal. As the noble metal, platinum, palladium, or the like can be used. In the EC anti-glare mirror according to the fourth aspect, the photocatalytic ability of the titanium oxide layer can be further improved by the noble metal covering the surface of the protective layer. As a result, even if organic substances such as hydrocarbons floating in the air adhere to the mirror surface, they can be decomposed into water, carbon dioxide, and the like by photocatalysis more quickly than the EC anti-glare mirror according to claim 3 and removed. . Therefore, the recovery of hydrophilicity when the hydrophilicity of the mirror surface is reduced by the attachment of organic substances such as hydrocarbons floating in the air to the surface of the silicon dioxide layer is further accelerated.

In each of the EC anti-glare mirrors according to the first to fourth aspects, the color of the EC layer is turned on and off by a voltage application / removal operation, thereby reversibly changing its translucency. The effect can be exhibited. Further, any of the EC anti-glare mirrors may constitute all of the mirrors to be used, or may constitute a part of all of them.

[0023]

The present invention will be described below in detail with reference to examples. (Embodiment 1) The EC anti-glare mirror 100 of this embodiment is shown in FIG.
As schematically shown in the cross section, the light reflector 110 includes a light reflector 110 that reflects light and an EC layer that is provided on the side of the light reflector 110 where the reflected light is viewed and whose light transmittance changes reversibly by an applied voltage. A first layer 120, a second layer 130, which is provided on the side on which the reflected light is viewed with respect to the first layer 120, and is formed of a transparent heat-generating layer through which an electric current flows to generate heat, and the first layer 120 and the second layer 130.
And an insulating layer 140 made of a transparent insulator
And an EC anti-glare mirror provided with a transparent and thin protective layer 150 provided on the side on which reflected light is viewed with respect to the second layer 130.

The light reflector 110 is formed on the flat surface of the glass substrate 112.
Aluminum film 114 formed on a smooth surface
is there. The aluminum film 114 is formed by a sputtering method.
To form a film. The first layer (EC layer) 120 includes a pair of ITs.
IrO between transparent electrode layers made of _XOxidation
Color layer, Ta_TwoO_FiveSolid electrolyte layer, and WO_ThreeThan
The reduction coloring layers were arranged in this order. These transparent electrodes
Each layer of electrode layer, oxidation coloring layer, solid electrolyte layer and reduction coloring layer
Are sequentially formed using a well-known electron beam evaporation system.
Done. The direction of applied voltage can be freely adjusted for the pair of transparent electrode layers
Connected to an external power supply (not shown) that can be switched to
Have been. This external power supply applies voltage to the transparent electrode layer.
Removal operation can be performed arbitrarily, and
The EC layer can be colored by discoloring the color layer.

The second layer (heating layer) 130 is made of ITO. Suitably, the thickness of this layer is between 20 and 50 nm. The sheet resistance is suitably in the range of 30 to 100 Ω / cm ² , and the heat output is 40 to 120 mW / c.
Suitably, it is at m ² . This layer is also connected to an external power supply (not shown) capable of flowing a current along the direction of layer expansion. This external power supply has a second layer 130 of 40 m.
A current that generates heat with a heating value of W / cm ² or more can be passed.

The insulating layer 140 is made of Al ₂ O ₃ . Suitably, the thickness of this layer is between 20 and 30 nm. The protection layer 150 is made of SiO ₂ . The thickness of this layer is 10-20
It is appropriate to be in nm. In the EC anti-glare mirror 100 of this embodiment, first, a light reflector 110 is prepared, and a first surface of the light reflector 110 is provided on the surface opposite to the surface provided with the aluminum film 114.
Layer 120, insulating layer 140, second layer 130, protective layer 150
Were sequentially formed by a sputtering method.

In the EC anti-glare mirror of this embodiment, water droplets adhering to the mirror surface can be quickly evaporated,
Can reduce the maximum total amount of water droplets that can adhere to the mirror surface by 50% with respect to the EC anti-glare mirror shown in FIG. (Embodiment 2) The EC anti-glare mirror 200 of this embodiment is shown in FIG.
As schematically shown in the cross section, the light reflector 210 includes a light reflector 210 that reflects light and an EC layer that is provided on the side of the light reflector 210 where the reflected light is viewed and whose light transmittance changes reversibly by an applied voltage. A first layer 220, a second layer 230, which is provided on the side on which the reflected light is viewed with respect to the first layer 220, and is made of a transparent heat generating layer through which a current flows and generates heat, and a first layer 220 and a second layer 230.
Insulating layer 240 made of a transparent insulator provided between
And a transparent and thin protective layer 250 provided on the visible side of the reflected light with respect to the second layer 230.
The EC anti-glare mirror includes a titanium oxide layer 252 made of titanium oxide, and a silicon dioxide layer 254 made of silicon dioxide provided on the side where the reflected light is viewed with respect to the titanium oxide layer 252.

The light reflector 210 is formed by forming an aluminum film 214 on a smooth surface of a glass substrate 212, and the aluminum film 214 is disposed so as to face the reflected light. The aluminum film 214 was formed by a sputtering method. First layer 220 and insulating layer 240
Is the same as that of the EC anti-glare mirror of Example 1.

The second layer (heating layer) 230 is made of ITO. Suitably, the thickness of this layer is between 40 and 60 nm. The sheet resistance is suitably in the range of ²⁰ to 30 Ω / cm ² , and the heat output is 40 to 120 mW / cm 2
² is appropriate. The titanium oxide layer 252 is 100
Has a thickness of about 300 nm, and the silicon dioxide layer 254 has a thickness of 1 to 300 nm.
It has a layer thickness of 2 nm. Each layer was formed by a vapor deposition method.

In the EC anti-glare mirror of this embodiment, water droplets adhering to the mirror surface can be quickly evaporated, and organic substances such as hydrocarbons floating in the air can be used as the EC anti-glare mirror of the first embodiment.
The maximum total amount of water droplets that can adhere to the mirror surface can be reduced by 40 to 50% compared to the case where the water droplets adhere to the surface of the anti-glare mirror. (Embodiment 3) The EC anti-glare mirror 300 of this embodiment is shown in FIG.
As schematically shown in the cross section, the light reflector 310 includes a light reflector 310 that reflects light and an EC layer that is provided on the side of the light reflector 310 where the reflected light is viewed and whose light transmittance changes reversibly by an applied voltage. A first layer 320, a second layer 330, which is provided on the side on which the reflected light is viewed with respect to the first layer 320, and is formed of a transparent heat generating layer through which a current flows and generates heat, and a first layer 320 and a second layer 330.
Layer 340 made of a transparent insulator and provided between
And a transparent and thin protective layer 350 provided on the side on which the reflected light is viewed with respect to the second layer 330.
The protective layer 35 includes a titanium oxide layer 352 made of titanium oxide and a silicon dioxide layer 354 made of silicon dioxide.
No. 0 is covered with a noble metal layer 360.

Light reflector 310, first layer 320, second layer 3
30, the insulating layer 340 and the protective layer 350
It is the same as that of the C anti-glare mirror. Noble metal layer 360
Is composed of Pt. This layer was formed by a vapor deposition method. Suitably, the thickness of the noble metal layer 360 is 0.1 nm or less. (Embodiment 4) An EC anti-glare mirror 400 according to the present embodiment is shown in FIG.
As schematically shown in the cross section, a heating light reflector 410 that reflects light and generates heat when a current is passed, and a heating light reflector 410 that is provided on the visible side of the reflected light with respect to the heating light reflector 410 and is transparent by an applied voltage. An EC layer 420 whose light property changes reversibly; an insulating layer 430 made of a transparent insulator provided between the heating light reflector 410 and the EC layer 420; Transparent thin protective layer 440
And an EC anti-glare mirror comprising:

The heating light reflector 410 is formed of a glass substrate 412.
An alloy film 414 of nickel and chromium was formed on the smooth surface of the above, and the alloy film 414 was disposed so as to face the side where the reflected light was viewed. The thickness of the alloy coating 414 is 50 to
Suitably, it is at 100 nm and its sheet resistance is 2
Suitably, it is between 0 and 30 Ω / cm ² . EC layer 42
0 and the insulating layer 430 are the same as those of the EC anti-glare mirror of Example 1, respectively.

The protective layer 440 includes a titanium oxide layer 442 made of titanium oxide, and a silicon dioxide layer 444 made of silicon dioxide provided on the side of the titanium oxide layer 442 on the side where reflected light is viewed. Note that when a photocatalysis occurs in the titanium oxide layer 442, free electrons are generated in the layer. An insulating layer 446 made of SiO ₂ was provided between the titanium oxide layer 442 and the EC layer 420 so that the free electrons did not affect the EC layer 420.

In the EC anti-glare mirror 400 of this embodiment, first, a light reflector 410 is prepared, and an insulating layer 430, an EC layer 420, and an EC layer 420 are formed on the surface of the nickel-chromium alloy film 414.
Insulating layer 446, titanium oxide layer 442, silicon dioxide layer 44
4 was sequentially formed by a vapor deposition method. (Embodiment 5) An EC anti-glare mirror 500 of this embodiment is shown in FIG.
As shown schematically in FIG. 1, a door mirror attached to the right side of a vehicle, and a portion surrounded by a square line (A
) In the same layer as the EC anti-glare mirror selected from Examples 1 to 4. Point B is the center of curvature of the mirror. A portion other than the portion A is provided with a light reflector that reflects light, an EC layer, and a transparent glass that protects the EC layer from external mechanical stress, in that order on the side where the reflected light of the light reflector is viewed. Consisting of

In many cases, the driver of the vehicle visually confirms the reflected image projected on the portion A to check the rear side. Therefore, the anti-glare effect is most needed in part A. In the door mirror of this embodiment, when water droplets such as raindrops adhere to the mirror surface, A
Water droplets adhering to the portion can be quickly evaporated. Therefore, the reflected image projected on the portion A can always be clearly recognized, and the rearward confirmation can be reliably performed.

With the door mirror having such a structure, the manufacturing cost of the door mirror can be reduced.

[0037]

When the EC anti-glare mirror according to claim 1 is used for a vehicle door mirror, the following effects can be obtained. When the driver drives the vehicle in rainy weather, it is possible to quickly evaporate the raindrops attached to the door mirror, so that the rear view can be reliably confirmed by the door mirror, and the vehicle can be driven more safely.

In the case where the mirror surface has high hydrophilicity, even if the mirror surface is fogged, the film spreads immediately and forms a water film, so that light scattering by water droplets is prevented and an anti-fogging effect can be obtained. . Further, since the heat generated in the heat generating layer can be efficiently used for evaporating water droplets adhered to the mirror surface, it is possible to reduce the power used for generating heat in the heat generating layer.

When the EC anti-glare mirror according to the second aspect is used for a vehicle door mirror, the following effects can be obtained in addition to the effects obtained by the EC anti-glare mirror according to the first aspect. In this EC anti-glare mirror, since the number of constituent layers can be further reduced as compared with the EC anti-glare mirror according to claim 1, the mirror can be made thinner and lighter. In addition, since the number of steps for forming a layer can be reduced by one, manufacturing costs can also be reduced.

When the EC anti-glare mirror according to the third aspect is used for a vehicle door mirror, the following effects can be obtained in addition to the effects obtained by the EC anti-glare mirror according to the first and second aspects. In this EC anti-glare mirror, even if organic substances such as hydrocarbons floating in the air adhere to the surface of the silicon dioxide layer and the hydrophilicity of the mirror surface is reduced, the light is applied to the mirror surface to restore the original hydrophilicity. Because it can be recovered, it is possible to quickly evaporate the raindrops attached to the door mirror and to obtain a permanent anti-fog effect.

When the EC anti-glare mirror according to the fourth aspect is used for a vehicle door mirror, the following effects can be obtained in addition to the effects obtained by the EC anti-glare mirror according to the third aspect. 4. The EC anti-glare mirror according to claim 3, wherein the EC anti-glare mirror recovers hydrophilicity when the hydrophilicity of the mirror surface is reduced by the attachment of an organic substance such as hydrocarbons floating in the air to the surface of the silicon dioxide layer. Since it is faster than the mirror, it is possible to quickly evaporate raindrops attached to the door mirror and to obtain the anti-fog effect more quickly.

[Brief description of the drawings]

FIG. 1 is a schematic cross-sectional view schematically illustrating a cross section of an EC anti-glare mirror according to a first embodiment.

FIG. 2 is a schematic cross-sectional view schematically illustrating a cross section of an EC anti-glare mirror according to a second embodiment.

FIG. 3 is a schematic cross-sectional view schematically illustrating a cross-section of an EC anti-glare mirror according to a third embodiment.

FIG. 4 is a schematic cross-sectional view schematically illustrating a cross section of an EC anti-glare mirror according to a fourth embodiment.

FIG. 5 is a diagram schematically illustrating a front surface of an EC anti-glare mirror according to a fifth embodiment.

[Explanation of symbols]

100: EC anti-glare mirror 110: Light reflector 112:
Glass substrate 114: Aluminum coating 120: First
Layer 130: Second layer 140: Insulating layer 150: Protective layer

Claims (4)

[Claims] 1. A light reflector for reflecting light, an electrochromic layer provided on the side of the light reflector for viewing the reflected light, the light transmitting property being reversibly changed by an applied voltage, and a current flowing to generate heat. A first layer formed of one of the transparent heat generating layers, and a second layer provided on the side on which reflected light is viewed with respect to the first layer and formed of the other of the electrochromic layer and the heat generating layer; An insulating layer provided between the layer and the second layer and made of a transparent insulator; and a transparent and thin protective layer provided on the side on which reflected light is viewed with respect to the second layer. Electrochromic anti-glare mirror characterized by the following. 2. A heat-generating light reflector which reflects light and generates heat by passing an electric current; and a light-reflecting side provided on the side of the reflected light with respect to the heat-generating light reflector. An electrochromic layer, which is provided between the exothermic light reflector and the electrochromic layer, an insulating layer made of a transparent insulator, and an electrochromic layer provided on a visible side of reflected light with respect to the electrochromic layer, An electrochromic anti-glare mirror, comprising: a transparent and thin protective layer. 3. The electrochromic anti-glare mirror according to claim 1, wherein said protective layer comprises a titanium oxide layer made of titanium oxide and a silicon dioxide layer made of silicon dioxide. 4. The electrochromic anti-glare mirror according to claim 3, wherein the surface of the protective layer is covered with a noble metal layer.