JPH0749466Y2 - Anti-glare mirror - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial field of application) The present invention relates to an antiglare mirror using an electro-optical element whose light transmittance changes in response to power supply.

(Prior Art) An electro-optical element such as a liquid crystal panel is being widely used, for example, as an anti-glare mirror for an automobile, because a stable gray level change can be obtained. The liquid crystal panel that constitutes the mirror body of such an antiglare mirror basically has a transparent conductive film formed on each of the opposing surfaces (inner side surfaces) of a pair of transparent substrates, and the liquid crystal is interposed between these transparent conductive films. And a light reflecting film is formed on the outer surface of one transparent substrate, and a polarizing film is arranged on the outer surface of the other transparent substrate. In this case, a sealing structure is required around the liquid crystal panel, that is, in the peripheral portion of the mirror body, so that the antiglare function cannot be obtained in this portion. For this reason, conventionally, a black frame portion is provided in the peripheral portion of the mirror body, that is, in a portion corresponding to the sealing structure.

(Problems to be Solved by the Invention) In the above-described conventional configuration, the effective area of the mirror body (the area where the reflected image is reflected) is reduced by the amount of the black frame portion around the periphery of the mirror body. . For this reason, when it is attempted to secure a large effective area, the mirror body and the mirror housing for accommodating the mirror body become large in size, and the external appearance and shape of the mirror housing are restricted by design. Further, when the mirror housing design is prioritized to be miniaturized, the effective area of the mirror body becomes small. Such a problem also occurs when an electrochromic display element is used as the electro-optical element.

The present invention has been made in view of the above circumstances, and an object thereof is to provide an anti-glare function by an electro-optical element, while being able to sufficiently increase the effective area of the mirror body, An object is to provide an anti-glare mirror that has the effect of increasing the degree of freedom in design.

[Structure of the Invention] (Means for Solving the Problems) In order to achieve the above-mentioned object, the present invention sandwiches an electro-optical material whose light transmittance changes according to a voltage application between opposing electrodes, and the above-mentioned opposing electrodes. A mirror main body including an electro-optical element formed by sealing an electrode and a peripheral portion of an electro-optical material with a sealing material, and a mirror main body configured by disposing a light reflecting film behind the electro-optical element, and the mirror main body. In an anti-glare mirror having a mirror housing to be housed, a light reflection near a light reflectance of the mirror body in a non-driven state of the electro-optical element is provided at a position corresponding to the sealing material in a peripheral portion of the mirror body. The auxiliary light reflecting film having a high refractive index is formed.

(Operation) In the mirror body using the electro-optical element, since the change in the light transmittance of the electro-optical material cannot be expected in the sealing material portion located in the peripheral portion, a reflected image can be obtained in that portion. Although not possible, an auxiliary light reflection film having a light reflectance close to that of the mirror body in the non-driven state of the electro-optical element is provided so as to correspond to this portion. As a result, a reflected image can be obtained in the entire mirror body, and thus a wide field of view can be obtained in the entire mirror body in the non-glare state.

(Embodiment) A first embodiment of the present invention will be described below with reference to FIGS. 1 and 2.

In FIG. 2, reference numeral 1 denotes a mirror housing of an automobile door mirror, for example, in which a mirror main body 2 is arranged so as to be vertically and horizontally swingable.

Then, FIG. 1 shows the sectional structure of the mirror body 2 as a model. In FIG. 1, 3 and 4
Is a pair of transparent glass plates that are substrates, and on each of these opposing surfaces, transparent conductive films 5 and 6 and a transparent alignment film as opposing electrodes.
7 and 8 are attached to each other in a laminated form. At this time, the auxiliary light reflection film 9 is formed in a frame shape in a peripheral portion (that is, a portion corresponding to the peripheral portion of the mirror body 2) on one transparent conductive film 5 before the alignment film 6 is laminated. Which is made of a low resistivity metal such as aluminum.

Then, between the alignment films 7 and 8, for example, a nematic type G-
The H liquid crystal 10 (corresponding to the electro-optical material in the present invention) is enclosed, and the polarizing film 11 is attached to the front side of the transparent glass plate 3 (the side opposite to the transparent conductive film 5). A liquid crystal panel 12 which is an electro-optical element is constituted by combining the liquid crystal 10 and the polarizing film 11 with the transparent glass plates 3 and 4, the transparent conductive films 5 and 6, the alignment films 7 and 8, and the like. In addition, 5a and
6a is a terminal for the transparent conductive films 5 and 6, 13 is a liquid crystal
10, in particular, a sealing material for sealing the transparent conductive films 5 and 6, the alignment films 7 and 8 and the peripheral edge of the liquid crystal 10, and the auxiliary light reflection film 9 is provided on the peripheral edge of the mirror body 2. It will be formed at a position corresponding to the sealing material 13. A light reflecting film 14 made of aluminum or the like is additionally provided on the back side of the transparent glass plate 4 (behind the liquid crystal panel 12). The light reflecting film 14 and the liquid crystal panel 12 constitute the mirror body 2. Has been done.

The mirror body 2 configured as described above reflects the light incident from the outside through the liquid crystal panel 12 by the light reflection film 14 as shown by the arrow in FIG. 1, and thereby a reflected image is obtained. To be At this time, the liquid crystal panel 12 is in a light absorbing state (light blocking state) when a driving voltage is applied between the transparent conductive films 5 and 6, and thus when the driving voltage is applied, An anti-glare effect that the reflected image on the light reflecting film 14 becomes dark can be obtained. The light reflectance of the light reflection film 14 in the non-glare state is higher than the light reflectance of the auxiliary light reflection film 9 (= a state close to 50%, specifically, about 60% or more). Is set to.

According to the configuration of the present embodiment described above, in the non-glare state where the liquid crystal panel 12 is not driven, the light reflectance of the mirror body 2 is about 60%, and the light reflectance is around the light reflection film 14. Since the light reflectance of the auxiliary light reflection film 9 is set to about 50%, a wide field of view can be obtained in the entire area of the mirror body 2. On the other hand, in the anti-glare state where the liquid crystal panel 12 is driven, the light reflectance of the auxiliary light reflection film 9 does not change, but the light reflectance is set lower than the normal light reflectance and Since the light reflection film 9 itself is relatively narrow, the reflected light at the auxiliary light reflection film 9 does not affect the visibility as a result. As a result, in both the anti-glare state and the non-glare state, it is possible to obtain a reflected image in the entire area of the mirror main body 2 and to make the effective area sufficiently large, and also in the design of the mirror housing 1. The degree of freedom of can be increased.

Incidentally, as shown in FIG. 3 showing the second embodiment of the present invention, an insulating film 15 may be interposed between the transparent conductive film 5, the auxiliary light reflection film 9 and the alignment film 7. In addition, in the above-described first embodiment, the auxiliary light reflection film 9 is provided on the transparent conductive film 5, but the fourth embodiment showing the third embodiment of the present invention.
As shown in the figure, the sealing material is placed between the transparent glass plate 3 and the polarizing film 11.
The auxiliary light reflection film 16 may be formed so as to correspond to 13, and the point is to form the auxiliary light reflection film at a position corresponding to the sealing material 13 in the peripheral portion of the liquid crystal panel 12. It is a thing.

A fourth embodiment of the present invention is shown in FIGS. 5 and 6, which will be described below. In FIG. 6, 17
Is a mirror housing of an automobile door mirror, inside which a mirror body 18 is disposed so as to be vertically and horizontally swingable.

FIG. 5 shows the sectional structure of the mirror main body 18 as a model. In FIG. 5, 19 is a transparent glass plate which is a substrate forming the surface of the mirror body 18, and a transparent electrode film 20 as an opposing electrode made of an ITO film is formed on the transparent glass plate 19 (lower surface in the figure). It is attached. Reference numeral 21 denotes an auxiliary light reflection film provided in a frame shape around the transparent electrode film 20 (that is, the peripheral portion of the mirror body 18), which is formed of a low-resistivity metal such as aluminum. Is set to be, for example, about 50%. Reference numeral 22 is an electrochromic reaction portion (corresponding to the electro-optical material in the present invention) provided on the transparent electrode film 20, which is configured as described below. That is, 23 is a transparent electrode film
20 and the auxiliary light reflection film 21 is an oxidative coloring film provided with the peripheral portion of the auxiliary light reflection film 21 left, which is a reversible electrolytic oxidative electrochromic substance (for example, IrO ₂ ).
Consists of Reference numeral 24 is a dielectric film provided on the oxidation coloring film 23, which is made of Ta ₂ O _5, for example. Further, 25 is the dielectric film 2
4 is a reduction color-forming film additionally provided on the surface, which is composed of a reversibly electroreducible electrochromic substance (for example, WO ₃ ).

On the other hand, 26 is a light-reflecting film that also serves as a counter electrode of the electrochromic reaction part 22 configured as described above, and this is provided in a region on the reduction color-forming film 25 that does not face the auxiliary light-reflecting film 21. There is. Then, the transparent electrode film 20 described above,
An electrochromic display element 27, which is an electro-optical element, is constituted by the electrochromic reaction portion 22 and the light reflection film 26, and in this case, the light reflectance in the non-energized state (non-glare state) of the electrochromic display element 27, That is, the light reflectance (corresponding to the light reflectance of the light reflecting film 26 as shown by the arrow in the figure) in the state where the oxidative coloring film 23 and the reduction coloring film 25 are decolored is equal to that of the auxiliary light reflecting film 21. Light reflectance (= 50
%) Is set to, for example, about 60%. Further, 28 is a sealing material which is provided so as to cover the electrochromic display element 27 and seals the peripheral portion thereof, and 29 is a reinforcing glass plate arranged on the sealing material 28.

Next, the operation of the above configuration will be described. Now, in the non-glare state where the electrochromic display element 27 is not energized, the light reflectance of the light reflecting film 26 is about 60%, and
Since the light reflectance of the auxiliary light reflecting film 21 located around the light reflecting film 26 is set to about 50%, the mirror body 18
A wide field of view can be obtained over the entire area. On the other hand, in order to switch the mirror body 18 to the antiglare state, a DC voltage having a positive potential is applied between the transparent electrode film 20 and the light reflection film 26 on the transparent electrode film 20 side. Then, water hydrogen ions (H ⁺⁾ and hydroxyl ions contained in the dielectric film 24 (OH ^-) and the is electrolyzed, the light reflection of the hydrogen ions (H ⁺⁾ is a negative potential film 26 thus reduction coloring film 25
It moves to the side and reduces it, and at the same time, the hydroxide ion (O
H ^-) in which is oxidized to move to the transparent electrode film 20 thus oxidized color film 23 side of the positive potential. Therefore, by such a reduction and oxidation reaction, the oxidation coloring film 23 and the reduction coloring film
25 becomes colored (colored). Then, in this color-developed state, the light reflectance of the light-reflecting film 26 is reduced to 10% or less, and thus an antiglare state is obtained. In such an anti-glare state, the light reflectance of the auxiliary light reflecting film 21 does not change, but the light reflectance is set lower than the normal light reflectance, and the auxiliary light reflecting film 21 itself is Since the width is relatively narrow, the reflected light from the auxiliary light reflecting film 21 does not affect the visibility as a result. To return the mirror body 18 from the anti-glare state to the non-glare state as described above, a DC voltage having a positive potential on the light reflection film 26 side is applied between the transparent electrode film 20 and the light reflection film 26. Then, the oxidation coloring film 23 and the reduction coloring film 25 become colorless (non-colored) by a reaction opposite to the above, and thereby returned to the non-glare state.

Therefore, the same effect as that of the first embodiment can be obtained by the configuration of the fourth embodiment described above.

By the way, generally, in the electrochromic display element 27, since the resistance value of the transparent electrode film 20 thereof is relatively high, there is a possibility that a variation phenomenon of the coloring speed, which causes temporary uneven coloring, may occur. In this embodiment, the transparent electrode film 20
Since the auxiliary light reflection film 21 made of a low-resistivity material is provided around the frame in a frame shape, the resistance value of the transparent electrode film 20 can be lowered, and the above phenomenon of variation in coloring speed is suppressed. There are advantages.

In the fourth embodiment, the auxiliary electrode film 21 is the transparent electrode film.
Although it is arranged on the transparent substrate 20, it is auxiliary on the transparent glass substrate 19 or the glass plate 29, respectively, as shown in FIGS. 7 and 8 showing the fifth and sixth embodiments of the present invention. Light reflection film 21 'or
21 ″ may be additionally provided.

Besides, the present invention is not limited to the embodiments described above and shown in the drawings. For example, a liquid crystal panel or an electrochromic display element having another structure may be used as an electro-optical element. Various modifications can be implemented without departing from the above.

[Effects of the Invention] According to the present invention, as is clear from the above description, in the antiglare mirror in which the antiglare function is obtained by the mirror body formed by combining the light reflecting film and the electro-optical element, The effective area can be made sufficiently large, and the practical effect such as the degree of freedom in designing the mirror housing for housing the mirror body can be increased.

[Brief description of drawings]

1 and 2 are for explaining a first embodiment of the present invention. FIG. 1 is a longitudinal sectional view showing a model structure of a main part, and FIG. 2 is an overall front view. is there. 3 and 4 show the first and second embodiments of the present invention, respectively.
FIG. 5, FIG. 5 and FIG. 6 show a fourth embodiment of the present invention, respectively. FIG. 1 and FIG. 2 corresponding diagrams, FIG. 7 and FIG. 8 show the fifth and sixth embodiments of the present invention, respectively. 1 is a view corresponding to FIG. 1 showing the embodiment of FIG. In the figure, 1 is a mirror housing, 2 is a mirror body, 3 and 4 are transparent glass plates, 5 and 6 are transparent conductive films (counter electrodes), 9 and 16 are auxiliary light reflection films, and 10 is a liquid crystal (electro-optical material). , 12 is a liquid crystal panel (electro-optical element), 13 is a sealing material, 14 is a light reflection film, 17
Is a mirror housing, 18 is a mirror body, 19 is a transparent glass plate, 20 is a transparent electrode film (counter electrode), 21, 21 ′ and 21 ″ are auxiliary light reflection films, 22 is an electrochromic reaction part (electro-optical material), Reference numeral 26 is a light reflection film (counter electrode), 27 is an electrochromic display element (electro-optical element), and 28 is a sealing material.

Claims (1)

[Scope of utility model registration request] 1. An electro-optical element formed by sandwiching an electro-optical material whose light transmittance changes according to a voltage application between opposing electrodes and sealing the peripheral portions of the opposing electrode and the electro-optical material with a sealing material. An anti-glare mirror having a mirror body configured by disposing a light-reflecting film behind the electro-optical element, and a mirror housing accommodating the mirror body. An anti-glare mirror, characterized in that an auxiliary light reflection film having a light reflectance close to that of the mirror body in a non-driven state of the electro-optical element is formed at a position corresponding to the stopper.