KR101728849B1 - A Liquid Crystal Mirror Having a Structure of Controlling a Reflectivity - Google Patents

Abstract

The present invention relates to a liquid crystal mirror having a reflectance control structure and, more specifically, relates to a liquid crystal mirror having a reflectance control structure which improves visibility while preventing glare by controlling an amount of light reflected in accordance with an amount of incident light. The liquid crystal mirror having a reflectance control structure comprises: a first mirror (11a) having a first reflectance; a second mirror (11b) arranged to face the first mirror (11a) having a reflectance different from that of the first mirror (11a); and a liquid crystal (13) disposed between the first mirror (11a) and the second mirror (11b) to control a property of incident light incident by applying a voltage. As such, the total reflectance is controlled by applying a voltage to the liquid crystal (13).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a liquid crystal mirror having a reflectance control structure,

The present invention relates to a liquid crystal mirror having a reflectance control structure, and more particularly, to a liquid crystal mirror having a reflectance control structure for improving visibility while preventing glare by controlling the amount of light reflected according to the amount of incident light .

Various shapes of mirrors that form images by reflection of light are being applied in industry or everyday life. A mirror that looks at the shape of an object at various positions using light reflection generally has a constant reflectance and has a reflectance of, for example, 70 to 90%. And various conductive materials may be coated on the entire surface of the mirror to increase the reflectance as required. Higher reflectance of the mirror may have the advantage of clarity, but it may be advantageous for the mirror to maintain an appropriate reflectivity depending on the application. For example, in the case of a rearview mirror of a car, the reflectance of the mirror is high and the mirror may be glazed when the reflectance is high. In the case of a liquid crystal such as a smart phone, when the reflectance is high, an image of an external object may be projected on the liquid crystal, resulting in low visibility.

Patent Publication No. 10-2008-0022846 includes a backlight unit, a lower polarizer disposed above the backlight unit, a liquid crystal positioned above the lower polarizer, and an upper reflective polarizer positioned above the liquid crystal, Type polarizing plate is characterized in that a periodically arranged metal line lattice is formed on a support.

Patent Publication No. 10-2005-0099236 relates to a structure for preventing glare by using a photochromic material inside a housing for forming a vehicle side mirror or a room mirror, and is a glass plate or a transparent synthetic resin plate having a predetermined shape, A polymer coating layer containing a photochromic organic compound and an ultraviolet coating layer formed on a front surface thereof in order to reflect light on a back surface thereof, and an ultraviolet coating layer formed on an upper portion and / or a lower portion of the medium, And an anti-glare mirror by a photochromic polymer matrix coating characterized in that a lamp is selectively installed.

The prior art discloses a method of increasing the brightness in the case of power shutdown or a method of adjusting the reflectance according to the discoloration characteristics due to ultraviolet transmission of a photochromic material. However, such a method is disadvantageous in that the control of the reflectance is limited by the incoming light or the control range is limited. Therefore, it is necessary to develop an anti-glare mirror that detects the amount of incident light and automatically increases a certain level of visibility.

The present invention has been made to solve the problems of the prior art and has the following purpose.

Prior Art 1: Patent Publication No. 10-2008-0022846 (published by LG Chem Co., Ltd., Mar. 12, 2008) Mirror-type liquid crystal display device using reflective polarizer Prior Art 2: Patent Publication No. 10-2005-0099236 (published by Kim, Kyung-Tae, October 13, 2005) Anti-glare mirrors by photochromic polymer matrix coating

SUMMARY OF THE INVENTION It is an object of the present invention to provide a liquid crystal mirror having a reflectance control structure for detecting the amount of incident light and automatically or electronically or electrically controlling the reflectance.

According to a preferred embodiment of the present invention, a liquid crystal mirror having a reflectance control structure includes: a mirror having one reflectance; 1 two mirrors, one mirror and two mirrors with different reflectance, placed facing the mirror; And a liquid crystal arranged between the one mirror and the two mirrors so as to control the characteristics of light incident by the voltage application, and the total reflectance is controlled by applying a voltage to the liquid crystal.

According to another preferred embodiment of the present invention, there is further provided a one or two electrode unit disposed on the rear surface of one mirror and on the front surface of two mirrors, wherein the one or two electrode unit has a voltage magnitude .

According to another preferred embodiment of the present invention, an incident detection unit for detecting the amount of incident light and a reflection detection unit for detecting the amount of reflected light are further included.

The mirror according to the present invention allows the reflectivity to be adjusted to any level by allowing the reflectance to be adjusted electrically or electronically. The mirror according to the present invention can be used as a rear mirror or a side mirror of an automobile or installed on a dead zone or a curved road so that the function of the mirror can be maintained regardless of external conditions. The mirror according to the present invention can be applied to various fields by being automatically operated according to preset conditions.

1 is a block diagram showing an embodiment of a liquid crystal mirror according to the present invention.
2 shows another embodiment of a liquid crystal mirror according to the present invention.
FIG. 3 shows an embodiment of a structure in which reflectance is controlled in a liquid crystal mirror according to the present invention.
4 shows an embodiment of the operation of the liquid crystal mirror according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto. In the following description, components having the same reference numerals in different drawings have similar functions, so that they will not be described repeatedly unless necessary for an understanding of the invention, and the known components will be briefly described or omitted. However, It should not be understood as being excluded from the embodiment of Fig.

1 is a block diagram showing an embodiment of a liquid crystal mirror according to the present invention.

Referring to FIG. 1, a liquid crystal mirror 10 includes a mirror 11a having a single reflectance; One mirror 11a and two mirrors 11b arranged so as to face one mirror 11a and having different reflectance; And a liquid crystal 13 arranged between the first mirror 11a and the second mirror 11b and adapted to adjust the characteristics of light incident upon the liquid crystal 13 by applying a voltage, do.

The liquid crystal mirror according to the present invention is characterized in that the reflectance is automatically controlled according to the amount of incident light. If the amount of incident light is small, all light can be reflected to form an image. In contrast, when the amount of incident light is large, some of the light can be reflected and the remaining light can be prevented from being reflected. This prevents, for example, the glare of automotive mirrors, road-mounted mirrors or everyday mirrors. In addition, the amount of light reflected from the mirror is controlled so that a recognizable image is formed regardless of the amount of incident light. The mirror can be a concave mirror, a convex mirror or a flat mirror, and the reflectance can be set appropriately according to the use of the mirror.

1 and 2 mirrors 11a and 11b can be a mirror capable of forming an image by the reflection of light, and the surface on which the light is incident becomes a mirror surface, and a part of the light is reflected and a mirror surface . The mirror surface can be formed, for example, by a coating, by the nature of the material itself, or by adhesion of a coating film, and can be made into any structure capable of forming various phases depending on the shape of the surface. The mirrors 11a and 11b may have a reflecting surface or a mirror surface formed in the same direction, and the reflecting surface or mirror surface may be arranged in parallel. The mirrors 11a and 11b can be made to have a reflectance of 50 to 90%, respectively, and have different reflectivities. For example, one mirror 11a may have a reflectance of 30 to 50%, and the two mirrors 11b may have a reflectance of 80 to 90%.

The first and second mirrors 11a and 11b disposed separately from each other have different reflectivities so that the total reflectance of the first and second mirrors 11a and 11b is 60 to 85% Can be set. The interval between the mirrors 11a and 11b can be determined by the transmittance or reflectance of the liquid crystal 13, and may be, for example, 0.5 to 3.0 mm.

A liquid crystal 13 may be disposed between the first and second mirrors 11a and 11b. The liquid crystal 13 has a function of changing the internal molecular arrangement according to the application of an electric field and thereby causing light transmittance, optical rotation, selective light scattering or polarization, and can be any form known in the art . The liquid crystal 13 according to the present invention has a function of changing the transmission characteristic or the polarization characteristic by the applied electric field, although the molecular alignment structure of the liquid crystal 13 is changed by external influences such as temperature, electric field or magnetic field or stress Lt; / RTI >

One or two electrode units 12a and 12b may be disposed on the rear surface of the first mirror 11a and on the front surfaces of the two mirrors 11b in order to change the transmittance of the liquid crystal 13 to light, The magnitude of the applied voltage can be adjusted according to the amount of incident light in the units 12a and 12b. The first and second electrode units 12a and 12b may be, for example, transparent electrodes of a thin film, for example, a transparent electrode having a light transmittance of 90% or more. And when the reflectance of the first and second mirrors 11a and 11b is set, it can be determined based on the transparency of the first and second electrode units 12a and 12b. The liquid crystal 13 can be arranged by the voltage applied to the first and second electrode units 12a and 12b so that the light transmitted through the first mirror 11a is incident on the second mirror 11b, .

1, when one incident light LL corresponding to a small amount of light is incident on one mirror 11a, a part of the incident light LL may be reflected by the one mirror 11a. The remaining light of the incident light LL can pass through the one mirror 11a and may or may not be incident on the two mirrors 12b depending on the transmittance of the liquid crystal 13. For example, if the voltage is not applied to the liquid crystal 13 by the first and second electrode units 12a and 12b, the transmitted incident light LL passes through the liquid crystal 13 and is incident on the two mirrors 11b . And is reflected according to the reflectance of the two mirrors 11b to form one reflected light LR together with the reflected light of the one mirror 11a. In contrast, when two incident lights HL corresponding to a large amount of light are incident on the first mirror 11a, a voltage is applied to the first and second electrode units 12a and 12b, and the light transmitted through the first mirror 11a is divided into two It is not incident on the mirror 11b and is scattered. Only the light reflected from the first mirror 11a forms the two reflected light HR. As described above, unreflected light among the first and second incident light LL and HL can be transmitted to the liquid crystal 13. If light is not transmitted through the liquid crystal 13, the light reflected through the entire mirror becomes the reflected light of the one mirror 11a. If one incident light LL is above a level at which a recognizable image is formed, an image may be formed by one reflected light LR, and the reflectance of one mirror may be, for example, 50%. This can prevent glare. On the other hand, if a small amount of incident light LL is low, the light transmitted through the one mirror 11a can be reflected by the two mirrors 11b to form one reflected light LR. For example, if the transmissivity of the electrode units 12a and 12b is 100%, the two mirrors 11b can have a reflectance of 80%. If the transmissivity of the electrode units 12a and 12b is 100% And a clearer image can be made by this. In this way, the amount of the one-reflected light LR can be determined by the liquid crystal 13, and thus the reflectance of the entire mirror can be adjusted.

In such a structure, the liquid crystal 13 may have polarizing properties, and the polarizing film may be attached to one mirror 11a or two mirrors 11b based on the polarization characteristics of the liquid crystal 13.

2 shows another embodiment of a liquid crystal mirror according to the present invention.

2, the liquid crystal 13 may be disposed between the first mirror 11a and the second mirror 11b, and the first and second electrode units 12a and 12b may be disposed on both sides of the liquid crystal 13 so as to face each other. Can be arranged. The first and second electrode units 12a and 12b may be, for example, a transparent electrode layer, and the first electrode unit 12a and the second electrode unit 12b may have the same or different electrode arrangement structure. The one-electrode unit 12a and the two-electrode unit 12b may be, for example, ITO transparent electrodes having a thickness of 10 to 1,000 nm, silver nanowire transparent electrodes or similar electrode layers. In order to form an electric field suitable for the arrangement of liquid crystals in the liquid crystal 13, the one electrode unit 12a may form one plane and the two electrode unit 12b may be arranged as a plurality of separate electrode groups. Since the one-electrode unit 12a and the two-electrode unit 12b have different electrode arrangements, the liquid-crystal 12 is arranged in various directions, and the transmittance of the first and second electrode units 12a and 12b to light Can be improved. The liquid crystal 13 and the one or two electrode units 12a and 12b can be formed integrally with each other. For example, the liquid crystal or the liquid crystal polymer (LCP) (12a, 12b) can be made. By applying a voltage to the first and second electrode units 12a and 12b, various types of electric fields can be formed inside the liquid crystal 13, thereby changing the arrangement of the liquid crystal molecules and changing the transmittance of light according to voltage application have.

The liquid crystal 13 may have a polarization characteristic and the one polarizing film 22a and the two polarizing film 22b having polarization characteristics corresponding thereto according to the polarization characteristic of the liquid crystal 13 may be one mirror 11a or two mirrors (11b). The polarizability of the first and second polarizing films 22a and 22b can be appropriately set in accordance with the characteristics of the liquid crystal 13. The first and second polarizing films 22a and 22b may be formed integrally with the first and second electrode units 12a and 12b. Specifically, the first and second electrode units 12a and 12b may be printed on the first and second polarizing films 22a and 22b, respectively, in a strip shape or in a separated polygonal shape. By making the strip-shaped or polygonal shape as described above, the light transmittance to the electrode units 12a and 12b is increased, thereby facilitating the printing of the electrodes. For example, the first and second electrode units 12a and 12b can be printed on the polarizing films 22a and 22b in the form of a continuous string. In such a structure, the first and second electrode units 12a and 12b It does not need to be a transparent electrode. The first and second polarizing films 22a and 22b and the one or two electrode units 12a and 12b may be integrally formed in various manners, and the present invention is not limited to the illustrated embodiments.

When the first and second polarizing films 22a and 22b and the first and second electrode units 12a and 12b are integrally formed, the first and second polarizing films 22a and 22b are combined with the first and second reflecting films 21a and 21b to form first and second mirrors 11a and 11b ) Can be formed. The first and second reflective films 21a and 21b may have a reflectance as described above. Thereafter, the liquid crystal 13 is disposed between the first and second mirrors 11a and 11b so that the liquid crystal mirror according to the present invention can be made.

The liquid crystal mirror according to the present invention can be made in various ways, and the present invention is not limited to the embodiments shown.

FIG. 3 shows an embodiment of a structure in which reflectance is controlled in a liquid crystal mirror according to the present invention.

Referring to FIG. 3, the reflectance of the liquid crystal mirror is controlled by a control unit 31 which determines a voltage to be applied to the electrode unit in accordance with an environmental condition; And a voltage regulating unit 34 which regulates the type or size of the electric field applied under the control of the control unit 31. [

The control unit 31 can determine the voltage level to be applied to the electrode unit based on the information sent from the incident detection unit 331 that detects the level of incident light or the reflection detection unit 332 that detects the level of the reflected light . As described above, the electrode unit may be composed of a pair of electrode layers facing each other, and the pair of electrode layers may have the same or different electrode arrangement structure. The transmittance of the incident light can be determined according to the electric field structure inside the liquid crystal unit formed by the electrode unit. The amount of incident light incident on the reflection mirror 10 can be detected by the incident detection unit 331 and transmitted to the control unit 31 and the reflection control unit 32. [ The reflection control unit 32 may have data according to the amount of light to be reflected depending on the amount of incident light. The reflection control unit 32 can also receive information on the environment from the environment detection unit 333. [ Information about the ambient environment may include information about the current environment in which the liquid crystal mirror 10, such as temperature, humidity, or illumination, is used. The reflection control unit 32 can determine the transmittance of the liquid crystal in accordance with the information transmitted from the incident detection unit 331 and the environment detection unit 333 and thereby determine the voltage to be applied to the electrode unit. Specifically, the reflection control unit 32 determines a reflectivity that is recognizable based on the information transmitted from the incident detection unit 331 and the environment detection unit 333, but can eliminate glare or other visible property reduction And the voltage of the electrode unit can be determined accordingly. The voltage of the electrode unit can be predetermined in accordance with the electrode array structure. The voltage determined by the reflection control unit 32 can be transmitted to the voltage adjustment unit 34 and the voltage adjustment unit 34 adjusts the voltage of the electrode unit disposed in the liquid crystal mirror 10, The reflectance can be adjusted. The reflectivity detected at the reflective mirror 10 can be detected by the reflection detection unit 332 and transmitted to the control unit 31 and the control unit 31 can detect the information transmitted from the reflection detection unit 332 by incident detection Unit 331 to check the operating state of the reflective mirror 10. [ And the reflection data of the reflection control unit 32 can be adjusted as necessary. Through this process, an optimal image without glare can be obtained from the liquid crystal mirror 10.

4 shows an embodiment of the operation of the liquid crystal mirror according to the present invention.

Referring to FIG. 4, a first polarizing film 22a may be disposed on one reflective film 21a and a second polarizing film 22b may be disposed on the second reflective film 21b. The one reflective film 21a and the two reflective film 21b may have different reflectivities and may be fixed to an appropriate transparent substrate as required. The incident detection unit 331 or the reflection detection unit 332 may be disposed on the one reflection film 21a. However, the incident detection unit 331 or the reflection detection unit 332 may be disposed at various positions. The first and second electrode units 12a and 12b may be connected to a voltage regulating unit 34 including a power source such as a battery. The balancing circuit 44 may be disposed as needed. The voltage applied to the first and second electrode units 12a and 12b by the voltage adjusting unit 34 can be adjusted. And the control unit 31 may be connected to a reflection control unit 32 which stores data related to the reflection condition.

When a large amount of light is incident, it can be detected by an incident detection unit 331 such as a photosensor and transmitted to the control unit 31 and the reflection control unit 32, for example. The control unit 31 can adjust the voltage regulating unit 34 so that a proper voltage is applied to the electrode units 12a and 12b. The voltage of the electrode unit 12a or 12b causes the light transmitted through the reflective film 21a to fail to reach the reflective film 21b, And can be, for example, 40 to 70%. The balance circuit 44 allows the voltage applied by the power source 43 to be maintained at a constant level in this process.

It can be detected by the incident detection unit 331 and transmitted to the reflection control unit 32 when the level of the incident light changes. The control unit 31 may adjust the voltage regulating unit 34 according to the voltage condition determined by the reflection control unit 32 to determine the voltage to be applied to the one or two electrode units 12a and 12b. The direction of the light reaching the two reflective film 21b can be measured by the optical direction sensor 46 and the determination of the applied voltage can be determined based on the data stored in the reflection control unit 32. [ If the amount of incident light is at a low level, the voltage applied to the first and second electrode units 12a and 12b is removed, so that at least a part of the light reaching the two reflection film 21b can be reflected. And the amount of the totally reflected light can be detected by the reflection detection unit 332 and transmitted to the control unit 31. [ The first and second polarizing films 22a and 22b may be disposed as described above and may be integrally formed with the first and second reflective films 21a and 21b and the first and second electrode units 12a and 12b, A single structure can be formed in a closed form by the openings 481 and 482. The sealing frames 481 and 482 may have a structure such as an automobile side mirror, a rear monitoring mirror, a blind spot monitoring mirror, or a general mirror depending on the application to be used.

The liquid crystal mirror according to the present invention may have various reflective structures and frame structures, and the present invention is not limited to the embodiments shown.

The mirror according to the present invention allows the reflectivity to be adjusted to any level by allowing the reflectance to be adjusted electrically or electronically. The mirror according to the present invention can be used as a rear mirror or a side mirror of an automobile or installed on a dead zone or a curved road so that the function of the mirror can be maintained regardless of external conditions. The mirror according to the present invention can be applied to various fields by being automatically operated according to preset conditions.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention . The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

10: Liquid crystal mirror 11a: 1 mirror
11b: 2 mirror 12a: one electrode unit
12b: two-electrode unit 13: liquid crystal
21a: 1 reflection film 21b: 2 reflection film
22a: 1 polarizing film 22b: 2 polarizing film
31: control unit 32: reflection control unit
34: Voltage regulation unit 43: Power supply
44: Balancing circuit 46: Optical direction sensor
331: incident detection unit 332: reflection detection unit
333: Environmental detection unit 481, 482: 1, 2 sealing frame
HL: 2 incident light HR: 2 reflected light
LL: 1 incident light LR: 1 reflected light
LR: Reflected light

Claims (3)

One mirror 11a having one reflectance;
One mirror 11a and two mirrors 11b arranged so as to face one mirror 11a and having different reflectance; And
And a liquid crystal 13 disposed between the first mirror 11a and the second mirror 11b so as to control the characteristics of light incident upon application of a voltage,
The total reflectance is adjusted by applying a voltage to the liquid crystal 13,
An incident detection unit 331 for detecting the amount of incident light and a reflection detection unit 332 for detecting the amount of reflected light and is further provided with information about the incident light detected from the incident detection unit 331 and information 332) of the liquid crystal (13) is adjusted based on the information about the reflected light detected by the liquid crystal (332). The plasma display device according to claim 1, further comprising one or two electrode units (12a, 12b) arranged on the rear surface of the first mirror (11a) and on the front surface of the two mirrors (11b) And the magnitude of the applied voltage is adjusted according to the amount of light. delete

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