WO2014084065A1 - Viewing angle control device - Google Patents

Abstract

The purpose of the present invention is to provide a viewing angle control device capable of arbitrarily changing the magnitude of a viewing angle. A viewing angle control device (10) according to the present invention is provided with a viewing angle control sheet (12) comprising: a transparent insulating layer (20); a plurality of conductor patterns (22a) formed on one principal surface of the transparent insulating layer (20); a transparent electrode layer (26) arranged opposite the one principal surface of the transparent insulating layer (20) at a distance; and an electrochromic layer (24) interposed between the transparent insulating layer (20) and the transparent electrode layer (26). A louver (30) is formed in the electrochromic layer (24) by depositing the electrochromic material starting from the conductor patterns (22a) in the direction orthogonal to the one principal surface of the transparent insulating layer (20) in accordance with the voltage applied between the conductor patterns (22a) and the transparent electrode layer (26), and the period for which the voltage is applied. The viewing angle control device (10) controls the height of the louver (30) by controlling the amount of electrochromic material deposited, and thereby controls the magnitude of the viewing angle.

Description

Viewing angle control device

The present invention relates to a viewing angle control device for controlling a viewing angle.

In Patent Document 1, as shown in FIG. 8A, a plurality of chromic layers 1 arranged in parallel in a predetermined direction with respect to the filter main surface and a chromic layer 1 adjacent to each other are arranged respectively. Further, a viewing angle control filter 3 including a plurality of transparent layers 2 is disclosed. The chromic layer 1 has a light absorption spectrum characteristic corresponding to an applied voltage, and light physical properties such as color and / or brightness change when a voltage is applied / not applied.
Further, in Patent Document 1, a plurality of grooves 4 arranged in parallel in a predetermined direction are formed in the transparent layer 2 ′ as shown in FIG. 8B, and an electrochromic substance is disposed in each groove 4. A viewing angle control filter 3 ′ in which the chromic layer 1 is formed is disclosed.
The viewing angle control filters 3 and 3 ′ described in Patent Document 1 can reversibly control the viewing angle by controlling the voltage applied to the chromic layer 1.

JP 2011-013451 A

However, according to the viewing angle control filter 3 as shown in FIG. 8A, the viewing angle angle depends on the structure of the spacing and height of the chromic layer 1 perpendicular to the filter main surface. Therefore, the viewing angle can only be controlled on and off, and the size of the viewing angle cannot be changed arbitrarily. In addition, in the viewing angle control filter 3 ′ described in FIG. 8B of Patent Document 1, an electrode is formed on the entire surface of the groove 4 formed of the transparent layer 2 ′, and a chromic layer is formed on the entire inner surface of the groove 4. In this case, since the entire inner surface becomes opaque, the size of the viewing angle cannot be arbitrarily changed, and the viewing angle can be controlled only by ON / OFF.

Moreover, in the manufacturing method of the viewing angle control filter described in patent document 1, after laminating | stacking the base material of a transparent electrode and a chromic layer in the thickness direction, and slicing this, the louver of a chromic layer is formed. ing. Since the chromic material is deposited in a direction in which the louver interval is narrowed (that is, a direction perpendicular to the chromic layer 1 in FIG. 8A) when the current is supplied to the chromic material, the viewing angle is reduced. However, a wider viewing angle than that of the original chromic layer 1 cannot be obtained in principle, and as the amount of deposition increases, the light cannot pass through and becomes darker. Therefore, it can be said that the substantial viewing angle control can be performed only on / off.

Therefore, a main object of the present invention is to provide a viewing angle control device capable of controlling the size of the viewing angle so that it can be arbitrarily changed.

A viewing angle control device according to the present invention is arranged to face a transparent insulating layer, a plurality of conductor patterns formed on one main surface of the transparent insulating layer, and spaced from the one main surface of the transparent insulating layer. A viewing angle control device comprising a viewing angle control sheet including a transparent electrode layer that is formed, and an electrochromic layer interposed between the transparent insulating layer and the transparent electrode layer, and applied to the conductor pattern and the transparent electrode layer A louver is formed by depositing a predetermined amount of electrochromic material from a conductor pattern in a direction orthogonal to one main surface of the transparent insulating layer in the electrochromic layer, depending on the voltage and the voltage application time. The viewing angle control device.
The viewing angle control device according to the present invention is preferably configured by stacking a plurality of viewing angle control sheets.
Furthermore, in the viewing angle control device according to the present invention, a conductor pattern is formed in a strip shape on one main surface of the transparent insulating layer in the plurality of viewing angle control sheets, and the conductor pattern in each viewing angle control sheet is a specific oblique in a cross-sectional view. It is preferable that the conductor pattern of each viewing angle control sheet is arranged along the direction and is controlled by applying a voltage independently for each viewing angle control sheet.
The viewing angle control device according to the present invention includes a plurality of conductor patterns formed in a dot shape, the conductor patterns formed in a dot shape are arranged in a matrix, and a voltage is independently applied to each conductor pattern. It is preferable to control.

According to the viewing angle control device according to the present invention, the plurality of conductor patterns formed on the one main surface of the transparent insulating layer and the transparent disposed to be opposed to the one main surface of the transparent insulating layer at an interval. Including a viewing angle control sheet in which an electrochromic layer is interposed between the electrode layer, the transparent insulating layer, and the transparent electrode layer, and a conductor applied depending on a voltage applied between the conductor pattern and the transparent electrode layer and a time for applying the voltage. The amount of electrochromic material deposited on the pattern can be controlled, and the height of the louver can be variably controlled, so that a viewing angle control device capable of controlling the size of the viewing angle can be obtained. it can.
In addition, when the viewing angle control device according to the present invention has a configuration in which a plurality of viewing angle control sheets are stacked, the amount of electrochromic material deposited in each viewing angle control sheet can be reduced, and as a result, the deposition is performed. Since the time can be shortened, the responsiveness of the control of the viewing angle can be improved.
Furthermore, in the viewing angle control device according to the present invention, a conductor pattern is formed in a strip shape on one main surface of the transparent insulating layer in the plurality of viewing angle control sheets, and the conductor pattern in each viewing angle control sheet is a specific oblique in a cross-sectional view. When the conductor pattern of each viewing angle control sheet is controlled so that a voltage can be applied independently for each viewing angle control sheet, the viewing angle is set on one main surface of the transparent insulating layer. The viewing angle direction can be set not only in a direction perpendicular to the direction but also in a direction other than that direction.
In the viewing angle control device according to the present invention, a plurality of conductor patterns are formed in a dot shape, the conductor patterns formed in a dot shape are arranged in a matrix shape, and a voltage can be applied independently for each conductor pattern. In this way, by forming the louvers with the conductor patterns arranged in the vertical direction among the dot-shaped conductor patterns arranged in a matrix, it becomes possible to control the viewing angle in the horizontal direction and the horizontal direction. By forming the louver with the conductor pattern 22a arranged in the vertical direction, the vertical viewing angle can be controlled.

According to the present invention, a viewing angle control device capable of controlling the size of the viewing angle so that it can be arbitrarily changed is obtained.

The above-mentioned object, other objects, features, and advantages of the present invention will become more apparent from the following description of the embodiments for carrying out the invention with reference to the drawings.

It is a perspective view solution figure in an example about a 1st embodiment of a viewing angle control device concerning this invention. (A) is, T ₁ hour view angle controlling sheet of the viewing angle control apparatus according to FIG. 1, a cross-sectional schematic view of a viewing angle control apparatus at the time when a voltage is applied, (b) is described in Figure 1 ₂ hours T to the view angle controlling sheet of the viewing angle control apparatus is a cross-sectional schematic view of the viewing angle control device in a when a voltage is applied. It is a perspective view solution figure in the other example about 1st Embodiment of the viewing angle control apparatus concerning this invention. It is a perspective view solution figure in an example about 2nd Embodiment of the viewing angle control apparatus concerning this invention. (A) is a cross-sectional solution figure at the time of applying a voltage only to the 1st viewing angle control sheet | seat in the viewing angle control apparatus of FIG. 4, (b) is a viewing angle control apparatus of FIG. FIG. 3 is a cross-sectional view when a voltage is applied to the first viewing angle control sheet and the second viewing angle control sheet in FIG. It is a perspective view solution figure in an example about 3rd Embodiment of the viewing angle control apparatus concerning this invention. It is a cross-sectional solution figure of the viewing angle control apparatus of FIG. (A) is sectional drawing of an example of the conventional viewing angle control apparatus, (b) is sectional drawing of the other example of the conventional viewing angle control apparatus.

An example of the first embodiment of the viewing angle control device according to the present invention will be described. FIG. 1 is a perspective view illustrating an example of a first embodiment of a viewing angle control device according to the present invention.

The viewing angle control device 10 includes a viewing angle control sheet 12. The viewing angle control device 10 includes a DC power supply 14 for applying a voltage to the viewing angle control sheet 12.

The viewing angle control sheet 12 includes a sheet-like transparent insulating layer 20. A plurality of conductor patterns 22 a are formed on the one main surface 20 a of the transparent insulating layer 20. Each conductor pattern 22a is formed in a strip shape. And one end in each conductor pattern 22a is connected by the connection conductor pattern 22b, and is extended and formed in the edge side in the transparent insulating layer 20. For example, glass is used for the transparent insulating layer 20. The conductor pattern 22a and the connecting conductor pattern 22b are made of transparent electrodes such as ITO (indium tin oxide). The width of the conductor pattern 22a and the pitch width of each conductor pattern 22a are arbitrarily determined depending on the intended use.

The electrochromic layer 24 is formed in a region where the connection conductor pattern 22b is not formed on the one main surface 20a of the transparent insulating layer 20. The electrochromic layer 24 is formed of an electrolyte made of an electrochromic material. That is, the electrochromic layer 24 is an electrolytic deposition type. Electrochromic materials have light absorption spectral properties or light reflecting properties. Note that the thickness of the electrochromic layer 24 is arbitrarily determined depending on the application to be used.

The electrolyte made of this electrochromic material is manufactured as follows. That is, as the material of the electrochromic layer 24, AgNO ₃ (silver nitrate) is prepared in a concentration of 50 mM, TBABr (tetrabutylammonium bromide) is prepared in a concentration of 250 mM, and CuCl ₂ (copper (II) chloride) is prepared as a mediator in a concentration of 10 mM. An electrochromic solution is prepared by dissolving them in DMSO (dimethyl sulfoxide). Then, a gel electrolyte is prepared by adding polyvinyl butyral (10 wt%) as a gelling agent to the electrochromic solution, and the adjusted gel electrolyte is disposed on one main surface 20a of the transparent insulating layer 20, and the electrochromic layer 24 Is formed.

In the electrochromic layer 24, a transparent electrode layer 26 is formed so as to cover the side opposite to the surface in contact with the transparent insulating layer 20. That is, the electrochromic layer 24 is interposed between the transparent insulating layer 20 and the transparent electrode layer 26. As the transparent electrode layer 26, a transparent electrode such as ITO (indium tin oxide) is used.

In addition, a protective layer 28 is provided so as to cover the side of the transparent electrode layer 26 opposite to the surface in contact with the electrochromic layer 24. For the protective layer 28, for example, a transparent insulating material such as glass is used.

The DC power supply 14 is provided for applying a voltage between the conductor pattern 22a and the transparent electrode layer 26. The DC power supply 14 can change the voltage.

In the viewing angle control device 10 according to the first embodiment, in the viewing angle control sheet 12, a predetermined voltage is applied between the conductor pattern 22 a and the transparent electrode layer 26 by the DC power supply 14. In the chromic layer 24, a louver 30 made of a deposit of electrochromic material is formed from each conductor pattern 22a in a direction orthogonal to the one main surface 20a of the transparent insulating layer 20, and as a result, the viewing angle is arbitrarily controlled. can do. The state control based on the light absorption spectral characteristic or the light reflecting characteristic of the electrochromic material and the height control of the louver 30 made of the deposit of the electrochromic material are applied between the conductor pattern 22a and the transparent electrode layer 26. The control is performed by controlling the magnitude of voltage or current and energization time, that is, controlling the energization amount. Note that the height of the louver 30 can be increased by increasing the energization amount. Further, the thickness of the viewing angle control sheet 12 is arbitrarily determined depending on the application to be used.

FIG. 2A is a cross-sectional view of the viewing angle control device when a voltage is applied to the viewing angle control sheet of the viewing angle control device described in FIG. 1 for T ₁ time, and FIG. FIG. ₂ is a cross-sectional view of the viewing angle control device when a voltage is applied to the viewing angle control sheet of the viewing angle control device illustrated in FIG. 1 for T ₂ hours. Here, T ₁ <T ₂ . The height of the louver 30 formed in the viewing angle control device 10 shown in FIG. 2A is short because the time for applying a voltage between the conductor pattern 22a and the transparent electrode layer 26 is short. Is lower than the height of the louver 30 formed in the viewing angle control device 10 described in the above. As a result, the viewing angle θ ₂ in FIG. 2B is narrower than the viewing angle θ _{1 in} FIG. Thus, by controlling the height of the louver 30, the field of view is limited by the louver 30 and the size of the viewing angle can be controlled.

In the viewing angle control apparatus 10 according to the first embodiment, the direction of the center line C ₁ of each viewing angle θ ₁ and θ ₂ is substantially orthogonal to the one main surface 20 a of the transparent insulating layer 20. It is. That is, in the viewing angle control device 10 according to the first embodiment, the conductor pattern 22a formed in the vertical direction and in the direction of the viewing angle substantially orthogonal to the one main surface 20a of the transparent insulating layer 20. The viewing angle in the orthogonal direction can be controlled.

Further, by changing the magnitude of the voltage applied between the conductor pattern 22a and the transparent electrode layer 26, a state based on the light absorption spectrum characteristic or light reflection characteristic of the electrochromic material deposited on the conductor pattern 22a is obtained. Can be changed. Here, the state based on the light absorption spectrum characteristic or the light reflecting characteristic is a transmission state, a specular state, or a black state.

On the other hand, the disappearance of the formed louver 30 is caused by applying a reverse voltage of the voltage applied to form the louver 30 or stopping the application of voltage between the conductor pattern 22a and the transparent electrode layer 26. It can be carried out. It is effective to apply a reverse voltage of the voltage applied to form the louver 30 in order to shorten the time for eliminating the formed louver 30.

According to the viewing angle control device 10 according to the first embodiment, for example, when the viewing angle control device 10 is attached to a screen of a personal computer (hereinafter referred to as a personal computer) or a portable terminal as an object. In addition, when the distance between the screen of the object and the object (the user of the personal computer and the third person) whose viewing angle is controlled is close to the object, depending on the amount of electrochromic material deposited Since the viewing angle is limited, it is possible to arbitrarily change the viewing angle over a wide range that has not been conventionally possible, and it is possible to provide an effective peeping prevention filter.
In addition, when the distance between the object (for example, the room) and the object person (third person) is long, the viewing angle control device 10 is disposed in an opening such as a window glass, so that privacy can be obtained while lighting in the room. It can be used as a blind that can be protected.

In addition, according to the viewing angle control device 10 according to the first embodiment, even if the viewing angle is changed by changing the height of the louver 30, the louver 30 is provided with each conductor pattern 22a. Since the width of the louver 30 does not change because the electrochromic material is deposited thereon, the viewing angle control device 10 has the advantage that the lightness of the light transmitted through the viewing angle control device 10 does not change. Have.

Moreover, since the transparent electrode normally used for the conductor pattern 22a has a high sheet resistance, it is necessary to form the transparent electrode thinly, and thus it is difficult to supply power necessary for depositing the electrochromic material. have. However, according to the viewing angle control device 10 according to the first embodiment, the conductor pattern 22a can be formed on the same plane in the transparent insulating layer 20, and is used as a terminal for applying a voltage to the conductor pattern 22a. Can be formed with an arbitrary width, it is possible to stably supply power to the conductor pattern 22a, and to realize a low voltage and high speed operation.

Next, another example of the first embodiment of the viewing angle control device according to the present invention will be described. FIG. 3 is a perspective view illustrating another example of the viewing angle control apparatus according to the first embodiment of the present invention.

3 has the same configuration as that of the viewing angle control device 10 except that the connection conductor pattern 22b is not provided.

In the viewing angle control device 10 ′ according to the first embodiment, the conductor pattern 22a is formed in a strip shape, but the present invention is not limited to this, and the plurality of conductor patterns 22a are formed in a dot shape. May be. The plurality of conductor patterns 22a formed in a dot shape are arranged in a matrix on the transparent insulating layer 20, for example.

The viewing angle control apparatus 10 ′ according to the first embodiment has the same effects as the viewing angle control apparatus 10 described above, and also has the following effects.
That is, according to the viewing angle control device 10 ′ according to the first embodiment, a voltage can be applied independently to each conductor pattern 22a. For example, the conductor pattern only on the half surface on one end side. By applying a voltage only to 22a, the louver 30 can be formed only on the half surface, and the louver 30 can be formed. Therefore, by applying a voltage only to the conductor pattern 22a that requires control of the viewing angle, a region that requires control of the viewing angle can be arbitrarily set.

In addition, according to the viewing angle control device 10 ′ according to the first embodiment, for example, by designating a region where viewing angle control is desired on the screen by a screen position recognition function used in a touch panel or the like, By controlling the voltage to be applied only to the conductor pattern 22a in the specified area, the louver 30 can be formed only in the specified area and the viewing angle can be controlled. Therefore, only the specified arbitrary area is specified. It is possible to prevent peeping and limit privacy.

Furthermore, according to the viewing angle control device 10 ′ according to the first embodiment, the conductor pattern 22a formed on the transparent insulating layer 20 is formed in a dot shape, and the conductor pattern 22a formed in the dot shape is a matrix. If the respective conductor patterns 22a are arranged so that a voltage can be applied independently, among the dot-like conductor patterns 22a arranged in a matrix, the louver is formed by the conductor patterns 22a arranged in the vertical direction. As a result, the horizontal viewing angle can be controlled, and the vertical viewing angle can be controlled by forming the louvers with the conductor patterns 22a arranged in the horizontal direction. That is, the viewing angle control device 10 'can limit the field of view in an arbitrary direction.

Next, an example of the second embodiment of the viewing angle control device according to the present invention will be described. FIG. 4 is a perspective view illustrating an example of the second embodiment of the viewing angle control apparatus according to the present invention.

The viewing angle control device 110 is configured by stacking two viewing angle control sheets, and includes a first viewing angle control sheet 112a and a second viewing angle control sheet 112b. Specifically, the second viewing angle control sheet 112b is provided so as to cover the transparent conductive layer 26 constituting the first viewing angle control sheet 112a. The viewing angle control device 110 then includes a first DC power supply 14a for applying a voltage to the first viewing angle control sheet 112a and a second for applying a voltage to the second viewing angle control sheet 112b. DC power supply 14b.

Here, the first viewing angle control sheet 112a and the second viewing angle control sheet 112b have the same configuration and the same configuration as the viewing angle control sheet 12 described in the first embodiment. Description is omitted.

In the viewing angle control device 110 according to the second embodiment, when a predetermined voltage is applied between the conductor pattern 22a and the transparent electrode layer 26 by the DC power supply 14a in the first viewing angle control sheet 112a. The electrochromic material is deposited according to the application time of the voltage, and as a result, the first louver 130a is formed on the conductor pattern 22a of the first viewing angle control sheet 112a. Similarly, in the viewing angle control device 110 according to the second embodiment, when a predetermined voltage is applied to the second viewing angle control sheet 112b, the electrochromic is applied according to the application time of the voltage. As a result, the second louver 130b is formed on the conductor pattern 22a of the second viewing angle control sheet 112b. As described above, in the viewing angle control device 110 according to the second embodiment, the first viewing angle control sheet 112a and the second viewing angle control sheet 112b each independently include the first louver 130a and the second viewing angle control sheet 112b. The control for forming the louver 130b is performed.

FIG. 5A is a cross-sectional view when a voltage is applied only to the first viewing angle control sheet 112a in the viewing angle control device 110 shown in FIG. 4, and FIG. It is a cross-sectional illustration figure at the time of applying a voltage to the 1st viewing angle control sheet | seat 112a and the 2nd viewing angle control sheet | seat 112b in the viewing angle control apparatus 110 of description. In FIGS. 5 (a) and 5 (b), the voltage application time indicates the state after the lapse of the same time.

In FIG. 5A, since the voltage is applied only to the first viewing angle control sheet 112a, only the first louver 130a is formed. On the other hand, in FIG. 5B, since the voltage is applied to the first viewing angle control sheet 112a and the second viewing angle control sheet 112b, the first louver 130a and the second louver 130b are formed. Yes. Therefore, the height of the first louver 130a formed in the viewing angle control device 110 shown in FIG. 5A is the same as the first louver formed in the viewing angle control device 110 shown in FIG. The height is lower than the total height of both 130a and the second louver 130b. Accordingly, the viewing angle control device 110 shown in FIG. 5B has the field of view limited by the first louver 130a and the second louver 130b, so that the viewing angle θ _{3 in} FIG. The viewing angle θ ₄ in (b) is narrower.

Further, in the viewing angle control device 110 according to the second embodiment, the direction of the center line C ₂ of each viewing angle θ ₃ and θ ₄ is substantially orthogonal to the one main surface 20a of each transparent insulating layer 20. Direction. That is, in the viewing angle control device 110 according to the second embodiment, each conductor formed in the direction of the viewing angle substantially perpendicular to the one main surface 20a of each transparent insulating layer 20 and in the vertical direction. The size of the viewing angle in the direction orthogonal to the pattern 22a can be controlled.

Further, a voltage applied between the conductor pattern 22a and the transparent electrode layer 26 in the first viewing angle control sheet 112a, or between the conductor pattern 22a and the transparent electrode layer 26 in the second viewing angle control sheet 112b. By changing the magnitude of the applied voltage, the light absorption spectrum characteristic or light reflection of the electrochromic material deposited on each conductor pattern 22a of the first viewing angle control sheet 112a and the second viewing angle control sheet 112b. The state based on the characteristics to be changed can be changed. The state based on the light absorption spectrum characteristic or the light reflecting characteristic is a transmission state, a specular state, or a black state.

On the other hand, the disappearance of the formed first louver 130a and second louver 130b occurs between the conductor pattern 22a and the transparent electrode layer 26 in the first viewing angle control sheet 112a or the second viewing angle control sheet 112b. The reverse voltage of the voltage applied to form the first louver 130a and the second louver 130b can be applied, or the voltage application can be stopped. In order to shorten the time for eliminating the formed first louver 130a and second louver 130b, the reverse voltages of the respective voltages applied to form the first louver 130a and the second louver 130b are used. It is effective to apply.

The viewing angle control device 110 according to the second embodiment has the same effects as the viewing angle control device 10 described above, and also has the following effects.
That is, in the viewing angle control device 110 according to the second embodiment, an attempt is made to obtain the same viewing angle as when the viewing angle control device 10 according to the first embodiment, that is, the viewing angle control sheet has a single layer configuration. In this case, the amount of electrochromic material deposited on each of the first viewing angle control sheet 112a and the second viewing angle control sheet 112b, that is, the energization amount can be reduced. Thereby, the responsiveness of the viewing angle control sheet can be improved. Further, by reducing the thickness of the first viewing angle control sheet 112a positioned below the second viewing angle control sheet 112b, the amount of deposited electrochromic material can be further reduced.

Next, an example of the third embodiment of the viewing angle control device according to the present invention will be described. FIG. 6 is a perspective view illustrating an example of the third embodiment of the viewing angle control device according to the present invention.

The viewing angle control device 210 is configured by stacking three viewing angle control sheets, and includes a first viewing angle control sheet 212a, a second viewing angle control sheet 212b, and a third viewing angle control sheet. 212c. Then, the viewing angle control device 210 has a first DC power supply 14a for applying a voltage to the first viewing angle control sheet 212a and a second for applying a voltage to the second viewing angle control sheet 212b. DC power supply 14b and a third DC power supply 14c for applying a voltage to the third viewing angle control sheet 212c.

Here, the first viewing angle control sheet 212a, the second viewing angle control sheet 212b, and the third viewing angle control sheet 212c have the same configuration, and the viewing angle control sheet 12 of the first embodiment. Since the configuration is the same as that in FIG.

In the viewing angle control device 110 according to the second embodiment, when the second viewing angle control sheet 112b is superimposed on the first viewing angle control sheet 112a, the second viewing angle control sheet 112b The conductor pattern 22a to be formed is arranged immediately above the conductor pattern 22a with respect to the conductor pattern 22a formed on the first viewing angle control sheet 112a, but the viewing angle control according to the third embodiment is performed. Unlike the viewing angle control device 110 according to the second embodiment as described above, the device 210 is configured such that when the second viewing angle control sheet 212b is overlaid on the first viewing angle control sheet 212a, the second The strip-shaped conductor pattern 22a formed in the viewing angle control sheet 212b is the strip-shaped conductor pattern 22a formed in the first viewing angle control sheet 212a. In contrast, it is arranged such shifted by a predetermined magnitude along the width direction of the conductor pattern 22a. Similarly, the strip-shaped conductor pattern 22a formed in the third viewing angle control sheet 212c is wider than the strip-shaped conductor pattern 22a formed in the second viewing angle control sheet 212b in the width direction of the conductor pattern 22a. Are arranged so as to deviate by a predetermined size along. Therefore, as shown in FIG. 7, from the conductor pattern 22a in the first viewing angle control sheet 212a toward the conductor pattern 22a in the second viewing angle control sheet 212b, with respect to the one main surface 20a of the transparent insulating layer 20 In the cross-sectional view, it is inclined along a specific direction. Similarly, a specific direction in a cross-sectional view with respect to the one main surface 20a of the transparent insulating layer 20 from the conductor pattern 22a in the second viewing angle control sheet 212b toward the conductor pattern 22a in the third viewing angle control sheet 212c. It is arranged incline along. As will be described later, the one main surface 20a of the transparent insulating layer 20 depends on the displacement in the width direction of each conductor pattern 22a in the second viewing angle control sheet 212b and the third viewing angle control sheet 212c. the inclination of the center line C ₃ of the viewing angle with respect to the orthogonal direction of the line is determined for.

In the viewing angle control device 210 according to the third embodiment, when a predetermined voltage is applied between the conductor pattern 22a and the transparent electrode layer 26 by the DC power supply 14a in the first viewing angle control sheet 212a. The electrochromic material is deposited according to the application time of the voltage, and as a result, the first louver 230a is formed on the conductor pattern 22a of the first viewing angle control sheet 212a. Similarly, in the viewing angle control device 210 according to the third embodiment, when a predetermined voltage is applied to the second viewing angle control sheet 212b, the electrochromic is applied according to the application time of the voltage. The material is deposited, and as a result, the second louver 230b is formed on the conductor pattern 22a of the second viewing angle control sheet 212b. Furthermore, in the viewing angle control device 210 according to the third embodiment, when a predetermined voltage is applied to the third viewing angle control sheet 212c, the electrochromic material is deposited according to the time during which the voltage is applied. As a result, the third louver 230c is formed on the conductor pattern 22a of the third viewing angle control sheet 212b. As described above, in the viewing angle control device 210 according to the third embodiment, the first viewing angle control sheet 212a, the second viewing angle control sheet 212b, and the third viewing angle control sheet 212c are independently provided. Control for forming the first louver 230a, the second louver 230b, and the third louver 230c is performed.

FIG. 7 is an illustrative sectional view of the viewing angle control device shown in FIG. In FIG. 7, since voltage is applied to each of the first viewing angle control sheet 212a, the second viewing angle control sheet 212b, and the third viewing angle control sheet 212c, the first louver 230a, the second A louver 230b and a third louver 230c are formed. Thus, the viewing angle θ ₅ is determined by the viewing angle being limited by the first louver 230a, the second louver 230b, and the third louver 230c. When a predetermined voltage is not applied to the third viewing angle control sheet 212c, the viewing angle is larger than the viewing angle θ ₅ because the third louver 230c is not formed. Further, when a predetermined voltage is not applied to any of the second viewing angle control sheet 212b and the third viewing angle control sheet 212c, the viewing angle direction is the one main surface 20a of the transparent insulating layer 20. On the other hand, the direction is substantially orthogonal.

In addition, since the conductor patterns 22a in the second viewing angle control sheet 212b and the third viewing angle control sheet 212c are formed so as to be shifted in the width direction, the center line C of the viewing angle that defines the direction of the viewing angle. ₃ is inclined by φ with respect to a line orthogonal to the one main surface 20 a of the transparent insulating layer 20. That is, in the viewing angle control device 210 according to the third embodiment, it can be tilted by a predetermined angle with respect to a line perpendicular to the one main surface 20a of each transparent insulating layer 20, And the magnitude | size of the viewing angle with respect to the direction of the viewing angle can be controlled.

Also, a voltage applied between the conductor pattern 22a and the transparent electrode layer 26 in the first viewing angle control sheet 212a, and a voltage applied between the conductor pattern 22a and the transparent electrode layer 26 in the second viewing angle control sheet 212b. The first viewing angle control sheet 212a and the second viewing angle control sheet 212c are changed by changing the magnitude of the applied voltage or the voltage applied between the conductor pattern 22a and the transparent electrode layer 26 in the third viewing angle control sheet 212c. The state of the electrochromic material deposited on each conductor pattern 22a of the viewing angle control sheet 212b and the third viewing angle control sheet 212c can be changed based on the light absorption spectrum characteristics or the light reflecting characteristics. The state based on the light absorption spectrum characteristic or the light reflecting characteristic is a transmission state, a specular state, or a black state.

On the other hand, the disappearance of the formed first louver 230a, second louver 230b, and third louver 230c is caused by the first viewing angle control sheet 212a, the second viewing angle control sheet 212b, or the third viewing angle control. A reverse voltage of a voltage applied to form the first louver 230a, the second louver 230b, and the third louver 230c is applied between the conductive pattern 22a and the transparent electrode layer 26 in the sheet 212c, or the voltage Can be performed by stopping the application of. Note that the first louver 230a, the second louver 230b, and the third louver 230c are formed in order to shorten the time required to eliminate the formed first louver 230a, second louver 230b, and third louver 230c. For this purpose, it is effective to apply reverse voltages of the applied voltages.

The viewing angle control device 210 according to the third embodiment has the same effects as the viewing angle control device 110 described above, and also has the following effects.
That is, according to the viewing angle control device 210 according to the third embodiment, the viewing angle direction is set in addition to the front surface of the viewing angle control device 210 (that is, the direction orthogonal to each transparent electrode layer 26). It is possible to realize a peep prevention filter used for a screen of a personal computer or a portable terminal having anisotropy and a blind disposed in an opening of a window.

In the viewing angle control device according to each of the above-described embodiments, the plurality of conductor patterns are formed in a strip shape on one main surface of the transparent insulating layer, but the direction in which the conductor patterns are formed is arbitrary. Can be set.

Further, in each of the above-described embodiments, an electrolytic deposition type electrochromic layer is used. However, the present invention is not limited to this, and the color developing type electrochromic type that can control transparency and reflection is used. A chromic layer can be used as well.

The viewing angle control device according to the present invention is suitable for an object requiring control of the viewing angle such as a screen of a personal computer or a portable terminal or a blind attached to cover a building window. Used.

10, 10 ′, 110, 210 Viewing angle control device 12, 12 ′ Viewing angle control sheet 14 DC power supply 14a First DC power supply 14b Second DC power supply 14c Third DC power supply 20 Transparent insulating layer 20a On the other hand, main surface 22a conductor pattern 22b conductor pattern for connection 24 electrochromic layer 26 transparent electrode layer 28 protective layer 30 louvers 112a, 212a first viewing angle control sheet 112b, 212b second viewing angle control sheet 130a, 230a first Louver 130b, 230b Second louver 212c Third viewing angle control sheet 230c Third louver θ ₁ , θ ₂ , θ ₃ , θ ₄ , θ ₅ viewing angle φ Inclination of center line of viewing angle C ₁ , C ₂ , C ₃ viewing angle center line

Claims (4)

1. A transparent insulating layer;
   A plurality of conductor patterns formed on one main surface of the transparent insulating layer;
   A transparent electrode layer disposed to face the main surface of the transparent insulating layer with a space therebetween;
   An electrochromic layer interposed between the transparent insulating layer and the transparent electrode layer;
   A viewing angle control device comprising a viewing angle control sheet including:
   Depending on the voltage applied to the conductor pattern and the transparent electrode layer and the time for which the voltage is applied, the electrochromic material in the electrochromic layer in a direction perpendicular to one main surface of the transparent insulating layer. A viewing angle control device characterized in that a louver is formed by depositing a predetermined amount.
2. The viewing angle control device according to claim 1, wherein a plurality of the viewing angle control sheets are stacked.
3. A conductor pattern is formed in a strip shape on one main surface of the transparent insulating layer in the plurality of viewing angle control sheets, and the conductor pattern in each viewing angle control sheet is arranged along a specific oblique direction in a cross-sectional view, and each viewing angle control The viewing angle control device according to claim 2, wherein the conductive pattern of the sheet is controlled by applying a voltage independently to each of the viewing angle control sheets.
4. The plurality of conductor patterns are formed in a dot shape, the conductor patterns formed in the dot shape are arranged in a matrix, and are controlled by applying a voltage independently for each conductor pattern, The viewing angle control apparatus according to claim 1 or 2.

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