The present invention relates to a light control sheet and a light control device.
JP 2020-177197 A describes a light control sheet including a first transparent electrode layer, a second transparent electrode layer, and a light control layer formed between the first transparent electrode layer and the second transparent electrode layer. The entire contents of this publication are incorporated herein by reference.
According to one aspect of the present invention, a light control sheet includes a first transparent electrode layer, a second transparent electrode layer, and a light control layer that is formed between the first transparent electrode layer and the second transparent electrode layer and exhibits a first state and a second state having a haze value lower than a haze value of the first state based on a magnitude of a voltage applied to the light control layer. The light control layer includes a transparent polymer layer having voids and including a liquid crystal composition and spacers such that the liquid crystal composition is filled in the voids and includes a dichroic dye and that the spacers define a thickness of the light control layer, exhibit a black color, and have an area occupancy ratio of greater than or equal to 0.7% in the light control layer.
According to another aspect of the present invention, a light control sheet includes a first transparent electrode layer, a second transparent electrode layer, and a light control layer that is formed between the first transparent electrode layer and the second transparent electrode layer and exhibits a first state and a second state having a haze value lower than a haze value of the first state based on a magnitude of a voltage applied to the light control layer. The light control layer includes a transparent polymer layer having voids and including a liquid crystal composition and spacers such that the liquid crystal composition is filled in the voids and that the spacers define a thickness of the light control layer and exhibit a black color, a content ratio of the dichroic dye of the liquid crystal composition in the light control layer is in a range of 3% by weight to 5% by weight, and the area occupancy ratio of the spacers and the content ratio of the dichroic dye are within a region of greater than or equal to an equation, y=−0.18x+0.99, in a two-dimensional coordinate system defined by an area occupancy ratio of the spacers and the content ratio of the dichroic dye, where y is the area occupancy ratio of the spacers, and x is the content ratio of the dichroic dye.
A more complete appreciation of the invention and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
Embodiments will now be described with reference to the accompanying drawings, wherein like reference numerals designate corresponding or identical elements throughout the various drawings.
A light control sheet according to an embodiment of the present invention will be described with reference to
The light control sheet is attached to, for example, transparent members provided to windows of various buildings such as a house, a station, and an airport, partitions installed in offices, display windows installed in stores, and the like. Alternatively, the light control sheet is attached to transparent members provided to windows of mobile objects such as vehicles and aircraft. The shape of the light control sheet may be flat or curved.
The first light control device will be described with reference to
As illustrated in
In the light control sheet 11N, the light control layer 23 is formed between the first transparent electrode layer 21 and the second transparent electrode layer 22. The first transparent electrode layer 21 is formed between the first transparent substrate 24 and the light control layer 23. The second transparent electrode layer 22 is formed between the second transparent substrate 25 and the light control layer 23.
The light control sheet 11N exhibits a first state and a second state having a haze value lower than that of the first state according to the magnitude of a voltage applied to the light control layer 23. Since the type of the light control sheet 11N of the first light control device 10N is normal, the light control sheet 11N exhibits the first state in a state in which a voltage is not applied to the light control layer 23. On the other hand, the light control sheet 11N exhibits the second state in a state in which a voltage is applied to the light control layer 23. The light control sheet 11N exhibiting the first state is opaque, and the light control sheet 11N exhibiting the second state is transparent. For example, the light control sheet 11N exhibiting the first state may have a haze value of greater than or equal to 80%, and the light control sheet 11N exhibiting the second state may have a haze value of less than or equal to 5%.
The light control sheet 11N includes a first electrode 21E attached to a part of the first transparent electrode layer 21 and a second electrode 22E attached to a part of the second transparent electrode layer 22. The light control sheet 11N further includes a wiring 26 connected to the first electrode 21E and a wiring 26 connected to the second electrode 22E. The first electrode 21E is connected to the driver unit 12 via the wiring 26. The second electrode 22E is connected to the driver unit 12 via the wiring 26.
The first transparent electrode layer 21 and the second transparent electrode layer 22 apply, to the light control layer 23, a voltage for switching the light control layer 23 between transparent and opaque. The transparent electrode layers 21 and 22 each have light permeability to transmit visible light. The light permeability of the first transparent electrode layer 21 enables visual recognition of objects through the light control sheet 11N. The light permeability of the second transparent electrode layer 22 enables visual recognition of objects through the light control sheet 11N, in the same manner as the light permeability of the first transparent electrode layer 21.
A material for forming the transparent electrode layers 21 and 22 may be, for example, any one selected from indium tin oxide, fluorine-doped tin oxide, tin oxide, zinc oxide, carbon nanotubes, and poly(3,4-ethylenedioxythiophene).
A material for forming the transparent substrates 24 and 25 may be a synthetic resin or an inorganic compound. Examples of the synthetic resin include polyester, polyacrylate, polycarbonate, and polyolefin. Examples of the polyester include polyethylene terephthalate and polyethylene naphthalate. An example of the polyacrylate is polymethyl methacrylate. Examples of the inorganic compound include silicon dioxide, silicon oxynitride, and silicon nitride.
Each of the electrodes 21E and 22E is, for example, a flexible printed circuit board (FPC). The FPC includes a support layer, a conductor, and a protective layer. The conductor is sandwiched between the support layer and the protective layer. The support layer and the protective layer are formed of an insulating synthetic resin. The support layer and the protective layer are formed of, for example, polyimide. The conductor is formed of, for example, a metal thin film. A material for forming the metal thin film may be, for example, copper. Each of the electrodes 21E and 22E is not limited to an FPC, and may be, for example, a metal tape.
The electrodes 21E and 22E are respectively attached to the transparent electrode layers 21 and 22 via unillustrated conductive adhesive layers. In a portion of each of the electrodes 21E and 22E which is connected to the conductive adhesive layer, the conductor is exposed from the protective layer or the support layer.
The conductive adhesive layer may be formed of, for example, an anisotropic conductive film (ACF), an anisotropic conductive paste (ACP), an isotropic conductive film (ICF), an isotropic conductive paste (ICP), or the like. From the viewpoint of handling properties in the production process of the light control device 10, the conductive adhesive layer is preferably an anisotropic conductive film.
Each of the wirings 26 is formed of, for example, a metal wire and an insulating layer covering the metal wire. The wire is formed of, for example, copper.
The driver unit 12 is formed to be capable of applying a voltage to the light control layer 23 of the light control sheet 11N. The driver unit 12 applies an AC voltage between the first transparent electrode layer 21 and the second transparent electrode layer 22. The driver unit 12 preferably applies an AC voltage having a rectangular waveform between the pair of the transparent electrodes 21 and 22. In other words, the driver unit 12 preferably outputs a rectangular-wave voltage signal.
With reference to
As illustrated in
The light control layer 23 satisfies the following conditions.
According to the light control sheet 11N, the area occupancy ratio of the spacers 23S exhibiting a black color is greater than or equal to 0.7% in the light control layer 23, so that the contrast of the light control sheet 11N can be enhanced.
Further, the light control layer 23 preferably satisfies the following condition.
The light control layer 23 contains greater than or equal to 2% by weight and less than or equal to 5% by weight of the dichroic dye 23DP, so that the fluctuation of the total light transmittance in the plane of the light control sheet 11N in the second state can be suppressed.
The content ratio of the spacers 23S in the light control layer 23 is the percentage of the weight of the spacers 23S to the total weight of the light control layer 23, i.e. to the sum of the weight of the transparent polymer layer 23T, the weight of the liquid crystal composition 23L, and the weight of the spacers 23S. When the specific gravity of the spacers 23S is 2, the content ratio of the spacers 23S may be, for example, greater than or equal to 0.8% by weight. When the specific gravity of the spacers 23S is 2, and the content ratio of the spacers 23S is 0.8% by weight, the area occupancy ratio of the spacers 23S is 0.7%. The content ratio of the dichroic dye 23DP in the light control layer 23 is the percentage of the weight of the dichroic dye 23DP to the above-described total weight of the light control layer 23.
The holding type of the liquid crystal composition 23L is any one selected from a polymer network type, a polymer dispersion type, and a capsule type. The polymer network type includes a three-dimensional mesh transparent polymer network and holds the liquid crystal composition 23L in the mutually communicating mesh voids 23D. The polymer network is an example of the transparent polymer layer 23T. The polymer dispersion type includes a large number of isolated voids 23D in the transparent polymer layer 23T, and holds the liquid crystal composition 23L in the voids 23D dispersed in the transparent polymer layer 23T. The capsule type holds the liquid crystal composition 23L having a capsule shape in the transparent polymer layer 23T. This causes formation of the voids 23D, which is to be filled with the liquid crystal composition 23L, in the transparent polymer layer 23T.
The liquid crystal composition 23L contains a liquid crystal compound 23LM. An example of the liquid crystal compound 23LM is any one selected from those based on a Schiff base, azo, azoxy, biphenyl, terphenyl, benzoic acid ester, tolan, pyrimidine, cyclohexanecarboxylic acid ester, phenylcyclohexane, and dioxane. The liquid crystal composition 23L contains, as the liquid crystal compound 23LM, positive-type nematic liquid crystals having positive dielectric anisotropy.
In the light control layer 23, the void diameter of the voids 23D is greater than or equal to 0.1 μm and less than or equal to 30 μm, and the content ratio of the liquid crystal composition 23L in the light control layer 23 is greater than or equal to 30% by weight and less than or equal to 70% by weight. This can enhance the effectiveness of the content ratio of the spacers 23S and the content ratio of the dichroic dye 23DP. The void diameter is measured in the cross section of the light control layer 23 along the thickness direction of the light control layer 23. When the voids 23D have a circular shape in the cross section, the diameter of the voids 23D is the void diameter. When the voids 23D have an elliptical shape, the major axis of the voids 23D is the void diameter. When the voids 23D have an amorphous shape, the major axis of an ellipse having the minimum major axis, among ellipses circumscribing the voids 23D, is the void diameter of the voids 23D.
The content ratio of the liquid crystal composition 23L in the light control layer 23 is the percentage of the weight of the liquid crystal composition 23L to the total weight of the light control layer 23. The content ratio of the liquid crystal composition 23L is equal to the sum of the blend ratio of the liquid crystal compound 23LM and the blend ratio of the dichroic dye 23DP when preparing the light control layer 23.
The dichroic dye 23DP has an elongated shape. The absorbance in the visible range in the major axis direction of the molecules of the dichroic dye 23DP is larger than the absorbance in the visible range in the minor axis direction of the molecules. The dichroic dye 23DP exhibits substantial transparency when the major axis direction is parallel or substantially parallel to the light incident direction. On the other hand, the dichroic dye 23DP exhibits a prescribed color when the major axis direction is perpendicular or substantially perpendicular to the light incident direction.
Therefore, the dichroic dye 23DP exhibits transparency when the major axis direction is aligned to be parallel or substantially parallel to the normal direction of a surface of the light control layer 23 in contact with the first transparent electrode layer 21 and a surface of the second transparent electrode layer 22 in contact with the light control layer 23. On the other hand, the dichroic dye 23DP exhibits a prescribed color when the major axis direction is aligned to be perpendicular or substantially perpendicular to the normal direction of a surface of the light control layer 23 in contact with the first transparent electrode layer 21 and a surface of the second transparent electrode layer 22 in contact with the light control layer 23. A color exhibited by the dichroic dye 23DP is preferably a black color or a color close to a black color. The dichroic dye 23DP is driven by a guest-host form with the liquid crystal compound 23LM as a host, so that the dichroic dye 23DP exhibits a color.
The dichroic dye 23DP is at least one selected from polyiodide, an azo compound, an anthraquinone compound, a naphthoquinone compound, an azomethine compound, a tetrazine compound, a quinophthalone compound, a merocyanine compound, a perylene compound, and a dioxazine compound. The dichroic dye 23DP may be one dye or a combination of two or more dyes. From the viewpoints of enhancing the light resistance of the dichroic dye 23DP and enhancing the dichroic ratio, the dichroic dye 23DP is preferably at least one selected from an azo compound and an anthraquinone compound. The dichroic dye 23DP is more preferably an azo compound.
The liquid crystal composition 23L may contain, other than the liquid crystal compound 23LM and the dichroic dye 23DP described above, for example, a monomer for forming the transparent polymer layer 23T.
The spacers 23S are dispersed in the entirety of the transparent polymer layer 23T. The spacers 23S define the thickness of the light control layer 23 in the surroundings of the spacers 23S and suppresses a fluctuation in the thickness of the light control layer 23. The spacers are a bead spacer. It is preferable that the spacers 23S exhibit a black color, and a color exhibited by the spacers 23S be the same color as a color exhibited by the dichroic dye 23DP. When the color exhibited by the spacers 23S is the same as a color exhibited by the dichroic dye, the depth of the color exhibited by the light control sheet 11N in the first state can be enhanced.
The spacers 23S may have a spherical shape or a columnar shape. The size of the spacers 23S in the thickness direction of the light control layer 23 is appropriately changed according to the thickness required of the light control layer 23. The size of the spacers 23S in the thickness direction of the light control layer 23 is, for example, greater than or equal to 10 μm and less than or equal to 25 μm. When the spacers 23S has a spherical shape, the average particle diameter of the spacers 23S is, for example, greater than or equal to 10 μm and less than or equal to 25 μm. The average particle diameter of the spacers 23S is obtained using a particle size distribution measuring device adopting principles such as laser light scattering, electrical resistivity change, and analysis of a captured image. The average particle diameter of the spacers 23S is a number average particle diameter. When the spacers 23S has a columnar shape, the average diameter of the spacers 23S is, for example, greater than or equal to 10 μm and less than or equal to 25 μm.
The area occupancy ratio of the spacers 23S may be, for example, greater than or equal to 3% and less than or equal to 8%. The area occupancy ratio of the spacers 23S is the percentage of the area occupied by the spacers 23S to the unit area of the light control sheet 11N. The area occupied by the spacers 23S is obtained by observing the light control sheet 11N in the second state from an eye point facing the plane in which the light control sheet 11N spreads. An example of the unit area in the light control sheet 11N is 1 mm×1 mm. The area occupied by the spacers 23S is calculated by observing the inside of the unit area of the light control sheet 11N in a transparent state using an optical microscope. The black color exhibited by the spacers 23S enables a region corresponding to the spacers 23S exhibiting a black color in an image captured by the optical microscope. The area occupied by the spacers 23S is obtained by binarizing the image captured by an optical microscope and summing the areas of granular regions exhibiting a black color. When the spacers 23S have a spherical shape, the granular region has a spherical shape. When the spacers 23S have a columnar shape, the granular region has a rectangular shape.
The area occupancy ratio of the spacers 23S may be, for example, greater than or equal to 0.7% and less than or equal to 8%, and may be greater than or equal to 0.7% and less than or equal to 4.5%.
A material constituting the spacers 23S may contain a transparent inorganic compound having electrical insulation properties, or may contain a transparent resin having electrical insulation properties. The transparent inorganic compound is any one selected from silicon dioxide and aluminum oxide. The transparent resin is at least one selected from acrylic resin, epoxy resin, phenol resin, melamine resin, polyester, polycarbonate, polyolefin, polyvinyl chloride, polyvinylidene chloride, polystyrene, and acetyl cellulose.
As described above, the spacers 23S contain a black pigment, so that they exhibit a black color. The black pigment is preferably a pigment capable of absorbing ultraviolet light. Examples of the black pigment capable of absorbing ultraviolet light may include carbon black, graphite, carbon nanotubes, and an oxide-based black pigment. The oxide-based black pigment may be a complex oxide. When the black pigment is capable of absorbing ultraviolet light, the light resistance of the light control sheet 11N containing the spacers 23S can be enhanced.
When the spacers 23S are dispersed in a coating liquid for forming the light control layer 23, i.e. a liquid body containing a curable compound and a liquid crystal compound, the spacers 23S may be surface-treated for imparting lyophilic properties.
As illustrated in
The light control sheet 11N in the first state has a haze value of greater than or equal to 80%. This can enhance the effectiveness of the content ratio of the spacers 23S and the content ratio of the dichroic dye 23DP. The haze value is obtained by a measurement method according to ASTM D 1003-00. The measuring instrument of the haze value is, for example, a BYK haze-gard i instrument (manufactured by BYK Gardner). In the measurement of the haze value, light rays contained in luminous flux entering the light control sheet 11N travel in straight lines. The maximum angle between the light rays contained in luminous flux entering the light control sheet 11N and the optical axis of the luminous flux is less than 3°. The light control sheet 11N is fixed such that the surface of the light control sheet 11N and luminous flux entering the surface forms a right angle±2°.
As illustrated in
The second light control device will be described with reference to
As illustrated in
A material for forming the first alignment film 27 and the second alignment film 28 is an organic compound, an inorganic compound, or a mixture thereof. Examples of the organic compound include polyimide, polyamide, polyvinyl alcohol, and a cyanide compound. Examples of the inorganic compound include silicon oxide and zirconium oxide. A material for forming the alignment films 27 and 28 may be silicone. Silicone is a compound that contains an inorganic moiety and an organic moiety.
The first alignment film 27 and the second alignment film 28 are, for example, a vertical alignment film. The vertical alignment film aligns the major axis direction of the liquid crystal compound to be perpendicular to a surface opposite a surface in contact with the first transparent electrode 21 and to a surface opposite a surface in contact with the second transparent electrode layer 22. In this manner, the alignment films 27 and 28 regulate the alignment in liquid crystal compounds contained in the light control layer 23.
With reference to
As illustrated in
As illustrated in
As illustrated in
A test example will be described with reference to
Hereinafter, a specific test example of the light control sheet 11N will be described.
Materials common among the light control sheets 11N prepared in a test example are illustrated below.
First, a light control sheet that does not contain the spacers 23S and the dichroic dye 23DP was produced. In production, there were prepared the first transparent substrate 24 provided with the first transparent electrode layer 21, and the second transparent substrate 25 provided with the second transparent electrode layer 22. Next, there was prepared a coating liquid containing the liquid crystal compound 23LM, a polymerization initiator, and a polymerizable composition. Then, the coating liquid was used to form a coating film between the first transparent electrode layer 21 and the second transparent electrode layer 22, and thereafter the polymerizable composition was polymerized in the coating film to obtain a light control sheet. The light control layer contained in the light control sheet had a thickness of 15 μm.
The blend ratios of materials (d) to (f) to the total weight of the coating liquid are set as follows. Before preparing the coating liquid, a mixture of the liquid crystal compound 23LM and a polymerizable composition was prepared at the following blend ratios.
Next, the blend ratios of a mixture of (d) liquid crystal compound 23LM and (f) polymerizable composition and the material (e) were set as follows.
In the above-described light control sheet that does not contain the dichroic dye 23DP and the spacers 23S, the blend ratio of the spacers 23S was changed to 0.3% by weight, 0.5% by weight, 1% by weight, 2% by weight, 3% by weight, 4% by weight, and 5% by weight to prepare seven types of light control sheets having different content ratios of the spacers 23S. The area occupancy ratio of the spacers 23S was 0.27% when the blend ratio was 0.3% by weight, 0.45% when the blend ratio was 0.5% by weight, and 0.9% when the blend ratio was 1% by weight. Further, the area occupancy ratio of the spacers 23S was 1.8% when the blend ratio was 2% by weight, 2.7% when the blend ratio was 3% by weight, 3.6% when the blend ratio was 4% by weight, and 4.5% when the blend ratio was 5% by weight.
At this time, the blend ratio of the mixture of (d) liquid crystal compound 23LM, (f) polymerizable composition, and (e) polymerization initiator was reduced by the content ratio of the spacers 23S based on the blend ratio when preparing the light control sheet that does not contain the spacers 23S. That is, the blend ratio of the mixture was set to 99.7% by weight when the blend ratio of the spacers 23S was 0.3% by weight, 99.5% by weight when the blend ratio of the spacers 23S was 0.5% by weight, and 99% by weight when the blend ratio of the spacers 23S was 1% by weight. The blend ratio of the mixture was set to 98% by weight when the blend ratio of the spacers 23S was 2% by weight, and 97% by weight when the blend ratio of the spacers 23S was 3% by weight. Further, the blend ratio of the mixture was set to 96% by weight when the blend ratio of the spacers 23S was 4% by weight, and 95% by weight when the blend ratio of the spacers 23S was 5% by weight.
In the above-described light control sheet that does not contain the dichroic dye 23DP and the spacers 23S, the blend ratio of the dichroic dye 23DP was changed to 2% by weight, and the blend ratio of the spacers 23S was changed to 0.3% by weight, 0.5% by weight, 1% by weight, 2% by weight, 3% by weight, 4% by weight, and 5% by weight. Accordingly, there were prepared seven types of light control sheets 11N containing 2% by weight of the dichroic dye 23DP and having a different content ratio of the spacers 23S.
At this time, the blend ratio of the mixture of (d) liquid crystal compound 23LM, (f) polymerizable composition, and (e) polymerization initiator was reduced by the blend ratios of the dichroic dye 23DP and the spacers 23S based on the blend ratio when preparing the light control sheet that does not contain the dichroic dye 23DP and the spacers 23S. That is, the blend ratio of the mixture was set to 97.7% by weight when the blend ratio of the spacers 23S was 0.3% by weight, 97.5% by weight when the blend ratio of the spacers 23S was 0.5% by weight, and 97% by weight when the blend ratio of the spacers 23S was 1% by weight. Further, the blend ratio of the mixture was set to 96% by weight when the blend ratio of the spacers 23S was 2% by weight, and 95% by weight when the blend ratio of the spacers 23S was 3% by weight. Further, the blend ratio of the mixture was set to 94% by weight when the blend ratio of the spacers 23S was 4% by weight, and 93% by weight when the blend ratio of the spacers 23S was 5% by weight.
In the above-described light control sheets 11N containing 2% by weight of the dichroic dye 23DP, the blend ratio of the dichroic dye 23DP was changed to 3% by weight, to thereby prepare seven types of light control sheets 11N that containing 3% by weight of the dichroic dye and having a different content ratio of the spacers 23S. At this time, the blend ratio of the mixture of (d) liquid crystal compound 23LM, (f) polymerizable composition, and (e) polymerization initiator was reduced by the blend ratios of the dichroic dye 23DP and the spacers 23S based on the blend ratio when preparing the light control sheet that does not contain the dichroic dye 23DP and the spacers 23S.
That is, the blend ratio of the mixture was set to 96.7% by weight when the blend ratio of the spacers 23S was 0.3% by weight, 96.5% by weight when the blend ratio of the spacers 23S was 0.5% by weight, and 96% by weight when the blend ratio of the spacers 23S was 1% by weight. Further, the blend ratio of the mixture was set to 95% by weight when the blend ratio of the spacers 23S was 2% by weight, and 94% by weight when the blend ratio of the spacers 23S was 3% by weight. Further, the blend ratio of the mixture was set to 93% by weight when the blend ratio of the spacers 23S was 4% by weight, and 92% by weight when the blend ratio of the spacers 23S was 5% by weight.
In the above-described light control sheets 11N containing 3% by weight of the dichroic dye 23DP, the blend ratio of the dichroic dye 23DP was changed to 4% by weight, to thereby prepare seven types of light control sheets 11N containing 4% by weight of the dichroic dye 23DP and having a different content ratio of the spacers 23S. At this time, the blend ratio of the mixture of (d) liquid crystal compound 23LM, (f) polymerizable composition, and (e) polymerization initiator was reduced by the blend ratios of the dichroic dye 23DP and the spacers 23S based on the blend ratio when preparing the light control sheet 11N containing 3% by weight of the dichroic dye 23DP.
That is, the blend ratio of the mixture was set to 95.7% by weight when the blend ratio of the spacers 23S was 0.3% by weight, 95.5% by weight when the blend ratio of the spacers 23S was 0.5% by weight, and 95% by weight when the blend ratio of the spacers 23S was 1% by weight. Further, the blend ratio of the mixture was set to 94% by weight when the blend ratio of the spacers 23S was 2% by weight, and 93% by weight when the blend ratio of the spacers 23S was 3% by weight. Further, the blend ratio of the mixture was set to 92% by weight when the blend ratio of the spacers 23S was 4% by weight, and 91% by weight when the blend ratio of the spacers 23S was 5% by weight.
In the above-described light control sheets 11N containing 3% by weight of the dichroic dye 23DP, the blend ratio of the dichroic dye 23DP was changed to 5% by weight, to thereby prepare seven types of light control sheets 11N containing 5% by weight of the dichroic dye 23DP and having a different content ratio of the spacers 23S. At this time, the blend ratio of the mixture of (d) liquid crystal compound 23LM, (f) polymerizable composition, and (e) polymerization initiator was reduced by the blend ratios of the dichroic dye 23DP and the spacers 23S based on the blend ratio when preparing the light control sheet 11N containing 2% by weight of the dichroic dye 23DP.
That is, the blend ratio of the mixture was set to 94.7% by weight when the blend ratio of the spacers 23S was 0.3% by weight, 94.5% by weight when the blend ratio of the spacers 23S was 0.5% by weight, and 94% by weight when the blend ratio of the spacers 23S was 1% by weight. Further, the blend ratio of the mixture was set to 93% by weight when the blend ratio of the spacers 23S was 2% by weight, and 92% by weight when the blend ratio of the spacers 23S was 3% by weight. Further, the blend ratio of the mixture was set to 91% by weight when the blend ratio of the spacers 23S was 4% by weight, and 90% by weight when the blend ratio of the spacers 23S was 5% by weight.
For each of the above-described light control sheets, the total light transmittance in the first state and the total light transmittance in the second state were calculated using a method in accordance with ASTM D 1003-00. In each light control sheet, a state in which no potential difference occurs between a pair of transparent electrode layers, i.e. a state in which an AC voltage is not applied between a pair of transparent electrode layers, is set to the “first state”. Further, a state in which an AC voltage having a rectangular wave shape of 50 Hz and 40 V is applied between a pair of transparent electrode layers was set to the second state. Further, for each light control sheet, the haze value in the second state was calculated using a method in accordance with ASTM D 1003-00. The haze value and total light transmittance were calculated using a haze and transparency measuring instrument (BYK haze-gard i instrument, manufactured by BYK Gardner).
For each light control sheet, the contrast was calculated using the following equation.
Contrast=total light transmittance in second state/total light transmittance in first state
With reference to Tables 1 to 5, the evaluation results of each light control sheet will be described.
The evaluation results of the light control sheet that does not contain the dichroic dye 23DP are as illustrated in Table 1 below.
As confirmed from Table 1, the total light transmittance in the first state is 100% when the content ratio of the spacers 23S is 0% by weight, and 94% when the content ratio of the spacers 23S is 0.3% by weight and 0.5% by weight. Further, it was confirmed that the total light transmittance in the first state is 94% when the content ratio of the spacers 23S is 1% by weight, 88% when the content ratio of the spacers 23S is 2% by weight, and 82% when the content ratio of the spacers 23S is 3% by weight. Further, it was confirmed that the total light transmittance in the first state is 76% when the content ratio of the spacers 23S is 4% by weight, and 70% when the content ratio of the spacers 23S is 5% by weight.
The total light transmittance in the second state is 100% when the content ratio of the spacers 23S is 0% by weight, and 99% when the content ratio of the spacers 23S is 0.3% by weight and 0.5% by weight. Further, it was confirmed that the total light transmittance in the second state is 99% when the content ratio of the spacers 23S is 1% by weight, 97% when the content ratio of the spacers 23S is 2% by weight, and 95% when the content ratio of the spacers 23S is 3% by weight. Further, it was confirmed that the total light transmittance in the second state is 94% when the content ratio of the spacers 23S is 4% by weight, and 92% when the content ratio of the spacers 23S is 5% by weight.
It was confirmed that the contrast is 1 when the content ratio of the spacers 23S is 0% by weight, and 1.1 when the content ratio of the spacers 23S is 0.3% by weight and 0.5% by weight. Further, it was confirmed that the contrast is 1.1 when the content ratio of the spacers 23S is 1% by weight, 1.1 when the content ratio of the spacers 23S is 2% by weight, and 1.2 when the content ratio of the spacers 23S is 3% by weight. Further, it was confirmed that the contrast is 1.24 when the content ratio of the spacers 23S is 4% by weight, and 1.31 when the content ratio of the spacers 23S is 5% by weight. These results demonstrate that in the light control sheet that does not contain the dichroic dye 23DP, the contrast is enhanced when the light control layer contains greater than or equal to 0.3% by weight of the spacers 23S, as compared to when the light control layer 23 does not contain the spacers 23S.
The evaluation results of the light control sheet 11N containing 2% by weight of the dichroic dye 23DP are as illustrated in Table 2 below.
As confirmed from Table 2, the total light transmittance in the first state is 11.0% when the content ratio of the spacers 23S is 0.3% by weight, 10.7% by weight when the content ratio of the spacers 23S is 0.5% by weight, and 10.3% when the content ratio of the spacers 23S is 1% by weight. Further, it was confirmed that the total light transmittance in the first state is 9.7% when the content ratio of the spacers 23S is 2% by weight, and 9.0% when the content ratio of the spacers 23S is 3% by weight. Further, it was confirmed that the total light transmittance in the first state is 8.4% when the content ratio of the spacers 23S is 4% by weight, and 7.7% when the content ratio of the spacers 23S is 5% by weight.
It was confirmed that the total light transmittance in the second state is 32.1% when the content ratio of the spacers 23S is 0.3% by weight, 31.8% when the content ratio of the spacers 23S is 0.5% by weight, and 31.5% when the content ratio of the spacers 23S is 1% by weight. Further, it was confirmed that the total light transmittance in the second state is 30.9% when the content ratio of the spacers 23S is 2% by weight, and 30.3% when the content ratio of the spacers 23S is 3% by weight. Further, it was confirmed that the total light transmittance in the second state is 30.0% when the content ratio of the spacers 23S is 4% by weight, and 29.3% when the content ratio of the spacers 23S is 5% by weight.
It was confirmed that the contrast is 2.9 when the content ratio of the spacers 23S is 0.3% by weight, and 3.0 when the content ratio of the spacers 23S is 0.5% by weight and 1% by weight. Further, it was confirmed that the contrast is 3.2 when the content ratio of the spacers 23S is 2% by weight, and 3.4 when the content ratio of the spacers 23S is 3% by weight. Further, it was confirmed that the contrast is 3.6 when the content ratio of the spacers 23S is 4% by weight, and 3.8 when the content ratio of the spacers 23S is 5% by weight.
The evaluation results of the light control sheet 11N containing 30% by weight of the dichroic dye 23DP are as illustrated in Table 3 below.
As confirmed from Table 3, the total light transmittance in the first state is 3.11% when the content ratio of the spacers 23S is 0.3% by weight, 2.93% when the content ratio of the spacers 23S is 0.5% by weight, and 2.75% when the content ratio of the spacers 23S is 1% by weight. Further, it was confirmed that the total light transmittance in the first state is 2.57% when the content ratio of the spacers 23S is 2% by weight, and 2.39% when the content ratio of the spacers 23S is 3% by weight. Further, it was confirmed that the total light transmittance in the first state is 2.22% when the content ratio of the spacers 23S is 4% by weight, and 2.04% when the content ratio of the spacers 23S is 5% by weight.
It was confirmed that the total light transmittance in the second state is 16.5% when the content ratio of the spacers 23S is 0.3% by weight, 15.2% when the content ratio of the spacers 23S is 0.5% by weight, and 14.9% when the content ratio of the spacers 23S is 1% by weight. Further, it was confirmed that the total light transmittance in the second state is 14.6% when the content ratio of the spacers 23S is 2% by weight, and 14.3% when the content ratio of the spacers 23S is 3% by weight. Further, it was confirmed that the total light transmittance in the second state is 14.1% when the content ratio of the spacers 23S is 4% by weight, and 13.8% when the content ratio of the spacers 23S is 5% by weight.
It was confirmed that the contrast is 5.0 when the content ratio of the spacers 23S is 0.3% by weight, 5.2 when the content ratio of the spacers 23S is 0.5% by weight, and 5.4 when the content ratio of the spacers 23S is 1% by weight. Further, it was confirmed that the contrast is 5.7 when the content ratio of the spacers 23S is 2% by weight, 6 when the content ratio of the spacers 23S is 3% by weight, 6.4 when the content ratio of the spacers 23S is 4% by weight, and 6.8 when the content ratio of the spacers 23S is 5% by weight.
In this manner, it was confirmed that the total light transmittances in the first state and the second state are significantly lowered when the light control layer 23 contains 3% by weight of the dichroic dye 23DP, as compared to when the light control layer 23 does not contain the dichroic dye 23DP. In addition, it was confirmed that the lowering rate of the total light transmittance in the first state is higher than the lowering rate of the total light transmittance in the second state. Further, it was confirmed that as the content ratio of the spacers 23S increases, the contrast also increases.
The evaluation results of the light control sheet 11N containing 4% by weight of the dichroic dye 23DP are as illustrated in Table 4 below.
As confirmed from Table 4, the total light transmittance in the first state is 1.41% when the content ratio of the spacers 23S is 0.3% by weight, 1.33% when the content ratio of the spacers 23S is 0.5% by weight, and 1.25% when the content ratio of the spacers 23S is 1% by weight. Further, it was confirmed that the total light transmittance in the first state is 1.17% when the content ratio of the spacers 23S is 2% by weight, and 1.09% when the content ratio of the spacers 23S is 3% by weight. Further, it was confirmed that the total light transmittance in the first state is 1.01% when the content ratio of the spacers 23S is 4% by weight, and 0.93% when the content ratio of the spacers 23S is 5% by weight.
It was confirmed that the total light transmittance in the second state is 11.6% when the content ratio of the spacers 23S is 0.3% by weight, 11.4% when the content ratio of the spacers 23S is 0.5% by weight, and 11.2% when the content ratio of the spacers 23S is 1% by weight. Further, it was confirmed that the total light transmittance in the second state is 11% when the content ratio of the spacers 23S is 2% by weight, and 10.8% when the content ratio of the spacers 23S is 3% by weight. Further, it was confirmed that the total light transmittance in the second state is 10.7% when the content ratio of the spacers 23S is 4% by weight, and 10.4% when the content ratio of the spacers 23S is 5% by weight.
It was confirmed that the contrast is 8.2 when the content ratio of the spacers 23S is 0.3% by weight, 8.6 when the content ratio of the spacers 23S is 0.5% by weight, and 9.0 when the content ratio of the spacers 23S is 1% by weight. Further, it was confirmed that the contrast is 9.4 when the content ratio of the spacers 23S is 2% by weight, 9.9 when the content ratio of the spacers 23S is 3% by weight, 10.5 when the content ratio of the spacers 23S is 4% by weight, and 11.2 when the content ratio of the spacers 23S is 5% by weight.
In this manner, it was confirmed that the contrast can be further enhanced when the light control layer 23 contains 4% by weight of the dichroic dye 23DP, as compared to when the light control layer 23 contains 3% by weight of the dichroic dye 23DP. Further, it was confirmed that as the content ratio of the spacers 23S increases, the contrast also increases.
The evaluation results of the light control sheet 11N containing 5% by weight of the dichroic dye 23DP are as illustrated in Table 5 below.
As confirmed from Table 5, the total light transmittance in the first state is 0.60% when the content ratio of the spacers 23S is 0.3% by weight, 0.57% when the content ratio of the spacers 23S is 0.5% by weight, and 0.54% when the content ratio of the spacers 23S is 1% by weight. Further, it was confirmed that the total light transmittance in the first state is 0.51% when the content ratio of the spacers 23S is 2% by weight, and 0.48% when the content ratio of the spacers 23S is 3% by weight. Further, it was confirmed that the total light transmittance in the first state is 0.44% when the content ratio of the spacers 23S is 4% by weight, and 0.41% when the content ratio of the spacers 23S is 5% by weight.
It was confirmed that the total light transmittance in the second state is 7.3% when the content ratio of the spacers 23S is 0.3% by weight, 7.2% when the content ratio of the spacers 23S is 0.5% by weight, and 7.1% when the content ratio of the spacers 23S is 1% by weight. Further, it was confirmed that the total light transmittance in the second state is 7.0% when the content ratio of the spacers 23S is 2% by weight, and 6.9% when the content ratio of the spacers 23S is 3% by weight. Further, it was confirmed that the total light transmittance in the second state is 6.8% when the content ratio of the spacers 23S is 4% by weight, and 6.6% when the content ratio of the spacers 23S is 5% by weight.
It was confirmed that the contrast is 12.2 when the content ratio of the spacers 23S is 0.3% by weight, 12.6 when the content ratio of the spacers 23S is 0.5% by weight, and 13.1 when the content ratio of the spacers 23S is 1% by weight. Further, it was confirmed that the contrast is 13.7 when the content ratio of the spacers 23S is 2% by weight, 14.4 when the content ratio of the spacers 23S is 3% by weight, 15.4 when the content ratio of the spacers 23S is 4% by weight, and 16.4 when the content ratio of the spacers 23S is 5% by weight.
In this manner, it was confirmed that the contrast can be further enhanced when the light control layer 23 contains 5% by weight of the dichroic dye 23DP, as compared to when the light control layer 23 contains 4% by weight of the dichroic dye 23DP. Further, it was confirmed that as the content ratio of the spacers 23S increases, the contrast also increases.
In
As confirmed from
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As illustrated in
In Equation (1), the content ratio of the spacers 23S is y, and the content ratio of the dichroic dye 23DP is x. A straight line corresponding to Equation (1) is denoted by a solid line in
A point determined by the content ratio of the spacers 23S and the content ratio of the dichroic dye 23DP is preferably within a region defined by the following Condition A1, in addition to Conditions B1 and C1.
Further, in a two-dimensional coordinate system defined by the area occupancy ratio of the spacers 23S and the content ratio of the dichroic dye 23DP, a point determined by the area occupancy ratio of the spacers 23S and the content ratio of the dichroic dye 23DP is preferably within a region defined by the following conditions.
In Equation (2), the area occupancy ratio of the spacers 23S is y, and the content ratio of the dichroic dye 23DP is x.
A point determined by the area occupancy ratio of the spacers 23S and the content ratio of the dichroic dye 23DP is preferably within a region defined by the following Condition A2, in addition to Conditions B2 and C2.
According to the present test example, it was confirmed that the contrast exceeds 5 when both the content ratio of the spacers 23S and the content ratio of the dichroic dye 23DP are within a region defined by the above-described Conditions B1 and C1, preferably in a region defined by Conditions A1 to C1. This effect can also be obtained when both the area occupancy ratio of the spacers 23S and the content ratio of the dichroic dye 23DP are within a region defined by the above-described Conditions B2 and C2, preferably in a region defined by Conditions A2 to C2.
A point determined by the content ratio of the spacers 23S and the content ratio of the dichroic dye 23DP may be within a region defined by the following conditions in the above-described two-dimensional coordinate system.
In Equations (3) and (4), the content ratio of the spacers 23S is y, and the content ratio of the dichroic dye 23DP is x. A straight line corresponding to Equation (3) and a straight line corresponding to Equation (4) are denoted by solid lines in
Further, in a two-dimensional coordinate system defined by the area occupancy ratio of the spacers 23S and the content ratio of the dichroic dye 23DP, a point determined by the area occupancy ratio of the spacers 23S and the content ratio of the dichroic dye 23DP may be within a region defined by the following conditions.
In Equations (5) and (6), the area occupancy ratio of the spacers 23S is y, and the content ratio of the dichroic dye 23DP is x.
According to the present test example, it was confirmed that when both the content ratio of the spacers 23S and the content ratio of the dichroic dye 23DP are within a region defined by the above-described Conditions A3 to C3, it is possible to achieve both the total light transmittance in the second state being greater than or equal to 7% and the contrast being greater than or equal to 6.5. That is, it can be said that the light control sheet 11N is unlikely to become excessively dark when the light control sheet 11N exhibits the second state, while the contrast is enhanced. This effect can also be obtained when both the area occupancy ratio of the spacers 23S and the content ratio of the dichroic dye 23DP are within a region defined by the above-described Conditions A4 to C4.
The occupied area and occupied surface area of the spacers 23S in the light control sheet 11N significantly contribute to enhancement of the contrast of the light control sheet 11N. In addition, the occupied area and occupied surface area of the spacers 23S have a correlation with the number of the spacers 23S. It is considered that since the specific gravity of the spacer 23S used in the present embodiment is 2, the above-described Condition A3, Equation (3), and Equation (4) can be generalized using specific gravity S as described below. Further, in the light control sheet 11N including the spacers 23S having specific gravity S, a point determined by the content ratio of the spacers 23S and the content ratio of the dichroic dye 23DP is preferably within a region defined by the following conditions in the two-dimensional coordinate system. The specific gravity S is a ratio of the mass of a target material per unit volume to the mass of a reference material per unit volume. The spacers 23S are an example of a target material.
The above-described Condition A1 can be generalized using specific gravity S as described below, in the same manner as Condition A3.
When the specific gravity S is 1, a straight line corresponding to Equation (3′) and a straight line corresponding to Equation (4′) are denoted by broken lines in
A point determined by the content ratio of the spacers 23S and the content ratio of the dichroic dye 23DP may be within a region defined by the following conditions in the two-dimensional coordinate system.
A point determined by the area occupancy ratio of the spacers 23S and the content ratio of the dichroic dye 23DP may be within a region defined by the following conditions in the two-dimensional coordinate system.
According to the present test example, it was confirmed that when both the content ratio of the spacers 23S and the content ratio of the dichroic dye 23DP are within a region defined by the above-described Conditions A1 to C5, it is possible to achieve both the total light transmittance in the second state being greater than or equal to 7% and the contrast exceeding 5. That is, it can be said that the light control sheet 11N is unlikely to become excessively dark when the light control sheet 11N exhibits the second state, while the contrast is enhanced. This effect can also be obtained when both the area occupancy ratio of the spacers 23S and the content ratio of the dichroic dye 23DP are within a region defined by the above-described Conditions A2 to C6.
As described above, the following advantageous effects can be obtained according to an embodiment of the light control sheet and the light control device.
The above-described embodiment can be implemented with the following modifications.
The specific gravity of the spacers 23S is not limited to 2, and may be, for example, 1.2. For example, the specific gravity of the spacers 23S made of acrylic resin containing carbon black is 1.2. The area occupancy ratio of the spacers 23S made of acrylic resin is 0.45% when the content is 0.3% by weight, the area occupancy ratio is 0.75% when 0.5% by weight, and the area occupancy ratio is 1.2% when 0.8% by weight. Further, the area occupancy ratio of the spacers 23S made of acrylic resin is 1.5% when the content is 1% by weight, the area occupancy ratio is 3% when 2% by weight, and the area occupancy ratio is 4.5% when 3% by weight. When the area occupancy ratio of the spacers 23S is greater than or equal to 0.7%, even the spacers 23S made of acrylic resin can have an effect equivalent to that of the above-described spacers 23S made of silica. That is, a comparable effect can be obtained as long as the area occupancy ratio of the spacers 23S in the light control layer 23 is comparable, regardless of the specific gravity of the spacers 23S.
A light control sheet according to an embodiment of the present invention includes a first transparent electrode layer, a second transparent electrode layer, and a light control layer formed between the first transparent electrode layer and the second transparent electrode layer. The light control sheet exhibits a first state and a second state having a haze value lower than that of the first state according to the magnitude of a voltage applied to the light control layer. The light control layer contains a transparent polymer layer containing voids, a liquid crystal composition filled in the voids, and spacers that define the thickness of the light control layer. The spacers exhibit a black color, and the content ratio of the spacers in the light control layer is greater than or equal to 2% by weight.
According to the light control sheet, the contrast of the light control sheet can be enhanced when the light control layer contains greater than or equal to 2% by weight of the spacers exhibiting a black color, as compared to when it does not contain the spacers.
A light control sheet includes a first transparent electrode layer, a second transparent electrode layer, and a light control layer formed between the first transparent electrode layer and the second transparent electrode layer. The light control layer includes a transparent polymer layer containing voids, and a liquid crystal composition filled in the voids. The alignment of a liquid crystal compound contained in the liquid crystal composition changes depending on the magnitude of a voltage applied between the transparent electrode layers. This allows the light control sheet to have a transparent state of transmitting most of the light entering the light control sheet and an opaque state of scattering light entering the light control sheet. Therefore, the light control sheet can be used as a partition that is disposed at the boundary between two spaces, such that visual confirmation of one space from the other space through the light control sheet is switchable between possible and impossible (for example, see PTL 1: JP 2020-177197 A).
As a structure capable of suppressing translucency when a light control sheet is opaque, there is proposed a structure capable of exhibiting black color when a light control sheet exhibits opaqueness. On the other hand, a light control sheet is also required to have enhanced transparency when it is transparent, i.e. to have an enhanced contrast that is a ratio of the transmittance when transparent to the transmittance when opaque, while being capable of suppressing translucency when opaque.
A light control sheet according to an embodiment of the present invention includes a first transparent electrode layer, a second transparent electrode layer, and a light control layer formed between the first transparent electrode layer and the second transparent electrode layer, and exhibits a first state and a second state having a haze value lower than that of the first state according to the magnitude of a voltage applied to the light control layer. The light control layer includes a transparent polymer layer containing voids, a liquid crystal composition filled in the voids and containing a dichroic dye, and spacers that define the thickness of the light control layer. The spacers exhibit a black color. The area occupancy ratio of the spacers in the light control layer is greater than or equal to 0.7%.
A light control device according to an embodiment of the present invention includes the light control sheet and a driver unit that applies a voltage to the light control layer contained in the light control sheet.
According to the above-described light control sheet and light control device, the area occupancy ratio of the spacers exhibiting a black color in the light control layer is greater than or equal to 0.7%, so that the contrast of the light control sheet can be enhanced.
In the light control sheet, the content ratio of the dichroic dye in the light control layer may be greater than or equal to 2% by weight and less than or equal to 5% by weight.
According to the light control sheet, the light control layer contains greater than or equal to 2% by weight and less than or equal to 5% by weight of the dichroic dye, so that the fluctuation of the total light transmittance in the plane of the light control sheet in the second state can be suppressed.
In the light control sheet, the content ratio of the spacers is greater than or equal to 2×(S/2)% by weight and less than or equal to 5×(S/2)% by weight. In a two-dimensional coordinate system defined by the content ratio of the spacers and the content ratio of the dichroic dye, the content ratio of the spacers and the content ratio of the dichroic dye may be within a region defined by two equations below.
In the equations, y is the content ratio of the spacers, x is the content ratio of the dichroic dye, and S is the specific gravity of the spacers.
According to the light control sheet, the content ratio of the dichroic dye and the content ratio of the spacers are within the above-described region, so that both the total light transmittance when the light control sheet is in the second state and the contrast of the light control sheet are within a suitable range.
In the light control sheet, the void diameter of the voids may be greater than or equal to 0.1 μm and less than or equal to 30 μm, and the content ratio of the liquid crystal composition in the light control layer may be greater than or equal to 30% by weight and less than or equal to 70% by weight.
According to the light control sheet, the void diameter is greater than or equal to 0.1 μm and less than or equal to 30 μm, and the content ratio of the liquid crystal composition is greater than or equal to 30% by weight and less than or equal to 70% by weight, so that the effectiveness of the content ratio of the spacers and the content ratio of the dichroic dye can be enhanced.
In the light control sheet, the haze value of the light control sheet in the first state may be greater than or equal to 80%. According to this light control sheet, the haze value of the light control sheet in the first state is greater than or equal to 80%, so that the effectiveness of the content ratio of the spacers and the content ratio of the dichroic dye can be enhanced.
A light control sheet for solving the above-described problem includes a first transparent electrode layer, a second transparent electrode layer, and a light control layer formed between the first transparent electrode layer and the second transparent electrode layer, and exhibits a first state and a second state having a haze value lower than that of the first state according to the magnitude of a voltage applied to the light control layer. The light control layer includes a transparent polymer layer containing voids, a liquid crystal composition filled in the voids and containing a dichroic dye, and spacers that define the thickness of the light control layer, and the spacers exhibit a black color. The content ratio of the dichroic dye is greater than or equal to 3% by weight and less than or equal to 5% by weight. In a two-dimensional coordinate system defined by the area occupancy ratio of the spacers and the content ratio of the dichroic dye, the area occupancy ratio of the spacers and the content ratio of the dichroic dye are within a region of greater than or equal to an equation below.
In the equation, y is the area occupancy ratio of the spacers, and x is the content ratio of the dichroic dye.
According to the light control sheet, the area occupancy ratio of the spacers exhibiting a black color and the content ratio of the dichroic dye in the light control layer are within a region of greater than or equal to the above-described equation, so that the light control layer contains greater than or equal to 3% by weight and less than or equal to 5% by weight of the dichroic dye while the contrast of the light control sheet is enhanced. This can suppress the fluctuation of the total light transmittance in the plane of the light control sheet in the second state.
In the light control sheet, the area occupancy ratio of the spacers may be less than or equal to 4.5%, and a point defined by the area occupancy ratio of the spacers and the content ratio of the dichroic dye may be within a region of less than or equal to an equation below:
According to the light control sheet, the contrast of the light control sheet can be enhanced, and further the total light transmittance when the light control sheet exhibits the second state can be enhanced.
According to an embodiment of the present invention, the contrast of the light control sheet can be enhanced.
Obviously, numerous modifications and variations of the present invention are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described herein.
Number | Date | Country | Kind |
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2022-119810 | Jul 2022 | JP | national |
The present application is a continuation of and claims the benefit of priority to International Application No. PCT/JP2023/027592, filed Jul. 27, 2023, which is based upon and claims the benefit of priority to Japanese Application No. 2022-119810, filed Jul. 27, 2022. The entire contents of these applications are incorporated herein by reference.
Number | Date | Country | |
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Parent | PCT/JP2023/027592 | Jul 2023 | WO |
Child | 19036629 | US |