JP6477654B2 - Light control film - Google Patents

Description

  The present invention relates to a light control film.

  There is known a light control layer including a polymer network having a network shape that expands three-dimensionally and liquid crystal molecules located in voids of the polymer network. In the light control layer, the haze value of the light control layer changes between a plurality of two or more values according to the magnitude of the voltage applied to the light control layer. Such a light control layer includes, for example, a light control layer, two transparent electrode layers that sandwich the light control layer in the thickness direction of the light control layer, and a resin-made support layer positioned one by one outside each transparent electrode layer. (For example, refer to Patent Document 1).

International Publication No. 2014/103039

  By the way, the light control film provided with the resin-made support layer is lighter than the light control film provided with the glass-made support layer, and is excellent in that it has flexibility. On the other hand, the resin support layer is more flammable than the glass support layer, and therefore the entire light control film including the resin support layer is more combustible than the light control film including the glass support layer. Cheap. However, the light control film provided with the resin-made support layer is required to be usable in an environment where flame retardancy is required, like the light control film provided with the glass support layer.

These matters are not limited to the light control layer including the polymer network, but are common to the light control film including the light control layer having a structure in which liquid crystal molecules are dispersed inside the resin layer.
An object of this invention is to provide the light control film which made it possible to improve a flame retardance.

  The light control film for solving the above problems includes a resin and liquid crystal molecules, a light control layer having a haze value of 2 or more that varies depending on the magnitude of an applied voltage, and transmits light. An electrode layer positioned on each of two surfaces facing each other in the thickness direction in the light control layer, and a surface that transmits light and contacts the light control layer in each of the electrode layers. And a resin base material positioned one on each of the opposite surfaces. At least one of the two substrates is a flame retardant substrate including a flame retardant layer, and the flame retardancy defined by the UL94 standard is VTM-2 or VTM-1 in the flame retardant layer.

  According to the said structure, since the flame-resistant layer contained in a flame-retardant base material has the predetermined flame retardance prescribed | regulated by UL94 specification, the flame retardance of a light control film is improved.

  The said light control film WHEREIN: It is preferable that the flame retardance defined by UL specification is V-0 in the said light control layer.

  According to the said structure, in addition to a flame retardant layer, since the light control layer also has the predetermined flame retardance prescribed | regulated by UL94 specification, the flame retardance of a light control film is further improved.

  In the light control film, each base material is the flame retardant base material, a thermal expansion coefficient of the flame retardant layer is 15 ppm / ° C. or more and 66 ppm / ° C. or less, and a thermal expansion coefficient of the light control layer is The coefficient of thermal expansion of the flame retardant layer may be equal to or lower.

  According to the above configuration, when each flame retardant layer is bent by heating the light control film, each flame retardant layer is bent toward the other flame retardant layer. Therefore, compared with the structure where each flame retardant layer is bent toward the opposite side to the other flame retardant layer, the light control layer is less likely to be broken. Therefore, the material forming the light control layer can be prevented from leaking to the outside of the light control film due to heating of the light control film.

  In the light control film, the flame retardant substrate may further include a support layer including a surface in contact with the electrode layer in the flame retardant substrate.

  According to the said structure, in a flame-retardant base material, since adhesiveness with respect to an electrode layer and a flame retardance can be given to each different layer, one layer has the adhesiveness with respect to an electrode layer, and a flame retardance. Compared with the structure which satisfy | fills both, the freedom degree in the formation material of a flame-retardant base material can be raised.

  In the light control film, one of the two base materials may be the flame retardant base material, and a refractive index of the flame retardant base material may be lower than a refractive index of the electrode layer.

  According to the above configuration, when the light incident on the light control film travels from the electrode layer to the flame retardant substrate, there is a critical angle in the incident angle at the flame retardant substrate. The range of the angle at which the emitted light is emitted does not become too large. Therefore, the straightness of the light emitted from the light control film is increased.

In the light control film, the flame retardant layer may have a function as at least one of an antireflection layer, an ultraviolet absorption layer, and a hard coat layer.
According to the said structure, functions other than a flame retardance can be added to a flame-resistant layer.

  The said light control film WHEREIN: The said flame-retardant base material may be provided between the said flame-retardant layer and the said support layer, and may be equipped with the contact bonding layer which adhere | attaches the said flame-retardant layer and the said support layer mutually. .

  According to the above configuration, since the flame retardant layer and the support layer formed separately are bonded by the adhesive layer, the flame retardant layer using a material that is difficult to form directly on the support layer as a forming material. Even if it exists, it can be used in combination with a support layer.

  In the light control film, the adhesive layer may have a function as at least one of an antireflection layer and an ultraviolet absorption layer.

  According to the said structure, functions other than adhere | attaching a flame-retardant layer and a support layer can be added to a contact bonding layer.

  In the light control film, the resin may form a polymer network having a network shape that expands three-dimensionally, and the liquid crystal molecules may be located in voids of the polymer network.

  According to the said structure, the flame retardance of a light control film provided with the light control layer which has a polymer network can be improved.

  According to the present invention, flame retardancy can be increased.

Sectional drawing which shows the cross-section in the 1st example of the light control film in 1st Embodiment which actualized the light control film. The partial expanded sectional view which expands and shows the partial cross-section of the light control layer with which a light control film is provided. Sectional drawing which shows the cross-section in the 2nd example of a light control film. Sectional drawing which shows the cross-section in the 3rd example of the light control film in 2nd Embodiment which actualized the light control film. Sectional drawing which shows the cross-section in the 4th example of a light control film.

[First Embodiment]
A first embodiment in which a light control film is embodied will be described with reference to FIGS. 1 to 3. Below, the structure of the 1st example of a light control film, the structure of a light control layer, the structure of the 2nd example of a light control film, the formation material of a light control film, and an Example are demonstrated.

[Configuration of the first example]
With reference to FIG. 1, the structure of the 1st example of a light control film is demonstrated.
As shown in FIG. 1, the light control film 10 includes a light control layer 11, two electrode layers 12, a flame retardant base material 13, and a base material 14.

  The light control layer 11 includes a resin and liquid crystal molecules, and has a haze value of 2 or more that varies depending on the magnitude of the applied voltage. Each electrode layer 12 transmits light and is positioned on each of two surfaces facing each other in the thickness direction in the light control layer 11. Of the two electrode layers 12, one electrode layer 12 is the first electrode layer 12a, and the other electrode layer 12 is the second electrode layer 12b.

  The haze value in the light control layer 11 varies depending on the magnitude of the voltage applied to the light control layer 11 through the electrode layer 12. In the light control layer 11, when the voltage is not applied to the light control layer 11, the haze value in the light control layer 11 is the largest. On the other hand, when the magnitude of the voltage applied to the light control layer 11 is equal to or greater than a predetermined specified value, the haze value in the light control layer 11 is the smallest. In a range where the magnitude of the voltage applied to the dimming layer 11 is not more than the predetermined value, the haze value in the dimming layer 11 decreases as the magnitude of the voltage applied to the dimming layer 11 increases.

  Each of the flame retardant base material 13 and the base material 14 is made of a resin that transmits light and is located on each of the surfaces of the electrode layers 12 opposite to the surface that contacts the light control layer 11. It is an example of a base material. In the light control film 10, only one of these two substrates is the flame retardant substrate 13 including a flame retardant layer. The flame retardancy of the flame retardant substrate 13 is higher than that of the substrate 14. Each of the flame retardant base material 13 and the base material 14 has a single-layer structure composed of one layer.

  In other words, in the light control film 10, the light control layer 11 is sandwiched between the first electrode layer 12 a and the second electrode layer 12 b in the thickness direction of the light control film 10. The flame retardant substrate 13 is located on the surface of the first electrode layer 12a opposite to the surface in contact with the light control layer 11, and the surface of the second electrode layer 12b opposite to the surface in contact with the light control layer 11 is opposite. The base material 14 is located on the side surface.

  The flame retardant substrate 13 is an example of a flame retardant layer, and the flame retardancy defined by the UL94 standard in the flame retardant substrate 13 is VTM-2 or VTM-1. In the light control film 10, one base material itself has a flame retardance among the two base materials which support the electrode layer 12. FIG.

  Thus, since the flame-retardant base material 13 has the predetermined flame retardance prescribed | regulated by UL94 specification, the flame retardance of the light control film 10 is improved.

  In the light control layer 11, the flame retardance defined by UL standard is V-0. In the light control film 10, since the light control layer 11 also has the predetermined flame retardance prescribed | regulated by UL94 standard in addition to the flame-retardant base material 13, the flame retardance of the light control film 10 is further improved.

  As described above, the flame retardant substrate 13 has flame retardancy that satisfies the criteria for being classified as VTM-1 or VTM-2 by the thin material vertical combustion test in the UL94 standard. Moreover, the light control layer 11 has the combustibility which satisfy | fills the criteria for classifying into V-0 by the vertical combustion test in UL94 specification.

  In addition, as for the flame-retardant base material 13 and the light control layer 11, it is still more preferable to satisfy | fill at least 1 among the four criteria described below.

(A) The oxygen index (ISO4589, JIS K7201) is 27 or more.
(B) In the exothermic test (ISO 5660), the total calorific value for 5 minutes is 8 MJ / m ² or less.
(C) Satisfies the flame retardant standard in the combustion test of railway vehicle materials.
(D) Pass the flameproof grade 1 of the flameproof test (JIS A1322).

  In the light control film 10, the refractive index of the flame retardant substrate 13 is lower than the refractive index of the electrode layer 12. That is, the refractive index of the flame retardant substrate 13 is lower than the refractive index of the first electrode layer 12a.

  Thereby, when the light incident on the light control film 10 travels from the electrode layer 12 to the flame retardant base material 13, there is a critical angle in the incident angle at the flame retardant base material 13. The range of the angle at which the light emitted from 13 is emitted does not become too large. Therefore, the straightness of the light emitted from the light control film 10 is enhanced.

  The flame retardant substrate 13 preferably has a function as at least one of an antireflection layer, an ultraviolet absorption layer, and a hard coat layer. Thereby, functions other than flame retardancy can be added to the flame retardant substrate 13.

  Among these, the antireflection layer is a layer that prevents reflection of light incident on the antireflection layer. When the flame retardant substrate 13 functions as an antireflection layer, the light control film 10 has the reflectance on the surface of the flame retardant substrate 13 opposite to the surface in contact with the electrode layer 12. It is smaller than the reflectance in other layers.

  Dimming through the flame retardant substrate 13 as compared with the case where the flame retardant substrate 13 does not have a function as an antireflection layer due to the flame retardant substrate 13 having a function as an antireflection layer. The proportion of light incident on the film 10 can be increased. As a result, when a voltage is applied to the light control layer 11, the light quantity inject | emitted from the flame-retardant base material 13 through the light control layer 11 can be enlarged.

  The ultraviolet absorbing layer is a layer that absorbs ultraviolet rays incident on the surface of the ultraviolet absorbing layer. When the flame retardant substrate 13 functions as an ultraviolet absorbing layer, the efficiency with which the flame retardant substrate absorbs ultraviolet rays is higher than the efficiency with which other layers in the light control film 10 absorb ultraviolet rays. When the flame retardant substrate 13 absorbs ultraviolet rays, it is difficult for the ultraviolet rays to reach the electrode layer 12 and the light control layer 11 which are layers located inside the flame retardant substrate in the light control film 10. Become. Therefore, the deterioration of each layer can be suppressed by irradiating these layers with ultraviolet rays.

  The hard coat layer is a layer having a high surface hardness. When the flame retardant substrate 13 functions as a hard coat layer, the surface hardness of the flame retardant substrate 13 is the same as that of the other layers included in the light control film 10. Higher than surface hardness. When the flame retardant substrate 13 functions as a hard coat layer, scratches are less likely to be formed on the surface of the flame retardant substrate 13, in other words, the surface of the light control film 10. Therefore, the state of the light emitted to the outside of the light control film 10 through the flame retardant substrate 13 is difficult to change.

  In addition, the base material 14 may have a function as at least one of an antireflection layer, an ultraviolet absorption layer, and a hard coat layer, like the flame retardant base material 13. In this case, each of the reflectance of the base material 14, the efficiency of absorbing ultraviolet rays, and the surface hardness only needs to be higher than the values of the layers other than the flame retardant base material 13 in the light control film 10. It may be greater than or equal to each value that the flammable substrate 13 has, or may be smaller than each value that the flame retardant substrate 13 has.

[Configuration of light control layer]
The configuration of the light control layer will be described with reference to FIG.
As shown in FIG. 2, the resin contained in the light control layer 11 forms a polymer network 11a having a network shape that expands three-dimensionally, and the liquid crystal molecules 11b are located in the voids of the polymer network 11a. . Therefore, the flame retardance of the light control film 10 provided with the light control layer 11 which has the polymer network 11a can be improved.

  The light control layer 11 includes a front surface 11F and a back surface 11R which is a surface opposite to the front surface 11F. In the light control layer 11, for example, the first electrode layer 12a is located on the front surface 11F, and the second electrode layer 12b is located on the back surface 11R.

  When a voltage is applied to the light control layer 11, at least some of the plurality of liquid crystal molecules 11b are aligned along one direction intersecting the front surface 11F and the back surface 11R, for example, a direction orthogonal to the front surface 11F and the back surface 11R. Thereby, light easily passes through the light control layer 11 from the front surface 11F toward the back surface 11R and from the back surface 11R toward the front surface 11F. As a result, the haze value in the light control layer 11 is smaller than when no voltage is applied to the light control layer 11.

  On the other hand, when no voltage is applied to the light control layer 11, the plurality of liquid crystal molecules 11b are irregularly arranged in the gap where the liquid crystal molecules 11b are located. This makes it difficult for light to pass through the light control layer 11 from the front surface 11F toward the back surface 11R and from the back surface 11R toward the front surface 11F. As a result, the value of haze in the light control layer 11 is larger than when a voltage is applied to the light control layer 11.

[Configuration of the second example]
The 2nd example of a light control film is demonstrated with reference to FIG.
As shown in FIG. 3, the light control film 20 includes a light control layer 11, a first electrode layer 12 a, a second electrode layer 12 b, a first flame retardant base material 21, and a second flame retardant base material 22. I have. In the thickness direction of the light control film 20, the light control layer 11 is sandwiched between the first electrode layer 12a and the second electrode layer 12b, and the surface of the first electrode layer 12a opposite to the surface in contact with the light control layer 11 The first flame retardant base material 21 is located in the second electrode layer 12b, and the second flame retardant base material 22 is located on the surface of the second electrode layer 12b opposite to the surface in contact with the light control layer 11.

  Like the flame retardant substrate 13 included in the light control film 10 of the first example, in the first flame retardant substrate 21, the flame retardancy determined by the UL94 standard is VTM-2 or VTM-1, 2 In the flame-retardant base material 22, the flame retardancy defined by the UL94 standard is VTM-2 or VTM-1. In the light control film 20 of the second example, since both of the two substrates are flame retardant substrates, the light control film 20 of the second example is higher in flame retardancy than the light control film 10 of the first example. have.

  Each of the first flame retardant substrate 21 and the second flame retardant substrate 22 is similar to the flame retardant substrate 13 included in the light control film 10 of the first example, and an antireflection layer, an ultraviolet absorbing layer, and It may have a function as at least one of the hard coat layers. In this case, only one of the first flame retardant substrate 21 and the second flame retardant substrate 22 may have the above-described function, or the first flame retardant substrate 21 and the first flame retardant substrate 21 2 The flame retardant base material 22 may have different functions or may have the same functions.

  Thus, in the light control film 20 of a 2nd example, each base material which comprises the light control film 20 is a flame-retardant base material. The thermal expansion coefficient of the first flame-retardant substrate 21 and the thermal expansion coefficient of the second flame-retardant substrate 22 are 15 ppm / ° C. or more and 66 ppm / ° C. or less, and the thermal expansion coefficient of the light control layer 11 is It is preferable that it is below the thermal expansion coefficient of the 1st flame-retardant base material 21 and below the thermal expansion coefficient of the 2nd flame-retardant base material 22.

  Thereby, when each flame-retardant base material bends by the heating of the light control film 20, each flame-retardant base material is bent toward another flame-retardant base material. Therefore, compared with the structure which each flame-retardant base material bends toward the opposite side to another flame-retardant base material, the light control layer 11 becomes difficult to break. Therefore, the material forming the light control layer 11 is prevented from leaking to the outside of the light control film 20 due to heating of the light control film 20.

  The thermal expansion coefficient of the first flame retardant substrate 21 and the thermal expansion coefficient of the second flame retardant substrate 22 are equal to each other. Note that the coefficient of thermal expansion of the first flame retardant substrate 21 and the coefficient of thermal expansion of the second flame retardant substrate 22 may be different from each other. In this case, the thermal expansion coefficient of each flame retardant substrate is 15 ppm / ° C. or more and 66 ppm / ° C. or less, and the thermal expansion coefficient of the light control layer 11 is the thermal expansion coefficient of each flame retardant substrate. It is sufficient that the following is satisfied.

[Light control film forming material]
The formation material of each layer which each of the light control film 10 of a 1st example and the light control film 20 of a 2nd example has is demonstrated.

[Light control layer]
As described above, the light control layer 11 includes the polymer network 11a including a resin and the plurality of liquid crystal molecules 11b located in the voids of the polymer network 11a. Among these, the resin constituting the polymer network 11a may be either a thermosetting resin or an ultraviolet curable resin.

  Moreover, in the light control layer 11, it is preferable that the formation material of the polymer network 11a contains the monomer which has a polar group, and a bifunctional monomer. The monomer having a polarity and the bifunctional monomer can be polymerized together with the above-described resin by applying heat or by irradiating with ultraviolet rays. As the monomer having polarity, a monomer having at least one polar group selected from the group consisting of a hydroxy group, a carboxy group, and a phosphate group can be used.

  As the liquid crystal molecule 11b, any one of a liquid crystal molecule constituting a nematic liquid crystal, a liquid crystal molecule constituting a smectic liquid crystal, and a liquid crystal molecule constituting a cholesteric liquid crystal can be used.

[Electrode layer]
Each electrode layer 12 may be a conductive film having optical transparency. As a material for forming the electrode layer 12, a metal oxide having optical transparency and conductivity can be used. As the metal oxide, indium tin oxide (ITO), tin oxide (SnO ₂ ), zinc oxide (ZnO), or the like can be used.

  Further, as the material for forming the electrode layer 12, a polymer having optical transparency and conductivity can be used.

[Base material]
As the base material 14, a resin film having optical transparency can be used. The resin listed below can be used for the resin film forming material. In addition, the numerical value in the drum which is described following each resin is an oxygen index. Resin film forming materials include polytetrafluoroethylene (95), polyvinyl chloride (45), polycarbonate (26), polyamide (23), polyvinyl alcohol (22), polyvinyl chloride (28 to 38), Polyphenylene oxide (27 to 29), polyethylene (17), and the like can be used.

[Flame retardant substrate]
As the flame retardant substrate, a flame retardant mixture obtained by adding a flame retardant to various resins that are the forming materials of the substrate 14 described above can be used. As the flame retardant, either an organic flame retardant or an inorganic flame retardant can be used. Examples of the organic flame retardant include a halogen flame retardant and a phosphorus flame retardant. Inorganic flame retardants can include metal hydroxides and antimony flame retardants.

[Example]
Example 1 corresponding to the light control film 20 of the 2nd example mentioned above is demonstrated.
[Example 1]
100 parts by weight of polycarbonate (manufactured by Sumika Stylon Polycarbonate Co., Ltd., Caliber 200-13, bisphenol A type polycarbonate) (Caliber is a registered trademark) and 15 parts by weight of a phosphorus flame retardant (Daihachi Chemical Industry Co., Ltd.) , PX-200) with a Henschel mixer to prepare a resin composition.

  The resin composition was supplied to the same-direction twin screw extruder, and the cylinder temperature was set to 280 ° C. Thereby, the resin composition was kneaded in a molten state. Thereafter, the molten resin composition was discharged from a T-die and cooled while being stretched using a pinch roll to obtain a flame-retardant base material having a thickness of 50 μm.

  An ITO (Indium Tin Oxide) film having a thickness of 0.1 μm was formed as an electrode layer on one surface of the flame retardant substrate. At this time, two conductive laminates that are laminates of the flame-retardant substrate and the electrode layer were prepared.

  Next, in one conductive laminate, a mixture of a liquid crystal and a photopolymerizable compound containing a resin is used on the surface of the electrode layer opposite to the surface in contact with the flame retardant substrate, using a screen printing apparatus. Printed. A nematic liquid crystal was used as the liquid crystal, and a mixture containing an ultraviolet curable resin, a bifunctional monomer, and a monomer having a hydroxy group was used as the photopolymerizable compound.

  The other conductive laminate was placed on the mixture layer so that the mixture layer and the electrode layer were in contact with each other, and the mixture layer and the electrode layer were brought into close contact with each other. Subsequently, the light control film of Example 1 which has a thickness of 120 micrometers was obtained by irradiating the layer of a mixture with an ultraviolet-ray.

  In the flame-retardant base material with which the light control film of Example 1 is equipped, it was recognized that the flame retardance of UL94 specification is VTM-1, and the oxygen index by ISO4589-2 is 27.

As described above, according to the first embodiment of the light control film, the effects listed below can be obtained.
(1) Since the flame retardant substrate has predetermined flame retardancy defined by the UL94 standard, the flame retardance of the light control film is enhanced.

  (2) In addition to the flame retardant substrate, the light control layer 11 also has a predetermined flame resistance defined by the UL94 standard, so that the flame retardance of the light control film is further enhanced.

  (3) In the light control film 20 of the second example, when each flame retardant substrate is bent by heating the light control film 20, each flame retardant substrate is bent toward the other flame retardant substrate. To do. Therefore, compared with the structure which each flame-retardant base material bends toward the opposite side to another flame-retardant base material, the light control layer 11 becomes difficult to break. Therefore, the material forming the light control layer 11 is prevented from leaking to the outside of the light control film 20 due to heating of the light control film 20.

  (4) In the light control film 10 of the first example, when the light incident on the light control film 10 travels from the electrode layer 12 to the flame retardant substrate 13, the incident angle at the flame retardant substrate 13 is a critical angle. Therefore, the range of the angle at which the light emitted from the flame retardant substrate 13 is emitted does not become too large. Therefore, the straightness of the light emitted from the light control film is increased.

  (5) Adding a function other than the flame retardancy to the flame retardant substrate by having the function as at least one of the antireflection layer, the ultraviolet absorbing layer, and the hard coat layer. Can do.

  (6) The flame retardance of a light control film provided with the light control layer 11 which has the polymer network 11a can be improved.

Note that the first embodiment described above can be implemented with appropriate modifications as follows.
-The light control layer 11 is not restricted to the structure which has the polymer network 11a, The structure by which the liquid crystal molecule was disperse | distributed in the resin layer including resin and a some liquid crystal molecule may be sufficient. Even if it is such a structure, if the light control film has a flame-retardant base material, the effect equivalent to (1) mentioned above can be acquired.

  The flame retardant substrate may not have a function as at least one of an antireflection layer, an ultraviolet absorption layer, and a hard coat layer. According to such a configuration, the degree of freedom in the forming material of the flame retardant base material and the freedom in the shape of the flame retardant base material are not required because the flame retardant base material does not have to have a function different from that of the flame retardant. The degree increases.

  -In the light control film 20 of a 2nd example, the thermal expansion coefficient of the light control layer 11 may be larger than the thermal expansion coefficient of each flame-retardant base material. According to such a configuration, the combination of the forming material of the light control layer 11 and the forming material of each flame retardant substrate is not easily restricted by the thermal expansion coefficient of each forming material, and thus the freedom of choice in each forming material The degree increases.

  -The thermal expansion coefficient of each flame-retardant base material may be smaller than 15 ppm / ° C, and may be larger than 66 ppm / ° C. In this case, the thermal expansion coefficient of the light control layer 11 may be equal to or less than the thermal expansion coefficient of each flame retardant substrate, or may be larger than the thermal expansion coefficient of each flame retardant substrate. According to such a configuration, the combination of the forming material of the light control layer 11 and the forming material of each flame retardant substrate is not easily restricted by the thermal expansion coefficient of each forming material, and thus the freedom of choice in each forming material The degree increases.

  -The flame retardance of the light control layer 11 may be other than V-0, and the light control layer 11 may have a flame retardance higher than V-0, and a difficulty lower than V-0. It may have flammability. According to the structure in which the light control layer 11 has a flame retardance higher than V-0, the flame retardance of a light control film can be improved more. On the other hand, according to the structure which the light control layer 11 has a flame retardance lower than V-0, the freedom degree in the formation material of the light control layer 11 increases.

  -The flame-retardant base material with which a light control film is provided is a layer located outside a flame-resistant layer, Comprising: The coating layer which covers the surface on the opposite side to the surface which touches the electrode layer 12 among each flame-resistant layers May be further provided. The coating layer may have flame retardancy that satisfies any flame retardancy defined by the UL standard.

An embodiment corresponding to such a modification will be described below.
[Example 2]
A film having a thickness of 38 μm (Lumirror T60 manufactured by Toray Industries, Inc., Lumirror is a registered trademark) and having a flame retardancy of V94-2 of UL94 standard was prepared as a flame retardant layer. An ITO thin film having a thickness of 0.1 μm was formed as an electrode layer on one surface of the flame retardant layer, thereby obtaining a conductive laminate that was a laminate of the flame retardant substrate and the electrode layer. . At this time, two conductive laminates were prepared.

  Next, in one conductive laminate, a mixture layer was formed on the surface of the electrode layer opposite to the surface in contact with the flame retardant layer in the same manner as in Example 1. And the other electroconductive laminated body was mounted in the layer of the mixture, and the layer of the mixture and the electrode layer were stuck. Subsequently, the laminated body which has a thickness of 120 micrometers was obtained by irradiating the layer of a mixture with an ultraviolet-ray.

  In the two flame retardant layers of the laminate, a coating layer having a thickness of 13 μm was formed on the surface of each flame retardant layer opposite to the surface in contact with the electrode layer. As the coating solution for forming the coating layer (Nippon Cima, NC-701), a coating solution configured so that the flame retardancy in the coating layer satisfies VTM-1 was used.

  Thereby, the light control film which has a flame-retardant base material comprised from a flame-resistant layer and a coating layer as the light control film of Example 2 was obtained.

  The light control film may have a configuration in which one alignment layer is provided between each electrode layer 12 and the light control layer 11. The alignment layer is a layer for aligning the major axis direction of the liquid crystal molecules contained in the light control layer 11 in a predetermined direction. In such a configuration, when a voltage is applied to the light control layer 11, the haze value in the light control layer 11 can be made higher than when no voltage is applied. For example, the light control film has a light transmission property when no voltage is applied to the light control layer 11, and has a light transmission property when a voltage is applied to the light control layer 11. It can be.

  -The light control layer 11 is a pigment | dye which has a predetermined color, Comprising: You may also contain the pigment | dye which does not prevent the movement of the liquid crystal molecule according to the magnitude | size of the voltage applied to the light control layer 11. FIG. According to such a configuration, the light control layer 11 can have a predetermined color.

[Second Embodiment]
With reference to FIG. 4 and FIG. 5, 2nd Embodiment which actualized the light control film is described. The second embodiment is different from the first embodiment in that the flame retardant base material includes a flame retardant layer and a support layer. Therefore, in the following, such differences will be described in detail, while the detailed description will be omitted by assigning the same reference numerals to the components common to the first embodiment.

  Moreover, below, the structure of the 3rd example of a light control film, the structure of the 4th example of a light control film, the formation material of a light control film, and an Example are demonstrated in order.

[Configuration of third example]
With reference to FIG. 4, the structure of the 3rd example of a light control film is demonstrated.
As shown in FIG. 4, the light control film 30 includes a light control layer 11, two electrode layers 12, and a base material 14, similarly to the light control film 10 of the first example. In the light control film 30, the light control layer 11 is sandwiched between the first electrode layer 12a and the second electrode layer 12b in the thickness direction of the light control film 30, and of the second electrode layer 12b, The base material 14 is located on the surface opposite to the surface in contact.

  The light control film 30 includes a flame retardant substrate 31, and the flame retardant substrate 31 includes a surface of the flame retardant substrate 31 opposite to the surface in contact with the first electrode layer 12 a. 31a. The flame retardant substrate 31 further includes a support layer 31 b including a surface in contact with the electrode layer 12 in the flame retardant substrate 31.

  For example, the flame retardant layer 31a may have the same configuration as the flame retardant base material 13 in the first embodiment. In addition, since the flame retardant layer 31a does not require adhesion to the electrode layer 12, a layer formed of a material having low adhesion to the electrode layer 12 may be used as long as the flame retardant layer 31a has flame retardance. It is. The support layer 31b may have a configuration equivalent to that of the base material 14 in the first embodiment, for example.

  Therefore, in the flame-retardant base material 31, the adhesion with respect to the 1st electrode layer 12a and a flame retardance can be given to each different layer. Therefore, the degree of freedom in the material for forming the flame retardant substrate 31 can be increased as compared with a configuration in which one layer satisfies both the adhesion to the first electrode layer 12a and the flame retardancy.

  The flame retardant base material 31 is provided between the flame retardant layer 31a and the support layer 31b, and includes an adhesive layer 31c that adheres the flame retardant layer 31a and the support layer 31b to each other. Thus, since the flame retardant layer 31a and the support layer 31b formed separately are bonded by the adhesive layer 31c, the flame retardant using a material that is difficult to form directly on the support layer 31b as a forming material. Even the layer 31a can be used in combination with the support layer 31b.

  In other words, the support layer 31b is located on the surface of the first electrode layer 12a opposite to the surface that contacts the light control layer 11, and the surface of the support layer 31b that contacts the first electrode layer 12a. An adhesive layer 31c is located on the opposite surface. The flame retardant layer 31a is located on the surface of the adhesive layer 31c opposite to the surface in contact with the support layer 31b.

  The adhesive layer 31c preferably has a function as at least one of an antireflection layer and an ultraviolet absorption layer. Thereby, functions other than bonding the flame retardant layer 31a and the support layer 31b to the adhesive layer 31c can be added.

  The support layer 31b may have a function as at least one of an antireflection layer and an ultraviolet absorption layer. In this case, the support layer 31b and the adhesive layer 31c may function as the same layer, or may function as different layers. In order to increase the functions of the light control film 30, the support layer 31b and the adhesive layer 31c preferably function as different layers.

  In addition, the flame retardant layer 31a has a function as at least one of an antireflection layer, an ultraviolet absorption layer, and a hard coat layer, like the flame retardant substrate 13 included in the light control film 10 of the first example. May be. In this case, the flame retardant layer 31a may function as the same layer as the support layer 31b and the adhesive layer 31c, or may function as different layers. In order to increase the functions of the light control film 30, the flame retardant layer 31a preferably functions as a layer different from the support layer 31b and the adhesive layer 31c.

  In addition, the flame-retardant base material 31 does not need to have the contact bonding layer 31c. In this case, by applying a coating liquid for forming a flame retardant layer on the surface of the support layer 31b opposite to the surface in contact with the first electrode layer 12a, the support layer 31b is directly flame retardant. A layer can be formed. In such a configuration, it is possible to reduce the thickness of the light control film 30 as much as the adhesive layer 31c can be omitted.

[Configuration of Fourth Example]
With reference to FIG. 5, the structure of the 4th example of a light control film is demonstrated.
As shown in FIG. 5, the light control film 40 includes the light control layer 11, the first electrode layer 12 a, the second electrode layer 12 b, the first flame retardant base material 41, and the second flame retardant base material 42. I have. In the thickness direction of the light control film 40, the light control layer 11 is sandwiched between the first electrode layer 12a and the second electrode layer 12b, and the surface opposite to the surface in contact with the light control layer 11 in the first electrode layer 12a The first flame retardant base material 41 is located in the second electrode layer 12b, and the second flame retardant base material 42 is located on the surface of the second electrode layer 12b opposite to the surface in contact with the light control layer 11.

  Each of the first flame retardant substrate 41 and the second flame retardant substrate 42 is similar to the flame retardant substrate 31 included in the light control film 30 of the third example, and includes a support layer, an adhesive layer, and a flame retardant. The layers are provided, and three layers are stacked in this order on each flame retardant substrate. More specifically, the first flame retardant substrate 41 includes a first flame retardant layer 41a, a first support layer 41b, and a first adhesive layer 41c, and the second flame retardant substrate 42 is a second flame retardant substrate 42. A fuel layer 42a, a second support layer 42b, and a second adhesive layer 42c are provided.

  Thus, in the light control film 40, since two base materials are both a flame retardant base material, the light control film 40 of a 4th example is a flame retardance higher than the light control film 30 of a 3rd example. have.

  The thermal expansion coefficient of the first flame retardant layer 41a and the thermal expansion coefficient of the second flame retardant layer 42a are 15 ppm / ° C. or more and 66 ppm / ° C. or less, and the thermal expansion coefficient of the light control layer 11 is the first flame retardant. It is preferable that it is below the thermal expansion coefficient of the layer 41a, and the thermal expansion coefficient of the 2nd flame retardant layer 42a.

  Thereby, when each flame retardant layer is bent by heating of the light control film 40, each flame retardant layer is bent toward the other flame retardant layer. Therefore, like the light control film 20 of the second example, the light control layer 11 is not easily broken, and the formation material of the light control layer 11 is suppressed from leaking to the outside of the light control film 40.

  The adhesive layer included in each flame retardant substrate is the same as the adhesive layer 31c included in the flame retardant substrate 31 in the light control film 30 of the third example, as at least one of an antireflection layer and an ultraviolet absorbing layer. It may have a function. In this case, only one of the first adhesive layer 41c and the second adhesive layer 42c may have the above-described function, and the first adhesive layer 41c and the second adhesive layer 42c are different from each other. It may have a function, and may have the same function mutually.

  In addition, the support layer with which each flame retardant base material may have a function as at least one of an antireflection layer and an ultraviolet absorption layer. Each support layer may function as the other support layer and the two adhesive layers, or may function as different layers. Alternatively, only one of the first support layer 41b and the second support layer 42b may be a layer having the above-described function.

  Moreover, the flame retardant layer included in each flame retardant substrate may have a function as at least one of an antireflection layer, an ultraviolet absorption layer, and a hard coat layer. Each flame retardant layer may function as the other flame retardant layer, the two support layers, and the two adhesive layers, or may function as different layers. Alternatively, only one of the first flame retardant layer 41a and the second flame retardant layer 42a may be a layer having the above-described function.

  In addition, each flame-retardant base material does not need to have an adhesive layer similarly to the flame-retardant base material 31 in the light control film 30 of the 3rd example mentioned above.

[Light control film forming material]
The formation material of an adhesive layer is demonstrated among each layer with which a light control film is provided.
[Adhesive layer]
The adhesive layer has only to be light transmissive and adhesive to adhere the flame retardant layer and the support layer to each other. An optical adhesive (Optical Clear Adhesive: OCA) can be used as a material for forming the adhesive layer.

[Example]
Example 3 corresponding to the light control film 40 of the 4th example mentioned above is demonstrated.
[Example 3]
A support layer was obtained using the same method as the method for forming a flame retardant substrate in Example 1, except that only polycarbonate was used as the material for forming the support layer. And the laminated body provided with a light control layer, two electrode layers, and two support layers was formed by forming an electrode layer and a light control layer using the same method as Example 1.

  Next, by applying a coating solution for a flame retardant layer having the following composition on the surface of each support layer opposite to the surface in contact with the electrode layer, the support layer has a thickness of 5 μm and a hard coat A flame retardant layer having a function as a layer was formed. This obtained the light control film of Example 3 which has a thickness of 130 micrometers.

[Flame retardant coating liquid]
PETA (Osaka Organic Chemical Co., Ltd., Viscoat # 300) 100 parts by weight Photopolymerization initiator (BASF, IRGACURE 184)
(IRGACURE is a registered trademark) 5 parts by weight Methyl ethyl ketone 100 parts by weight Magnesium hydroxide (manufactured by Sakai Chemical Industry Co., Ltd., MGZ-3) 50 parts by weight

  In the flame-retardant layer with which the light control film of Example 3 is equipped, it was recognized that the flame retardance of UL94 specification is VTM-1, and the oxygen index by ISO4589-2 is 27.

As described above, according to the second embodiment of the light control film, in addition to the effects (1) to (6) described above, the effects listed below can be obtained.
(7) In the flame-retardant base material, the adhesion to the electrode layer 12 and the flame retardancy can be provided in different layers, so that one layer has the adhesion to the electrode layer 12 and the flame retardancy. Compared with the structure satisfying both, the degree of freedom in the material for forming the flame-retardant substrate can be increased.

  (8) Since the separately formed flame retardant layer and the support layer are bonded by the adhesive layer, even if the flame retardant layer is made of a material that is difficult to form directly on the support layer. , And can be used in combination with a support layer.

  (9) Since the adhesive layer has a function as at least one of the antireflection layer and the ultraviolet absorbing layer, functions other than bonding the flame retardant layer and the support layer to the adhesive layer can be added.

The second embodiment described above can be implemented with appropriate modifications as follows.
-The adhesive layer with which a flame-retardant base material is provided is a function as an antireflection layer and an ultraviolet absorption layer, and does not need to have functions other than the function to adhere | attach a flame-retardant layer and a support layer. According to such a configuration, the degree of freedom in the material for forming the adhesive layer is increased.

  -In a flame-retardant base material provided with two layers and an adhesive layer that adheres the two layers to each other, of the two layers, the layer in contact with the electrode layer has UL-standard flame retardancy of VTM-1 or VTM- 2 may be a flame retardant layer. Even if it is such a structure, since a flame-retardant base material contains a flame-resistant layer, the effect equivalent to (1) mentioned above can be acquired.

  DESCRIPTION OF SYMBOLS 10,20,30,40 ... Light control film, 11 ... Light control layer, 11a ... Polymer network, 11b ... Liquid crystal molecule, 11F ... Front surface, 11R ... Back surface, 12 ... Electrode layer, 12a ... 1st electrode layer, 12b ... 2nd electrode layer, 13, 31 ... flame retardant substrate, 14 ... substrate, 21, 41 ... 1st flame retardant substrate, 22, 42 ... 2nd flame retardant substrate, 31a ... flame retardant layer, 31b ... support layer, 31c ... adhesive layer, 41a ... first flame retardant layer, 41b ... first support layer, 41c ... first adhesive layer, 42a ... second flame retardant layer, 42b ... second support layer, 42c ... first 2 adhesive layers.

Claims (9)

A light control layer containing a resin and liquid crystal molecules, and having a haze value of 2 or more that varies depending on the magnitude of an applied voltage;
Two electrode layers that transmit light and sandwich the light control layer in the thickness direction of the light control layer;
A resin base material that transmits light and is positioned one by one outside each of the electrode layers,
Of the two substrates, at least one is a flame retardant substrate including a flame retardant layer,
The light control film in which the flame retardancy defined by UL94 standard is VTM-2 or VTM-1 in the flame retardant layer.
The light control film according to claim 1, wherein the light control layer has a flame retardancy defined by UL standards of V-0. Each of the substrates is the flame retardant substrate,
The thermal expansion coefficient of the flame retardant layer is 15 ppm / ° C. or more and 66 ppm / ° C. or less,
The light control film of Claim 1. The thermal expansion coefficient of the said light control layer is below the thermal expansion coefficient of the said flame-resistant layer. The light control film according to any one of claims 1 to 3, wherein the flame retardant substrate further includes a support layer including a surface in contact with the electrode layer in the flame retardant substrate. One of the two substrates is the flame retardant substrate,
The light control film of Claim 1. The refractive index of the said flame-retardant base material is lower than the refractive index of the said electrode layer. The light control film according to any one of claims 1 to 5, wherein the flame retardant layer has a function as at least one of an antireflection layer, an ultraviolet absorbing layer, and a hard coat layer. The light control film according to claim 4, wherein the flame retardant base material includes an adhesive layer that is located between the flame retardant layer and the support layer and adheres the flame retardant layer and the support layer to each other. . The light control film according to claim 7, wherein the adhesive layer has a function as at least one of an antireflection layer and an ultraviolet absorption layer. The resin forms a polymer network having a network shape that expands three-dimensionally,
The light control film according to any one of claims 1 to 8, wherein the liquid crystal molecules are located in voids of the polymer network.