JP6096847B2 - Polymer dispersed liquid crystal dimming configuration - Google Patents

Description

  The present invention relates to a light control configuration, and particularly describes a polymer dispersed liquid crystal light control configuration.

  In order to prevent excessive rays from entering the room due to the progress of science, the current glass surface is provided with a heat insulating sheet, or a polymer-dispersed liquid crystals (PDLC), low Although it has been replaced by radiation glass (Low-E glass), electrochromic glass, etc., each of the above four has advantages and disadvantages. Among them, polymer-dispersed liquid crystal and electrochromic glass completely emit light. By shielding and switching the light transmittance, it meets the user's needs for architectural glass, and the polymer dispersed liquid crystal layer is superior to electrochromic glass in terms of reaction speed and manufacturing cost Therefore, there is an opportunity to be applied in large quantities as architectural glass.

  For example, “Light-regulation membrane” as disclosed in Patent Document 1 includes a polymer-dispersed liquid crystal layer, a surface-constituting layer disposed on one of the polymer-dispersed liquid crystals, and the surface. A pressure-sensitive adhesive layer placed on the other side of the polymer-dispersed liquid crystal layer away from the configuration, wherein the polymer-dispersed liquid crystal layer is composed of two liquid crystal layers and two liquid crystal layers respectively disposed on both sides of the liquid crystal layer. Two conductive polymer layers, two first polymer compound layers installed on one of these conductive layers separated from the liquid crystal layer, and one of these first polymer compound layers separated from the liquid crystal layer, respectively. It includes two pressure-sensitive adhesive layers and two second polymer compound layers respectively installed on one of these pressure-sensitive adhesive layers separated from the liquid crystal layer. By adhering to the transparent glass using the pressure-sensitive adhesive layer, and further energizing these conductive layers, an external applied electric field is formed in the liquid crystal layer, and the liquid crystal therein is aligned. The amount of light transmitted through can be controlled.

  However, the polymer-dispersed liquid crystal layer can adjust the amount of visible light incident on the room, but cannot prevent infrared rays that raise the room temperature, and the user wants to take in a large amount of light into the room. In this case, the temperature of the room rises and the temperature is lowered by using a cooling device or the like, which leads to waste of energy. It is an issue between.

US Patent Publication No. US20110255035

  The main object of the present invention is to solve the problem that the polymer-dispersed liquid crystal cannot block infrared rays.

  In order to achieve the above object, the present invention provides a liquid crystal light control layer, a first infrared-resistant light-transmitting conductive layer, a second infrared-resistant light-transmitting conductive layer, a first light-transmitting substrate, and a second light-transmitting substrate. The liquid crystal light control layer includes a plurality of liquid crystals, and the first infrared light-resistant light-transmitting conductive layer and the second infrared light-resistant light-transmitting conductive layer include a nichrome alloy as a material. The first light-transmitting substrate and the second light-transmitting substrate are separated from one of the first infrared-resistant light-transmitting conductive layers and the liquid crystal light-modulating layer, respectively. The liquid crystal light control layer is installed on one of the second infrared-resistant light-transmitting conductive layers and energizing the first infrared-resistant light-transmitting conductive layer and the second infrared-resistant light-transmitting conductive layer. An external electric field is generated, and these liquid crystals are aligned with the external electric field to further change the translucency of the liquid crystal light control layer. Thereby, it provides a polymer dispersion type liquid crystal light control structure.

As described above, the present invention has the following features.
First, by installing the first infrared-resistant translucent conductive layer and the second infrared-resistant translucent conductive layer, it is possible to block infrared rays at the same time as the conduction, and to combine the two functions into one layer. By having it together, reducing the number of layers can reduce the cost and the thickness of the configuration.
Second, by providing the first infrared-resistant translucent conductive layer and the second infrared-resistant translucent conductive layer, the incidence of infrared rays is blocked, so that the generation of thermal energy can be reduced.

It is a schematic diagram which shows the 1st Example which concerns on this invention before electricity supply. It is a schematic diagram which shows the 1st Example which concerns on this invention after electricity supply. It is the schematic diagram which showed use of the 1st Example which concerns on this invention. It is the schematic diagram which showed use of the 2nd Example which concerns on this invention.

  Detailed description and technical contents of the present invention will be described below with reference to the drawings.

  Referring to FIGS. 1A and 1B, the present invention relates to a liquid crystal light control layer 10, a first infrared-resistant light-transmitting conductive layer 21, a second infrared-resistant light-transmitting conductive layer 22, a first light-transmitting substrate 31, and a second light-transmitting substrate 31. The liquid crystal light control layer 10 includes a plurality of liquid crystals 11, and the first infrared light-resistant light-transmitting conductive layer 21 and the second infrared light-resistant light-transmitting conductive layer 22 are included in the liquid crystal light-control layer. 10, the first light-transmissive substrate 31 and the second light-transmissive substrate 32 are arranged on one side of the first infrared-resistant light-transmissive conductive layer 21 and the liquid crystal light-modulating layer, which are separated from the liquid crystal light-modulating layer 10. 10 is disposed on one of the second infrared-resistant translucent conductive layers 22 apart from 10. Among them, the first infrared-resistant translucent conductive layer 21 and the second infrared-resistant translucent conductive layer 22 are made of a nichrome alloy or an oxidized nichrome alloy, thereby blocking the incidence of infrared rays. By reducing the generation and adjusting the oxidation degree of the nichrome alloy, the color temperature of the polymer-dispersed liquid crystal dimming configuration according to the present invention, the first infrared-resistant translucent conductive layer 21 and the second infrared-resistant The degree of infrared resistance of the translucent conductive layer 22 can be adjusted, and by adjusting the color temperature according to the present invention, it is possible to design according to the customer according to different needs of the user.

For example, if it is attached to a French window, a skylight of a vehicle, and a general window in a building, each requires a different light shielding degree and color temperature, so by utilizing the adjustment of the oxidation degree of the nichrome alloy according to the present invention, Each request can be met.
In addition, since the first infrared-resistant translucent conductive layer 21 and the second infrared-resistant translucent conductive layer 22 have the functions of conductivity and infrared resistance at the same time, the production cost and the thickness of the present invention can be reduced. it can.

  The first light-transmitting substrate 31 and the second light-transmitting substrate 32 are any of a compound comprising polyethylene terephthalate, polyethylene naphthalate, glass, polyimide, polycycloolefin polymer, cyclic olefin copolymer, and combinations thereof. In this embodiment, the material of the first light transmitting substrate 31 and the second light transmitting substrate 32 is glass having a thickness of 0.3 millimeters (mm) or less, and is flexible, so roll-to-roll. Since production is possible by the method, production cost can be reduced and production volume can be improved.

  The present invention further includes a first antioxidant protective layer 41, a second antioxidant protective layer 42, an ultraviolet resistant layer 50, an adhesive layer 80, and a release layer 60, and the first antioxidant protection. The layer 41 is disposed between the first infrared-resistant light-transmissive conductive layer 21 and the first light-transmissive substrate 31, and the second antioxidant protective layer 42 is disposed between the second infrared-resistant light-transmissive conductive layer 22 and the first light-transmissive conductive layer 21. In the present embodiment, the material of the first antioxidant protective layer 41 and the second antioxidant protective layer 42 includes titanium dioxide, and oxygen and hydrogen are contained in the second transparent substrate 32. By preventing the liquid crystal light control layer 10 from being damaged, the service life of the liquid crystal light control layer 10 can be extended, and the UV light resistant layer 50 is separated from the liquid crystal light control layer 10. Installed on one side of the first translucent substrate 31 to enter ultraviolet rays that cause lesions in human cells In addition, the liquid crystal light control layer 10 can be prevented from peeling off due to long-term irradiation with ultraviolet rays, and the adhesive layer 80 and the peeling layer 60 are separated from the first translucent substrate 31. When the release layer 60 is peeled off by sequentially installing on one of the ultraviolet layers 50, the adhesive layer 80 can be used to affix to the corresponding substrate.

  When the first infrared-resistant translucent conductive layer 21 and the second infrared-resistant translucent conductive layer 22 are not energized, the liquid crystal 11 is arranged in an arbitrary direction, so that incident light is external. The first infrared-resistant light-transmitting conductive layer 21 and the second infrared-resistant light-transmitting conductive layer 22 are energized. In this case, the liquid crystal light control layer 10 generates an external electric field, and the liquid crystals 11 are aligned according to the external electric field and arranged in a specific direction, and the light transmittance of the liquid crystal light control layer 10 is increased. By improving the input of different voltages, the orientation angle of the liquid crystal 11 is adjusted to adjust the light transmission. In this embodiment, the liquid crystal 11 is exemplified as a forward alignment type liquid crystal, but is not limited thereto. A reverse orientation type liquid crystal can also be used for the liquid crystal light control layer 10. In this case, in contrast to the forward direction type liquid crystal, the light transmittance of the liquid crystal light control layer 10 decreases when energized. When not energized, the translucency of the liquid crystal light control layer 10 is improved.

  Further, referring to FIG. 2, after peeling off the release layer 60, the adhesive layer 80 is used to apply the present invention to the glass 70 on the building or other places where adjustment of lighting is necessary. The light transmittance is controlled by the liquid crystal light control layer 10, infrared rays are blocked using the first infrared resistant light transmitting conductive layer 21 and the second infrared resistant light transmitting conductive layer 22, and the ultraviolet resistant The layer 50 is used to prevent the incidence of ultraviolet rays.

  Furthermore, referring to FIG. 3, it is a schematic view showing the use of the second embodiment according to the present invention, and in this embodiment, the first light transmitting substrate 31 is a glass 70 applied to a building or a vehicle. Therefore, it is not necessary to further attach and peel the release layer 60. The user can consider the installation and its use by selecting the most suitable implementation method according to different usage situations.

As described above, the present invention has the following features.
First, the first infrared-resistant translucent conductive layer and the second infrared-resistant translucent conductive layer reduce generation of thermal energy by preventing incidence of infrared rays.
Second, since the first infrared-resistant translucent conductive layer and the second infrared-resistant translucent conductive layer have the functions of conductivity and infrared resistance at the same time, the production cost and the thickness of the entire configuration can be reduced. it can.
Third, by adjusting the oxidation degree of the nichrome alloy, the color temperature of the light control configuration according to the present invention and the infrared resistance of the first infrared-resistant translucent conductive layer and the second infrared-resistant translucent conductive layer. The degree can be adjusted.
Fourth, since the thickness of the first light-transmitting substrate and the second light-transmitting substrate is 0.3 mm (mm) or less and flexible, it can be produced by a roll-to-roll method. In addition, the production amount can be improved.
Fifth, the first antioxidant protective layer and the second antioxidant protective layer prevent oxygen and hydrogen from damaging the liquid crystal light control layer 10, The useful life can be extended, and the UV resistance of the present invention can be improved by using titanium dioxide for the first antioxidant protective layer and the second antioxidant protective layer.
Sixth, the ultraviolet resistant layer prevents the incidence of ultraviolet rays that cause lesions in human cells, and also prevents the liquid crystal light control layer 10 from being unusable by being peeled off by long-term irradiation with ultraviolet rays. be able to.

    The detailed description of the present invention described above is only a preferred embodiment of the present invention, and does not limit the scope claimed by the present invention. Changes, modifications, and the like made based on the scope of the present invention belong to the scope of the claims of the present invention.

DESCRIPTION OF SYMBOLS 10 Liquid crystal light control layer 11 Liquid crystal 21 1st infrared light transmission conductive layer 22 2nd infrared light transmission conductive layer 31 1st light transmission board 32 2nd light transmission board 41 1st antioxidant protection layer 42 2nd antioxidant protection Layer 50 UV resistant layer 60 Peeling layer 70 Glass 80 Adhesive layer

Claims (7)

A liquid crystal light control layer including a plurality of liquid crystals;
A first infrared-resistant light-transmitting conductive layer and a second infrared-resistant light-transmitting conductive layer, each of which is disposed on both sides of the liquid crystal light-controlling layer , including an oxidized nichrome alloy .
A first light-transmissive substrate and a first light-transmissive substrate disposed on one of the first infrared-resistant light-transmissive conductive layers separated from the liquid crystal light-modulating layer and one of the second infrared-resistant light-transmissive conductive layers separated from the liquid crystal light-modulating layer; A two-translucent substrate;
Including
By energizing the first infrared-resistant light-transmissive conductive layer and the second infrared-resistant light-transmissive conductive layer, the liquid crystal light control layer generates an external electric field, and these liquid crystals are adapted to the external electric field. A polymer-dispersed liquid crystal light control structure that is oriented and further changes the light transmittance of the liquid crystal light control layer.   A first antioxidant protective layer disposed between the first infrared-resistant translucent conductive layer and the first translucent substrate; and between the second infrared-resistant translucent conductive layer and the second translucent substrate. The polymer-dispersed liquid crystal light control structure according to claim 1, further comprising a second antioxidant protective layer to be installed.    The polymer dispersed liquid crystal light control structure according to claim 2, wherein the first antioxidant protective layer and the second antioxidant protective layer contain titanium dioxide as a material. 2. The polymer-dispersed liquid crystal light control structure according to claim 1, further comprising an ultraviolet-resistant layer installed on one side of the first light transmitting substrate away from the liquid crystal light control layer. 5. The polymer dispersed liquid crystal light control structure according to claim 4, further comprising a release layer disposed on one of the ultraviolet resistant layers separated from the first light transmitting substrate. The first light-transmitting substrate and the second light-transmitting substrate may be any of a compound comprising polyethylene terephthalate, polyethylene naphthalate, glass, polyimide, polycycloolefin polymer, cyclic olefin copolymer, and combinations thereof. The polymer dispersed liquid crystal light control structure according to claim 1. 7. The polymer dispersed liquid crystal light control structure according to claim 6, wherein a material of the first light transmitting substrate and the second light transmitting substrate is glass having a thickness of 0.3 mm or less.