KR20230115096A - Smart windows assembly - Google Patents

Abstract

The present invention is to provide a smart window assembly that variably controls light transmittance and applies thermal insulation with low emissivity. The smart window assembly of the present invention includes an outer glass exposed to the outside, a transmittance variable film attached to the inside of the outer glass as an outer adhesive layer, an inner glass attached to the inner side of the transmittance variable film as an inner adhesive layer, and the transmittance variable film It includes a low emissivity layer provided on at least one side of.

Description

Smart window assembly {SMART WINDOWS ASSEMBLY}

The present invention relates to a smart window assembly, and more particularly, to a smart window assembly applying heat shielding with variable light transmittance and low emissivity.

According to what is known, smart glass and film products can control transparency and light transmittance according to control of power. For example, smart glass and film products include Polymer Dispersed Liquid Crystal (PDLC), Polymer Network Liquid Crystal (PNLC), and Variable Polarized Liquid Crystal (VPLC). They can vary the light transmittance.

The PDLC film controls the scattering rate of light and is attached to windows of vehicles and buildings to block the view from the outside. The PDLC film exhibits an opaque state when voltage is not applied and a transparent state when voltage is applied, and is used for heat shielding and active privacy requirements.

The PNLC film has the same function as the PDLC, but exhibits a transparent state when voltage is not applied and an opaque state when voltage is applied, so it can be applied to mobility driving safety. The VPLC film controls the polarized light and adjusts the transmittance of light by adjusting the phase of the polymer. The VPLC film does not generate scattering due to its high brightness, and enables the user to finely adjust the light source linearly.

Window glass or roof glass of automobiles and window glass of buildings are required to protect privacy by varying the transmittance of light and to save energy by blocking heat. Also at this time, it is required to reduce the manufacturing cost.

One embodiment of the present invention is to provide a smart window assembly that variably controls light transmittance and applies heat shielding with low emissivity.

A smart window assembly according to an embodiment of the present invention includes an outer glass exposed to the outside, a transmittance variable film attached to the inside of the outer glass as an outer adhesive layer, and an inner glass attached to the inner adhesive layer on the inner side of the transmittance variable film, And a low emissivity layer provided on at least one surface of the variable transmittance film.

The outer glass and the inner glass may be formed of soda lime glass.

The outer adhesive layer and the inner adhesive layer may be formed of one of poly vinyl butyral (PVB), ethyl vinyl acetate (EVA), and liquid resin.

The low emissivity layer may be formed on an outer surface of the variable transmittance film.

The low emissivity layer may be directly formed on the outer surface of the variable transmittance film by sputtering.

The low-emissivity layer may be formed in a low-emissivity film structure on a transparent film, and the low-emissivity film may be attached to an outer surface of the variable transmittance film through a lamination method.

The low-emissivity film may form a single structure including a first metal oxide layer, the low-emissivity layer, and a second metal oxide layer sequentially deposited on the transparent film through a sputtering process.

The low emissivity film forms a double structure including a first low emissivity film and a second low emissivity film, the first low emissivity film is attached to the outer surface of the variable transmittance film through a first adhesive film, The second low emissivity film may be attached to the outer surface of the first low emissivity film through a second adhesive film.

The low emissivity layer may form a single structure including a first metal oxide layer, the low emissivity layer and the second metal oxide layer sequentially deposited on the outer surface of the variable transmittance film by a sputtering process.

The low emissivity layer forms a double structure including a first low emissivity layer, a second low emissivity layer, a first metal oxide layer, a second metal oxide layer, and a third metal oxide layer, wherein the first low emissivity layer It is formed on the first metal oxide layer formed on the outer surface of the variable transmittance film, the second low emissivity layer is formed on the second metal oxide layer formed on the outer surface of the first low emissivity layer, the third metal oxide layer may be formed on an outer surface of the second low emissivity layer.

The variable transmittance film is an active smart window film including one of a polymer dispersed liquid crystal (PDLC), a polymer network liquid crystal (PNLC), and a variable polarized liquid crystal (VPLC). can be

As such, one embodiment of the present invention can be effectively applied to window glass of automobiles or buildings because the transmission heat variable film variably controls light transmittance and blocks heat with low emissivity by the low emissivity layer. The smart window assembly of one embodiment can protect privacy by varying the transmittance of light and save energy by blocking heat.

In one embodiment, the low emissivity layer is applied to one side of the transmission heat variable film, the outer glass and the inner glass are formed of soda lime glass, and the outer adhesive layer and the inner adhesive layer are polyvinyl butyral (PVB; Poly vinyl butyral), ethyl Since it is formed of one of ethyl vinyl acetate (EVA) and liquid resin, manufacturing costs can be reduced.

1 is an exploded perspective view of a smart window assembly according to a first embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along line II-II of FIG. 1 .
3 is a cross-sectional view of a smart window assembly according to a second embodiment of the present invention.
Figure 4 is a cross-sectional view of the low emissivity film applied to Figure 3.
5 is a cross-sectional view of a smart window assembly according to a third embodiment of the present invention.
6 is a cross-sectional view of a smart window assembly according to a fourth embodiment of the present invention.
7 is a cross-sectional view of a smart window assembly according to a fifth embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein. In order to clearly describe the present invention in the drawings, parts irrelevant to the description are omitted, and the same reference numerals are assigned to the same or similar components throughout the specification.

1 is an exploded perspective view of a smart window assembly according to a first embodiment of the present invention, and FIG. 2 is a cross-sectional view taken along line II-II of FIG. 1 . 1 and 2, the smart window assembly 100 of the first embodiment includes an outer glass 10, a transmission heat variable film 30, an inner glass 20 and a low emissivity layer 41.

The smart window assembly 100 may be applied to window glass or roof glass of automobiles and window glass of buildings. The smart window assembly 100 is configured to protect privacy and save energy by blocking heat while varying light transmittance.

The out glass 10 is exposed to the outside of the space in which the smart window assembly 100 is installed. The inner glass 20 is exposed inside the space where the smart window assembly is installed. The transmission heat variable film 30 is provided and attached between the outer glass 10 and the inner glass 20 .

For example, an out adhesive layer 51 is provided on the inner surface of the outer glass 10 to attach the variable transmittance film 30 to the inner surface of the outer glass 10 . An inner adhesive layer 52 is provided on the inner surface of the variable transmittance film 30 to attach the inner glass 20 to the inner surface of the variable transmittance film 30 .

For example, the outer adhesive layer 51 and the inner adhesive layer 52 may be formed of one of polyvinyl butyral (PVB), ethyl vinyl acetate (EVA), and liquid resin. can

PVB laminated glass film is a macro molecular material made by condensation reaction of polyvinyl alcohol and butyraldehyde and has thermoplastic properties. PVB laminated glass film has strong acid and alkali resistance and excellent adhesion due to hydrogen bonding between plate glass and PVB film.

EVA laminated glass film can be used as an alternative to PVB laminated glass film, and is made of ethylene-based polymer resin. The EVA laminated glass film has excellent transparency, high tensile stress, and excellent adhesion, and in particular, its durability against humidity is superior to that of the PVB laminated glass film.

Resin used in laminated glass is a chemical single-component polymer that does not contain solvents or plastisizers. The resin material maintains the transparency of the laminated glass even after being cured by heat or ultraviolet rays. In addition, since the resin has a low reaction with moisture, it reduces delamination that occurs in laminated glass.

In addition, since the liquid resin fills the gap between glass even if there is warpage (curvature) of the original plate subjected to the tempering heat treatment, the lifting phenomenon between layers is reduced compared to the case of using a film. Resin is easy to control in thickness, allowing for custom-engineered configurations.

The low emissivity layer 41 may be provided on at least one surface of the variable transmittance film 30 . That is, as shown in FIG. 2 , the low emissivity layer 41 may be provided directly on the outer surface of the variable transmittance film 30 . The low emissivity layer 41 is formed of a reflective metal layer, and includes, for example, a silver-palladium-copper alloy (APC; Ag-Pd-Cu alloy).

The reflective metal layer may have a solar heat gain rate of 0.4 or less and a heat transmittance rate of 4 (W/m2K) or less. Solar Heat Gain Coefficient (SHGC) means the ratio of solar heat introduced into the interior to the total solar heat incident on the entire outer glass 10, and has a range of 0 to 1. The lower the value of the solar heat gain rate, the better the heat blocking effect. The solar heat gain rate of ordinary glass (3T clear glass) is 0.88.

Thermal transmittance (U-value) means the amount of heat passing in unit time from a higher temperature to a lower temperature through a unit area of a solid between different temperatures. The lower the value of the thermal transmittance, the better the thermal blocking effect. The thermal transmittance of ordinary glass (3T) is 5.9.

Low-E (LOW-EMISSIVITY) means blocking heat with low emissivity. Emissivity refers to the ratio of energy that an object radiates to the inside after absorbing external light energy. Theoretically, an object that absorbs external energy and radiates 100% to the inside and does not reflect to the surface is called a blackbody, and the emissivity value of a blackbody is defined as 1.

Silver coating, which is an example of a low-emissivity (Low-E) coating, lowers emissivity through a silver coating layer. Therefore, since the low emissivity layer 41 reflects external infrared energy from the outer surface, it absorbs the infrared energy and minimizes the amount of radiation to the inside.

That is, the low-emissivity layer 41 prevents energy inflow from the outside to the inside and energy outflow from the inside to the outside regardless of the season. In this way, the low emissivity layer 41 enhances thermal insulation performance. The low emissivity layer 41 may be directly formed on one surface of the variable transmittance film 30 by a sputtering method.

Since the outer glass 10 and the inner glass 20 are formed of soda lime glass, cost reduction and production yield improvement can be realized. The outer adhesive layer 51 and the inner adhesive layer 52 are formed of polyvinylbutyral (PVB), ethylvinylacetate (EVA), or liquid resin and have a transparent property, so that light is not blocked unnecessarily.

The transmittance variable film 30 is formed of an active smart window film including, Polymer Dispersed Liquid Crystal (PDLC), Polymer Network Liquid Crystal (PNLC), and Variable Polarized Liquid Crystal (VPLC). Liquid Crystal) can be formed as an active smart window film.

Meanwhile, the low emissivity layer 41 may be formed on a separate transparent film and attached to the smart window assembly 100 through lamination. In addition, the low emissivity layer may be formed in a single structure or a double structure on the outer surface of the variable transmittance film 30 .

For example, in the transmittance variable film 30 formed of PDLC, visible light transmittance is 3 to 81%, haze is 5% or less, energy transmittance is 8 to 84%, visible light reflectance is 4% or more, and energy reflectance is 3 % or higher (see Table 1). Since the transmittance variable film 30 controls the transmittance of visible light in a wide range, privacy is protected by blocking the external view.

division PDLC PDLC + single low emissivity layer smart window assembly Visible Light Transmittance (TL) 3-81% 2-43% 1 to 28% turbidity 5% or less 5% or less - Energy transmittance (TE) 8-84% 3-28% 1-8% Visible Light Reflectance (RL) 4% or more 4% or more 4% or more Energy reflectance (RE) 3% or more 42% or more 42% or more

In this way, in the transmittance variable film 30 and the single structure low emissivity layer 41 formed on one surface of the transmittance variable film 30, the visible light transmittance is 2 to 43%, the turbidity is 5% or less, and the energy transmittance is 3 to 43%. 28%, the visible light reflectance is set to 4% or more, and the energy reflectance is set to 42% or more (see Table 1). The variable transmittance film 30 and the low emissivity layer 41 form a high energy reflectance to increase thermal insulation performance.

The smart window assembly 100 further includes the outer glass 10, the outer adhesive film 51, the inner glass 20, and the inner adhesive film 52, so that the visible light transmittance is 1 to 28% and the energy transmittance is 1 ~8%, the visible light reflectance is set to 4% or more, and the energy reflectance is set to 42% or more (see Table 1).

Referring to Table 1, comparing before and after applying the low emissivity layer 41 to the variable transmittance film 30, it can be seen that visible light transmittance and energy transmittance are significantly reduced, and energy reflectance is remarkably increased. It can be seen that visible light transmittance and energy transmittance are further reduced in the smart window assembly 100 to which the transmittance variable film 30 and the low emissivity layer 41 are applied.

The smart window assembly 100 of the first embodiment controls the transmittance of visible light in a wide range with the variable transmittance film 30, thereby protecting privacy by blocking the external view, and the variable transmittance film 30 and the low emissivity layer 41 It is possible to increase the thermal insulation performance by forming a high energy reflectance.

In the smart window assembly 100 of the first embodiment, the variable transmittance film 30 uses a transparent plastic substrate to adjust the transmittance of light, so when applied to automobiles or buildings, the function for maximizing energy efficiency required by the market is does not exist. The low emissivity layer 41 implements maximization of energy efficiency without interfering with the control of transmittance.

Hereinafter, various embodiments of the present invention will be described. Compared to the first embodiment and the previously described embodiments, descriptions of the same configurations are omitted and descriptions of different configurations are described.

3 is a cross-sectional view of a smart window assembly according to a second embodiment of the present invention, and FIG. 4 is a cross-sectional view of a low emissivity film applied to FIG. 3 . Referring to FIG. 3, in the smart window assembly 200 of the second embodiment, the low emissivity layer 41 is formed of a low emissivity film 410 structure using a transparent film 413. The smart window assembly 200 forms a single structure by attaching the low emissivity film 410 to the outer surface of the variable transmittance film 30 through an adhesive film 61 as one layer.

Referring to FIG. 4 , the low emissivity film 410 sequentially includes a first metal oxide layer 411 , a low emissivity layer 41 , and a second metal oxide layer 412 on a transparent film 413 . The first metal oxide layer 411 is deposited and formed on the transparent film 413 by a sputtering process, and the low emissivity layer 41 is deposited and formed on the first metal oxide layer 411, and the low emissivity layer 41 ), the second metal oxide layer 412 may be formed by deposition.

In the reflective metal layer, the low emissivity layer 41 lowers the solar heat gain rate to 0.4 or less and the thermal transmittance to 4 (W/m2K) or less. The first metal oxide layer 411 enables the low emissivity layer 41 to be formed on the transparent film 413 and protects one surface of the low emissivity layer 41, and the second metal oxide layer 412 is a low emissivity layer ( 41) to protect the other side.

The adhesive film 61 may be formed of a double-sided adhesive film (eg, PSA; Pressure Sensitive Adhesive, OCA; Optical Clear Adhesive). The adhesive film 61 may be laminated to the variable transmittance film 30 and the low emissivity film 410 may be attached to the adhesive film 61 through lamination.

An out adhesive layer 51 is provided on the inner surface of the outer glass 10 to attach the low emissivity film 410 having a single structure to the inner surface of the outer glass 10 . An inner adhesive layer 52 is provided on the inner surface of the variable transmittance film 30 having a single structure, and the inner glass 20 is attached to the inner surface of the variable transmittance film 30 .

The low emissivity film 410 uses the variable transmittance film 30 and a separate transparent film 413, forms the low emissivity layer 41 on the transparent film 413, and attaches it to the variable transmittance film 30 through lamination. do. Therefore, the low emissivity film 410 facilitates the formation and handling of the low emissivity layer 41 .

5 is a cross-sectional view of a smart window assembly according to a third embodiment of the present invention. Referring to Figure 5, the smart window assembly 300 of the third embodiment is a two-layer low-emissivity film (420; 421, 422) with an adhesive film (61; 611, 612) interposed on the outer surface of the variable transmittance film (30). attached to form a double structure.

The smart window assembly 300 attaches the first low emissivity film 420 to the outer surface of the variable transmittance film 30 via the first adhesive film 611, and attaches the first low emissivity film 420 to the outer surface of the first low emissivity film 421. A double structure is formed by attaching the second low emissivity film 422 through the two adhesive films 612 .

The first adhesive film 611 is laminated on the outer surface of the variable transmittance film 30, the first low emissivity film 421 is attached to the outer surface of the first adhesive film 611 through lamination, and the second adhesive film 612 ) may be laminated on the outer surface of the first low emissivity film 421, and the second low emissivity film 422 may be attached to the outer surface of the second adhesive film 612 through lamination.

An out adhesive layer 51 is provided on the inner surface of the outer glass 10 to attach the second low emissivity film 422 having a double structure to the inner surface of the outer glass 10 . An inner adhesive layer 52 is provided on the inner surface of the double structure variable transmittance film 30 to attach the inner glass 20 to the inner surface of the variable transmittance film 30 .

The first and second low emissivity films 421 and 422 may further increase the effect of blocking heat with respect to light transmittance by the variable transmittance film 30 . That is, visible light transmittance and energy transmittance are reduced in the double compared to the single.

6 is a cross-sectional view of a smart window assembly according to a fourth embodiment of the present invention. Referring to FIG. 6, the smart window assembly 400 of the fourth embodiment includes a first metal oxide layer 411, a low emissivity layer 41 and a second metal oxide layer 412 on the outer surface of the variable transmittance film 30. To form a single structure.

The first metal oxide layer 411 is deposited and formed on the transparent film 413 by a sputtering process, and the low emissivity layer 41 is deposited and formed on the first metal oxide layer 411, and the low emissivity layer 41 ), the second metal oxide layer 412 may be formed by deposition.

An out adhesive layer 51 is provided on the inner surface of the outer glass 10 to attach the second metal oxide layer 412 having a sputtering single structure to the inner surface of the outer glass 10 . An inner adhesive layer 52 is provided on the inner surface of the transmittance variable film 30 of the sputtering single structure, and the inner glass 20 is attached to the inner surface of the transmittance variable film 30 .

7 is a cross-sectional view of a smart window assembly according to a fifth embodiment of the present invention. Referring to FIG. 7, the smart window assembly 500 of the fifth embodiment includes a first metal oxide layer 411, a low emissivity layer 41, and a second metal oxide layer 412 on the outer surface of the variable transmittance film 30. , The second low emissivity layer 42 and the third metal oxide layer 414 are provided to form a double structure.

The first metal oxide layer 411 is deposited and formed on the transparent film 413 by a sputtering process, and the low emissivity layer 41 is deposited and formed on the first metal oxide layer 411, and the low emissivity layer 41 ), a second metal oxide layer 412 is deposited on the second metal oxide layer 412, a second low emissivity layer 42 is deposited on the second metal oxide layer 412, and a third metal oxide layer is formed on the second emissivity layer 42. (414) may be deposited.

An out adhesive layer 51 is provided on the inner surface of the outer glass 10 to attach the second low emissivity film 422 having a sputtering double structure to the inner surface of the outer glass 10 . An inner adhesive layer 52 is provided on the inner surface of the transmittance variable film 30 of the sputtering double structure, and the inner glass 20 is attached to the inner surface of the transmittance variable film 30 .

In the variable transmittance film 30 and the low emissivity layer 41 and the second low emissivity layer 42 having a double structure formed on one surface of the variable transmittance film 30, the visible light transmittance is 1 to 28% and the turbidity is 5% or less. , the energy transmittance is set to 1 to 8%, the visible light reflectance to 4% or more, and the energy reflectance to 42% or more (see Table 2).

division PDLC PDLC + double low emissivity layer Visible Light Transmittance (TL) 3-81% 1-28% turbidity 5% or less 5% or less Energy transmittance (TE) 8-84% 1-8% Visible Light Reflectance (RL) 4% or more 4% or more Energy reflectance (RE) 3% or more 42% or more

Although not separately shown, the smart window assembly (schematic structure is the same as that of FIG. 3) may form a variable transmittance film in an opaque black type when no voltage is applied. The white type transmittance variable film forms an opaque state when a voltage is applied.

In this case, in the transmittance variable film and the double low emissivity layer formed on both sides of the transmittance variable film, the visible light transmittance is 0 to 1%, the turbidity is 5% or less, the energy transmittance is 1 to 8%, the visible light reflectance is 4% or more, and The energy reflectance is set to 42% or more (see Fig. 3).

The low emissivity layer 41 of the double structure, the second low emissivity layer 42, and the black PDLC have a visible light transmittance of 0 to 1% in a voltage unapplied state, and the low emissivity layer 41 of the double structure, the second low emissivity layer ( 42) and the visible light transmittance of PDLC in the non-applied state of 1 to 28%, and the rest is the same.

From Table 2, it can be seen that the visible light transmittance and the energy transmittance are significantly reduced in the smart window assembly to which the double-structured low-emissivity layer is applied compared to the single-structured low-emissivity layer, and, conversely, the energy reflectance is reduced.

division PDLC + double low emissivity layer Black PDLC + double low emissivity layer Visible Light Transmittance (TL) 1-28% 0-1% turbidity 5% or less 5% or less Energy transmittance (TE) 1-8% 1-8% Visible Light Reflectance (RL) 4% or more 4% or more Energy reflectance (RE) 42% or more 42% or more

In Table 2, in the smart window assembly to which the low-emissivity layer of the double structure is applied, the transmittance of visible light is opposite according to the white type or black type of the transmittance variable film, and the visible light reflectance, energy transmittance, and energy reflectance are the same. . Therefore, both types can be used appropriately.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and it is possible to carry out various modifications within the scope of the claims and the detailed description of the invention and the accompanying drawings, and this is also the present invention. It goes without saying that it falls within the scope of the invention.

10: Out glass 20: Inner glass
30: transmission heat variable film 41: low emissivity layer
42: second low emissivity layer 51: out adhesive layer
52: inner adhesive layer 61: adhesive film
100, 200, 300, 400, 500: smart window assembly
410: low emissivity film 420: low emissivity film
411: first metal oxide layer 412: second metal oxide layer
413: transparent film 414: third metal oxide layer
421: first low emissivity film 422: second low emissivity film
611: first adhesive film 612: second adhesive film

Claims (11)

Out glass exposed to the outside;
Transmittance variable film attached to the inside of the outer glass as an out adhesive layer;
An inner glass attached to the inside of the variable transmittance film as an inner adhesive layer; and
Smart window assembly comprising a low emissivity layer provided on at least one surface of the variable transmittance film. According to claim 1,
The outer glass and the inner glass are formed of soda lime glass. According to claim 1,
The outer adhesive layer and the inner adhesive layer
A smart window assembly formed of one of polyvinyl butyral (PVB), ethyl vinyl acetate (EVA), and liquid resin. According to claim 1,
The low emissivity layer is a smart window assembly formed on the outer surface of the variable transmittance film. According to claim 4,
The low-emissivity layer is a smart window assembly formed directly on the outer surface of the variable transmittance film by sputtering. According to claim 4,
The low emissivity layer is formed in a low emissivity film structure on a transparent film,
The low-emissivity film is a smart window assembly attached to the outer surface of the variable transmittance film by a lamination method. According to claim 6,
The low-emissivity film is a smart window assembly forming a single structure including a first metal oxide layer, the low-emissivity layer and a second metal oxide layer sequentially deposited on the transparent film by a sputtering process. According to claim 6,
The low emissivity film forms a double structure including a first low emissivity film and a second low emissivity film,
The first low emissivity film is attached to the outer surface of the variable transmittance film through a first adhesive film,
The second low emissivity film is a smart window assembly attached to the outer surface of the first low emissivity film through a second adhesive film. According to claim 5,
The low emissivity layer is a smart window assembly forming a single structure including a first metal oxide layer, the low emissivity layer and the second metal oxide layer sequentially deposited by a sputtering process on the outer surface of the variable transmittance film. According to claim 9,
The low emissivity layer forms a double structure including a first low emissivity layer, a second low emissivity layer, a first metal oxide layer, a second metal oxide layer, and a third metal oxide layer,
The first low emissivity layer is formed on the first metal oxide layer formed on the outer surface of the variable transmittance film,
The second low emissivity layer is formed on a second metal oxide layer formed on an outer surface of the first low emissivity layer,
The third metal oxide layer is a smart window assembly formed on an outer surface of the second low emissivity layer. According to claim 1,
The transmittance variable film is
A smart window assembly that is one of Polymer Dispersed Liquid Crystal (PDLC), Polymer Network Liquid Crystal (PNLC) and Variable Polarized Liquid Crystal (VPLC).