RU101971U1 - MULTILAYER PHOTOCHROME HEAT-SAVING POLYMER FILM - Google Patents

Abstract

 1. A multilayer photochromic polymer film containing a polymer substrate, a functional photosensitive photochromic layer and an infrared reflective layer located on the side of exposure to solar radiation, as well as an adhesive layer, characterized in that it contains an additional intermediate transparent polymer layer made between the adhesive layer and a photosensitive photochromic layer, which is placed on one side of the polymer substrate, and is deposited on an infrared reflective layer placed on the other side of the polymer substrate outer protective layer. ! 2. A multilayer photochromic polymer film containing a polymer substrate, a functional photosensitive photochromic layer and an infrared reflective layer located on the side of solar radiation, as well as an adhesive layer, characterized in that it contains an additional intermediate transparent polymer layer made between the adhesive layer and An infrared reflective layer, which is placed on one side of the polymer substrate, and is applied on a photosensitive photochromic layer, placed on the other side of the polymer substrate, on outer protective layer. ! 3. A multilayer photochromic polymer film containing a polymer substrate, a functional photosensitive photochromic layer and an infrared reflective layer located on the side of solar radiation, as well as an adhesive layer, characterized in that it contains an additional intermediate transparent polymer layer made between the photosensitive photochromic layer and an infrared reflective layer arranged sequentially on one side of the polymer substrate, and an outer protector

Description

The utility model relates to multifunctional multilayer polymer films, which include spectrally selective IR reflective layers and photosensitive organic photochromic layers deposited on a polymer substrate, as well as the possibility of combining them to create sun-protected heat-saving polymer film materials with variable (adaptive) light transmission in the visible spectral regions depending on the intensity of solar radiation for use in construction, automotive and aviation industry for glazing large light openings.

The most vulnerable part of buildings from the point of view of thermal insulation are windows - translucent enclosing structures. Their peculiarity is that they perform two opposite functions: on the one hand, they must pass a lot of light into the premises, providing a comfortable level of lighting indoors, in accordance with current standards, and on the other hand, they must protect from excessively bright sunlight, heat, cold, wind and rain.

The most pronounced trend in modern architecture is the widespread use of various translucent structures. However, almost continuous glazing of modern high-rise buildings leads to large energy consumption for air conditioning in the summer. In order to reduce the thermal effect of sunlight, tinted (bulk) glass, energy-saving glass with heat and reflective coatings deposited on its surface are widely used. However, the use of such glasses, in addition to reducing the heat load, leads to a significant reduction in indoor lighting and, as a result, a marked increase in electricity consumption for indoor lighting.

Currently, the urgent task in the field of glazing used in the construction industry and vehicles is the creation of windows that provide automatic reversible change in light transmission depending on the level of illumination. This problem can be solved in several ways, mainly using transparent photochromic or electrochromic materials. When using electrochromic materials while transmitting an electric current controlled by a photodiode, reversible changes in light transmission occur, that is, a source of electric current is required.

More promising is the use of photochromic materials, which are divided into organic and inorganic photochromic materials.

Inorganic photochromic materials have high light fastness, in addition, inorganic photochromic silicate glasses based on silver halides have a long service life. Photochromism in such glasses is due to the formation of the microcrystalline phase of silver halides, which occurs after heat treatment of the glass.

The disadvantages of photochromic silicate glasses based on photosensitive AgHa1 microcrystals are the great difficulties and the cost of producing large-sized glazings used in construction and in vehicles.

Known photochromic flexible material based on a polymer binder and photochromic glass particles introduced into the polymer binder layer in an amount of 10-40 wt.% [DE application No. 3308186, IPC B05D 5/06].

Known composite material based on AgBr and silicate-containing airgels [DE patent No. 3844003, IPC C09K 9/00, DE application No. 4129409, IPC C03B 8/02].

Known photochromic triplexes and duplexes based on nanoparticles of photochromic silicate glass, prepared in various ways and introduced into the adhesive layer, including a silane polymer binder [application JP No. 11174622, IPC G03C 1/73, application JP No. 200401323298, IPC C03C 17 / 34, Application US No. 2002114956, IPC B32V 9/00].

Known photochromic multilayer material based on CuHa1 and AgHa1 using polyvinyl butyral as a binder [application GB No. 1458771, IPC S09K 9/00].

Known photochromic triplexes made by photo - and thermopolymerization of acrylic monomers and oligomers, as well as by using amino-cured epoxy resin and containing particles of photochromic glass with a size of 0.05-0.1 mm. [application WO No. 20088058657, IPC C08F 2/00, application US No. 2008118650, IPC B05D 3/00].

Known photochromic triplex, consisting of two layers of transparent glass containing the inner and outer surfaces, which are interconnected by an intermediate layer, which is a polyvinyl butyral film comprising particles of photochromic glass, and the polyvinyl butyral film contains from 1 to 80 wt.% Particles of photochromic glass with a size of 0.05-0.3 mm, while on one of the outer surfaces of the glass is coated, reflecting infrared thermal radiation. [RU patent for utility model No. 80163, IPC С03С 27/12].

The disadvantage of all polymer compositions containing particles of inorganic photochromic silicate glasses is light scattering due to the difference in the refractive indices of the polymer film and the particles of photochromic glass, which cannot be completely eliminated. Moreover, due to the different temperature dependence of the refractive indices of the polymer film and silicate glass, the light scattering of the composite material will change with temperature, leading to a deterioration in the transparency of the material.

To increase the heat-reflecting ability of the window, special low-emission glasses and multilayer low-emission polymer films are used.

Known low-emission transparent coating with increased corrosion resistance, containing a transparent substrate and at least three layers on it, arranged in order: dielectric, metal, dielectric. The thickness of each dielectric layer is 10-60 nm, and the metal layer is 7-20 nm. Silver is used as the metal, and AI-Si eutectic nitride or oxynitride, obtained by magnetron sputtering of a target from the above alloy at constant current in an atmosphere of a mixture of argon and nitrogen in a single vacuum cycle, is used as a metal. [Patent RU No. 2132406, IPC С23С 14/06, ВВВ 17/06].

Known multilayer film with selective light transmission, containing a transparent organic substrate with a layer of copper or silver located on it, a thickness of 3-6 nm and a subsequent layer of dielectric. The dielectric layer is a two-component island structure in the form of a disordered mixture of chromium particles and chromium oxide with a thickness of 3-6 nm. [Patent RU No. 2043932, IPC B32B 15/08].

However, these known films do not contain a photochromic layer, which provides a change in light transmission depending on illumination, and only works as an infrared reflective film.

Known photochromic polymer material made in the form of a polymer matrix, which introduced black carbon particles (soot) that filter the solar radiation and absorb infrared radiation [Patent EP No. 0805363, IPC G02B 1/04]. This film does not reflect IR radiation, absorbs both in the visible and in the infrared wavelength range, as a result of which it is subjected to strong heating, leading to the destruction of the photochromic layer.

Closest to the proposed is the well-known multifunctional multilayer photochromic film containing a polymer substrate, a photosensitive photochromic layer, an infrared reflective layer located on the side of the light source and an adhesive layer for gluing to the surface, shown in Figure 1 [A.A. Dunaev, A.O.Ayt, V.A. Barachevsky "Multifunctional multilayer photochromic film." Nanotechnology. No. 1, 2006].

However, in this film, the infrared reflective layer (heat-reflecting coating) does not have protection against corrosion and abrasion, and the adhesive layer is directly applied to the photochromic layer and negatively affects it by diffusion of the components of the adhesive composition into the photochromic layer.

The specified film is a prototype of the claimed utility model.

The objective of the proposed utility model is the creation of durable and durable multifunctional heat-saving and photochromic sun-protection polymer films based on transparent heat-reflecting coatings and photosensitive photochromic layers that are resistant to external mechanical and atmospheric influences.

The problem is achieved due to the fact that in a multilayer photochromic polymer film containing a polymer substrate, a functional photosensitive photochromic layer and an infrared reflective layer located on the side of solar radiation, as well as the adhesive layer, contains an additional intermediate transparent polymer layer made between the adhesive a layer and a photosensitive photochromic layer, which are placed on one side of the polymer substrate, and on the infrared reflective layer, placed on the other side of the floor dimensional substrate coated outer protective layer.

In another embodiment, in a multilayer photochromic polymer film containing a polymer substrate, a functional photosensitive photochromic layer and an infrared reflective layer located on the side of solar radiation, as well as an adhesive layer, an additional intermediate transparent polymer layer is formed between the adhesive layer and the infrared reflective a layer that is placed on one side of the polymer substrate, and on the photosensitive photochromic layer placed on the other side of the polymer substrate is applied externally cured protective layer.

In another embodiment, a multilayer photochromic polymer film containing a polymer substrate, a functional photosensitive photochromic layer and an infrared reflective layer located on the side of solar radiation, as well as an adhesive layer, contain an additional intermediate transparent polymer layer made between the photosensitive photochromic layer and the infrared reflective a layer placed sequentially on one side of the polymer substrate, and the outer protective layer, which is applied to the infrared reflective layer, and the adhesive layer is placed on the other side of the polymer substrate.

The utility model is illustrated by drawings.

Figure 1 Prototype utility model.

Figure 2, Figure 3, Figure 4 options for the location of the layers in a multilayer photochromic polymer film.

Figure 1 shows the structure of the known multilayer photochromic polymer film, which contains a polymer substrate 1 made, for example, of polyethylene terephthalate (PET), a photochromic layer 2, an infrared reflective layer 3 located on the side of exposure to solar radiation and an adhesive layer 4, for gluing to the surface, for example, glass.

Figure 2. given the structure of the inventive multilayer photochromic polymer film, which contains a polymer substrate 1, a photochromic layer 2, an infrared reflective layer 3 located on the side of exposure to solar radiation and an adhesive layer 4, for gluing to the surface, for example, glass. The multilayer photochromic polymer film (MTPP) has an intermediate transparent polymer layer 5 located between the adhesive layer 4 and the photochromic layer 2. In addition, it is equipped with a protective layer 6, which is deposited on the infrared reflective layer 3. The introduction of an intermediate transparent polymer layer 5 eliminates the negative the effect of the adhesive layer on the photochromic layer by diffusing the components of the adhesive composition into the photochromic layer, and also protect the photochromic layer from oxygen diffusion into it. The introduction of an intermediate transparent polymer layer 5, made, for example, of a polymer based on polyvinyl vinyl alcohol, can significantly extend the functioning of the multilayer polymer photochromic film. The introduction of a protective layer 6, made, for example, of organosilicon polymer, allows you to protect the infrared reflective layer 3 from external mechanical and atmospheric influences, including exposure to weak acid and alkaline solutions. In addition, UV adsorbers can be introduced into the protective layer 6 to completely absorb UV radiation.

In figure 3. an embodiment of the structure of the inventive multilayer photochromic polymer film, which contains a polymer substrate 1, a photochromic layer 2, an infrared reflective layer 3 located on the side of exposure to solar radiation and an adhesive layer 4, for gluing to the surface, for example, glass, is given. The multilayer photochromic polymer film has an intermediate transparent polymer layer 5 located between the adhesive layer 4 and the IR reflective layer 3 and it is provided with a protective layer 6, which is deposited on the photochromic layer 2.

In this case, the adhesive layer 4 is applied to the intermediate transparent polymer layer 5 from the side of the infrared reflective layer 3. The photochromic layer 2 and the infrared reflective layer 3 are located on different sides of the polymer substrate 1, this arrangement eliminates the influence of the adhesive layer 4 on the infrared reflective layer layer 2. The remote location of the photochromic layer 2 relative to the glass inside the room creates additional protection for the photochromic layer 2 by shielding the solar radiation in front of the lying layers and significantly increasing the life of the ITF AP This arrangement of the photochromic layer 2 refers to a film intended for gluing to glass indoors. The protective layer 6 protects the photochromic layer 2 from external mechanical and atmospheric influences, including exposure to weak acid and alkaline solutions, and also protects the photochromic layer 2 from oxygen diffusion into it. In addition, UV adsorbers can be introduced into the intermediate layer 5 to completely absorb UV radiation.

Figure 4. an embodiment of the structure of the inventive multilayer photochromic polymer film, which contains a polymer substrate 1, a photochromic layer 2, an infrared reflective layer 3 located on the side of exposure to solar radiation and an adhesive layer 4, for gluing to the surface, for example, glass, is given. The adhesive layer 4 is deposited on the polymer substrate 1. The multilayer photochromic polymer film has an additional intermediate transparent polymer layer 5 located between the photochromic layer 2 and the infrared reflective layer 3 and a protective layer 6 that is deposited on the infrared reflective layer 3.

In this case, the photochromic layer 2, an additional intermediate transparent polymer layer 5, the IR reflecting layer 3 and the protective layer 6 are located on one side of the polymer substrate 1, and the adhesive layer 4 is located on the other side of the polymer substrate 1. This arrangement of the photochromic layers refers to the film designed for gluing on glass outside the room.

As a result of this arrangement of layers, greater efficiency is achieved both in the spectrally selective IR reflecting layer 3 and in the photochromic layer 2, which increases the energy-saving effect. An additional intermediate transparent polymer layer 5, located between the IR reflecting layer 3 and the photochromic layer 2, creates additional thermal protection between the layers and protects the photochromic layer 2 from oxygen diffusion into it. The protective layer 6 protects the photochromic layer 2 from external mechanical and atmospheric influences, including exposure to weak acid and alkaline solutions.

The proposed design of a multilayer photochromic polymer film is multifunctional, provides not only an automatic change in light transmission depending on the intensity of solar radiation, but also a reduction in energy costs through the use of IR reflective coating.

A multilayer photochromic polymer film is characterized by a constant reflection of infrared radiation up to 95%; reversible decrease in the intensity of visible light to 80%; a constant decrease in the intensity of UV radiation to 99%. The use of the adhesive layer allows it to be glued to the glazing, thereby ensuring its impact resistance and explosion safety. Putting this film into practice opens up new functional possibilities for glazing used in the construction industry and transport equipment.

Claims (3)

1. A multilayer photochromic polymer film containing a polymer substrate, a functional photosensitive photochromic layer and an infrared reflective layer located on the side of exposure to solar radiation, as well as an adhesive layer, characterized in that it contains an additional intermediate transparent polymer layer made between the adhesive layer and a photosensitive photochromic layer, which is placed on one side of the polymer substrate, and is deposited on an infrared reflective layer placed on the other side of the polymer substrate outer protective layer. 2. A multilayer photochromic polymer film containing a polymer substrate, a functional photosensitive photochromic layer and an infrared reflective layer located on the side of solar radiation, as well as an adhesive layer, characterized in that it contains an additional intermediate transparent polymer layer made between the adhesive layer and An infrared reflective layer, which is placed on one side of the polymer substrate, and is applied on a photosensitive photochromic layer, placed on the other side of the polymer substrate, on outer protective layer. 3. A multilayer photochromic polymer film containing a polymer substrate, a functional photosensitive photochromic layer and an infrared reflective layer located on the side of solar radiation, as well as an adhesive layer, characterized in that it contains an additional intermediate transparent polymer layer made between the photosensitive photochromic layer and an IR reflective layer arranged sequentially on one side of the polymer substrate, and an outer protective layer that is applied to the IR reflective layer, and an adhesive layer is placed on the other side of the polymer substrate.