JP6767661B2 - Gray tones low emissivity glass - Google Patents

Description

The present invention relates to a low-emissivity glass having a grayish appearance visually, and particularly to a gray-colored low-emissivity glass having one Ag layer.

In recent years, windowpanes using low-emissivity glass on which a low-radioactive laminated film (hereinafter, also referred to as a low-emissivity film) is formed have become widespread for the purpose of improving cooling and heating efficiency. This low-emissivity glass takes in visible light into the room and satisfies the daylighting required for the window glass, while the low-emissivity film reflects light in the near-infrared region to the infrared region. The temperature rise can be suppressed. In addition, since it blocks the transfer of heat from the room to the outside, it has a high ability to keep the room warm and insulate.

The above low emissivity film is usually a laminate of an Ag layer and a dielectric layer, but by setting the thickness of each layer and the ratio of the thickness within a specific range, the transmitted color, the reflected color, etc. Can be desired. Taking advantage of the above-mentioned color characteristics of the low-emission film, low-emission glass having clear (almost colorless) or low-saturation transparent colors such as blue, green and yellow, and reflective colors such as blue and green It was used. Further, as a glass for which a sense of unity with the wall surface is desired, a low-emission glass having a transmissive color with suppressed saturation and lightness, and a reflectance and a reflective color that are not overstated is also required.

As a method for obtaining a desired transmitted color or reflected color of low-emissivity glass, a method using a light absorbing layer that absorbs visible light has been proposed in addition to setting the film thickness and ratio of each layer within a specific range as described above. There is. For example, Patent Document 1 describes low-radiation glass in which a low-radiation layer such as Ag, an alloy of Ni, Cr, Ni and Cr, a light-absorbing metal layer such as Ti, a silicon nitride layer, and a dielectric layer are laminated in this order. Proposed. The document describes that the light absorbing metal layer absorbs visible light to a certain extent so that the low emissivity glass has a predetermined color.

Further, Patent Document 2 proposes a low-emissivity glass in which two Ag layers are used and an absorption layer is provided on the Ag layer. According to the document, it is possible to control the transmitted color of glass by appropriately selecting an absorbent material, and to make the transmitted color a neutral color. Further, in the embodiment, it is disclosed that the transparent color is gray and can be adjusted from green to blue.

Further, although the relationship between the absorption layer and the color is not clearly stated, for example, Patent Document 3 discloses a low-emissivity glass in which a high absorption main layer such as Ti is provided on the substrate side of the Ag layer. The document describes that the transmitted color is blue or blue-green and the reflected color is blue-green.

Special Table 2015-526369 Special Table 2008-540320 Special Table 2005-523869

As mentioned above, in recent years, there has been an increasing demand for improving the appearance quality of buildings. Specifically, there is a demand for architectural windowpanes that have a greater sense of unity with the wall surface, and there is a demand for low-emissivity glass that has a grayish appearance visually.

In order for the visual appearance to have a gray color tone, it is common to use low-emission glass in which the visible light transmittance is kept low and the transmitted color is gray. On the other hand, since the transmitted color and the reflected color are combined and visually recognized by the human eye, it is known that the impression of the color actually seen by the eye is greatly affected by the reflected color. Here, conventionally, low-emission glass having a clear color tone or a silver color tone is known as one that does not seem to exhibit a specific color when visually viewed, and usually has a visible light transmittance of 75 to 5. A color tone of about 80% is called a clear color tone, a color tone having a visible light transmittance of about 70%, and a color tone having a visible light reflectance of about 20% are called a silver color tone. In the case of the above-mentioned clear color tone or silver color tone, the reflected color is often pale blue in order to prevent the human eye from seeing the color tone.

When the present inventor examined a low-emissivity glass that visually exhibits a gray color tone, the use of a low-emissivity film having one Ag layer among the low-emissivity glasses suppresses the color tone as compared with the case of using two layers. It was found that it exhibited a gray color tone. Therefore, if we proceed with the study using a low-emission film with one Ag layer, the visible light transmittance may be kept low and the low-emission glass with a gray transmitted color may make it easier to see the reflected color strongly. I found out that there is.

Therefore, an object of the present invention is to obtain a gray-colored low-emissivity glass capable of suppressing the tint of the reflected color in the low-emissivity glass having a gray-colored appearance visually.

As a result of diligent studies by the present inventors on the above problems, it was found that a low-emissivity glass having a reflected color of neutral to blue can obtain a good gray color tone with suppressed tint. Therefore, in order to achieve the above-mentioned transmitted color and reflected color, further studies were carried out, and it was found that a light absorbing layer that absorbs visible light was provided at a specific position of the low radiation film using one Ag layer. It was found that it is possible to reduce the visible light transmittance to 65% or less and make the transmitted color gray. On the other hand, if the light absorption layer is provided at a specific position, the transmitted color may be gray but a pale color may be exhibited, or the reflected color may be mixed with red to give an appearance. A new problem was found that was unfavorable. Further examination of this problem revealed that by setting each layer of the low emissivity film within a specific film thickness range, the above-mentioned problem of tint can be suppressed and the reflected color can be set to neutral to blue. It was.

That is, according to the present invention, in a gray-colored low-radiation glass in which a low-radiating film having one Ag layer is formed on the glass plate surface and the transmitted color exhibits a gray-colored tone, the low-radiating film is sequentially applied from the glass plate surface. A first dielectric layer, an Ag layer, a second dielectric layer, a light absorbing layer, and a third dielectric layer are laminated, and the optical film thickness of the first dielectric layer is 45 to 80 nm. The physical film thickness of the Ag layer is 7 to 10 nm, the total optical film thickness of the second dielectric layer and the third dielectric layer is 75 to 110 nm, and the second dielectric layer and the third dielectric layer. It is a gray-colored low-emission glass characterized in that the film thickness of the second dielectric layer is 18 to 55% with respect to the total value of the film thickness.

Further, the light absorption layer may have at least one selected from the group consisting of Ti, NiCr, Nb, and stainless steel.

Further, the light absorption layer may have Ti, and the physical film thickness of the light absorption layer may be 3 to 8 nm.

Further, the Ag layer may have a barrier layer directly above it.

Further, the visible light transmittance of the gray color low emissivity glass may be 55 to 65%.

Further, the gray-colored low-emissivity glass and the glass plate may be integrated with each other via a hollow layer to form double glazing.

INDUSTRIAL APPLICABILITY According to the present invention, it is possible to obtain a gray color tone low radiation glass capable of suppressing the tint of a reflected color in a low radiation color glass having a gray color tone visually, which contributes to improvement of the appearance quality of a building. Can be provided.

It is sectional drawing which shows one Embodiment of the low emissivity glass of this invention. It is a figure which plotted a ^* and b ^* of transmitted light of an Example and a comparative example. It is a figure which plotted a ^* and b ^* of the reflected light of the film surface reflection of an Example and a comparative example. It is a figure which plotted a ^* and b ^* of the reflected light of the glass surface reflection of an Example and a comparative example.

1: Explanation of terms

(optical properties)
In the present specification, the following various optical characteristics are all measured using a self-recording spectrophotometer (manufactured by Hitachi, Ltd., U-4000).

(Visible light transmittance, visible light reflectance)
The "visible light transmittance" and "visible light reflectance" (hereinafter, also referred to as "reflectance") in the present specification conform to JIS R3106 (1998) when the thickness of the glass plate is 3 mm. Calculated by the method.

(Gray color)
As used herein, the term "gray color" refers to the appearance of a visual appearance being gray. However, since it is difficult to concretely quantify the result of visual observation, in the present specification, the following "optical characteristics of transmitted light" and "optical characteristics of reflected light" fall within predetermined values. Was set to "gray color tone".

(Optical characteristics of transmitted light)
In the gray color tone in the present specification, the visible light transmittance of the transmitted light is 65% or less, and the transmitted color is gray. The "gray color" of transmitted light is a CIE L ^* a ^* b ^* chromaticity coordinate diagram of the transmitted color of low-emission glass calculated in accordance with JIS Z8781-4 when the thickness of the glass plate is 3 mm. It is assumed that a ^* is within the range of -4 or more and 0 or less, and b ^* is within the range of -4 or more and 1 or less. Further, the visible light transmittance may be preferably 55 to 65%, a ^* may be -3 or more and 0 or less, and b ^* may be -3 or more and 0 or less.

(Optical characteristics of reflected light)
The visible light reflectance of the reflected light for obtaining the gray color tone in the present specification is less than 20%, and the reflected color is neutral to blue. In addition, the reflected light is reflected on the glass plate surface side, which is a non-deposited surface (hereinafter, may be referred to as "glass surface reflection") and reflection on the low emission film surface side (hereinafter, referred to as "film surface reflection"). Both are evaluated, and in the gray tone of the present specification, both the reflection color of the glass surface reflection and the film surface reflection are neutral to blue. The above "neutral to blue" means each reflected color calculated in accordance with JIS Z8781-4 when the thickness of the glass plate is 3 mm, and is represented by a CIE L ^* a ^* b ^* chromaticity coordinate diagram. In terms of values, a ^* is -5 or more and 0 or less, and b ^* is -20 or more and 0 or less. Preferably, in the glass surface reflection ^{a *} is -3, 0 or less, and ^{b *} is -10 or more, -5 or less, the film surface reflection ^{a *} -4 or more, 0 or less, and ^{b *} - It may be in the range of 15 or more and -5 or less.

(Physical film thickness)
The physical film thickness has the same meaning as a generally used film thickness, and is simply the thickness of a thin film. In the present specification, the film formation rate at the time of producing the single layer film is determined from the product of the film thickness of the single layer film produced under the same film formation conditions as at the time of producing the low radiation film and the transport speed of the base material. It is a value obtained and calculated the film thickness of the corresponding layer of the low radiation film using the film formation rate.

(Optical film thickness)
The optical film thickness is a value represented by the product of the physical film thickness and the refractive index. In the present specification, the refractive index at a wavelength of 550 nm of a single-layer film produced under the same film formation conditions as when producing a low-emission film. It is a value calculated from the product of the film thickness. The refractive index in the present invention was calculated by measuring the transmittance and reflectance of the monolayer film and using the obtained values by an optical simulation (Reflectance-transmitance method).

(Description of membrane)
In the present specification, "ZnAl" refers to a film in which Zn is mixed with Al, and does not mean that Zn and Al are mixed at a ratio of 1: 1. The Al content is appropriately selected, but may be, for example, 1 to 10 wt%. Further, the film in which ZnAl is oxidized is described as "ZnAlO", but this also does not indicate that Zn: Al: O is 1: 1: 1.

Further, "NiCr" indicates an alloy film mainly containing Ni and Cr, and does not indicate that Ni and Cr are mixed at a ratio of 1: 1. The content of the above components may be appropriately selected, and for example, the Ni content may be 55 to 85 wt% and the Cr content may be 10 to 25 wt%. It may also contain other elements such as Fe.

Further, "stainless steel" particularly refers to a mixture of Fe, Cr, and Ni, and may be hereinafter referred to as "SUS". The contents of the above three components may be appropriately selected, and for example, Fe may be contained in an amount of 50 to 80 wt%, Cr may be contained in an amount of 10 to 25 wt%, and Ni may be contained in an amount of 0 to 20 wt%. It may also contain other elements such as Mn and Mo.

Further, "ZnSn" indicates a film in which Zn is mixed with Sn, and does not mean that Zn and Sn are mixed at a ratio of 1: 1. The Sn content is appropriately selected, but may be, for example, 30 to 70 wt%. Further, the film in which ZnSn is oxidized is described as "ZnSnO", but this also does not indicate that Zn: Sn: O is 1: 1: 1.

(Light absorption layer)
The "light absorption layer" in the present specification is a layer having a visible light absorption rate of 20 to 30% of the light absorption layer single layer. Usually, in the case of low emissivity glass as in the present invention, it is not easy to measure the optical characteristics of only a specific layer in the low emissivity film. Therefore, in the present specification, the visible light absorption rate calculated by the following method is used. It was defined as "visible light absorption rate of a single layer of light absorption layer".

First, a glass plate / a light absorption layer / an arbitrary dielectric layer was formed in this order on a soda lime glass plate having a thickness of 3 mm, and the visible light absorption rate A was calculated by a method according to JIS R3106 (1998). Next, a glass plate similar to the above and an arbitrary dielectric layer were formed on the glass plate in the order of the glass plate / the arbitrary dielectric layer, and the visible light absorption rate B was calculated. Next, the visible light absorption rate A-visible light absorption rate B was calculated, and the obtained value was used as the visible light absorption rate of the light absorption layer.

The light absorption layer is of the same type and film thickness as the low emissivity film to be produced. Further, as the arbitrary dielectric layer formed on the light absorption layer, the same type and the same film thickness as the dielectric layer formed on the light absorption layer may be used in the low emissivity film to be produced. As a result of studies by the present inventors, it was found that even if the film thickness of the dielectric layer formed on the light absorption layer changes, the visible light absorption rate of the light absorption layer does not change significantly. This is because the light absorption layer is oxidized or acid nitrided from the surface side at the initial stage when the dielectric layer is formed on the light absorption layer, but after the dielectric layer is formed to some extent, the light absorption layer is formed. It is considered that this is because the oxidation and oxynitride of the material do not proceed further in the film thickness direction.

2: Each configuration of low-radiation glass In the present invention, in a gray-colored low-radiation glass in which a low-radiating film having one Ag layer is formed on the surface of a glass plate and the transmitted color exhibits a gray tone, the low-radiating film is formed. , The first dielectric layer, the Ag layer, the second dielectric layer, the light absorption layer, and the third dielectric layer are laminated in this order from the surface of the glass plate, and the optical film of the first dielectric layer. The thickness is 45 to 80 nm, the physical film thickness of the Ag layer is 7 to 10 nm, the total optical film thickness of the second dielectric layer and the third dielectric layer is 75 to 110 nm, and the second dielectric layer. It is a gray-colored low-emission glass characterized in that the thickness of the second dielectric layer is 18 to 55% with respect to the total thickness of the third dielectric layer.

One of the preferred embodiments of the present invention is shown in FIG. Each configuration will be described below.

(Glass plate G)
The glass plate G to be used is not particularly limited, but for example, commonly used soda lime glass, non-alkali glass, highly transparent glass, wind-cooled reinforced glass, chemically reinforced glass, wire-reinforced glass, and wire-reinforced glass. , Bosilicate glass, low expansion glass, zero expansion glass, low expansion crystallized glass, zero expansion crystallized glass and the like can be used.

In addition to the above glass plate G, a transparent substrate such as a resin may be used, and examples thereof include polyethylene terephthalate resin, polyethylene naphthalate resin, polyether sulfone resin, polycarbonate resin, and polyvinyl chloride resin.

The thickness of the glass plate G is not particularly limited, but may be 3 to 19 mm, which is generally used as a window glass for construction.

(Dielectric layer)
The dielectric layers 11, 12, and 13 may be transparent thin films of oxides, nitrides, or oxynitrides containing at least one selected from the group consisting of Al, Si, Ti, Zn, In, and Sn. preferable. The first layer 11, the second layer 12, and the third layer 13 of the dielectric layer adjust the reflection color and the transmission color of the low emissivity film, and are desired by setting each film thickness within a specific range. It is possible to obtain low emissivity glass. Further, each layer may be a laminated layer of two or more types of films.

(First Dielectric Layer 11)
The first dielectric layer 11 is a layer formed between the glass plate G and the Ag layer 2, and has an optical film thickness of 45 to 80 nm. If it is less than 45 nm, the reflectance on the glass surface side may become too high, or the bluish tint of the reflected color on the film surface side may become too strong, and if it exceeds 80 nm, the reflected color becomes reddish. Preferably, the lower limit value may be 60 nm or more and the upper limit value may be 80 nm or less. Further, it is preferable to use a film having a zinc oxide structure as the first dielectric layer 11 and to form the Ag layer 2 directly above the film because the crystallinity of the Ag layer 2 is improved.

(2nd Dielectric Layer 12, 3rd Dielectric Layer 13)
The second dielectric layer 12 and the third dielectric layer 13 are layers formed on the Ag layer 2, and are light absorbing layers between the second dielectric layer 12 and the third dielectric layer 13. By forming 4, the transparent color can be gray. Further, by setting the total value of the optical film thicknesses of the second dielectric layer 12 and the third dielectric layer 13 and the ratio of the film thickness of the second dielectric layer to the total value within a specific range, it is desired. It became possible to obtain a reflected color.

In the present invention, the total optical film thickness of the second dielectric layer 12 and the third dielectric layer 13 is 75 to 110 nm. If it is less than 75 nm, the reflected color may be reddish, and when viewed from an angle, the reflected color tends to be strongly reddish. On the other hand, if it exceeds 110 nm, the transmitted color may be yellowish or the reflectance on the glass surface side may become too high, resulting in an unfavorable appearance. Preferably, the lower limit value may be 80 nm or more and the upper limit value may be 100 nm or less. Further, in the present invention, the film thickness of the second dielectric layer 12 is 18 to 55% of the total film thickness of the second dielectric layer 12 and the third dielectric layer 13. If it is less than 18% or more than 55%, the reflected color on the film surface side or the glass surface side may be reddish. Preferably, the lower limit value may be 20% or more and the upper limit value may be 45% or less.

Further, it is preferable to use a material having excellent moisture resistance and physical / chemical durability for the third dielectric layer 13. Among them, it is preferable to arrange a layer having physical and chemical durability in the layer of the dielectric layer 13 farthest from the glass plate G (hereinafter, may be referred to as “top layer”). For example, it is preferable to use a laminated structure of a ZnSnO layer having excellent moisture resistance and TiO ₂ having excellent physical and chemical durability.

(Ag layer 2)
The Ag layer 2 is a layer having a function of reflecting infrared rays, and the Ag layer 2 is one layer in the present invention. The Ag layer 2 is an Ag film or an Ag alloy film containing Ag as a main component. The Ag alloy film may contain metals such as palladium, gold, platinum, nickel, and copper in a range of 5 wt% or less.

In the present invention, the physical film thickness of the Ag layer 2 is 7 to 10 nm. If it is less than 7 nm, the film thickness may become too thin, and the film quality may be deteriorated, the film may be discontinuous, or the infrared reflection performance may be insufficient. Further, if it exceeds 10 nm, the reflected color may strongly exhibit a reddish or bluish tint.

(Barrier layer 3)
Generally, the barrier layer is formed directly above the Ag layer, and when a dielectric layer or the like is formed on the upper layer, the Ag layer is prevented from being deteriorated by a reactive gas such as oxygen gas. Is. Usually, a metal film or an alloy film is used as the barrier layer so as not to deteriorate the Ag layer at the time of formation. Many metal films and alloy films absorb visible light, but if another dielectric layer is formed directly above the barrier layer, it will be oxidized or oxynitride due to the gas containing oxygen and nitrogen used at this time. , It is possible to reduce the amount of visible light absorbed. Therefore, in general, ZnAl, Ti, NiCr, Nb, stainless steel, etc. are formed on the Ag layer and sufficiently oxidized or oxynitrided in the subsequent step of forming the dielectric layer to maximize the visible light absorption rate. A smaller layer is used.

Also in the present invention, it is preferable to use the barrier layer as described above. When used, the barrier layer 3 is formed directly above the Ag layer 2. Further, as a result of studies by the present inventors, if the barrier layer 3 absorbs a large amount of visible light, the transmitted color does not become gray or the reflected color strongly exhibits a tint, which is desired. It turned out that it does not become low-emission glass. Therefore, it is desirable that the barrier layer 3 does not absorb visible light as much as possible after forming all the layers of the low emissivity film. When forming the layer directly above the Ag layer 2, if a gas that deteriorates the Ag layer 2 is not used, the barrier layer 3 may not be used.

As the barrier layer 3 to be used, a film generally used as described above may be used. The film thickness that can be sufficiently oxidized or nitrided varies depending on the type of film used and the film forming conditions. For example, ZnAl is 1.5 to 3.5 nm, Ti is 1.0 to 2.5 nm, and NiCr is 1. 0 to 2.0 nm, Nb may be 1.0 to 2.0 nm, and stainless steel may be 1.5 to 2.5 nm.

(Light absorption layer 4)
The light absorption layer 4 is a layer formed between the second dielectric layer 12 and the third dielectric layer 13. In the present invention, by forming the light absorption layer 4 between the second dielectric layer 12 and the third dielectric layer 13, the visible light transmittance of transmitted light is 65% or less, and the transmitted color is gray. It is possible to do.

As the light absorption layer 4 in the present specification, a layer having a visible light absorption rate of 20 to 30% in a single layer obtained by the above-mentioned measurement method was used. Further, the film may have a higher visible light absorption rate than the barrier layer 3. In this specification, the visible light absorption rate of the light absorption layer 4 is calculated as described above, but the measurement of the visible light absorption rate does not necessarily have to be the present method.

As the light absorption layer 4, it is preferable to use a material having an extinction coefficient of 1 or more in the visible region. Further, it is more preferable to use a metal film or an alloy film as in the barrier layer 3 described above, and it may have at least one selected from the group consisting of, for example, Ti, NiCr, Nb, and stainless steel. When a dielectric layer (for example, a third dielectric layer 13 or the like) is formed on the upper layer of the light absorption layer 4, the surface of the light absorption layer 4 is oxidized by using a gas containing oxygen or nitrogen. It is oxynitride and the visible light transmittance increases. Therefore, it is desirable to increase the film thickness of the light absorption layer 4 so that it is not completely oxidized or nitrided. The suitable film thickness may be appropriately selected depending on the type of film to be used. For example, the film thickness may exceed the barrier layer 3 described above. For example, the light absorption layer 4 has Ti, and the light absorption layer 4 has Ti. The physical film thickness of the absorption layer 4 is preferably 3 to 8 nm.

(Low emissivity membrane)
It is desirable that the obtained low emissivity film is formed so as to have the first dielectric layer 11 on the surface of the glass plate G. Further, an arbitrary layer may be formed between the glass plate G and the low emissivity film, between each layer of the low emissivity film, or in the uppermost layer of the low emissivity film as long as various performances are not impaired.

3: Method for producing low-emissivity glass An example of the method for producing low-emissivity glass of the present invention will be described below. The present invention is not limited to the following.

The low emissivity film of the low emissivity glass of the present invention is preferably formed by a sputtering method, an electron beam deposition method, an ion plating method, or the like, but the sputtering method is suitable because it is easy to secure productivity and uniformity. There is.

The low emissivity film is formed by the sputtering method while the glass plate is conveyed in the apparatus in which the sputtering target, which is the material of each layer, is installed. At this time, the atmospheric gas used for sputtering is introduced into the vacuum chamber that forms the film provided in the device, and by applying a negative potential to the target, plasma is generated in the device to perform sputtering. Do.

Further, the method of obtaining the desired film thickness is not particularly limited because it differs depending on the type of the sputtering apparatus, but a method of controlling the film thickness by changing the film forming speed by adjusting the input power to the target and the introduced gas conditions , A method of controlling the film thickness by adjusting the transport speed of the substrate is widely used.

When forming each of the dielectric layers, either a ceramic target or a metal target may be used as the target. In any case, the gas conditions of the atmospheric gas to be used are not particularly limited, and for example, the gas type and the mixing ratio may be appropriately determined from Ar gas, O ₂ gas, N ₂ gas and the like according to the target membrane. Further, as the gas to be introduced into the vacuum chamber, any third component other than Ar gas, O ₂ gas and N ₂ gas may be contained.

When the barrier layer is used, a reactive gas atmosphere such as O ₂ gas, N ₂ gas, or CO ₂ gas is used so that the barrier layer can be oxidized or oxynitride when the second dielectric layer is formed. It is preferable to form a film inside.

When forming the Ag layer, an Ag target or an Ag alloy target is used as the target to be used. Ar gas is preferably used as the atmospheric gas to be introduced at this time, but different types of gases may be mixed as long as the optical characteristics of the Ag film are not impaired.

When forming the barrier layer, the target to be used may be appropriately selected, and an inert gas such as Ar may be used as the atmospheric gas to be introduced. At this time, the barrier layer is made thick enough to be oxidized or oxynitrided in a subsequent process.

When forming the light absorption layer, the target to be used may be appropriately selected, and an inert gas such as Ar may be used as the atmospheric gas to be introduced. Further, it is preferable to use a target of a material having an extinction coefficient of 1 or more in the visible region, and it may have at least one selected from the group consisting of, for example, Ti, NiCr, Nb, and stainless steel. Further, when a reactive gas such as oxygen is used when forming the light absorption layer, an oxidized or acid nitrided film may be formed and the visible light absorption rate may be reduced. Therefore, an inert gas such as Ar is used. It is desirable to use.

The surface of the light absorption layer may be oxidized or acidnitrided depending on the combination of the material used for the light absorption layer and the gas used at the time of forming the third dielectric layer later. As described above, if oxidation or oxynitriding occurs, the visible light absorption performance is impaired. Therefore, when a material that is oxidized or oxynitrided is used, a portion that is not oxidized or oxynitrided even after the formation of the third dielectric layer is sufficient. It is desirable that the film thickness is such that it remains. For example, when the light absorption layer is Ti, the physical film thickness of the light absorption layer 4 is preferably 3 to 8 nm.

A DC power supply, an AC power supply, or a power supply in which AC and DC are superimposed are used as the plasma generation source, but if abnormal discharge is likely to occur when forming the dielectric layer, a pulse is applied to the DC power supply. It is preferable to use a power source or an AC power source.

4: Double glazing The low emissivity glass of the present invention may be used as a single plate or laminated glass for buildings, but when used as double glazing, it is possible to protect the low emissivity film and it is expensive. It is preferable as a window glass for a building because it exhibits heat insulating properties. That is, one of the preferred embodiments of the present invention is a double glazing in which the above-mentioned gray-colored low-emissivity glass and a glass plate are integrated via a hollow layer. Since the appearance of the double glazing is gray, it is possible to improve the appearance quality of the building in harmony with the wall surface.

When used as double glazing, the surfaces of low emissivity glass on which the low emissivity film is formed face each other at predetermined intervals so as to form a hollow layer with other glass plates, and the peripheral portion is sealed with a spacer or a sealing material. .. The hollow layer is filled with an inert gas such as Ar, He, Ne, Kr, Xe, dry air, N _2, etc. Normally, dry air is used, but the heat insulation performance and sound insulation performance are further improved. For this purpose, Ar gas, Ne gas, or the like may be used.

The spacer has a desiccant inside and is fixed between at least two glass plates via a sealing material such as butyl rubber or silicone, and a lightweight aluminum material or resin material is used. The portion surrounded by the spacer, the low emissivity glass, and the glass plate is a hollow layer, and the heat insulating property of the double glazing can be changed depending on the thickness of the hollow layer and the type of gas to be enclosed.

Examples and comparative examples of the present invention are described below. The present invention is not limited to the following aspects.

In each of the Examples and Comparative Examples, a film was formed on soda lime glass having a thickness of 3 mm using a magnetron sputtering apparatus. Further, in each of the Examples and Comparative Examples, the glass plate and the film were not heated, and no particular heating was performed except when the temperature of the glass plate rises due to sputtering during film formation.

The film thickness of each layer was obtained as shown in Table 1 by adjusting the transport speed of the glass plate. Further, the above-mentioned transport speed was calculated by forming a single-layer film for each type of film in advance and determining the film-forming speed, and using this film-forming speed. In Tables 1, 2, and 4, the dielectric layer is described by the optical film thickness, and the Ag layer, the barrier layer, and the light absorption layer are described by the physical film thickness. Further, in Table 1, the first dielectric layer is D ₁ , the second dielectric layer is D ₂ , the third dielectric layer is D ₃ , the Ag layer is Ag, the barrier layer is B, the light absorption layer is A, and so on. The ratio of D ₂ represented by D ₂ / (D ₂ + D ₃ ) × 100 is described as the ratio (%).

(Examples 1 to 11, Comparative Examples 1 to 7)
First, the glass plate was held by the base material holder, and a desired target was placed in each vacuum chamber. A magnet is arranged on the back side of the target. Next, the inside of the vacuum chamber was exhausted by a vacuum pump.

Next, the first dielectric layer was formed on the glass plate. A Zn (hereinafter sometimes referred to as ZnAl) target to which 2 wt% of Al was added was used as the target, and 1100 W of electric power was applied to the ZnAl target from a DC power source through a power cable. At this time, while the vacuum pump was continuously operated, argon gas was introduced into the vacuum chamber at 20 sccm and oxygen gas was introduced at 40 sccm, and the pressure was adjusted to 0.4 Pa. From the above, a ZnAlO film was obtained.

Next, an Ag layer was formed on the ZnAlO film. The Ag target was introduced into the target, argon gas was introduced at 45 sccm as the atmosphere gas in the vacuum chamber, and the pressure was adjusted to 0.3 Pa. The power input from the DC power supply was set to 300 W. From the above, an Ag film was obtained.

Next, a barrier layer was formed on the Ag film. A ZnAl target was introduced into the target, argon gas was introduced at 100 sccm as the atmosphere gas in the vacuum chamber, and the pressure was adjusted to 0.7 Pa. The power input from the DC power supply was 450 W. From the above, a ZnAl film was obtained.

Next, a ZnAlO film was formed as a second dielectric layer on the barrier layer. The film forming conditions were the same as those of the first dielectric layer, except that the transport speed was adjusted to obtain a desired film thickness.

Next, a Ti film was formed as a light absorption layer on the second dielectric layer. A Ti target was introduced into the target, argon gas was introduced at 80 sccm as the atmosphere gas in the vacuum chamber, and the pressure was adjusted to 0.6 Pa. The power input from the DC power supply was set to 330 W. From the above, a Ti film was obtained.

Next, a ZnSnO film was first formed on the light absorption layer as a third dielectric layer. Zn (hereinafter sometimes referred to as "ZnSn") target in which 50 wt% of Sn is added to the target, the atmosphere gas in the vacuum chamber is introduced with argon gas at 10 sccm and oxygen gas at 50 sccm, and the pressure is 0.4 Pa. Adjusted. The power input by the DC power supply was set to 1100 W. From the above, a ZnSnO film was obtained.

Next, a TiO ₂ film was formed on the ZnSnO film as the uppermost layer. A Ti target was introduced into the target, argon gas was introduced at 40 sccm and oxygen gas was introduced at 40 sccm as the atmosphere gas in the vacuum chamber, and the pressure was adjusted to 0.5 Pa. Further, the power input by the DC power supply to which the pulse of 20 kHz was applied was set to 3050 W. From the above, a TiO ₂ film was obtained.

By the same method as the above method, the film thickness of each layer was set as shown in Table 1, and samples of Examples 1 to 11 and Comparative Examples 1 to 7 were obtained.

(Measurement of various optical characteristics)
The following various optical characteristics were measured for each of the obtained samples. A self-recording spectrophotometer (manufactured by Hitachi, Ltd., U-4000) was used for all measurements. The results obtained are shown in Tables 2 and 3.

(Visible light transmittance, visible light reflectance)
Visible light transmittance and visible light reflectance were calculated by a method conforming to JIS R3106 (1998).

(Transparent color, reflective color)
For the transmitted color and the reflected color, the values of a ^* and b ^* were calculated in accordance with JIS Z8781-4. As for the reflected color, a ^* and b ^* were obtained for the film surface reflection and the glass surface reflection, respectively.

(Confirmation of light absorption layer)
The visible light absorption rate of the light absorption layers used in Examples 4, 5, 7 and Comparative Example 5 was calculated by the following method. First, a sample of a glass plate / light absorption layer / third dielectric layer is formed in this order on a soda lime glass plate having a thickness of 3 mm, and the visible light absorption rate A is calculated by a method conforming to JIS R3106 (1998). did. However, in the above Examples and Comparative Examples, two layers are laminated as the third dielectric layer. In this study, only the film in contact with the light absorption layer is used as the "third dielectric layer". Next, the same glass plate and the third dielectric layer as described above were formed on the glass plate in the order of the glass plate / the third dielectric layer, and the visible light absorption rate B was calculated. Next, the visible light absorption rate A-visible light absorption rate B was calculated, and the obtained value was used as the visible light absorption rate of the light absorption layer. The light absorption layer and the third dielectric layer were of the same type and film thickness as those of the Examples and Comparative Examples.

Next, for the barrier layers used in Comparative Examples 2 and 3, the visible light absorption rate was calculated by the same method as described above. At this time, samples were formed in the order of glass plate / barrier layer / second dielectric layer. The above results are shown in Table 2.

Among the examples and comparative examples, the light absorption layer of Example 4 has the thinnest film thickness, and the light absorption layer of Example 5 has the thickest film thickness. In both cases, the visible light absorption rate was in the range of 20 to 30%. Further, in Example 7 and Comparative Example 5, the light absorption layer has the same thickness, but the film thickness of the third dielectric layer formed above is more than twice as different. It was found that the visible light absorption rate was about the same in both cases, and the influence of the film thickness of the third dielectric layer formed on the upper layer was not large.

Moreover, when the visible light absorption rate of the barrier layer was measured as a reference example, the visible light absorption rate was less than 6%. Further, it was found that even if the thickness of the second dielectric layer formed above changes, there is no significant difference in the visible light absorption rate as in the case of the light absorption layer described above.

(Comparative Examples 8 to 15)
Low emissivity glass was obtained in the same manner as in Example 1 except that the stacking order of each layer and each film thickness were as shown in Table 4. In Comparative Examples 8 and 12, the position where the light absorption layer was formed was between the first dielectric layer and the glass plate, and in Comparative Examples 9 and 13, the first dielectric layer was used as two layers and the first dielectric layer was formed. Between the two layers, in Comparative Examples 10 and 14, it was between the first dielectric layer and the Ag layer, and in Comparative Examples 11 and 15, it was between the Ag layer and the second dielectric layer.

With respect to Comparative Examples 8 to 15, the visible light transmittance, the visible light reflectance, and the colors of the transmitted light and the reflected light were determined by the same method as the above-mentioned method for measuring the optical characteristics. The results obtained are shown in Table 5.

For each optical characteristic of Examples 1 to 11 and Comparative Examples 1 to 15, a diagram in which transmitted light a ^* and b ^* are plotted in FIG. 2 and a diagram in which film surface reflections a ^* and b ^* are plotted in FIG. , A figure in which a ^* and b ^* of the glass surface reflection are plotted is shown in FIG. 4, respectively. From FIGS. 2 to 4, it was found that all of Examples 1 to 11 were within the range of numerical values indicating a gray color tone. In addition, the visible light transmittance was 65% or less in each of the examples, which was within the range of the numerical values indicating the gray color tone. Further, the visible light reflectance of the film surface reflection was 7% or less, and the visible light reflectance of the glass surface reflection was 19% or less, so that no glare or the like occurred even in visual observation.

On the other hand, in Comparative Example 1 in which the Ag layer is 11 nm, the reflected color a ^* of the film surface reflection has a value of reddish color, and b ^* has a value of exhibiting a deep blue color, which is the object of the present invention. It became unsuitable. Further, in Comparative Examples 2 and 3 in which the ratio of the film thickness of the second dielectric layer was out of the range of claim 1, the reflection color of the film surface reflection or the glass surface reflection was reddish. Further, in Comparative Examples 4 and 5 in which the total value of the film thicknesses of the second dielectric layer and the third dielectric layer is out of the range of claim 1, the reflected color of the glass surface reflection is reddish or the transmitted color. However, it became yellowish and the glass surface reflectance became high. Further, in Comparative Examples 6 and 7 in which the film thickness of the first dielectric layer is out of the range of claim 1, the bluish tint of the reflected light reflected on the film surface becomes deep and the glass surface reflectance becomes high, so that the film surface becomes high. In the reflection and the glass surface reflection, it became reddish.

Comparative Examples 8 to 11 are examples in which the position of forming the light absorption layer in the low emissivity film was changed, but no gray color tone was obtained in any of the comparative examples. Further, Comparative Examples 12 to 15 are examples in which the film thickness of each layer is changed in order to bring the light absorption layer closer to the gray color tone in the low emissivity film formed at the same position as Comparative Examples 8 to 11. However, in either case, it was not possible to obtain a gray color tone.

G: Glass plate, 2: Ag layer, 3: Barrier layer, 4: Light absorption layer, 11: First dielectric layer, 12: Second dielectric layer, 13: Third dielectric layer

Claims (6)

In gray-colored low-emissivity glass in which a low-emissivity film having one Ag layer is formed on the surface of a glass plate and the visual appearance is grayish.
The low emissivity film is formed by laminating a first dielectric layer, an Ag layer, a second dielectric layer, a light absorption layer, and a third dielectric layer in order from the surface of the glass plate.
The optical film thickness of the first dielectric layer is 45 to 80 nm.
The physical film thickness of the Ag layer is 7 to 10 nm.
The total optical film thickness of the second dielectric layer and the third dielectric layer is 75 to 110 nm, and the second dielectric is relative to the total film thickness of the second dielectric layer and the third dielectric layer. the thickness of the body layer Ri 18-55% der,
The visible light transmittance of the transmitted light is 65% or less, the transmitted color is gray, and the transmitted color is gray.
Visible light reflectance of the reflected light is less than 20%, gray tone low emissivity glass reflected color characterized by neutral-blue der Rukoto. The gray-colored low-emissivity glass according to claim 1, wherein the light absorbing layer has at least one selected from the group consisting of Ti, NiCr, Nb, and stainless steel. The gray-colored low-emissivity glass according to claim 1, wherein the light-absorbing layer has Ti, and the physical film thickness of the light-absorbing layer is 3 to 8 nm. The gray-colored low-emissivity glass according to any one of claims 1 to 3, wherein the Ag layer has a barrier layer directly above the glass. The gray-colored low-emissivity glass according to any one of claims 1 to 4, wherein the visible light transmittance is 55 to 65%. A double glazing in which the gray-colored low-emissivity glass according to any one of claims 1 to 5 and a glass plate are integrated via a hollow layer.