JPH0432784B2 - - Google Patents

Description

[Detailed description of the invention] 〔Technical field〕 The present invention relates to anti-glare, heat-reflecting glass.

The anti-glare, heat-reflecting glass of the present invention can be applied to automobile windshield glass, residential window glass, and the like.

[Prior art]

Conventionally, for example, in the windshield glass of an automobile, a shaded band glass in which the upper side of the windshield glass is colored is used in order to provide an anti-glare effect.

This windshield glass is made of shaded band glass by coloring an intermediate film in the laminated glass, such as polyvinyl butyral, blue or green.

On the other hand, in order to keep the interior of a car cool and prevent solar energy from entering, window glass is coated with a heat ray reflective film to reflect heat rays. There are two ways to provide this heat ray reflective film on the window glass: one is to affix a heat ray reflective film to the window glass, and the other is to coat it with an optical interference film, but the latter is more durable and has a better heat ray reflecting effect. Therefore, the latter is generally used. In the case of such an optical interference film, due to the characteristics of the optical interference film, the hue of the reflected light changes when the angle at which the glass is viewed changes, and the reflectance of visible light is large, causing noticeable glare, so an anti-reflection film for visible light is provided. There are many cases. Therefore, visible light is sufficiently transmitted through the glass, and there is no anti-glare effect at all. Therefore, in order to simultaneously achieve the two objectives of ensuring coolness in the vehicle interior and anti-glare effect, conventional techniques have been used to combine the coloring of the intermediate film in the laminated glass and the coating of the glass surface with an optical interference film. I needed to.

However, in this conventional method, since the above-mentioned two items are manufactured separately, there are problems in that workability is poor and costs are high. Therefore, there is a desire for an anti-glare, heat-reflecting glass that has a simpler structure and achieves the above two objectives at a low cost.

[Purpose of the invention]

The present invention has been made in order to solve the problems of the prior art described above, and provides an anti-glare, heat-reflecting glass with a simple structure and low cost, which can simultaneously ensure the coolness of the vehicle interior and provide an anti-glare effect. The purpose is to

[Structure of the invention]

According to the present invention, such object is a heat ray reflective glass in which an optical interference film in which optical thin films are laminated in multiple layers is provided on the surface of a transparent substrate, the optical thin film constituting the optical interference film. A colored absorbing material is mixed in at least one of the transparent substrates up to a certain distance from the edge of the transparent substrate,
Between the part where the colored absorbent material is mixed and the part where no colored absorbent material is mixed, the amount of mixed colored absorbent material is shifted from the part where the colored absorbent material is mixed to the part where it is not mixed. This is achieved by an anti-glare, heat-reflecting glass characterized by being provided with a gradually decreasing blur area.

In the present invention, commonly used transparent materials such as glass and resin can be used as the transparent substrate. Furthermore, as the glass, not only laminated glass but also tempered glass or partially tempered glass can be used.

A heat ray reflecting film made of an optical interference film in which multiple optical thin films are laminated is provided on the transparent substrate.

An optical thin film is a thin film formed on the surface of a substrate such as glass for the purpose of preventing reflection, increasing reflection, etc. on the substrate surface, and utilizes the interference effect of light. An optical thin film may be formed of only one layer, but it may also be formed as a so-called multilayer film in which high refractive index materials and low refractive index materials are alternately laminated. Zirconium oxide (ZrO ₂ ), titanium oxide (TiO ₂ ), etc. are used as high refractive index substances, and silicon dioxide (SiO ₂ ), magnesium fluoride (MgF ₂ ), etc. are used as low refractive index substances. It will be done.

When the optical thin film is formed as a multilayer film, the antireflection effect and the reflection increasing effect can be further enhanced. Furthermore, it is possible to widen the wavelength range of light that causes reflection prevention or increased reflection, and to increase the degree of freedom in selecting the material forming the thin film in relation to its refractive index.

In the present invention, as the heat ray reflective film, for example,
A multilayer film in which a TiO ₂ film and a SiO ₂ film are laminated can be used.

In the present invention, each film thickness of the heat ray reflective film is an optical film thickness of λ/4 (λ: wavelength of infrared rays to be reflected).

This heat ray reflective film is formed on a transparent substrate by an appropriate surface treatment technique such as vacuum evaporation, sputtering, or ion plating.

A colored absorption material absorbs light of a specific color among visible light. These colored absorbing materials include nitrides such as titanium nitride (TiN), titanium carbide (TiC), and silicon nitride (Si ₃ N ₄ ), lead oxide (PbO),
Oxides such as copper oxide (CuO), other inorganic materials,
Also, metals such as chromium (Cr), aluminum (Al), and tungsten (W) can be used.
This colored absorption material is mixed into the optical thin film material constituting the heat ray reflection film when the heat ray reflection film is formed by a vacuum film forming method. The amount of colored absorbent material mixed in depends on the materials mixed, etc., but is 1 to 50% by weight (hereinafter referred to as
All percentages are by weight). For example, when coloring a titanium oxide-silicon dioxide based heat ray reflective film, titanium nitride is mixed into the titanium oxide film.
When titanium nitride is thick, it exhibits a golden reflective color, but when it is extremely thin, it absorbs a bluish tint. In other words, 20% titanium nitride in a 0.1 μm titanium oxide film.
When mixed, it becomes bluish and the visible light transmittance decreases.
It will be around 50%.

In the anti-glare, heat-reflecting glass of the present invention, the position where the colored absorbing material is mixed varies depending on the purpose and location of use, but in the case of an automobile windshield glass, it is the upper part of the windshield glass.
In residential window glass, etc., it may be mixed in the upper part or the peripheral edge part.

In the present invention, the amount of mixed colored absorbent material is the same until passing a certain distance from one end,
The structure is such that the amount of mixture gradually decreases toward the rear end, and finally, the film consisting only of the heat ray reflective film continues for a certain distance, and the amount of mixture becomes 0. This can be obtained by partially controlling the amount of the optical thin film material and the colored absorption material reaching the transparent substrate by masking a portion using the vacuum film forming method such as sputtering described above.

[Action of the invention]

In the present invention, in the area where there is only a heat ray reflective film that is not mixed with a colored absorbing material, approximately 60% of the infrared rays are absorbed.
The light is reflected, ensuring a cool interior. Visible light passes through this area, and almost no color is attached. On the other hand, in the portion where the colored absorbing material is mixed into the optical thin film constituting the heat ray reflective film, a portion of visible light is absorbed, and therefore the film is colored. In the blurred area where the colored absorbing material gradually decreases, the same color as the visible light rays appears to gradually become lighter from the area where the colored absorbing material is mixed to the area where it is not mixed.

〔Effect of the invention〕

Therefore, the colored heat ray reflective glass according to the present invention provides the following effects.

(a) In the present invention, the heat ray reflecting film and the visible light absorbing film, which were conventionally produced separately, can be produced at the same time, thereby shortening the production process and greatly improving the work system.

(b) Since the heat ray reflective film and the visible light absorbing film can be produced at the same time, costs can be reduced.

(c) Since the colored absorbing material absorbs a portion of infrared rays, the heat ray blocking effect is greater, making the interior of the vehicle cooler than before.

(d) The heat ray reflective film formed using the vacuum film forming method has good adhesion to the transparent substrate and is hard, so it is durable and
Excellent scratch resistance.

(e) In the area where the heat ray reflective film gradually decreases, the color changes gradually, so a very natural appearance can be created, and an anti-glare effect can be obtained without causing any discomfort to the viewer.

〔Example〕

Embodiments of the present invention will be described below with reference to the drawings.

Fig. 1 is a perspective view showing an embodiment of the present invention in which the anti-glare, heat-reflecting glass is applied to an automobile windshield glass, Fig. 2 is a sectional view taken along the line - - of Fig. 1, and Fig. 3 is a portion of Fig. 2. The enlarged view and FIG. 4 are schematic configuration diagrams showing the outline of the method for producing the anti-glare heat-reflecting glass of the present invention, where a is a view of the inside of the vacuum chamber viewed from above, and b is a view of the inside of the vacuum chamber viewed from the side. 5 is a graph showing the transmission spectrum of the anti-glare, heat-reflecting glass according to the example of the present invention, and FIG. 6 is a graph showing the visible light transmittance of the anti-glare, heat-reflecting glass according to the example of the present invention. be.

In FIG. 1, shaded band glass with a heat ray reflection function is provided in the hatched area.

In FIG. 2, reference numeral 1 denotes a glass substrate as a transparent substrate, which is made of partially tempered glass. A heat ray reflective film 2 is provided on the outer surface of the glass substrate 1, and the glass substrate 1 and the heat ray reflective film 2 form a windshield glass 3 as the heat ray reflective glass of the present invention. Windshield glass 3 is fixed between window frame 4 and molding 5 with conductive adhesive 6. Note that 7 is a dam that prevents the conductive adhesive 6 from protruding, and 8 is a spacer that fills the gap between the windshield glass 3 and the window frame 4 and prevents the windshield glass 3 from shifting downward.

As shown in a partially enlarged view in FIG. 3, the heat ray reflecting film 2 is composed of four layers of optical thin films. As this optical thin film, titanium oxide (TiO ₂ ) 2a, which is a high refractive index material, and silicon dioxide (SiO ₂ ) 2b, which is a low refractive index material, are alternately laminated.
In Fig. 3, the range A is only the heat ray reflective film, and the range C is the part where titanium nitride is included in the titanium oxide 2a of the first and third layers constituting the heat ray reflective film.
This is the part where 20% of the titanium nitride is mixed, and the range B is the part where the amount of titanium nitride mixed gradually decreases from C to A. Note that the width of the B range was 30 mm, and the width of the C range was 70 mm.

When the wavelength of the infrared rays to be reflected is set to 1050 nm, the thickness of each optical thin film of the heat ray reflective film is 1050 Å for titanium oxide 2a, and 1800 Å for silicon dioxide 2b.
becomes. However, silicon dioxide 2b on the outermost surface is 900
It was set as Å.

The above-mentioned anti-glare, heat-reflecting glass was formed on glass by ion plating according to the method shown in FIG. That is, as shown in FIG. 4, a windshield glass 1 was placed in a vacuum chamber 9, titanium oxide was placed in an evaporation source 10, and titanium nitride was placed in an evaporation source 11. Then, as shown in FIG. 4a and b, the shutter 12 is moved to
The titanium nitride was provided so that it was in contact with the part B, and a part of the titanium nitride was in contact with the part B.

In this state, while feeding the windshield glass in the direction of arrow D, apply a titanium oxide film to the part A.
1050 Å, 20 Å in the titanium oxide film 1050 Å in the C part
% of titanium nitride was obtained, and in part B, a film was obtained in which the titanium nitride content gradually decreased from 20% to 0% from C to A. Subsequently, silicon dioxide was placed in the evaporation sources 10 and 11, and a silicon dioxide film of 1800 Å was formed in the same manner as above. Furthermore,
On top of this, a titanium oxide film of approximately 1050 Å is formed in the same manner as the first layer, and finally, approximately 1050 Å thick is formed in the same manner as the second layer.
900 Å of silicon dioxide was formed.

The transmission spectrum of the colored heat-reflecting glass obtained as a result is shown in Figure 5, and the visible light transmittance is shown in Figure 6.
As shown in the figure.

As is clear from Fig. 5, the transmission spectrum c of the part C is bluish compared to the transmission spectrum a of the part A, which provides an anti-glare effect and prevents sunlight from entering the vehicle interior. It can be seen that the interrupting performance has also been significantly improved.

Also, as is clear from Figure 6, the visible light transmittance glass in part A is 90%, whereas the part A is made of glass with a visible light transmittance of 90%, while the part A is made of glass with a visible light transmittance of 90%.
visible light transmittance is 30% (25% or more according to regulations)
It can be seen that the visible light transmittance of part B gradually decreases from A to C.

Furthermore, in the present invention, when producing an anti-glare, heat-reflecting glass, a conventional vacuum chamber used for ion plating can be used as is. Therefore, a film having an anti-glare effect and a heat ray blocking effect can be formed at the same time, which is more efficient than producing them separately as in the conventional method.

Although specific embodiments of the present invention have been described above, the present invention is not limited to these embodiments, and includes various embodiments within the scope of the claims. .

For example, the colored absorbing material does not need to be titanium nitride, and titanium carbide, lead oxide, or other suitable materials can be used.

Further, in the examples, titanium nitride is mixed with titanium carbide, but it may be mixed with silicon dioxide, or may be mixed with both titanium oxide and silicon dioxide.

[Brief explanation of drawings]

Fig. 1 is a perspective view showing an example in which the anti-glare heat reflective glass of the present invention is applied to an automobile windshield glass, Fig. 2 is a sectional view taken along the line - - in Fig. 1, and Fig. 3 is a portion of Fig. 2. It is an enlarged view. FIG. 4 is a schematic configuration diagram showing an outline of the method for producing an anti-glare, heat-reflecting glass according to an embodiment of the present invention, in which a is a view of the inside of the vacuum chamber viewed from above, and b is a view of the inside of the vacuum chamber viewed from the side. FIG. 5 is a graph showing the transmission spectrum of the anti-glare, heat-reflecting glass according to the example of the present invention, and FIG. 6 is a graph showing the visible light transmittance of the anti-glare, heat-reflecting glass according to the example of the present invention. It is. 1... Glass substrate, 2... Optical interference film, 2a...
...Titanium oxide film (optical thin film), 2b...Silicon dioxide film (optical thin film), 3...Windshield glass, 4...Window frame, 5...Mall, 6...Conductive adhesive, 7...Dam , 8... Spacer, 9... Vacuum chamber, 10... Evaporation source, 11... Evaporation source, 12...
Shyatsuta.

Claims (1)

[Scope of Claims] 1. A heat ray reflective glass in which an optical interference film in which optical thin films are laminated in multiple layers is provided on the surface of a transparent substrate, wherein at least one of the optical thin films constituting the optical interference film is provided. A colored absorbing material is mixed in at a certain distance from the edge of the transparent substrate.
Between the part where the colored absorbent material is mixed and the part where no colored absorbent material is mixed, the amount of mixed colored absorbent material is shifted from the part where the colored absorbent material is mixed to the part where it is not mixed. An anti-glare, heat-reflecting glass characterized by being provided with a gradually decreasing blur area. 2. In claim 1, the heat-reflecting glass is an automobile windshield glass, and the windshield glass is such that the colored absorbing material is mixed in the same amount up to a certain distance from the upper end of the windshield glass. 1. A windshield glass comprising: a portion having a gradually decreasing amount of mixed colored absorbing material; and a portion containing only a heat ray reflecting film without mixed colored absorbing material.