RU2737824C1 - Dichroic mirror - Google Patents

Abstract

FIELD: optics.

SUBSTANCE: invention relates to dichroic mirrors, also known as optical filters. Invention can be used in home, in car rear-view mirrors, in media industry, in particular, this mirror can be installed before photo or video transmitting devices, as front panel of mirror TV sets. Dichroic mirror includes a glass plate having a front surface and a rear surface with a coating of its rear surface with a structure of layers including a metal and a metal oxide. Layers are arranged sequentially in the following order, starting from surface of glass plate: first layer consisting of metal, on which the second layer consisting of metal oxide is applied.

EFFECT: technical result is simplification of dichroic mirror manufacturing technology, as well as improvement of its optical characteristics.

9 cl, 1 dwg

Description

The present invention relates to dichroic mirrors, also known as optical filters. The invention can be used in everyday life, in car rear-view mirrors, in the media industry, in particular, this mirror can be installed in front of photo or video transmitting devices, as the front panel of mirror TVs.

Known designs containing a system that combines a rear-view mirror with a display, emitter and / or electromagnetic sensor hidden behind the mirror surface. In these systems, the display / emitter or sensor works through a mirror, while the mirror itself reflects what is expected of its function, thanks to a specific coating device that is simultaneously capable of reflecting a significant portion of the visible spectrum and can transmit a sufficient amount of electromagnetic radiation emitted by the display. / by the emitter and / or absorbed by the sensor.

All of these systems installed in vehicles typically have reflectivity between 35% and 55% (usually measured according to SAE J964 or equivalent methodology) and they are often mounted with reflective layer (s) located (s) on the front surface of the mirror in relation to the position of the observer. This embodiment assumes the presence of a maximum ability to reflect and transmit simultaneously, which requires that both operate in more or less the same portions of the electromagnetic spectrum.

In some cases, system designs in which the reflective layer is located on the front surface are not preferred, and hence there is a need for a dichroic mirror containing a multilayer structure of interference layers on the back surface. Using. With this design on the rear side, the reflectance is usually given a higher value than the transmittance. For example, when using a thin layer of chromium as a reflector, it is known that the following values can be obtained:

Thus, it can be stated that light hardly passes through when the reflection exceeds 58-60%.

It has been found that the use of a multilayer structure of interference layers and a suitable metal reflector on the back of the mirror can increase both transmittance and reflectance.

A dichroic mirror is known from the prior art, disclosed, for example, in WO 2006045835 A1, 04.05.2006, in which it has a front surface and a rear surface, with a coating on the rear surface of a multilayer structure.

The coated substrate has a transmission at 550 nm of at least 6% and a reflectance of more than 45%.

The coated substrate may have a blue tint in reflected light, but it may also give a neutral tint in reflected light. In this case, the hunter colorimetric values a * and b * are preferably -10 to + 10, and the purity is preferably less than 13%, more preferably less than 10%.

This system is especially interesting in prismatic interior day / night mirrors. The reflector must be behind the glass to allow a high level of "daytime" reflection. The front surface of the glass itself, with its intrinsic refractive index, gives a low level of reflection, commonly referred to as "nighttime". At the same time, according to this device, the transmission is kept at a sufficient level to allow the use of a display / emitter and / or a sensor device placed behind the mirror. This mirror can also be used in "self-adjusting", sometimes called "electrochromic" automatic day / night mirrors, where the highest possible reflection of the mirror is required to increase the optical range of the device. Such a system can be applied to any suitable transparent substrate (e.g. glass or plastic) by methods generally known in the art for such a design, e.g. by immersion processes, pyrolytic deposition such as chemical vapor deposition (CVD), or physical vapor deposition ( FNP), or a combination of any of these methods.

Another interesting advantage of these structures is their long service life, which allows processing without deterioration (mechanical resistance to scratching) and have significant self-protection against corrosion (climatic stability).

The dichroic rear-view mirrors disclosed in the aforementioned source of information were obtained by applying on the back side (the side opposite to the observer) a soda-lime glass substrate of a multilayer structure of different layers. These layers were deposited by magnetically enhanced vacuum deposition. In this well known method, glass is passed alternately through deposition chambers where suitable materials are bombarded under vacuum.

In the manufacture of this mirror, the following sequence of layers is used on a glass substrate in the following order (in the direction from the observer):

- the first layer - titanium oxide (TiO ₂ )

- the second layer is silicon oxide (SiO ₂ )

- the third layer is silicon (Si) or chromium (Cr).

This structure shows the following optical characteristics:

at 550 nm, the transmittance is at least 6%, preferably 8% and the reflectance is 45%, preferably more than 50%.

However, the mentioned dichroic mirrors in the known source of information are complicated in manufacturing technology, since they use three coating layers, one of which consists of a metal, and the other two - of different metal oxides. In addition, the optical characteristics of these mirrors are not good enough, since in dichroic mirrors, the percentage ratio of the reflection and transmission of the luminous flux is of great importance. Optimum for such mirrors is a high reflection coefficient with a high light transmittance.

The closest to the claimed invention in terms of the totality of essential features is a dichroic mirror, disclosed, for example, in WO 2000026701 A1, 05/11/2000 or in US 6292302 B1, 09/18/2001, in which a multilayer structure is used, including the first layer of oxide applied to the glass plate metal and then a second layer consisting of an oxidizing metal or semi-metal and a protective coating of thickness and composition sufficient to significantly prevent oxygen penetration during subsequent heat treatment. In this case, the following characteristics of the obtained dichroic mirror were obtained: transmittance at least 24% in the wavelength range 550-650 nm, reflectance at least 45%.

However, the technological process of manufacturing this mirror is rather laborious, since in addition to using a magnetron sputtering chamber, it is necessary to use heat treatment of the resulting product and, in addition, the optical characteristics of this mirror are not good enough, since with a good transmittance there is an insufficiently high reflection coefficient.

The technical problem to be solved by the claimed invention, with the achievement of the corresponding technical result, is to simplify the technology for manufacturing a dichroic mirror, as well as to improve its optical characteristics.

The task is solved as follows.

A dichroic mirror includes a glass plate having a front surface and a rear surface, with a coating of its rear surface with a structure of layers including a metal and a metal oxide, while the layers are arranged sequentially in the following order, starting from the surface of the glass plate: the first layer consisting of metal on which is superimposed by a second layer consisting of a metal oxide.

The following features characterize the claimed invention in particular cases, in specific forms of its implementation.

- the metal used is aluminum or silicon or nickel or chromium or niobium;

- titanium oxide or zinc oxide or niobium oxide or tin oxide or bismuth oxide is used as a metal oxide;

- most preferably aluminum is used as the metal;

- most preferably titanium oxide is used as the metal oxide;

- the dichroic mirror has the following optical characteristics: at a wavelength of 550 nm, the transmittance is 16% -20%, and the reflectance is 60% -65%;

- the optical thickness of the first layer is from 85 to 240 nm, preferably from 100 to 225 nm .;

- the optical thickness of the second layer is from 150 to 250 nm, preferably from 180 to 200 nm;

- the dichroic mirror has a neutral tint in reflected light;

- the color in reflection gives a purity of less than 13%, preferably less than 10%.

- on top of all the above layers, there is a protective coating made of a polymer film or a film with another glass plate, forming a triplex system with a mirror.

These features are essential and interrelated with each other to form a stable set of essential features sufficient to solve the problem.

FIG. 1 shows graphs showing the spectral characteristics of the claimed dichroic mirror, which shows the following:

A - absorption of solar energy in (%) depending on the wavelength in (nm);

R1 - light reflection from the side of the mirror deposition in (%) depending on the wavelength in (nm);

R2 - reflection of light from the outside of the mirror in (%) depending on the wavelength in (nm);

T - solar energy transmission in (%) depending on the wavelength in (nm).

The essence of the invention is as follows.

For the manufacture of the declared mirror, glass is mainly used not lower than the M1 or O / W grade, with a thickness of 2-6 mm.

The manufacturing process of the claimed mirror is as follows.

First, a metal, for example aluminum, is sprayed onto one of the glass surfaces in a vacuum chamber of magnetron sputtering at a residual pressure of 3 ÷ 6 × 10-3 Pa.

After spraying the glass surface with a layer of aluminum of the required light transmission, it becomes anti-reflective, i.e. a layer of a metal oxide, for example titanium TiO ₂ , is applied to it, with an enrollment of about 30%. This is done in a vacuum chamber of magnetron sputtering.

When coated with titanium oxide, the stoichiometry of aluminum changes, as a result of which it gains hardness and its reflection increases.

For example, aluminum, having a light transmission of 12%, is anti-reflective by 5%, as a result of which the reflection increases by 12% and, as a result, the reflectance of aluminum becomes 17%.

Titanium oxide with a wavelength of about 150 man. it is possible to vary the color of the mirror coating, and make it, for example, warmer, colder or neutral.

The spraying process is controlled by special devices.

As a result, in accordance with the composition of the coatings and the sequence of their deposition indicated in the independent claim of the invention, the claimed dichroic mirror has good optical characteristics, consisting in a sufficiently high percentage of light reflection with a good percentage of light transmission.

In addition to the above advantages and technical results, the declared dichroic mirror has another technical result, which consists in a sufficiently effective screening of electromagnetic radiation.

This is especially important when using the claimed mirror in the media industry, in particular when placing it in front of the screen of television receivers or the display of computer monitors, as the front panel of mirror televisions.

In all embodiments of the claimed mirror, on its rearmost side along the periphery, there can be coatings of the following materials: paint / enamel / polymer light-impermeable film, or, in addition, on top of all these layers, a protective coating of a polymer film or a film with another glass plate can be located, forming with mirror triplex system.

The claimed invention is industrially applicable, since its implementation does not require materials and technologies not known from the prior art to date.

Claims (9)

1. A dichroic mirror comprising a glass plate having a front surface and a rear surface, with a coating of its rear surface with a structure of layers including metal and metal oxide, characterized in that the layers are arranged sequentially in the following order, starting from the surface of the glass plate: the first layer, composed of metal - aluminum, on which a second layer of metal oxide is superimposed. 2. A dichroic mirror according to claim 1, characterized in that the metal used is aluminum or silicon, or nickel, or chromium, or niobium. 3. A dichroic mirror according to claim 1, characterized in that titanium oxide or zinc oxide, or niobium oxide, or tin oxide, or bismuth oxide is used as the metal oxide. 4. Dichroic mirror according to claim 1, characterized in that it has the following optical characteristics: at a wavelength of 550 nm, the transmittance is 16-20% and the reflectance is 60-65%. 5. A dichroic mirror according to claim 1, characterized in that the optical thickness of the first layer is from 85 to 240 nm, preferably from 100 to 225 nm. 6. A dichroic mirror according to claim 1, characterized in that the optical thickness of the second layer is from 150 to 250 nm, preferably from 180 to 200 nm. 7. A dichroic mirror according to claim 1, characterized in that it has a neutral tint in reflected light. 8. A dichroic mirror according to claim 1, characterized in that the reflection color gives a purity of less than 13%, preferably less than 10%. 9. A dichroic mirror according to claim 1, characterized in that, in addition, on top of all said layers, there is a protective coating made of a polymer film or a film with another glass plate, forming a triplex system with the mirror.

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