RU2467895C1 - Heated mirror - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: invention relates to automotive heated mirrors. Proposed mirror comprises glass carrier with rear side provided with 100-130 nm-thick aluminium reflection layer. Aluminium oxide 2-3 nm-thick barrier layer is arranged on said reflection layer. Tin oxide 150-250 nm-thick current-conducting layer is arranged on said barrier layer to carry electric contacts. Besides, 50-60 nm-thick titanium oxide layer and magnesium fluoride 70-75 nm-thick layer are arranged between carrier and reflection layer, on carrier side.

EFFECT: higher safety.

2 dwg

Description

The invention relates to the construction of heated mirrors used as automobile mirrors to ensure the safe operation of vehicles, and can be used on all types of vehicles, as well as mirror heating panels for heating rooms.

The heating of an external car mirror is relevant for areas with a humid and cold climate, as it is an effective and versatile tool that allows you to remove water drops, frost, snow, ice from the mirror surface, and also prevents the mirror from freezing when the car moves in the cold season.

It is known that a heated mirror contains a non-conductive substrate with a reflective layer deposited on its rear side, the reflective layer made of pure chromium and chromium oxide, the ratio of chromium and chromium oxide selected so that the layer resistance dissipates the applied electric energy in the required manner, cm Patent FR 2695789, IPC H05B 3/84, 1994.

The disadvantages of the known mirror are: a low reflection coefficient, which in the spectral region of 0.4 ÷ 0.7 μm does not exceed 50%, the need to comply with a given proportion of pure chromium and chromium oxide.

It is known a heated mirror containing a glass substrate with a reflective conductive layer of stainless steel on its back side, the reflective layer is made in a vacuum chamber by magnetron sputtering of stainless steel, see patent RU 2248681, IPC 7 Н05В 3/84, 2003.

The disadvantage of the presented mirror is not a high reflection coefficient of 50-65% in the spectral region of 0.4 ÷ 0.7 μm.

A heated mirror is known containing a glass substrate and a reflective aluminum layer 10 microns thick on its back surface. The aluminum layer is separated by a series of parallel dielectric lines, forming a labyrinthine strip 1 mm wide. Electrical contacts are located on both sides of the strip of aluminum layer, see patent GB 2303465, IPC 6 Н05В 3/84, 1995.

A disadvantage of the known mirror is that the reflective layer is separated by lines, which affects the quality of the reflected image and reduces the magnitude of the reflection coefficient, the value of which does not exceed 80%.

The closest in technical essence is a heated mirror containing a glass substrate, on the back side of which there is a reflecting layer of aluminum with a thickness of 100-300 nm, on the reflecting layer there is a barrier layer of aluminum oxide with a thickness of 2-3 nm, and on the barrier layer is conductive a layer of tin oxide with a thickness of 150-250 nm, on which electrical contacts are located, see patent RU 2306681, IPC 8 Н05В 3 / 84,2006.

A disadvantage of the known mirror is the insufficiently high reflection coefficient, comprising 83-85% in the spectral region of 0.4 ÷ 0.7 μm.

An object of the invention is to provide a heated mirror with a large reflection coefficient.

The technical problem is solved in that a heated mirror containing a glass substrate, on the back side of which there is a reflecting layer of aluminum with a thickness of 100-300 nm, on the reflective layer there is a barrier layer of aluminum oxide with a thickness of 2-3 nm, a conductive layer is located on the barrier layer from tin oxide with a thickness of 150-250 nm, on which electrical contacts are located, in which between the substrate and the reflective layer on the side of the substrate there is additionally a layer of titanium oxide with a thickness of 50-60 nm, and then a layer of fluorine thickness of 70-75 nm.

The solution to the technical problem allows to increase the reflection coefficient of the heated mirror up to 94%.

Figure 1 is a schematic sectional view of a heated mirror. It consists of a glass substrate 1, a layer of titanium oxide 2, a layer of magnesium fluoride 3, a reflective layer of aluminum 4, a barrier layer of aluminum oxide 5, a conductive layer of tin oxide 6 and two electrical contacts 7, and the power dissipation on the mirror is from 2 to 20 watts. The presence of additional layers of titanium oxide from magnesium fluoride between the substrate and the reflective layer of aluminum increases the reflection coefficient of the heated mirror to 94% in the visible spectral range of 0.4 ÷ 0.7 μm. The inventive heated mirror heats up in 3-7 seconds to 20 ° C, providing quick removal of moisture from the surface of the mirror.

The manufacture of heated mirrors is carried out in a vacuum chamber by magnetron sputtering. The substrate is pre-degreased and placed in a vacuum chamber, from which air is pumped out to a pressure of P _ost = 2.6 · 10 ^-3 Pa. The substrate is heated in a vacuum chamber to a temperature of 220 ° C. Then a mixture of argon and oxygen gases is supplied to a pressure of P _ost = 0.26 Pa. The substrate is closed by a shutter and a discharge is ignited on a magnetron with a titanium target. The oxide film is removed from the target surface within 5 minutes of burning the discharge, after which the shutter is removed and a layer of titanium oxide 50-60 nm thick is sprayed onto the substrate. The flow of a mixture of argon gases and oxygen is stopped. Then, a layer of magnesium fluoride is applied by thermal evaporation. The sputtering of a layer of magnesium fluoride is carried out until the layer reaches a geometric thickness of 70-75 nm. The substrates are kept in vacuum for 30 minutes to cool them. Then argon gas is supplied to the vacuum chamber to a pressure of P _ost = 0.26 Pa. The substrate is closed with a shutter and a discharge is ignited on a magnetron with an aluminum target. The oxide film is removed from the target surface within 5 minutes of burning the discharge, after which the shutter is removed and a reflective layer of aluminum with a thickness of 100-300 nm is sprayed. At the end of the deposition of aluminum, oxygen is supplied to the vacuum chamber to a pressure of P = 0.1-0.3 Pa. In an oxygen atmosphere, a continuous, non-conductive electric current, a non-porous alumina film of a thickness of 2-3 nm is formed on the surface of aluminum metal, playing the role of a barrier layer between the aluminum and conductive layers. After three minutes, the oxygen supply is stopped, and pumped out of the vacuum chamber to a pressure of P _ost = 2.6 · 10 ^-3 Pa. A mixture of argon and oxygen gases is introduced into the vacuum chamber. At a pressure of P = 0.2-0.3 Pa, a conductive layer of tin oxide with a thickness of 150-250 nm is sprayed onto the surface of the barrier layer.

The inventive heated mirror has a reflection coefficient R of up to 94% in the visible region of the spectrum of 0.4 ÷ 0.7 μm. The spectral dependence of the reflection of the inventive heated mirror is presented in figure 2.

The invention is illustrated by the following examples of specific performance.

Example 1. A heated mirror with a size of 100 mm by 190 mm, formed sequentially from layers of titanium oxide with a thickness of 55 nm, magnesium fluoride with a thickness of 73 nm, aluminum with a thickness of 250 nm, aluminum oxide with a thickness of 2.5 nm, tin oxide with a thickness of 150 nm, connected to a 12 V current source, consumes about 2 W and provides a reflection coefficient of 94%.

Example 2. A heated mirror with a size of 100 mm by 190 mm, formed sequentially from layers of titanium oxide with a thickness of 50 nm, magnesium fluoride with a thickness of 70 nm, aluminum with a thickness of 200 nm, aluminum oxide with a thickness of 2 nm, tin oxide with a thickness of 200 nm, connected to a current source voltage of 12 V, consumes about 20 W and provides a reflection coefficient of 93%.

Example 3. A heated mirror with a size of 100 mm by 190 mm, formed successively from layers of titanium oxide 60 nm thick, magnesium fluoride 75 nm thick, aluminum 300 nm thick, aluminum oxide 3 nm thick, tin oxide 250 nm thick, connected to a current source voltage of 12 V, consumes about 20 watts and provides a reflectivity of 92%.

The claimed technical solution of a heated mirror allows increasing the reflection coefficient up to 94% in the visible spectral region of 0.4 ÷ 0.7 μm and provides reliable electrical isolation of the conductive layer from the reflective layer and the stability of the dissipation of power dissipation on the mirror. The location of the layers on the back of the substrate provides high resistance to mechanical and climatic influences in harsh operating conditions of vehicles, moreover, it is easy to manufacture and convenient when using it on vehicles. The inventive object allows you to quickly remove condensate while maintaining a high reflection coefficient. The object can be used as mirror heating panels for space heating.

Thus, the inventive mirror with heating increases the reflection coefficient to 94% in the visible region of the spectrum of 0.4 ÷ 0.7 μm compared with the prototype, where the reflection coefficient is 83-85%. Power dissipation on the mirror is from 2 to 20 W with a voltage source of 12 V.

Claims (1)

A heated mirror containing a glass substrate, on the back side of which there is a reflecting layer of aluminum with a thickness of 100-300 nm, a reflecting layer of aluminum oxide is located on a reflective layer with a thickness of 2-3 nm, and a conductive layer of tin oxide with a thickness of 150- 250 nm, on which there are electrical contacts, characterized in that between the substrate and the reflective layer on the side of the substrate are additionally a layer of titanium oxide with a thickness of 50-60 nm, and then a layer of magnesium fluoride with a thickness of 70-75 nm.

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