CH661561A5 - GLAZING WITH A COATING. - Google Patents

Description

The present invention relates to a glazing unit carrying a coating of metal oxide formed by pyrolysis, transmitting light and forming a screen against solar radiation. The use of glazing with a coating forming a screen against solar radiation is well known for buildings, in order to reduce the solar thermal gain of the building, especially during hot sunny periods, so that the temperature inside of the building can be easily maintained at a level which, for example, is comfortable for the occupants of the building and can be tolerated by computers or other temperature sensitive electronic equipment located inside the building.

As an example, European Patent No. EP 0 075 516 A1 teaches to provide glass with a coating forming a screen against solar radiation consisting of titanium dioxide deposited at the rate of approximately 140 mg / m2, which corresponds to a thickness of about 35 nm. Known glazings with a coating of titanium dioxide 35 to 40 nm thick provide effective protection against solar radiation and give a metallic shade in reflection due to interference effects. From a commercial point of view, it is extremely important that such a coating gives in reflection a shade which is neutral or is acceptable in other ways. Unfortunately, the known titanium dioxide coatings up to 40 nm thick which meet this requirement are too thin to have adequate abrasion resistance, so that the product has an insufficient shelf life. It would be possible to give the coating greater resistance to abrasion by making it thicker. For example, we found

that titanium dioxide coatings having a thickness of the order of 50 nm to 60 nm can have a satisfactory abrasion resistance for the intended purpose. However, increasing the thickness of such a coating will have the effect of altering its shade in reflection, and a coating of titanium dioxide from 50 nm to 60 nm gives in reflection an unpleasant yellowish color.

One of the objects of the present invention is to provide a glazing unit carrying a coating of metal oxide formed by pyrolysis, transmitting light, forming a screen against solar radiation such that the color of the coating, seen in reflection, can be modified in a way which is not entirely dependent on the thickness of the coating.

The present invention provides a glazing unit carrying a metal oxide coating formed by pyrolysis, transmitting light and forming a screen against solar radiation, characterized in that at least 95% by weight of the metal ions in the coating are tin and titanium ions, and in that the relative proportions of tin and titanium ions in the coating are such that they give the coating a refractive index of 2.2 or less.

The refractive index of a thin coating of titanium dioxide formed by pyrolysis is about 2.3: By adopting the present invention, the refractive index of the coating is reduced by the addition of a sufficient amount of tin ions, and therefore a coating according to the invention can be produced with the same optical thickness, but with a greater actual thickness, than a coating of substantially pure titanium dioxide. It will be noted that the abrasion resistance of such a coating depends on the nature and the actual thickness of the coating, while interference effects due to the coating will depend on its optical thickness. The optical thickness of a coating which governs its reflection properties is given by twice its actual thickness multiplied by its refractive index. Therefore, the present invention provides a means for increasing the abrasion resistance of a coating while controlling its color in reflection, so that the resulting coating has better aging properties. The abrasion resistance of a coating according to the invention is improved compared to a titanium dioxide coating of the same optical thickness, because the coating according to the invention has a greater actual thickness, and also because the addition of tin ions changes the nature of the coating in a way which is beneficial to abrasion resistance. It is therefore possible to simulate a thin coating of titanium dioxide, but with better aging properties.

The refractive index of a coating can be measured by a conventional ellipsometry technique as described in "Thin Film Phenomena", KL Chopra, Me. Graw Hill, 1969, pages 738 to 741, and references in the present description, specific refractive index values are references to values measured by this technique, the measurement being carried out by means of the sodium D line.

To test the abrasion resistance of a coating, an annular friction piece can be used, back and forth, having an internal diameter of 2 cm and an external diameter of 6 cm, corresponding to a surface friction of 25 cm2, and formed of a felt pad on an annular metal piece. The friction piece is fixed to a weighted tube (weight of the assembly: 1.7 kg) sliding vertically in a support. Constant contact is therefore ensured between the friction piece and the sample. The hole through the annular metal part forms a reservoir for an aqueous suspension of ground sand having an average grain diameter of 0.1 mm, which is allowed to flow between the felt pad and the glazing carrying the coating. that we are testing. The support carrying the friction part is animated by a movement5

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back and forth by means of a crank system, with an amplitude of 3 cm and a frequency of 1 Hz. After a certain time, one obtains a trace of wear consisting of claws very close to one of the other, of the undamaged coating remaining between them, possibly followed by the complete or substantially complete removal of the coating. Specific or comparative references, in the present description, to abrasion resistance, are references to the abrasion resistance measured by this test.

In the preferred embodiments of the invention, the relative proportions of tin and titanium ions in the coating are such that they give the coating a refractive index which is equal to or greater than 1.9. This ensures that the coating will have a high level of reflection of visible light.

Advantageously, the relative proportions of tin and titanium ions in the coating are such that they give the coating a refractive index equal to or less than 2.15. This results in a relatively greater actual thickness for a given otic thickness of the coating. Preferably, the coating comprises at least 30% tin and at least 30% titanium calculated as a percentage by weight of the respective dioxide in the coating. We have found that this gives the best compromise between the protective properties with respect to the solar radiation of the coating (which are largely due to the presence of titanium) and the reduction in the refractive index and the increase in the abrasion resistance (which is due to the presence of tin). To obtain the best abrasion resistance, the coating preferably comprises at least 40% tin calculated as a percentage by weight of tin dioxide in the coating.

In the preferred embodiments of the invention, the thickness of the coating and the relative proportions of tin and titanium ions in the coating are such that they give an interference increase in the reflection of visible light in the length range. waves less than 500 nm. In this way, the glazing has a metallic tint when viewed in daylight, in reflection, from the side carrying the coating.

Advantageously, the coating is carried by a sheet of glass.

Such a glass can be clear glass, or it can be opaque glass, for example to be used as a light panel for floors of buildings. Embodiments of the invention in which the glass is tinted glass, for example bronze glass, have advantageous light absorbing properties.

Different embodiments of the invention will now be described in more detail in the following examples

Control sample

A coating of titanium dioxide 45 nm thick can be formed on glass as described in Example 1 of British Patent No. 1,397,741 by pyrolysis of titanium acetylaceto-nate. It has been found that formed in this way, the titanium dioxide coating has a refractive index of 2.3, and therefore an optical thickness in reflection of 207 nm. When testing the abrasion resistance of this coating, it is found that over at least the central area of the abraded surface, the coating is substantially completely removed in 5 minutes.

Example 1

An oxide coating comprising 40% tin and 60% titanium calculated as a percentage by weight of the respective dioxide in the coating, is formed by pyrolysis on a hot glass substrate of a solution containing titanium acetyl acetonate and tin dibutyl diacetate. The resulting coating has a refractive index of 1.9 and is formed under a thickness of 55 nm, so that it has the same optical thickness as the coating of the control sample. When testing the abrasion resistance of this coating, it is noted, after abrasion for 30 minutes, that some scratches appear in the coating when the latter is inspected under a microscope.

The coating has a metallic hue in reflection. In a variant of this example, the coating is formed on tinted glass to give a reduction in light transmission.

Example 2

A freshly formed hot ribbon of clear float glass 6 mm thick is conveyed through a coating station at a speed of 8.5 meters per minute. The atmosphere in the coating station has an average temperature of about 300 ° C, and the tape entering the coating station has an average temperature of about 600 ° C. A coating forming solution is made as follows:

Dibutyl tin acetate 6.7 kg

Titanium diacetylacetonated isopropylate 12.5 kg Dimethylformamide ad. 100 1

This solution is sprayed at the rate of 120 liters per hour to form a coating of 42 nm thickness on the glass ribbon.

The composition of the coating calculated by weight is 47% tin dioxide and 53% titanium dioxide, and the coating has a refractive index of 1.9.

A sheet cut from this ribbon observed on the side of the face carrying the coating has a light transmission factor of 74.2% and the light reflection factor of this face carrying the coating is 22.5%. The coating has a metallic shade in reflection and its abrasion resistance is similar to that described in Example 1.

In a variant of this example, the coating is formed on tinted glass to give a reduction in light transmission.

Example 3

A hot ribbon of clear float glass 8 mm thick is coated by pyrolysis with a coating forming solution manufactured as follows:

Tin dibutyldiacetate 9.3 kg

Titanium diacetylacetonatedisopropylate 27.8 kg Dimethylformamide ad. 1001

The solution is sprayed onto the tape at the rate of 87 liters per hour to form a coating 53 nm thick containing 40% tin dioxide by weight. The refractive index of the coating is 2.1.

A sheet cut from this ribbon observed on the side of the surface carrying the coating has a light transmission factor of 66% and the light reflection factor of this surface carrying the coating is 28%. The coating has a metallic shade in reflection and its abrasion resistance is similar to that described in Example 1.

In a variant of this example, the coating is formed on tinted glass to give a reduction in light transmission.

Example 4

A freshly formed hot ribbon of 6 mm thick bronze float glass is passed through a coating station.

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A coating forming solution is made as follows:

Dibutyldiacetate tin 13.2 kg

Titanium diacetylketonatedisopropylate 27.8 kg

Dimethylformamide ad. 1001

This solution is sprayed at the rate of 82 liters per hour to form a coating 50 nm thick on the glass ribbon.

The composition of the coating calculated by weight is 42% tin dioxide and 58% titanium dioxide, and the coating has a refractive index of 2.1.

A sheet cut from this ribbon observed on the side of the surface carrying the coating has a light transmission factor of 39% and the light reflection factor of this surface carrying the coating is 24%. The coating has a metallic shade in reflection and its resistance to abrasion is similar to that described in Example 1. As an alternative to each of the examples above, the coating forming solution used contains additives so forming in the coating a doping agent constilo killing up to 5% by weight of the metal ions in the coating, the relative proportions of tin and titanium dioxides remaining at the given values.

Claims (8)

661561 1. Glazing carrying a coating of metal oxide formed by pyrolysis, transmitting light and forming a screen with respect to solar radiation, characterized in that at least 95% by weight of the metal ions in the coating are ions of tin and titanium, and in that the relative proportions of tin and titanium ions in the coating are such that they give the coating a refractive index equal to or less than 2.2. 2. Glazing according to claim 1, characterized in that the relative proportions of tin and titanium ions in the coating are such that they give the coating a refractive index which is equal to or greater than 1.9. 2 3. Glazing according to one of claims 1 or 2, characterized in that the relative proportions of tin and titanium ions in the coating are such that they give the coating a refractive index equal to or less than 2.15. 4. Glazing according to one of claims 1 to 3, characterized in that the coating comprises at least 30% tin and at least 30% titanium calculated as a percentage by weight of the respective dioxide in the coating. 5. Glazing according to claim 4, characterized in that the coating comprises at least 40% tin calculated as a percentage by weight of tin dioxide in the coating. 6. Glazing according to one of claims 1 to 5, characterized in that the thickness of the coating and the relative proportions of tin and titanium ions in the coating are such that they give an interference increase in the reflection of light visible in the wavelength range less than 500 nm. 7. Glazing according to one of claims 1 to 6, characterized in that the coating is carried by a sheet of glass. 8. Glazing according to claim 7, characterized in that the glass is tinted glass.