DE2548904B2 - Process for the production of light-filtering, heat or radio rays reflecting or electrically heatable organic triplex glass - Google Patents

Description

The invention relates to methods of making light filtering. Heat or radio waves reflective or electrically heatable organic triplex glass for certain purposes, such as for glazing cabins and passenger areas of land, water and air vehicles and as a gasification agent, e.g. B. for glasses, helmets, protective masks and protective screens and others.

At present, organic flat glasses (polyacrylate, polycarbonate glass, etc.) are coated with inorganic ones ■ Ctoffen by thermal vacuum evaporation. Depending on The composition and thickness of these coatings have predetermined characteristics, namely spectral curves for Reflection, absorption and transmission of various radiations, electrical conductivity and others Properties. Organic glasses, on the surface of which the mentioned functional inorganic coatings are applied, are used for the production of light-filtering, heat or radio rays reflecting, electrically heated glass and other types of glazing for certain purposes, as the Coatings are partially transparent to visible light because of their small thickness, d. H. a certain amount of light let through.

In the glazing of means of transport and the production of certain types of glass, organic glass can usually only be used in the form of triplex glass, which has higher strength values than multilayer organic glazing. The triplex process (see DE-PS 13 01022 and SU-PS 2 TI 989) consists of the following: The adhesion-promoting polyvinylethylal layer is applied to the surfaces of two organic glasses that are to be connected (glued) to form a triplex glass, after which one produces the composite pane, which consists of the organic panels to be glued with an interposed glued polyvinyl butyral film. The composite pane is placed in a rubber bag, exposed to a vacuum to remove the air and pressed in a water, gas or paraffin autoclave at elevated temperature and pressure.

In the production of organic triplex glass for certain purposes (light-filtering, Heat, reflecting radio rays, electrically heated and other types of glass) are glued using the triplex method so that one of two glasses one inorganic, right-hand-permeable applying functional Üherzug by thermal vacuum evaporation (see American Aviation, 1969,33, No. 2, p. 50; Material Engineering, 1969, 70, No. 2, Pp. 32-34).

In addition to solving the problem of developing solid organic triplex glass for specific purposes, the triplex process is also used as a process for protecting against external influences from inorganic coatings applied to the surface of organic glass by thermal vacuum evaporation are upset.

A disadvantage of the known method is that during the gluing in the manufacture of a Laminated pane, treating in a vacuum and pressing to local mechanical damage of the above-mentioned inorganic, light-partially transparent coating due to the action of the adhesive polyvinyl butyral film leads. This leads to large reject rates (approx. 30%) of the organic triplex glass obtained.

From DE-OS 24 07 363 a semi-reflective glazing with at least one film made of gold, silver or copper is known which is deposited on a transparent substrate, and optionally with an or several layers of materials intended to increase the adhesion of this film.

The proposed layer that is supposed to protect the functional layer made of gold, silver or copper is one Layer of quartz, glass, aluminum oxide or magnesium fluoride. This protective layer is made with the help of a Electron gun placed in a pressure chamber by evaporation. This is done in the introduction to the description the mentioned OS stated that this proposal is disadvantageous because after the known interconnection process only very difficult to obtain layers of homogeneous thickness and the protective layer modify the transmission spectrum of the glazing against visible radiation. It will therefore Suggested in the OS to select one instead of the protective layers suggested as inexpedient, which has a semiconducting composition which has a quasi-metallic reflection in the infrared range having, the thickness of this layer is chosen such that the transmission spectrum of the Base layers is not significantly changed. Layers made of are particularly advantageous Tin oxide, indium oxide doped or suggested as a mixture and titanium nitride. Their protective layers should applied to the metal to be protected by radio frequency discharge.

The subject matter of the invention is evident from the preceding claim.

The task of the known solution was therefore to provide a glass, in particular an inorganic glass, with a Metal layer through a protective layer against mechanical damage, especially when cleaning windows to protect and the like. The object of the present invention, however, was to provide a functional layer on one organic glass-like substrate when glued to another organic glass from damage protect with the adhesive or during the gluing / u. It is not obvious to the expert that only a certain combination between functional cover and protective cover from the multitude of possible, solves the problem posed according to the invention. Based on the statements in the latter OS

had the expert even doubt have, for example, whether a combination of gold and quartz at all effective, it had to pass even greater doubt, for example, oh, a combination of aluminum and magnesium fluoride is effective because aluminum is mentioned only as aluminum oxide in the protective layer. To make matters worse, according to the invention, the protective layers were chosen not only with regard to the protection of the functional layer, but also with regard to their compatibility with the functional layer and their influence on the organic layered glass. With the solution according to the invention, glasses with the following properties are obtained:

Light filter properties

More functional coating

A. Au
50% 0 A. Cu
14% 0 A. Cu ₂
18% 0 A. Al
14% 0

Spectral light transmission Wavelength, nm

UV range Visible IR range

to 340 400-740 740-1110

30-53 14-30

45-60 48-52

12-30 15-30

10-20 10-14

where Λ = oil permeability.

All light filter materials weaken the effect of the IR range (heat reflective properties) while maintaining the required permeability in the visible area.

Radio ray reflection properties

Functional translucent cover wedge,%

Divergence the effect the radio waves

50
45-50

around 30-40 dB
at 13-2OdB

Electric conductivity
Functional gold coating

With a light transmission of 50%, a specific electrical power of 0.2 to 0.3 W. adhered to. Under these conditions any icing is removed.

The proposed procedure is carried out as follows.

The organic glass (polyacrylate, polycarbonate glass, etc.) is fastened in a vacuum chamber and the glass surface to which the inorganic, partially translucent coating is to be applied, is cleaned. The surface is cleaned by ion bombardment of the surface with a glow discharge. An inorganic light partial passage is then applied to the cleaned surface of the organic glass. functional coating by thermal vacuum evaporation (residual pressure of 10 ~ ⁴ to 10- ⁵ Torr) of the above compounds. In some cases it is necessary to treat the coating obtained by vaporising the surface of the organic glass with the inorganic substance in the medium of a gaseous substance. During the evaporation of the sulfide, for example, the subsequent treatment of the coatings obtained in sulfur is required

ίο The thickness of the functional coating is 5 to 500 nm, depending on the type of substance to be applied and the intended use of the triplex glass.

After applying the inorganic light component

In the case of a negligent, functional coating, the inorganic, colorless, partially translucent protective coating is applied to the eh.2 surface by thermal vacuum evaporation (residual pressure of 10 ⁴ to 10 ⁵ Torr) of the corresponding substances. The thickness of the protective coating is 50 to 1000 nm, depending on the type of compound to be applied and the intended use acs triplex glass.

Then the so-called organic glass is glued, one functional and one Has inorganic protective coating, with the similar coating-free organic glass. On the surfaces of the two organic glasses is an adhesive polyvinyl ethylal layer for this purpose upset. The polyvinyl ethylal layer that promotes adhesion is applied to the entire surface to be glued

so on the surface of the second organic glass which has no inorganic coating. What that Organic glass with the inorganic coating is concerned, the adhesion-promoting polyvinylethylal layer is used only on sections of its to be glued

Ji surface applied to the said inorganic Do not have coatings. When applying the inorganic functional and the inorganic Protective coating by thermal vacuum evaporation can be used, for example, to create a generally p'ugs-free zone keep above the surface perimeter of the organic glass by applying a mask of appropriate The mold used during the coating process only on the named surface zone of the organic

4> glass applied. Wine has inorganic coatings the entire surface of the organic glass to be bonded is applied, the adhesion-promoting Polyvinyläthylalschicht not be applied to the surface of this glass at all.

■ in After applying the adhesive polyvinyl ethylal layer the composite pane is produced, consisting of the organic glasses to be glued with the glued in between Polyvinyl butyral film. The composite pane is turned into a

■ 55 rubber bag inserted, placed under vacuum and in pressed in an autoclave at 98-150 ° C and a pressure of 3 to 18 atm.

This enables high quality products to be made without defects; H. without mechanical damage the functional coating.

example 1 Light filtering organic tripiex glass

b ^r> on the surface of an organic glass of polycarbonate is brought to a functional coating of Kupferf l) -si> LFID (Cu 2 S), which has the predetermined Spektraleigenschaftcn. To do this, the customer (l) -

sulfide (10- ⁵ Torr) at first evaporated in vacuo. During the evaporation, the copper (l) sulfide dissociates into copper and sulfur, whereby the coating obtained on the surface of the organic glass contains copper and copper oxide in addition to copper (l) sulfide. So that the coating consists entirely of copper (1) sulfide and has a green color, the glass with the coating applied by thermal vacuum evaporation is placed in a vacuum thermostat, where the coating is treated with sulfur vapors at a residual pressure of 1 to 10 Torr between 70 and 80 "C for 2 to 6 hours (depending on the thickness of the coating).

Sulfide wearing the glass with the functional coating consists of copper (1) into the vacuum chamber, and brings a protective coating of lithium fluoride by thermal evaporation of lithium fluoride in vacuo at 10- ⁵ Torr residual pressure on the said coating.

The organic glass, which has inorganic coatings, is then bonded using the triplex method the similar coating-free organic glass.

Example 2
Light-filtering organic triplex glass

The light-filtering organic triplex glass is produced analogously to Example 1, but with the difference that the functional coating, obtained by thermal evaporation of copper (I) sulfide, not with sulfur vapors before applying the protective coating. Lithium fluoride is treated. The functional cover therefore consists of copper (I) sulfide, copper and copper oxide and is not green in color as in Example 1. but orange.

Example 3

Radio rays reflective
organic triplex glass

On the surface of an organic polymethyl methacrylate glass the functional aluminum coating is applied by thermal vacuum evaporation of aluminum. On top of the aluminum coating, a protective coating of magnesium fluoride wini through its ίο thermal vacuum evaporation applied. Then the gluing takes place in the triplex process organic glass having inorganic coatings with a similar non-coating organic glass.

Example I 4

Electrically heatable organic triplex glass

Thermal vacuum evaporation is used to apply to the surface of the organic polymethyl methacrylate glass a gold coating, which serves as a heating element and has current-carrying rails, on. On the Gold coating is the protective coating made of titanium oxide by thermal vacuum evaporation of titanium oxide upset. Then the bonding takes place; * in the triplex

r> process of organic glass, which has inorganic coatings, with the similar organic coating-free Glass.

Example 5
Heat reflecting organic triplex glass

The manufacture of heat reflective glass is similar to that described in Example 3 The difference, however, is that a Germani-Γ) umÜberzug is used, which was applied by thermal vacuum evaporation of germanium.

Claims (1)

Claim: Process for the production of light-filtering, heat or radio rays reflecting or electrically heatable organic triplex glass by applying an inorganic one for light rays partially permeable, functional coating on the organic glass by thermal evaporation in a vacuum and gluing said ι ο glass to a coating-free organic glass by means of a polyvinyl butyral film, characterized in that that before bonding to the functional coating by thermal vacuum evaporation applies a protective coating, the ι> with copper sulfide or copper (l) sulfide, copper and Copper oxide consists of lithium fluoride as a functional coating, and magnesium fluoride for aluminum or germanium and gold from titanium oxide. 20th