DE10131932C2 - Process for producing a heat-reflecting layer system for transparent substrates and layer system produced thereafter - Google Patents

Description

The invention relates to a method for producing a heat-reflecting layer systems for transparent substrates, preferably glass, which consists of at least one electrically highly conductive functional layer to which at least one metallic Blocker layer - also called intermediate layer - immediately adjoins, and several highly refractive antireflection coatings, according to patent 100 46 810. The layer system is also referred to as a low-e layer system.

Layer systems of this type on glass are suitable for subsequent hardening or bending process of the coated glass pane, e.g. B. for vehicles, preferably also as heat insulating safety glazing.

A large number of such heat-reflecting layer systems are known. The layer system generally consists of a functional layer, base and top layer, the latter as Anti-reflective layers serve. The individual layers can be in the overall system Repeat several times. Usually used as a functional layer for heat reflection Precious metals - preferably silver - due to their good selective reflectivity already used for thin layers. The anti-reflective layers are used for Improvement of the optical properties in the visible wavelength range and are at least on one side of the functional layer or on the one above the functional layer applied blocker layer arranged. The anti-reflective layer affects decisive is the overall layer system with regard to its electrical property, d. H. Conductivity, mechanical properties, e.g. B. scratch resistance and chemical Properties, e.g. B. Resistance to acids.

It is known to improve the optical properties, in particular to increase it the transmission in the visible range, highly refractive anti-reflective layers, preferably dielectric metal oxides or nitrides, above and / or below the Arrange functional layer. When applying a metal oxide as an anti-reflective coating on the functional layer and when bending and / or hardening coated glass panes the associated heating leads to the oxidation of the functional layer, to Diffusion of the silver into the anti-reflective coating, for the diffusion of components of the Anti-reflective coating in the silver and / or to agglomerations within the  Functional layer. Through these effects, the reflectivity of the coating for Thermal radiation and the transmission in the visible range reduced.

To avoid these disadvantages, it is known to use suitable functional layers Protect materials - called blockers - from partial destruction by one Blocker layer is arranged above and / or below the functional layer (DE 38 25 671 A1; US 4,894,290; DE 196 32 788 A1).

Another possibility is to suppress the partial oxidation of the functional layer the use of nitrides as an anti-reflective coating is known (US 5,837,108). However, can generally also not here, particularly in the case of hardenable or bendable layer systems the arrangement of a blocker layer can be dispensed with entirely. Besides, that is Refractive index of metal nitrides is generally significantly lower than that of metal oxides leads to less anti-reflective coating (bandwidth).

It is known not to improve the properties of the anti-reflective coating to be arranged only as a single layer, but a sub-layer system consisting of at least two To use layers, which are mostly made of dielectric material (DE 39 41 026 A1; DE 39 41 027 A1). However, it was found that by combining the two individually assessed properties of the individual layers as a partial layer system in particular the mechanical resistance is adversely affected.

It has been used to remedy the shortcomings of the prior art with the patent 100 46 810 a heat reflective layer system for proposed transparent substrates, which consists of at least one anti-reflective layer, at least a functional layer made of silver and at least one on one side of the functional layer applied blocker layer made of a metal or a metal alloy and at least a cover layer, which is formed by vapor deposition or sputtering in a vacuum can be applied by applying the metal particles for the blocker layer during the coating is regulated so that the silver of the functional layer and a gradient layer is formed as a blocker layer in the metal of the blocker layer, that at the production of an anti-reflective coating from several individual metal oxide layers Supply of the metal oxide particles to be applied for the individual layers is regulated in such a way that a gradient layer is created and that in the production of the gradient layers the regulation takes place in such a way that the proportion of the layer material in the  Coating sequence first layer to be applied from 100% to 0% and in opposite directions the proportion of the layer material of the subsequent layer changes from 0% to 100%. The layer system produced by the proposed method consists of a Blocker layer made of a metal or a metal alloy, which with the silver of the Functional layer forms a gradient layer, and when the anti-reflective layer is off consists of several individual layers, it is a gradient layer made of the metal oxides Individual layers.

The use of metal oxides for the anti-reflective layer or layers is not a problem optimal solution.

The invention has for its object the method for producing a heat reflective layer system according to the patent 100 46 810 with respect to further used material. It should also be color neutral, mechanically high resilient, chemically stable, long-term stable and temperature-resistant. The layer system should harden without reducing light transmission or emissivity and be flexible.

According to the invention the object is achieved according to claims 1 and 2.

The essence of the invention is that when building up the anti-reflective coating several individual layers according to the patent 100 46 810 these from below Different metal nitrides exist and the material content of a layer from the beginning 100% to 0% reduced and the proportion of material in the following layer is reversed increased from 0% to 100%. It was found that such a gradient layer made of metal nitrides also improves the overall properties of the system.

The method according to the invention is known to be carried out in such a way that the Coating stations for the production of the anti-reflective coating for every metal nitride layer in the coating system so that the Distributions of the particles to be applied on the substrate level or the previous one Partially overlay already applied layer. The properties of the gradient layer can be easily with means of process control, e.g. B. Distance of the coating stations, parameters of energy feed-in, ratio of the feed-in powers, influence.

The invention is described using an exemplary embodiment. The associated drawing shows a layer system with function and blockers designed as a gradient layer layer and one-sided anti-reflective layer.

The method according to the invention is carried out as follows:
The figure shows a layer system in which, in a first method step, an anti-reflective layer 1 is applied to the glass pane as a gradient layer composed of quasi two individual layers made of AlN and Si ₃ N ₄ . The proportion of the first applied material - AlN - continuously decreases during the application from a proportion of 100% over the thickness of the layer to 0%, while the proportion of the next material - Si ₃ N ₄ - increases in the opposite direction from 0% to 100% , Thereafter, the function is applied from 2 Ag and on the functional layer 2 from the Ag blocker layer 3 as a continuous gradient layer of NiCr and Ag. Layer Within this blocker layer 3 , the gradient of both materials is 0% to 100% and vice versa. The transition from functional layer 2 to blocker layer 3 is not smooth, but there is a separation of the two layers, although it cannot be determined exactly. An upper anti-reflective layer 4 made of TiO _{2 is} applied thereon.

Claims (2)

1. A method for producing a heat-reflecting layer system for transparent substrates, in particular glass, consisting of at least one anti-reflective layer, which consists of several individual layers, at least one functional layer made of silver and at least one side of this functional layer applied metallic blocker layer consisting of the silver and the Metal is performed as a gradient layer and the proportion of the metallic layer material of the first layer changes from 100% to 0% and, in the opposite direction, the proportion of the following metallic layer material changes from 0% to 100%, as well as at least one anti-reflective or top layer, the layers be applied by vapor deposition or sputtering in a vacuum, according to patent 100 46 810, characterized in that the individual layers of the anti-reflective layer are produced from different metal nitrides and the supply of the metal nitride particles to be applied for the single layer is regulated in such a way that a gradient layer is formed, the proportion of one metal nitride of one layer of which is changed from 100% to 0% and, in the opposite direction, the metal nitride of the other layer is changed from 0% to 100%. 2. Heat reflecting layer system, produced according to claim 1, consisting of at least one anti-reflective coating from several individual layers, at least a functional layer made of silver, at least one on one side of the functional layer applied metallic blocker layer as a gradient layer from this Metal and silver, the proportion of the metal in the blocker layer becoming silver its thickness from 100% to 0% and the opposite proportion of silver to metal Blocker layer changes continuously or discontinuously from 0% to 100%, as well at least one anti-reflective, adhesive, protective and / or top layer, according to patent 100 46 810, characterized in that the individual layers of the Anti-reflective layer consist of a metal nitride and a gradient layer are, the proportion of the layer material that in the coating sequence first layer to be added from 100% to 0% and the opposite proportion of the layer materials of the subsequent layer from 0% to 100% continuously or dis changes continuously.