DE3241516A1 - Multilayer system for thermal insulation application - Google Patents

Abstract

A multilayer system for thermal insulation application is proposed that has a high reflection capacity in the infrared spectral range and a high transmission capacity in the visible spectral range. The layer system is built up on a substrate (10) and has a metal layer (12) as a reflection layer for the infrared radiation, which metal layer is applied to the substrate (10) with the insertion of a dielectric cover layer (11). A polymeric film protective layer (14) on the side of the multilayer system facing away from the substrate (10) serves as protection against mechanical damage and as additional protection against corrosive effects on the metal layer (12). This protective layer (14) is preferably applied with the insertion of a further dielectric cover layer (13) to the side of the multilayer system on which the infrared radiation is incident. <IMAGE>

Description

9.11. 1982 Rs / Hm

ROBERT BOSCH GMBH, 7OOO STUTTGART 1

State-of-the-art multi-layer system for thermal insulation applications

The invention is based on a multilayer system the genre of the main claim. Such a multi-layer system for thermal protection application is for example known from DE-OS 30 27 256. This document describes a multi-layer system with a Support, e.g. made of polyester, on which a dielectric layer for anti-reflective coating of an overlying metal layer is applied. By suitable choice of the thickness and Bredh number of the dielectric layer there is an interference effect so that only a very small amount of light in the visible spectral range is incident on the metal layer through the carrier Part is reflected and can pass largely unhindered through the multilayer system. on the other hand is infrared heat radiation, which comes from the side facing away from the wearer, e.g. from an interior forth on the metal layer, in high

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Dimensions reflected. The arrangement described "has a further dielectric layer corresponding to the first-mentioned dielectric layer on the one facing away from the carrier Side of the metal layer that has the transmittance for visible light further increased and exerts a certain anti-corrosive effect without the reflectivity for infrared radiation noticeably impaired.

From DE-OS 27 03 688 is another heat protection device known for translucent closed room openings. This arrangement has on the inside of the room, to which the infrared radiation is to be deflected back, a plastic protective layer with low absorption capacity in the infrared spectral range, so that the infrared radiation does not heat the protective plastic layer and reflected largely unhindered in the warm room will. A metal layer sits on top of the plastic protective layer and on top of it a cover layer, which is also can consist of a plastic film, e.g. of polyethylene. This top layer has the function of mechanical carrier of the multi-layer system. It is on the outside, e.g. next to a pane of glass. Such an arrangement has a high reflectivity in the infrared spectral range, but it is Transmittance in the visible spectral range is relatively low because, on the one hand, nothing against reflection the visible light is done on the metal layer and because on the other hand the outwardly directed carrier cover layer is not modified for high transmittance for the visible spectral range.

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Advantages of the invention

The multilayer system according to the invention with the characteristic Features of the main claim has the advantage that without significant losses in terms of transmittance very good mechanical protection and corrosion protection in the visible spectral range the side of the metal layer which is not protected by the carrier is reached. To improve the Corrosion protection on the side facing away from the carrier and it is more practical to have an anti-reflective coating on this side also on this side of the metal layer a dielectric cover layer between the metal layer and inserted the protective layer. Advantageous further developments and improvements of the multi-layer system specified in the main claim are explained in more detail in the subclaims and in the following description.

drawing

An embodiment of the invention is shown in the drawing shown schematically and explained in more detail in the following description. The figure shows an arrangement each with a dielectric cover layer on both sides of the metal layer and with a polymer film protective layer on the surface facing away from the carrier.

Description of the embodiment

In the figure, 10 denotes a carrier, which is preferably made of a polyester film with a thickness consists of 10 to 200 µm. Alternatively, a 10 to 50 .mu.m thick acetate film, for example, can be used as the carrier 10 or a 20 to 100 µm thick PVC sheet can serve. On the

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A first dielectric cover layer 11 with a thickness of 10 "to U0, which contains at least one metal oxide, but preferably a mixture of titanium oxide and bismuth oxide or optionally separate layers of these metal oxides, sits around the carrier Metal layer 12, preferably a 5 to 20 nm thick silver layer, which is covered by a second dielectric cover layer 13 with the same composition as the first dielectric cover layer 11. The outer termination on the side facing away from the carrier 10 is formed by a protective layer 1 hour and the material composition of the layer sequence 10 to 13 corresponds essentially to the design described in the earlier patent application P 31 hO 100. The carrier 10 faces the incident light, the protective layer 1U sits on the side of the multi-layer system facing an interior space from which the infrared radiation impinges ft. In the event of a reversal of the radiation passage, such that the carrier 10 is exposed to the long-wave infrared radiation, the absorption in the carrier causes greater heating of the film.

The mode of operation of the multilayer system is such that overall a high reflectivity in the infrared spectral range and a high transmittance in the visible spectral range is guaranteed. For this a material with high transmittance for visible light is selected for the carrier 10, e.g. a polyester film having a thickness of 10 to 200 µm. The metal layer 12, which is preferably consists of silver, is anti-reflective by the dielectric cover layers 11 and 13, which in their thickness

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and are selected in their material with respect to the refractive index so that an interference occurs and the At the interfaces of the metal layer 12 reflected portion of the visible light is suppressed, so that With the exception of a small part, practically all incident light pass through the multilayer system can. The dielectric cover layer 11 has the same structure as that in terms of its composition Cover layer 13 and preferably contains two metal oxides, namely titanium oxide and bismuth oxide. This is where the titanium oxide comes in the task of, to increase the UV resistance of the silver layer, while bismuth oxide has a strong anti-corrosive properties Has an effect. In the illustration shown, the layers 11 and 13 are mixed layers of the two metal oxides, but the two cover layers 11 and 13 could each also have two layers with separate layers of the metal oxides.

The dielectric cover layer 13 provides protection against UV light and corrosion protection for the metal layer and thus complements the protective layer 1h in an excellent manner, which preferably serves to provide mechanical protection for the multilayer system. Since the layers 13 and 1 k have to be permeable to infrared light without significant absorption, a low absorption in the range of infrared radiation, i.e. in the wavelength range between 5 and 1 + 0, is to be observed in their structure and their choice of material. In addition to the structure already described for the dielectric cover layer 13 with regard to the protective layer Ik, polymer films have proven particularly useful, the dimensioning of the layer thickness and / or the material selection of the polymer film being chosen so that no significant absorption of infrared radiation occurs. Particularly

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thin polymer film protective layers can be produced from siloxane polymers, the polymerisation preferably taking place in a plasma. Here, hexamethyldisiloxane (HMDS) has proved particularly suitable which has a sufficient vapor pressure and can thus be inserted without great expenditure on apparatus as a vapor in the evacuated coating system and in a glow discharge as a protective layer ^ h on the dielectric top layer 13 polymerized. A protective layer 1U produced in this way has a thickness of preferably -0.2 / .mu.m, at most it reaches a layer thickness of -.1. The protective layer 1k can furthermore be formed from a lacquer film, which is preferably applied, for example sprayed, to the dielectric cover layer 13 in a thickness between 1 and 5 μm.

If, on the other hand, the protective layer "\ k is to be made thicker to increase the mechanical stability, the material is selected such that a substance with low absorption in the infrared spectral range is applied, preferably a protective layer 1U made of polyethylene or polypropylene. Here, the protective layer 1 k connected as a laminate to the rest of the layer system, the protective layer Ik itself being designed as a plastic film.

The multilayer system according to the invention thus relates to a layer sequence 11, 12, 13 applied in vacuum processes, with at least one Metal layer 12 and preferably multiple dielectric

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Cover layers 11 and 13 are vapor-deposited or sputtered. The dielectric cover layers 11 and 13 are after Composition or layered structure optimized so that that the best possible resistance to environmental influences is achieved. While the protective effect of the dielectric layers 11 and 13 when installing the multilayer system between glass in general is sufficient when using the multilayer system Glass or in the form of roller blinds or curtains an "additional" Protection especially against mechanical damage is necessary. This is done on the coated Carrier 10, i.e. in the embodiment on the dielectric Cover layer 13 as protective layer 1U is a polymer film applied, which only slightly affects the optical properties of the layer system, but one very good additional mechanical protection guaranteed. The layer thickness of the polymer film is set so that that although a sufficient mechanical protective effect is achieved, but no significant absorption the infrared radiation takes place and / or the material for this additional coating is selected in such a way that that the best possible transmission of the protective layer 1 it is given in the infrared range.

Plasma polymerization, a coating with a liquid synthetic resin according to one of the usual continuous application processes or e.g. the formation of a laminate with a further plastic film in question. ·

The formed by Plasmapolymerisatiofi organosilicon films as a protective layer satisfy the condition 1 k a low infrared absorption already due to the small layer thickness of less than 1 in order to be in this order

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procedure for technical reasons. Kine Such a protective layer 1 ¹ I illustrates but due to its tightness and mechanical properties despite their small thickness provides protection against mechanical influences and an additional protection against corrosive influences represents. Further details about the preparation and properties of such films are, for example in the publication "Plasma -Polymerization "ACS Symposium Series 108, Washington DC 1979. Of the available siloxanes, hexamethyldisiloxane in particular has proven successful as a protective layer for 1 hour , which already at a thickness of 2 µm ensures good protection and practically does not change the optical properties.

A thicker protective layer ^ h is obtained when applying a resist film from the liquid phase, because the coating films can not be applied in the above-described small thickness. When using an acrylic resin that is applied by spraying, the infrared absorption of the protective layer 1 h increases rapidly with increasing thickness, with a protective layer thickness of 20 µm already resulting in an absorption of about 50 % of the infrared radiation in the protective layer 1 h . This absorption value should not be exceeded under any circumstances, although if other lacquers with lower infrared absorption are used, thicker protective layers may prove to be permissible. In addition to acrylates, fluorocarbon-based paints, polyester resins or epoxy resins are also possible. However, since all paint systems have strong absorption bands in the infrared range, careful coordination of the thickness is necessary if the IR reflection properties of the metal

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layer 12 should be avoided. According to the tests carried out, the thickness of the protective layer should not be less than 1 μm when using a layer of lacquer, so that a closed and pore-free application is still possible. On the other hand, the lacquer layer thickness should not be more than 5 μm, so that the infrared reflectivity of the metal layer 12 does not drop below a value of about 80 % of the multilayer system without a protective layer for 1 hour . In this thickness range, the impairment of the optical properties occurring in the visible spectral range, in particular due to scattering, streaking and absorption, is still negligibly small.

H for producing a laminate of the protective layer 1 and the underlying layers of the multilayer system by using a plastic film is used as film material, preferably polyethylene, which has a good permeability to infrared radiation. A polypropylene film also has similar good properties.

Claims (1)

181 9.11- 1982 Rs / Hm ROBERT BOSCH GMBH, TOOO STUTTGART 1 Expectations {1 ·) Multi-layer system for heat protection application with high. Reflectivity in the infrared spectral range and with high transmittance in the visible spectral range, with a carrier, with a metal layer and with reflective reducing, dielectric, metal oxide-containing cover layers preferably on both sides of the metal layer, characterized in that on the side of the metal layer (12) facing away from the carrier (10) there is a protective polymer film layer (1U) is arranged with low absorption in the infrared spectral range. 2. Mehrschichtsys system according to claim 1, characterized in that the layer thickness of the polymer film protective layer (1 k ) is so small that there is no significant absorption of IR radiation. 3. Multi-layer system according to claim 2, characterized in that the polymer film protective layer (1U) consists of Siloxane polymer, preferably composed of a plasma polymer. BATH ORIGINAL U. Multi-layer system according to claim 3, characterized in that the protective layer (1U) consists of hexamethyldisiloxane (HMDS) exists. 5. Multi-layer system according to claim 3 or k , characterized in that the protective layer (iU) has a layer thickness ^ 1 / um, preferably a layer thickness ^ - 0.2 / um. 6. Multi-layer system according to claim 2, characterized in that that the protective layer (TU) consists of a paint film. 7. Multi-layer system according to claim 6, characterized in that the lacquer film protective layer (1U) is sprayed on is. 8. Multi-layer system according to claim 6, characterized in that the paint film protective layer (1U) a Thickness between 1 / µm and 5 / µm. 9. Multi-layer system according to claim 1, characterized in that the polymer film protective layer (iU) consists of a material with low absorption in the infrared spectral range consists. 10. Multi-layer system according to claim 9 »characterized in that that the protective layer (1U) made of polyethylene consists. 11. Multi-layer system according to claim 9, characterized in that that the protective layer (TU) consists of polypropylene. BAD ORIGINAL ^ O £. 4 I ^ IU A. O 12. Multi-layer system according to one of claims 10 or 1i, characterized in that the protective layer (iH) is formed from a laminate with a plastic film.