DE3139104A1 - Method of producing a high-temperature insulation - Google Patents

Abstract

In the method of producing a radiation-resistant high-temperature insulation, a high-temperature insulating material is immersed in a liquid coating material and then roasted. The insulating material used is a porous, heat-resistant material such as ceramic fibre material. If the insulation is used in the field of solar energy, SiC and a hardener are preferably used for the radiation-opaque coating material.

Description

Process for the production of a high temperature 1 insulation

In some areas, e.g. in the use of solar energy t concentrating mirror systems are heat insulating materials for high Temperatures required that are exposed to the concentrated radiation. For such Purposes can be the conventional high-quality flea temperature insulation materials, such as felt, A1203 or SiO2 sheets or fibers, do not use them because they are insulations fail after a short time when exposed to concentrated light or are radiolucent will.

The invention is based on the object of a method of the above to develop said type, with which a radiation-resistant high-temperature insulation can be produced k d nn.

According to the invention, the object is achieved by coating at least one side a high-temperature insulation material with a largely radio-opaque Layer dissolved.

As a result, the radiation no longer penetrates the insulation material one, so that its insulating properties are retained for a long time. Also works the coating has a beneficial effect on the effective insulation strength.

Another advantage of the method according to the invention is to be found therein see that especially when using porous or fibrous insulating materials the coating at the same time provides protection against environmental pollution and pollution offers. In this way, the life of the insulation is increased compared to the conventional one Insulations prolonged by increasing the abrasion and weather resistance as well as the durability can be improved under mechanical stress.

The inventive method is also suitable for the production of Isolation of all shapes.

The labeling the insulating material by immersion in liquid coating material and then Heating take place.

In the case of large-area insulation, it is advantageous if the radiopaque Layer is sprayed onto the insulating material.

When using the insulation in a place similar to your sunlight According to a further development of the invention, the radiation spectrum is a coating made of silicon carbide (SiC) and a hardener is provided. Such shifts drove Too high radiopacity iii area of solar rays.

Depending on the requirements of the respective application, a harder one can be used Layer made of TiO2 or a layer for lower radiation intensity made of MnO and the hardener. The hue of the coating also lets through the choice of these materials or their mixture, if necessary, also includes SiC Retention the required radiation and permeability 5 i gkei determine t accordingly. As harders are heat-resistant and radiation-resistant Harder provided.

Using an absorbent insulation material you get radiation-resistant Insulations with excellent adherence to the radio-opaque layer and only by dipping into or spraying on the mixture of a hardener and a coating material suitable for the respective application and subsequent hardening. The insulation material soaks up the hardener that thereby an intimate connection of the insulation material with which is relatively evenly forming layering material.

Suitable materials for thermal insulation are absorbent, porous insulating materials, preferably ceramic fiber material made of SiO2 or SiOo and Al 2 03. The density of the insulation material can preferably be 100 to 300 kg / m 2.

According to one embodiment of the invention, a 100 to 300 kg / m3 dense insulating material in a thick mixture of hardener and coating material Immersed for a few seconds and then annealed to around 600 - 1200 ° C. With an immersion time of just 2 seconds, a largely radiopaque can be achieved Create Layer A longer immersion time, up to about 1 minute or more, is required Requirements for a higher mechanical stability of the insulation can be advantageous. If the coating liquid is standing still, the coating material settles relatively quickly, so that the insulation after a short immersion time - that of the density of the mixture depends - just soaks up even harder, being the radiopaque Layer reaches a thickness in the range of a millimeter.

An increase in the coating thickness is achieved in that the Mixture liquid is kept in motion during the immersion process.

The method according to the invention was carried out on the following examples carried out: Example 1 A plate made of 70% A1203 and 30% Si02 as high temperature 3 Insulation material with a density of 200 kg / ni was coated on one side as follows. The application limit of this material is 1600 ° C. The fibers of the plate are 60% crystalline and 40% amorphous.

From an ifli trade under the trademark "Carborundum -Härter W - blue "available liquid hardener (viscosity = 4 centipoises) and silicon carbide powder With very fine grain (99% pure SiC) in the same volume ratio of harder / SiC 2/1 a pulpy liquid was mixed.

The insulation material was in this - not moving - mixture t submerged the surface for between 2 seconds and 2 minutes. It sucked Insulation material on the harder and the SiC sat evenly distributed on the immersed surface. Then the sample was in the furnace at Annealed at a maximum of 11000C for up to 3 hours and cooled in air.

With a coating thickness of less than 1 mm, a Isolation with only 0.20 'transmission for the Sorlnenstrahl-Spectrum can be generated. The coating is gray - black.

Example 2 A procedure as in Example 1 was carried out in the only instead of SiC titanium oxide (TiC2) for the Eeschichturl; was used. The volume ratio of the hardener / TiO2 mixture was 2/1 Herewith a colored layer was created at. The insulation coated in this way left 17.5 ° /, the emitter in the solar spectral range.

Example 3 A procedure as in Example 1 was followed only the SiC was replaced by MnO. The transmission of the with a brownish Layer-related insulation was 195% this time.

The insulation material (under the trade name Pyrostop 200/1600 - obtainable) alone, however, leaves about the same strength, density and irradiation 37 »5% of the radiation passes through.

In all examples it was found that the samples neither underwent a deformation in the kiln during subsequent irradiation. Even after one hour of irradiation with 540 kW / m², the surface did not show any Damage. During the irradiation, the surface reached a temperature of around 1100 ° C.

It has also been shown that the penetrating into the insulation material Hardener has a relatively homogeneous transition from the pure insulating material to the coating which leads to a good thermal expansion compensation and thus a good one Ensures adhesion of the coating. The mechanical and optical properties the coating are determined by the choice of coating materials or their combination certainly

Claims (9)

P a t e n t a n s p r ü c h e 1. Process for producing a High-temperature insulation characterized by a coating on at least one side a high-temperature insulation material with a largely radio-opaque Layer. 2. The method according to claim 1, characterized in that the insulation material is immersed in liquid coating material and then heated. 3. The method according to claim 1, characterized in that the strahleTdurchla.ssige Coating is sprayed onto the insulating material. 4. The method according to any one of the preceding claims, characterized in that that for the Beschichtunc a mixture of Stliziuiukarbid (SiC) and a temperature-resistant Hardener is used. 5. The method according to any one of claims 1 to 3, characterized in that that for the coating a mixture of a temperature-resistant hardener and one or more of the following materials, silicon carbide (SiC), titanium oxide (Ti02) and manganese oxide (MnO) is used. 6. The method according to any one of the preceding claims, characterized in, that as a high-temperature insulation material, an absorbent, porous material, in particular a ceramic fiber material made of SiO2 or SiO2 and Al2 03 is used. 7. The method according to claim 6, that the density of the high temperature insulation material about 100 to 300 kg / m3, in particular about 200 kg / m3. 8. The method according to any one of claims 4 to 6, characterized in that that the hardener and the coating material become more or less viscous Mixture are mixed that this mixture is applied to the insulation material is, and that finally the insulation coated in this way at about 600-1200-C to annealed for about 3 hours and then cooled in air. 9. The method according to claims 7 and 8, characterized in that that the coating unysmat eri a 1 by immersion for 2 seconds to 1 minute of the insulation material into the liquid mixture of hardener and coating material is applied.