DE3051009C2 - - Google Patents

Description

The invention relates to a thermal insulation board according to the Preamble of claim 1.

Such a thermal insulation board is from DE-OS 27 48 307 known. It consists of two layers, namely once an insulation layer based on silica airgel and secondly from a protective or storage layer made of mineral fibers with fillers. Through the Prefabrication to a two-layer press plate is available this insulation board for any application without assembly work or the like. For connecting the two layers for Available.

The protective or storage layer made of mineral fibers with Compared to the insulation layer, fillers only show relatively low thermal resistance, so carries little to the thermal insulation. Will the thickness of the insulation layer to achieve the required thermal resistance designed, the thickness adds up the bearing layer so that the entire thermal insulation panel compared to the thermally required thickness the insulation layer has a not inconsiderably increased thickness receives. This is like for different use cases especially when storing an electric heating coil disadvantageous for glass ceramic hot plates, because there the required thermal insulation is achieved at the narrowest height must become.  

For this special application of storage electric heating coil of a ceramic hob it is known, for example from DE-OS 28 06 367, a Insulation board based on silica airgel with one layer between the heating coil and the bottom of the Arrange the receptacle of the radiant heater, so that the excellent thermal insulation properties of this special thermal insulation material at the lowest possible height be exploited. Adequate temperature resistance in the immediate vicinity of the heating coil, which lies directly on the insulation layer by adding alumina, which one Sintering the silica airgel at temperatures above counteracts about 700 ° C; can be used as aluminum oxide in the form of reinforcing fibers or as additional Mixing in an amount up to 12% in the insulation material based on silica airgel be. The use of only the highly effective Thermal insulation material for the thermal insulation board and the waiver to additional bearing elements that increase the overall height enable adequate thermal insulation despite the flat design. There are substances for opacifiers manganese dioxide, titanium dioxide and zirconium oxide.

Insulation material of this type is extremely high Thermal resistance, but is mechanically little stable since there are already low voltage peaks tends to crumble or crumble.  

Therefore all edges must be protected, for what about a separate spacer ring between the lower surface the glass ceramic cover of the hotplate and the upper one Contact surface of the insulating material is used. In particular is the attachment of the heating coil on this material difficult. In the case of DE-OS 28 06 367 are for this Metal wire clips provided in the insulation material are plugged in. By working the heating coil in the In operation, however, these metal wire clips loosen after just a few heating cycles and cannot do so form sufficient anchoring.

Therefore, it is from DE-AS 23 39 768 or DE-OS 25 51 137 and 27 44 079 have also become known, special storage facilities for the heating coil at the top of the insulation layer, so that the At least the insulation layer does not absorb the bearing forces alone got to. If a really reliable position securing the heating coil is to be achieved, this must be done structurally significant effort.

According to the older German patent application P 30 08 505.3 The insulation layer has therefore already been proposed based on fine-pored silica airgel to be provided only in the bottom area of the receptacle and above it a molded body made of temperature-resistant and in particular mechanically strong material, such as aluminum silicate bonded with inorganic adhesive, to provide for the clean storage of the heating coil. However, this material has poorer insulation, so that a use of only the material of the insulation layer the overall height the device slightly enlarged. For that the Shaped bodies for storing the heating coil as cheap Pressed part are produced, which only in the receiving shell must be used immediately pressed against the bottom of the receptacle Contains material of the thermal insulation layer. Here is  but again relatively expensive, the material of the bottom insulation layer in a peripheral edge over the Level of the heating coil pull up what to aim for is, even if at the peripheral edge of the heating coil accordingly good thermal insulation should take place to a Avoid heating the edge of the holder.

In contrast, the invention is based on the object a thermal insulation board specified in the preamble of claim 1 genus to create that both with excellent thermal insulation properties low height, as well as a constructive simple and reliable position securing of the heating coil enables.

The solution to this problem results from the characteristic Features of claim 1.

This creates a two-layer construction the prefabricated that forms the thermal insulation material Thermal insulation board achieved in which the lower Insulating layer based on silica airgel in the known way for maximum thermal insulation is used in the tightest of spaces, while the upper bearing layer in contrast, the thermal insulation properties drop only slightly having. But that's the top one Bearing layer hardened, to achieve high temperature resistance an inorganic binder is used. Such hardening of finely dispersed, microporous produced in flame pyrolysis Insulating materials are in the older German patent application P 29 42 087.9 has been proposed, whereby also temperature-resistant inorganic binders, preferred about glass-forming substances are used; on this older application is for further details as far as expressly referred.  

However, there is a base material for the bearing layer the base of fumed alumina instead of fumed Use silica as fumed silica gives slightly better thermal insulation properties, Material based on alumina airgel, however even without additional measures is more temperature resistant. In addition, in that Insulation material of the bearing layer high temperature resistant Materials such as manganese oxide, titanium oxide or zirconium oxide be introduced to the temperature resistance To increase demand further.

The thermal insulation board according to the invention thus allows the Heating coil directly on the bearing layer of the Store insulation board. The thermal insulation board can be prefabricated in a cost-effective manner, for what one of the layers - the insulation layer or the bearing layer - made of amorphous powder of the desired Pre-pressed consistency to achieve pressure fixation, then the material of the other layer is applied and with the pre-pressed layer under higher Pressure is pressed, followed by curing suitable heat exposure can take place. This creates a one-piece thermal insulation panel, which is an intimate Connection of the insulation layer with the bearing layer Clawing of the particles guaranteed. Because the mechanically stable bearing layer for the insulation layer an additional Offers support, the two-layer formed in this way Thermal insulation board without excessive risk of Damages handled, transported and dispatched to be in another place in the invention if necessary Device to be installed. The Production of the thermal insulation board as a molded part allows moreover without any additional effort the installation of helical grooves on the top  the bearing layer, in which the heating coil is extremely simple with a high temperature resistant inorganic Glue can be glued in, as well as a trough-shaped Formation of this area of the bearing layer with rotating Peripheral edge due to mechanical strength of the material of the bearing layer immediately Support surface for the glass ceramic cover of the hotplate can form so that a separate spacer ring can be dispensed with in a cost-effective manner.

Further details, features and advantages of the invention result from the following description of a Embodiment based on the drawing.

The only figure in the drawing shows a section by a radiant heater with a thermal insulation panel according to the invention.

The radiant heater illustrated consists essentially of a receiving shell 1 made of metal, in particular aluminum sheet, and thermal insulation material in the form of a thermal insulation panel 2 , which is arranged on the inside of a peripheral wall 3 of the receiving shell 1 between the bottom 4 and a heating coil 5 . The electrically operated heating coil 5 has electrical connections, not shown, which are led out of the area of the receiving shell 1 in a suitable manner. The device shown is used for radiant heating of a glass-ceramic cover of a hotplate, the glass-ceramic plate (not shown in detail) resting on a support surface 22 and thus receiving a distance from the upper edge of the peripheral wall 3 of the receiving shell 1 and from the heating coil 5 . The peripheral wall 3 of the receiving shell 1 and thus the entire device has an essentially circular shape in plan view and is concentric with a central axis 14 .

The thermal insulation panel 2 consists of an upper bearing layer 7 , which receives the heating coil 5 in helical grooves 8 . On the side of the bearing layer 7 opposite the heating coil 5 , an insulating layer 9 is provided, which lies against the bottom 4 of the receiving shell 1 and consists of fine-pored silica airgel. This material is known per se and, in addition to the silica airgel, generally has a mineral fiber reinforcement and / or an opacifying agent; Such highly effective thermal insulation materials are marketed by the patent owner under the name MICROTHERM (registered trademark), reference being made to the relevant DE-OS 27 47 663, 27 48 307 and 27 54 956 for details of the material, to which reference is expressly made is taken. Preferably, a material for the insulation layer 9 is used, which consists of 30 to 50% fumed silica, 20 to 50% opacifying agent and 5 to 15% aluminum fibers, and is in a density of 200 to 400 kg / m³, but is not organic or inorganic needs to be hardened. Such a special thermal insulation material has a thermal conductivity that is lower than still air and is also only slightly temperature-dependent. However, the plates pressed from powdery raw materials from such a material are mechanically less resistant and difficult to manufacture. For this reason, panels made of this material are usually surrounded by a solid glass fabric during production and subsequently cut to the desired shape.

The upper bearing layer 7 consists of an aluminum oxide airgel instead of the silica airgel of the insulation layer 9 , or a suitable mixture of both aerogels. Such insulating material based on aluminum oxide airgel is resistant to higher temperatures than on the basis of silica airgel. In addition, the bearing layer 7 can contain additives to high-temperature-resistant materials such as manganese oxide, zirconium oxide or titanium oxide, if required, to further increase the temperature resistance. Above all, however, the material of the bearing layer 7 is hardened with an inorganic binder, for example with suitable glass-forming substances, as is known per se from the older German patent application P 29 42 087.9, to which for further details in connection with the hardening of such material explicit reference is made. As a result, the material of the bearing layer 7 has only slightly poorer thermal insulation properties than that of the insulating layer 9 , but is mechanically considerably stronger and more resistant, so that securing the position of the heating coil 5 directly on the bearing layer 7 no longer poses any problems. For this purpose, for example, the metal wire clips holding the heating coil 7 could be inserted into the material of the bearing layer 7 , the grooves 8 not being absolutely necessary, but it is preferred to fix the heating coil 5 in helical grooves 8 by means of a high-temperature-resistant inorganic adhesive 6 , adhesive with a Temperature resistance up to 1150 ° C, so completely sufficient, are available.

As a result of the hardening of the material of the bearing layer 7 , the bearing surfaces 22 can be formed directly on the upper side of a peripheral edge 10 which, in the illustrated manner, surrounds a trough in the bearing layer 7 for receiving the heating coil 5 on the circumference and thus radiates heat to the peripheral wall 3 of the receiving shell 1 safely avoids. To further increase the stability of the material in the area of the bearing surface 22 , the material in the upper end area 11 of the peripheral edge 10 can be additionally compressed.

The thermal insulation board 2 from the lower insulation layer 9 and the upper bearing layer 7 together with grooves 8 and peripheral edge 10 with a bearing surface 22 can be produced as a one-piece pressed part. For this purpose, the powdery material of one of the layers 7 or 9 is first introduced into a press mold and pre-pressed for fixing the pressure, the pressure should be below 25 bar and a pressure of 15 to 20 bar being preferred; good results were achieved at a pressure of 18 bar. Then the material of the other layer 9 or 7 is added and the blank for the entire thermal insulation board 2 is pressed in one go under a higher pressure of more than 25 bar, in particular at a pressure between 25 and 40 bar; good results were achieved with a pressure of 30 bar. Preferably, the bearing layer 7 is first pressed in the reverse position and remains in this position for the final pressing.

In order to achieve the compression of the end region 11 of the peripheral edge 10 , in the course of the re-pressing, a suitable edge stamp, which acts on the bearing surface 22, is subsequently compressed, so that an additional operation is not necessary for this.

The blank for the thermal insulation board 2 is expediently pressed in the position reversed relative to the operating position, since then an easier filling of the relief-like bottom of the press chamber is possible, which corresponds to the negative of the bearing trough of the bearing layer 7 for the heating winding 5 . The edge stamp for the recompression then presses against the support surface 22 on the blank from below.

After appropriate exposure to heat by heat radiation or in a conventional oven at about 700 ° C for 20 to 30 minutes, the finished thermal insulation panel 2 can be removed. For assembly, only the adhesive 6 needs to be introduced into the grooves 8 and the heating coil 5 inserted, after which the thermal insulation panel 2 with the heating coil can be inserted into the receiving shell. The molded body forming the thermal insulation board 2 has sufficient stability due to the hardening of the bearing layer 7 , the more susceptible free edge of the insulating layer 9 being protected against breakage by the rounding corresponding to the rounding between the peripheral wall 2 and the bottom 4 of the receiving shell 1 . Therefore, the thermal insulation board 2 can be shipped and assembled without great risk of damage, even if there is no hardening of the insulation layer 9 , and is of course independently tradable.

A concrete example is given below for the material of the bearing layer 7 or the insulating layer 9 .

example

Material for the bearing layer 7 :

29.2% fumed silica
29.2% fumed alumina
20.0% ilmenite
8.1% Al₂O₃
11.0% aluminum silicate fiber
2.5% hardener

Material for the insulation layer 9 :

59.6% fumed silica
34.8% ilmenite
5.6% aluminum silicate fiber

The percentages relate to percentages by weight in the raw material mix.

Claims (4)

1. Thermal insulation board for the storage of an electrical heating element, in particular for the heating coil of a glass ceramic hotplate, the thermal insulation board having at least one bottom-side highly effective insulation layer made of flame-pyrolysis, microporous, particulate insulating material as a base material, in particular with mineral fiber reinforcement and / or opacifying agent, and to which Insulating layer ( 9 ) is a bearing layer ( 7 ) with different properties compared to the insulating layer ( 9 ) and forms together with this the thermal insulation plate designed as a one-piece molded part, characterized in that the bearing layer ( 7 ) is also a microporous, made in flame pyrolysis, has particulate insulating material as the base material and preferably mineral fiber reinforcement and / or opacifier, but is hardened with an inorganic binder, and that the insulating material of the bearing layer ( 7 ) pyr has or is such alumina. 2. Thermal insulation panel according to claim 1, characterized in that the insulating material of the bearing layer ( 7 ) is enriched with high-temperature resistant materials such as in particular manganese oxide, titanium oxide or zirconium oxide. 3. Thermal insulation panel according to claim 1 or 2, characterized in that the bearing layer ( 7 ) on the insulation layer ( 9 ) opposite side is trough-shaped with an integral peripheral edge ( 10 ) which is at least approximately the thickness of a heating coil provided as intended ( 5 ) protrudes in the direction parallel to their central axis ( 14 ). 4. Thermal insulation panel according to claim 3, characterized in that the peripheral edge ( 10 ) in its a support surface ( 22 ) for the usual glass ceramic cover or the like of the hotplate forming end region ( 11 ) is additionally compressed.