DE102006045451A1 - Heat-insulating element for electric radiant heating elements, e.g. hot plates or rings, comprises pressed or sintered material containing pyrogenic silica and treated ash from burnt biological material, e.g. rice husks - Google Patents

Abstract

Formed thermally-insulating elements (2, 3) consisting of pressed and/or sintered thermal insulation material (I) containing pyrogenic silica, in which material (I) also contains 1-50 wt.% burnt and treated biological material (II). An independent claim is included for a method for the production of such elements (2, 3) by pretreating and then burning biological material (II) and using the ash (optionally after further treatment) together with pyrogenic silica as material for the production of insulating elements (2, 3).

Description

Field of application and status of the technique

The The invention relates to a thermal insulation molding as well a method for its production. Such a thermal insulation molding is by Pressing and / or sintering of thermal insulation material produced, wherein the thermal insulation material fumed silica contains or silicon-containing, in particular has silicon dioxide.

Such thermal insulation molding are for example from the EP 1236949 A as well as the EP 750444A known. The disadvantage of known such heat-insulating molded bodies is that the fumed silica is relatively expensive and this greatly influences or increases the overall costs of such a heat-insulating molded body.

Task and solution

Of the Invention is based on the object, a Wärmedämmformkörper mentioned above and to create a corresponding manufacturing process with which Disadvantages of the prior art can be avoided and especially on relatively cheap Way created a thermal insulation molding can be.

Is solved this task by a thermal insulation molding with the features of claim 1 and a method for its preparation with the features of claim 15. Advantageous and preferred embodiments The invention is the subject of the further claims and will become hereafter explained in more detail. Some the following listed Features are described only once. However, they both apply regardless for the Thermal insulation molding as also for his Production method. The wording of the claims is expressed by express Reference made to the content of the description.

According to the invention the thermal insulation material, made of which the thermal insulation molding is between 1% and 50% biogenic or biological Material that is burned and possibly pretreated and / or has been treated. The replacement of otherwise used pyrogenic silica through biological material gives a significant cost advantage, even if it is only a partial replacement.

In Embodiment of the invention comprises the biological material shells of cereals or rice in particular. This biological material will, under certain circumstances after a pretreatment, burned and the ashes, possibly after a post-treatment, the thermal insulation material admixed or used for producing a thermal insulation molding.

Of the Advantage of using biological material is that it partly in very large Quantities is available. Especially if the biological material Grain trays or rice husks is, so there is this as a waste product The grain processing, so to speak, for free and in large quantities.

As a pretreatment, the biological material can be placed in a solution with water or an aqueous solution, wherein it may be an oxidizing solvent. This solvent is preferably peroxide, nitrate or permangate. Particularly advantageously, the biological material is placed in hydrogen peroxide. This pretreatment results in a particularly good subsequent dissolution of the silicon components from the biological material. This is on the WO 02/092507 A1 in particular for executability issues, the content of which is made explicit reference to the content of this description.

In Another embodiment of the invention, it is possible that said solution in the Preheated warmed up is, in particular to a temperature between 20 ° C and 100 ° C. Especially Advantageously, a heating takes place to a temperature above 80 ° C, where it possible is the pressure over Increase normal pressure and thus to reinforce the effect.

It is possible, too, before this step of pre-treatment yet another step to carry out the pretreatment, namely not just to wash the biological material and of gross impurities but also with hot aqueous solution or hot steam pretreat. In this case, the biological material, for example in the hot aqueous solution be inserted.

Advantageous this pretreatment step takes a longer time, especially a few hours, for example at least 12 hours up to 48 hours. The temperature the hot ones aqueous solution or of the hot Steam can be between 60 ° C and 100 ° C lie.

It may be beneficial to the biological material before insertion in the watery solution or before the aforementioned step of treating with aqueous solution or hot Steam not only to wash, but also to grind or crush. It has been shown that then the extraction of silicon dioxide especially possible is.

The Burning of the biological material causes oxidation. Advantageous The biological material can be burned under increased oxygen supply be, so that as possible enhanced oxidation takes place. In a further embodiment of the invention, the temperature of the oxidizing or burning in a range between 400 ° C and 1600 ° C varies become. Advantageously, the temperature is between 500 ° C and 800 ° C.

Of further it is possible the biological material or its ash after burning calcine and then finely grind. The material obtained thereby can then be used particularly well for the production of a thermal insulation molding.

The Material for the addition to the thermal insulation material can also according to the invention be excellent, that impurities in the range below 300 ppm lie. Advantageously, they are below 100 ppm. Such impurities can from the 1st main group or the 2nd main group of the periodic table such as sulfur or phosphorus. These will as especially harmful viewed as they called the radiators for radiant heating in the Damage continuous operation. The particle sizes of Impurities can Kgs in the range between 2 μm and 100 μm lie. In particular, they are in the range between 4 microns and 50 microns.

By The aforementioned method steps, it is possible that the treated biological material has more than 95% silica. Especially advantageous it is at least 99% silicon dioxide.

The silicon dioxide produced from biological material as described above can amount to a maximum of 30% of the fraction of fumed silica in the thermal insulating molding. It is advantageous about 10%. Furthermore, the thermal insulation material can be mixed with a special silica having an above-average BET surface area. This may advantageously be more than 130 m ² / g.

Of others can the thermal insulation molding or be added to the material for its preparation turbidity. These reduce the permeability of infrared rays and thus contribute to a better thermal insulation behavior in, in particular, when the thermal insulation molding for use with radiant heating elements serves.

to Improvement of the strength can be Thermal insulation molding fibers be added. For this purpose, for example, offer ceramic fibers at. In a further embodiment of the invention, binders can be used be added.

Of the Thermal insulation molding can on the one hand be plate-like or flat. On or above one essentially flat surface can radiant heating elements can be arranged, as is known in the art. The radiant heating elements in the form of annealed wires or flat strips can partly in the surface be embedded.

In an alternative embodiment of the invention, the thermal insulation molding may have ring shape. Such a ring may be between one of the radiant heating elements carrying the aforementioned surface and a cover, for example, a glass ceramic plate of a Hob, be arranged.

These and other features go out the claims also from the description and the drawings, wherein the individual features each for alone or in the form of subcombinations an embodiment of the Invention and other fields be realized and advantageous also for protectable versions can represent for the protection is claimed here. The subdivision of the application into individual Sections and intermediate headings restrict the not in its generality among these statements.

Brief description of the drawings

embodiments The invention are shown schematically in the drawings and will be closer in the following explained. In the drawings shows:

1 a section through a radiant heater with a thermal insulation molding according to the invention and

2 an oblique view of the radiant heater 1 ,

Detailed description the embodiments

In the 1 and 2 is in each case an electric radiant heater 10 shown at the bottom of a glass ceramic plate 8th is pressed. The radiant heater 10 has a receiving tray 1 on, preferably made of sheet metal. In this is a thermal insulation molding as Un terlage 2 inserted. The underlay 2 carries in recesses 9 in a known manner heating conductor 5 ,

In the middle area has the base 2 a frustoconical survey 4 on. This serves as a support for the temperature sensor 7 of the temperature monitor 6 , This is well known in the art.

Outside of the pad 2 lies on this inside the receiving dish 1 an outer circumferential, ring-like edge 3 on. This edge 3 serves as a spacer to the radiant heater 10 at a predetermined distance from the glass ceramic plate 8th to keep. He also forms a thermal insulation to the side.

In 2 is the sake of clarity on the presentation of the heating element 5 and the associated recesses 9 has been dispensed with.

From the drawings it can be seen that the requirements for the thermal insulation in the form of the pad 2 and the spacer element in the form of the edge 3 are different. The underlay 2 carries the heating conductor 5 and is exposed to higher temperatures. On the other hand, it has to attach the heating element 5 be educated.

The edge 3 again requires a certain strength, especially compressive strength to accommodate the contact pressure can. There are also requirements for the properties as thermal insulation.

Both with the underlay 2 as well as at the edge 3 the use of the thermal insulation material according to the invention is possible. For the edge 3 In general, the proportion of fibers and / or binders can be selected higher. Otherwise, the same material can be used with any of the compositions described above, wherein, for example, about 10% of the fumed silica in the thermal insulation material has been replaced by appropriately treated rice husk ash.

Claims (24)

Thermal insulation molding ( 2 . 3 ) consisting of compressed and / or sintered thermal insulation material, the thermal insulation material containing fumed silica, characterized in that the thermal insulation material has a proportion of 1% to 50% of burned and treated biological material. Thermal insulation molding after Claim 1, characterized in that the biological material cereal bowls or rice husk and the thermal insulation material ash of these shells contains. Thermal insulation molding after Claim 1 or 2, characterized in that the cereal bowls or rice husks are pretreated by placing in a solution with Water and an oxidizing solvent, preferably the solvent Peroxide, nitrate or permanganate is and especially the cereal husks or rice husks are inserted in hydrogen peroxide. Thermal insulation molding after one of the preceding claims, characterized in that the cereal bowls or rice bowls or their ashes calcined after calcination and finely ground have been. Heat-insulating molding according to one of the preceding claims, characterized in that the proportion of combusted and treated biological material to a maximum of 30% of a part of fumed silica in the thermal insulation molding ( 2 . 3 ), preferably about 10%. Thermal insulation molding according to claim 5, characterized in that at least a portion of the fumed silica has a larger than average BET surface area, preferably more than 130 m ² / g. Thermal insulating molding according to one of the preceding claims, characterized in that the burned and treated biological material contains more than 95% SiO ₂ , preferably at least 99% SiO ₂ . Thermal insulation molding after one of the preceding claims, characterized in that contaminants of the burned and treated biological material, in particular impurities from the 1st main group or the 2nd main group of the periodic table such as sulfur or phosphorus, in the range below 300 ppm, preferably below 100 ppm. Thermal insulation molding after one of the preceding claims, characterized in that the grain sizes of the burned and treated biological material in the range between 2 microns and 100 microns, especially in the area between 4 μm and 50 μm. Thermal insulation molding after one of the preceding claims, characterized by turbidity to reduce permeability of infrared radiation. Heat-insulating molding according to one of the preceding claims, characterized in that it is dish-like ( 2 ) is ausgebil det with a substantially flat surface, on or above the radiant heating elements ( 5 ) are arranged. Heat-insulating molding according to one of claims 1 to 10, characterized in that it has a ring shape for the arrangement of radiant heating elements ( 5 ) in the in the ring ( 3 ) or space. Heat-insulating molding according to one of the preceding claims, characterized that it has fibers. Thermal insulation molding after one of the preceding claims, characterized in that it is used to increase the strength of the binder having. Process for the production of a thermally insulating molding ( 2 . 3 ) according to any one of the preceding claims, characterized in that biological material is pretreated and then burned, and this ash is used after further treatment optionally together with fumed silica as thermal insulation material for the production of a thermally insulating molded body ( 2 . 3 ). Method according to claim 15, characterized in that that the biological material comprises cereal husks or rice husks. Method according to claim 15 or 16, characterized that the biological material is pretreated before burning by inserting into a solution with water and an oxidizing solvent, preferably the solvent Peroxide, nitrate or permanganate, and in particular the biological material is placed in hydrogen peroxide. Method according to claim 17, characterized in that that the solution heated is before the insertion of the biological material, preferably on a temperature between 20 ° C and 100 ° C, especially between 80 ° C and 100 ° C, preferably the pressure is higher is as normal pressure. Method according to claim 17 or 18, characterized that the biological material before being placed in a solution with Water and an oxidizing solvent pretreated with hotter aqueous solution or hot steam, preferably by longer Loading. Method according to claim 19, characterized that the biological material for a minimum of 12 hours with the hot aqueous solution or hot steam is pretreated, preferably between 12 and 48 hours, wherein in particular the temperature is between 60 ° C and 100 ° C. Method according to one of claims 15 to 20, characterized that the biological material is washed in a first step and then ground. Method according to one of claims 15 to 21, characterized that the biological material is burned under increased oxygen supply. Method according to one of claims 15 to 22, characterized that the biological material oxidizes at temperatures between 400 ° C and 1600 ° C. or is burned, preferably at temperatures between 500 ° C and 800 ° C. Method according to one of claims 15 to 23, characterized that the biological material or its ash calcined after burning and finely ground.