DE3916097A1 - Inorganic thermal insulation material - Google Patents

Abstract

The system includes transmission cells defining different geographical areas, each having a transmitter for simulcast address transmission at a first data bit rate and for transmitting the address and a message at a second high data bit rate. A paging transceiver generates and transmits an acknowledgment signal in response to receiving a transmitted address at the first data bit rate. Receivers located within each of the transmission cells receive the transmitted acknowledgment signal. An apparatus responsive to the received acknowledgment signal identifies the transmission cell in which the paging transceiver is located effecting the selection of the transmitter in the transmission cell in which the paging transceiver is located to transmit the address and message at the second data bit rate.

Description

The invention relates to an asbestos-free inorganic Thermal insulation compound with sound and vibration insulating properties.

The thermal insulation compositions currently used in the art are under the action of higher temperatures, which is an expansion the volume of gases or gases trapped in the mass cause evaporation of trapped water. The thermal insulation masses produced according to this principle consist of mineral components, such as. Keramsite, Vermiculite, perlite, silica and the like, being used as a binder Among other things, serving water glass, whose proportion can be up to 45%.

Organic thermal insulation compositions are based on polystyrene, Polyvinyl chloride, polyethane, polyethylene, polycarbonate and their copolymers and mixtures, and carbonic acid diamide Formaldehyde resins, silicone resins and melamine resins produced. The Structure of Organic Thermoisolationsmassen and their Density is mainly due to the use of propellants achieved during the polymerization or condensation processes. The blowing agents used are carbonates and amine compounds, during the thermal decomposition of the blowing agent carbon dioxide and nitrogen are released by the structure the mass is formed in the plastic phase.

Because of the physico-chemical properties of the organic Thermal insulation compounds is their use over a temperature range limited to about 60-80 ° C. you are Flammable and can not be in the environment of organic solvents be used.

The inorganic thermal insulation compositions used in the art can basically be divided into three groups:

The I. group comprises compositions based on cement and gypsum, wherein Grains used with only small geometric differences which are held together at the touch points. Modified products from this group contain additional Foaming constituents, the structure of the mass formed by air bubbles (foam concrete, foam silicates, Foam, etc.). In practice, aluminum powder is mixed in, causing a strong evolution of gas by the reaction with  according to the alkaline medium, whereby after cementation a gas concrete or gas silicate is created.

The II. Group includes thermal insulation compositions based on Ground glass (foam glass), being used as a blowing agent at elevated Temperature in the liquid phase of the glass of carbon, soot, calcium and magnesium carbonate.

To the III. Group belong to thermal insulation masses based on Waterglass and Silikatfüllstoffen with a particle size of below 1.0 mm. This group includes masses that already have a final structure have or whose structure is formed only under the action of heat becomes. These masses can be reinforced with tissue and as plates, such as. B. PALUSOL, are produced. In the the technology currently used thermal insulation materials and thermal insulation compounds have a number of shortcomings that their restrict practical use.

Porous plastics are resistant only in a low Temperature range, they are flammable and sensitive to bacterial media. When decaying at higher temperatures will be released toxic products.

Thermal insulation compositions based on cement and gypsum are difficult to produce and have a long curing time and a high specific weight. The use of these masses is mainly on moldings for straight and vertical spaces limited. They have bad thermal insulation parameters and easily absorb water.

The foam glass is not flammable and has proportionate good thermal insulation properties, but the heat treatment, which is necessary because of elimination of internal stresses caused a distinct anisotropy, which adversely affects the mechanical Values and performance characteristics. About that in addition, the foam glass is cut as plates, which are cut out of a block be prepared, causing the sealed cells are separated and increases the water absorbency becomes.

The group of silicate compositions is for use as thermal insulation partitions and fire partitions. The main lack of these products is that they are not water resistant  are, therefore, an additional coating with flammable Plastic coatings is necessary. The currently used Thermal insulation compositions based on silicate get their final structure only after the effect of heat at the place of their attachment. It There is no possibility for their expansion in the ambient temperature from about 20 ° C.

The invention relates to a thermal insulation compound, the also has sound and vibration insulating properties and from aqueous solutions of sodium or potassium silicates as main binder as well as additives such as: condenser, correcting agent, Catalysts, stabilizers, inert and active fillers and the formation of a porous structure at ambient temperature and at elevated temperature affecting additives is formed.

The thermal insulation compositions according to the invention can in two Modifications are present. The one modification consists of two separate main components (liquid + minced, solid constituents) which are mixed on site, the Another modification is a homogeneous mass in the form of granules or moldings, etc. Each modification may contain an additive, the already at ambient temperature, a volume expansion causes.

The object of the invention is the preparation of a thermal insulation compound, which has great thermal resistance, not flammable is to be used at temperatures of 650 to 950 ° C can, is physiologically neutral, from at elevated temperature no poisonous components are released, which also at complicated geometric shapes can be used and the additional sound and vibration insulating properties has.

This goal is achieved by a modification or refinement the water glass used as a sol in the field of homogenization and alignment of the sol particles is a very sensitive one Medium is, by formation of insulating covers, which prevent the accumulation of CO₂ on the particles and at the same time but do not disturb the electrolytic balance achieved. In addition, a change in the viscosity is effected, resulting in better wetting of the used mineral  Ingredients through the modified water glass achieved can be.

The new thermal insulation masses based on water glass exist according to the invention

• A) 70.0 to 98.0 parts by weight of sodium or potassium waterglass, 0.8 to 14.0 parts by weight of phthalates, 0.2 to 1.0 parts by weight of surfactant, 1.0 to 15.0 parts by weight of activated carbon or carbon black; and
• B) 30.0 to 90.0 parts by weight of silica (in powder or Colloid form), 0.3 to 2.5 parts by weight of iron oxide (Fe₂O₃ + FeO), 3.5 to 20.0 parts by weight of mica, 4.0 to 20.0 parts by weight Montmorillonite clay, 0.5 to 15.0 parts by weight of dicalcium silicate, 1.4 to 9.9 parts by weight of aluminum silicates (Al₂O₃ · SiO₂), and either 0.2 to 1.3 parts by weight of aluminum and titanium oxides (Al₂O₃ + TiO₂) and 0.1 to 1.3 parts by weight of calcium oxide (CaO) or 0.1 to 2.6 parts by weight of aluminum powder or Iron and silicon dust with a silicon content of at least 45%.

The thermal insulation composition according to the invention is characterized by Homogenization of the main components A and B obtained, the after mixing together a mass with liquid or viscous Consistency should form. When mixing together the Ingredients A and B are evoked reactions that the Consolidation and curing of the mass according to have. Under heat a volume increase of the mass takes place by 100 to 120%, and a reduction in specific gravity up to 45%. In the thermal insulation composition according to the invention the possibility of mixing the volume of the mass already when mixing up to 50%.

The inventive method for producing the new Thermal insulation compound is characterized in that the water glass with dibutyl and / or dioctyl phthalate with the addition of surfactant and activated carbon and then with the remaining ingredients is mixed.

Through the use of some water glass finishing additives in the production of the mass wins by chemical means Stable mass in the temperature range at 60 to 250 ° C thermoplastic Properties, thereby completing any complicated shapes in this temperature range is made possible.  

In that modification of the thermal insulation compound according to Invention which expands at ambient temperature in place of CaO and Al₂O₃ + TiO₂ aluminum powder or iron and silicon dust with a silicon content of at least 45% used.

The thermal insulation composition according to the invention is thermoactive, d. H. that basic structure that has a great thermal resistance owns, arises only after the first heat effect. The kinetics in the formation of the structural skeleton of the Thermal insulation composition according to the invention is that the shells of the sol and gel particles are destroyed and the water trapped in them is freed as Water vapor in the formation of the spherical structure in the Final phase of gelation of SiO in water glass is decisive. The formation of this structure takes place at a temperature from 180 to 300 ° C instead. At higher temperatures (up to 600 ° C) occurs a ceramic bond of the components.

The thermal insulation composition according to the invention becomes, for example in the production of fire protection partitions and Thermal insulation partitions in industrial installations, in which Thermal insulation of district heating pipes, as a protective coating of flammable materials and as a fire extinguishing agent in case of fire of liquid hydrocarbons (eg on the water surface) used. The thermal insulation composition according to the invention also has sound and vibration insulating properties, what considering the great temperature resistance of the mass for the protection of z. As electric furnaces, rolling mills, steel mills staff can be exploited. The thermal insulation composition according to the invention is both in Ambient temperature as well as in the elevated temperature range (up to 1200 ° C) non-toxic and can be applied to tissues and mats become.

The object of the invention will become apparent from the following examples explained in more detail:

Example 1

700 kg of sodium silicate with a specific gravity of 1.49 g / cm³ and a modulus of 2.8 (modulus = SiO₂ / Na₂O)  with 140 kg of dibutyl phthalate C₁₆H₂₂O₄, 10 kg of the sodium salt of alkylbenzenesulfonic acid and 150 kg of activated carbon with particle sizes by Max. Homogenized 1.3 mm, yielding about 1000 kg of the ingredient A won. Immediately afterwards be under constant stirring 300 kg of dusty silica, 25 kg Iron oxide mixture (Fe₂O₃ + FeO), 13 kg of alumina and titanium oxide (Al₂O₃ + Ti₂O), 200 kg mica powder, 200 kg montmorillonite clay, 150 kg of dicalcium silicate, 13 kg of calcium oxide and 99 kg crushed aluminum silicates supplied, whereby about 2000 kg of the thermal insulation composition according to the invention be prepared for the production of heat-insulating moldings can be used. These moldings can after a Heat treatment for 2.5 hours at a temperature used by 700 ° C as thermal insulation in metallurgical furnaces become.

example 2

980 kg of sodium silicate with a specific weight of 1.30 g / cm³ and a modulus of 3.2 (modulus = SiO₂ / Na₂O) be with 8 kg of dioctyl phthalate C₂₄H₃₈O₄, 2 kg of sodium salt of cerylbenzenesulfonic acid and 10 kg of activated carbon with particle sizes homogenized below 1.0 mm, yielding about 1000 kg of the ingredient A are produced. Subsequently, under constant Stir 900 kg of dusty silica, 3 kg of iron oxide mixture (Fe₂O₃ + FeO), 2 kg of alumina and titanium oxide (Al₂O₃ + TiO₂), 35 kg of mica, 40 kg of montmorillonite clay, 5 kg Dicalcium silicate, 1 kg of calcium oxide and 14 kg of aluminum silicate powder fed, creating about 2000 kg of thermal insulation mass be prepared according to the invention, for the production is used by granules and moldings, which after a 3.5 hours heat treatment at one temperature used by 600 ° C as thermal insulation in metallurgical plants could be.

example 3

700 kg of potassium silicate with a specific gravity of 1.28 g / cm³ and a modulus of 2.9 are mixed with 140 kg of dibutyl phthalate,  10 kg of sodium salt of alkylbenzenesulfonic acid and Homogenized 150 kg of activated carbon, whereby about 1000 kg of Component A can be obtained.

In a second container containing a mixing device equipped, will be 300 kg of dusty silica, 25 kg Iron oxide mixture (Fe₂O₃ + FeO), 200 kg mica, 200 kg montmorillonite clay, 150 kg of dicalcium silicate, 26 kg of aluminum powder and 99 kg aluminum silicate powder homogenized, whereby about 1000 kg of component B of the thermal insulation composition according to of the invention. Then become part of A while constantly stirring 700 kg of the ingredient B, whereby about 1700 kg of the thermal insulation mass according to of the invention, which are used as filling mass for Pouring of insulation gaps is determined. After 24 hours at a temperature of 20 ° C, the mass had its volume increased by about 30%, and after subsequent heating up to 550 ° C it increased its volume by another 100%.

example 4

980 kg potassium water glass with a specific gravity of 1.39 g / cm³ and a modulus of 3.8 are mixed with 8 kg of dioctyl phthalate, 2 kg of sodium salt of alkylbenzenesulfonic acid and 1 kg Activated carbon homogenized, creating about 1000 kg of the ingredient A won.

In a second container containing a mixing device 900 kg of dust-like silica, 3 kg Iron oxide mixture (F₂O₃ + FeO), 35 kg mica powder, 40 kg montmorillonite clay, 5 kg of dicalcium silicate, 3 kg of aluminum powder and 14 kg aluminum silicate powder homogenized, creating about 1000 kg of component B of the thermal insulation composition according to of the invention.

Subsequently, the component A with constant stirring 650 kg of ingredient B fed, creating about 1650 kg the thermal insulation composition according to the invention are obtained, as filling compound for pouring insulation columns or intended for granule production. After 24 hours at a  Temperature of 20 ° C, the mass had its volume about 25% enlarged, and after subsequent heating up to At 600 ° C, it increased its volume by a further 110%.

The thermal insulation composition according to the invention is characterized by the following technical characteristics:

specific weight 150 to 450 kg / m³ Compressive strength 1.5 to 8.5 kg / cm³ soundproofing 30 to 40 dB (6 mm) temperature resistance 1200 ° C Working temperature range for continuous use 850 to 950 ° C Thermal conductivity 0.004 to 0.005 kcal / m.h ° C

Claims (2)

1. Inorganische Thermoisolationsmasse based on water glass, characterized in that they are made

• A) 70.0 to 98.0 parts by weight of sodium or potassium waterglass, 0.8 to 14.0 parts by weight of phthalates, 0.2 to 1.0 part by weight of surfactant, 1.0 to 15, 0 parts by weight of activated carbon or carbon black; and
• B) 30.0 to 90.0 parts by weight of silica (in powder or colloid form), 0.3 to 2.5 parts by weight of iron oxide (Fe₂O₃ + FeO), 3.5 to 20.0 parts by weight. Parts of mica, 4.0 to 20.0 parts by weight of montmorillonite clay, 0.5 to 15.0 parts by weight of dicalcium silicate, 1.4 to 9.9 parts by weight of aluminum silicates (Al₂O₃ · SiO₂), and either 0 , 2 to 1.3 parts by weight of aluminum and titanium oxides (Al₂O₃ + TiO₂) and 0.1 to 1.3 parts by weight of calcium oxide (CaO) or 0.1 to 2.6 parts by weight of aluminum powder or iron - And silicon dust with a silicon content of at least 45%.

2. A method for producing a Thermoisolationsmasse after Claim 1, characterized in that the water glass with Dibutyl and / or Dioctylphthalat with the addition of surfactant and activated carbon modified and then with the rest Ingredients is mixed.