HU229740B1 - Process for the production of building material and thermal insulation plaster, lightweight concrete, shaped building element and construction auxiliary material produced by the process - Google Patents

Description

7151G

P 10 00030

January 2013

Process for the production of building materials and thermal insulation plaster, lightweight concrete, shaped building elements and construction auxiliaries produced by the process

FIELD OF THE INVENTION

The present invention relates to a process for the production of a building material and to a thermally insulating plaster and lightweight concrete produced by the process, as well as to a thermally insulating shaped building element and auxiliary construction material.

BACKGROUND OF THE INVENTION

Masonry units currently commonly used in the construction industry are only able to provide the statutory and desirable thermal insulation value with subsequent external and / or internal insulation. Materials suitable for the construction of new structures and the thermal insulation of existing buildings and structures are known.

Such a solution is described in HU 213 905 B, which relates to a process for the production of lightweight concrete admixtures and lightweight concrete. The additive is prepared by wetting the foamed plastic particles with water or water glass and then mixing them with cement powder. The admixture is used for the production of lightweight concrete, pavements, masonry units and leveling and / or thermal insulation layers.

The construction product according to EP 1 508 552 B2 comprises wood wool chips and latent heat storage elements, the latter increasing the heat storage capacity of the product.

According to HU 224 364 B, in the production of concrete or mortar, a plant admixture is added together with a finely ground mineral to a binder and mixing water.

The lightweight concrete described in KR 20030093415 A contains, in addition to cement, an animal or vegetable blowing agent, a semi-rigid elastomeric foam, a rubber component and a fibrous component.

-2A GB 2 175 294 discloses a process for the production of a heat-insulating concrete element in which fibrous plant material, in particular rice husk, is added to water and a binder, such as cement or gypsum, after pre-wetting to improve the bond.

According to HU 207 694 B, lime powder with a water-repellent surface is produced by treating powdered or milled quicklime with an emulsion of linseed oil and denatured alcohol, then drying and, if necessary, pulverizing. The lime powder is mixed with cement to form an uncompacted cement mixture. Lime powder is used to make a watertight cement mortar by adding cement, sand and water.

According to US 2007/0175366 A1, which corresponds to EP 1 840 099 A2, a water-repellent lime powder is prepared by mixing vegetable oil, detergent and quicklime. The lime powder treated in this way is made into a water-repellent additive by the addition of water, which can be used in the production of waterproofing cement mortar and concrete.

Hungarian Patent Application Laid-Open No. P 99 00531 discloses a water-repellent composition for a building material additive consisting of quicklime and vegetable oil. The composition is used to make waterproof concrete or plaster.

KR 20070108332 A discloses a process for the production of sound-insulating and sound-absorbing floor structures and side walls, in which a foaming additive comprising at least one of vermiculite powder, perlite powder, carbon and far-infrared emitting material, aluminum powder and zinc powder a blowing catalyst comprising at least one of sodium bicarbonate, a blowing stabilizer comprising at least one of crystalline cellulose and carboxymethylcellulose, a reinforcing component comprising at least one of kaolin and bentonite, an ionic coagulant component comprising at least one of montmorillonite and calcium chloride, and water are mixed, and consolidated.

HU 213 184 B discloses a process for preparing a water-repellent composition in which quicklime, oil, alcohol and water are mixed and the resulting composition is ground after standing. The composition is water repellent when added to a mixture of cement and sand

-3 cement mortar is produced, which is used as a plaster to insulate walls.

HU 223 711 B1 discloses an admixture for waterproofing concrete and cement mortar prepared by mixing a liquid hydrophobizing agent containing palmitic acid, stearic acid, oleic acid, linoleic acid, linolenic acid and optionally erucic acid, ethyl acetate and ethyl alcohol in admixture with powdered quicklime. A liquid catalyst containing the agent and a catalyst additive is added, wherein the catalyst additive contains gasoline, benzene, pyridine and methanol, then water is added to the uniformly stirred material, and the finished material is dehydrated and allowed to cool.

Hungarian Pat. water is added to the mixture. Sunflower oil or rapeseed oil or a mixture thereof is used as the vegetable oil.

Hungarian Pat. the organic binder is a water-soluble and / or dispersible homopolymer, co- and terpolymer, optionally vinyl chloride, or a vinyl ester of saturated or unsaturated aromatic organic acids, or vinyl butyral, or an ethylene or acrylic acid ester, or a styrene or alkyl isocyanate, or silane and siloxane.

SUMMARY OF THE INVENTION

According to the invention, it is an object to provide a process for the production of a mixed-use building material which can be used both in the construction industry and in neighboring industries and which can be used as masonry, building boundary material, plaster mortar, filler and cladding material. in the construction of a building, both

-4for renovating an existing building, or as a stand-alone structure, and which offers a cost-effective, simple solution with good heat, fire, water and sound insulation properties and excellent vapor diffusion and adhesive strength values. The object of the invention has been to provide these values as far as possible in combination with increasing the cost-effectiveness and versatility of production and application.

The invention therefore relates, on the one hand, to a process for preparing a building material in which an emulsion containing vegetable oil and solvent is contacted with quicklime and then water and binder are added to the slurry impregnated with the emulsion, characterized in that 60-96% by weight of After contacting with 40% by weight, the emulsion-impregnated calcined lime is hydrated by evaporating the bulk of the solvent by adding water 1.2-1.8 times, preferably 1.4-1.6 times, by volume, and the resulting hydrated material is dried. A hydraulic binder comprising a blowing agent, preferably sodium bicarbonate, and a cement and / or isocyanate-based binder is added in an amount such that 0.25 to 0.6 parts by weight of the blowing agent and 6.5 to 20 parts by weight of the hydraulic binder are present per 1 part by weight of the hydrated material. , a volume-increasing amount of 2 to 12 units per volume per 1 volume of the added binder thus obtained Again, the resulting material is stirred evenly with additional water and allowed to solidify or solidify.

According to a preferred embodiment of the process, 75-90% by weight of the quicklime is impregnated with 10-25% by weight of the emulsion.

Preferably, the contacting of the quicklime with the emulsion is performed by spraying the emulsion onto the piece of quicklime conveyed on a conveyor belt.

Preferably, the vegetable oil is linseed oil with a high vegetable dry matter content. Sunflower or rapeseed oil can be used instead of linseed oil. Denatured alcohol or acetone can be used as the solvent. The mixing is preferably carried out by introducing air in a closed box mixer until an emulsion is formed. The purpose of the solvent is to promote the absorption of the vegetable oil used as a hydrophobicizing agent in the quicklime.

The hydration is preferably carried out by adding water to the emulsion-soaked lime after evaporation of most of the solvent in a few minutes, resulting in a fine-grained, ca. A strongly hydrophobic lime hydrate powder with a particle size of 2 μ is formed.

It is preferred to use 0.3 to 0.4 parts by weight of sodium bicarbonate per 1 part by weight of the dried hydrated material as a blowing agent in the process. Ammonium bicarbonate can also be used as a blowing agent.

The hydraulic binder is preferably cement in an amount such that 9 to 15 parts by weight of cement is present per part by weight of the hydrated material. An isocyanate-based binder can be used in addition to or instead of cement to produce a faster setting and harder building material.

The process according to the invention can be carried out by adding the blowing agent and the hydraulic binder to the hydrated material in one step by dry mixing, in which the materials are mixed by mechanical and / or air-blown methods.

However, an embodiment may be preferred in which the blowing agent and the hydraulic binder are added to the hydrated material in two steps by first adding the blowing agent and then the hydraulic binder, optionally together with the bulking agent. Such two successive technological steps are expedient if the hydrophobized additive is prepared elsewhere than the additive binder, the latter being used as the required hydraulic binder, e.g. due to the much higher weight of cement, it may be advisable to produce it at the point of use. The second technological step can also take place at the place of use by adding the hydraulic binder and the bulking agent together to the hydrophobized additive and mixing the material evenly with the addition of additional water.

In the process according to the invention, the bulking agent is preferably an organic or inorganic filler which does not chemically react with the additive binder, such as fibrous and / or granular paper, straw, cellulose or rubber, or a plastic, such as a scrap of plastic waste, or a mixture thereof. Mineralized plant derivatives, industrial waste cork waste may be used as bulking agents,

-6 straw straw, cherry seeds. By mineralization is meant a process that inhibits the decomposition of organic matter.

It is preferred to use polystyrene beads as the bulking agent in an amount such that 4-6 volumes of polystyrene beads per unit volume of dopant binder.

The role of the bulking material, as is known per se, is to increase the thermal insulation capacity of the building material produced. According to the invention, when the bulking agent is mixed with the addition of water due to the hydrophobic additive, the bulking agent is also soaked in the hydrophobic vegetable oil, which results in the vapor which may condense in the incorporated thermal insulation .

Other quality enhancing and / or coloring agents may be added in addition to the bulking agent. These can be, for example, setting accelerators or antifreeze agents. By using coloring additives, it is possible to distinguish the thermally insulating building elements with different parameters produced according to the invention and to produce a building material which meets aesthetic requirements.

An alkali silicate material which increases the hardness of the building material, preferably sodium silicate, can be used as a quality-improving additive. It may also be advantageous to use calcium chloride, which on the one hand accelerates the setting of the cement and on the other hand improves the thermal insulation capacity and the vapor diffusion factor.

As a quality-improving additive, a fibrous material made of metal, glass, plastic and / or organic or inorganic waste and / or a mesh made of such material can be used to increase the strength of the building material or to strengthen its surface.

According to the process of the invention, a building material having a bulk density of 80 to 900 kg / m ³ , preferably 190 to 330 kg / m ³ , can be produced in the solidified state.

The material prepared by the process according to the invention is used as a liquid building material and / or as a solid building material. In the latter case, with the addition of further water, the liquid mixture which has been uniformly mixed is poured into the desired form and solidified or allowed to solidify at a temperature of 22 to 80 ° C, preferably 40 to 50 ° C.

The invention further relates to a thermally insulating plaster and to a thermally insulating lightweight concrete made of a building material produced by the method according to the invention.

The invention also relates to a method of manufacturing a thermally insulating building element, such as a prefabricated panel, a sandwich panel, a fire barrier or a shaped building material, e.g. is formed from a building material by molding.

Due to the material composition and construction of the building material produced by the method according to the invention, it is highly refractory. This means, on the one hand, that it transmits little heat under the influence of a non-combustible and strong fire, on the other hand, that its temperature returns to ambient temperature within minutes after the fire has ceased, and that it retains its strength to a great extent.

The solid building material prepared by the process of the present invention can be used as a building structural material, or as a thermal insulating, sound and fire barrier material, or as another stand-alone structural or civil engineering structure.

The building material according to the invention can be used as a masonry and / or a subfloor and / or a slab and / or as an insulation on these structures and / or as an external heat and sound insulation and / or for making the structures fireproof or fireproof. It is also suitable for the insulating structure of other systems, structures, equipment, wires, reservoirs, pipes and pools.

The building material produced by the process according to the invention can also be used for filling, insulating, increasing the insulating value or making it fire-retardant for structures and / or profiles, pipes, metals, plastics and other materials.

It is also possible to use the prepared building material together with hot-dip galvanized steel, iron, wood or reinforced concrete or other supporting structures in the construction of buildings, or to use the prepared building material as a soundproofing, fire-resistant stand-alone structure and / or in combination with other such structures. The pH of the building material according to the invention is 12, which is a significant advantage for the corrosion inhibition of the associated iron structures.

With the building material according to the invention, a complete building can be constructed by attaching the formwork to the steel structure with the remaining spacers made of the building material according to the invention and filling the formwork with the liquid building material according to the invention, optionally from a mixer car. so the

The solidifying building material according to the invention forms a homogeneous structure with the spacers made of the same material, which is particularly advantageous for thermal insulation.

The building material according to the invention can be fixed using a dowel and / or a clamp, a clamp and / or an adhesive bridge or other adhesive.

The liquid building material prepared by the process of the present invention, e.g. the plaster mortar can be applied mechanically, for example with a plastering machine or a concrete pump, and / or manually.

The building material according to the invention is suitable e.g. for the series production of buildings with reduced energy requirements that meet the requirements of a “passive house” in a modular panel structure.

The building material according to the invention can be used in the following fields:

structural construction and insulation of industrial, agricultural buildings, residential buildings, halls;

external, internal, gap and space filling, fire retardant, soundproof masonry;

in all types of layered building structures;

in a prefabricated element and / or panel structure;

exterior plaster;

internal plaster (insulation, fire protection of listed buildings);

construction and thermal and fire insulation of any flat, ribbed and inclined slab;

making and insulating substrates (including stepping);

attic construction and insulation;

insulation behind heavy cladding, wood, metal and other cladding materials;

insulation of high / low temperature industrial spaces, facilities;

insulation of prefabricated houses;

fire protection solutions (eg walls, structures);

insulation of district heating and other pipelines;

sound insulation, sound insulation (eg walls, doors, structures);

insulation of swimming pools;

insulation of tanks and containers;

-Insulation of doors and other profiles of plastic, aluminum and other materials by filling (does not burn out during cutting and welding);

other industrial, construction applications in which the building material is used without modification.

The industrial applications of the building material according to the invention can be divided into the following groups:

Together with a load-bearing structure, a complete, heat-bridge-free building can be cast or manufactured, e.g. in a modular panel system from the building material according to the invention (base, wall, slab, roof).

It can be used as a mortar, as an insulating material for vertical, inclined and horizontal surfaces.

As a stand-alone structure, e.g. soundproof, fireproof wall, can be used as a pre-formed and reinforced thermal insulation element.

It can be used as a heat, sound and fire barrier cover for other products and systems (eg pipes, tanks).

The advantage of the building material according to the invention over pre-existing building materials is that it can be used to save valuable time and money, while its heat, sound and fire-retardant properties are much greater. The building material according to the invention can be used and used both in the construction industry and in neighboring industries. It can be used both as masonry, as a building bounding material, as a plastering mortar, as a filling and cladding material, both for the construction of a new building and for the renovation of an existing building, or as a stand-alone structure; offers a cost-effective, simple solution with good thermal insulation (λ = 0.1-0.032 W / mK), fire protection (class A2), water and sound insulation properties, excellent vapor diffusion ability (μ <15) and adhesive strength.

By using the building material, the thermal bridges can be completely eliminated, and due to its castability, it is the perfect solution for all gaps, gaps and surface unevenness.

The use of the building material according to the invention can also revolutionize the door and window industry, as it allows manufacturers to return to the production of 1-2 air chambers, significantly cheaper profiles, while the thermal insulation value of the profiles can be reduced below the passive house requirements (0.8 W / mk). The limitation so far has been that it fills the profile that increases the insulation value

- 10 materials were burned out of the profiles at the welding points during the production of the doors and windows, thus creating significant thermal bridges at the corners.

The building material according to the invention, in contrast to the materials used hitherto as insulation, is resistant to insects and rodents, so that they do not move into it. Due to the degree of flexibility of the building material, when used in conjunction with a metal support structure, the buildings constructed are highly earthquake resistant. The impact material of the building material according to the invention is also advantageous.

The building material according to the invention provides protection not only against the permanent cooling of the building, but also, due to its thermal inertia, against its heating, so that it can be used with particular advantage in warm climatic conditions.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be described, by way of example, with reference to the accompanying drawings, in which: FIG

Figure 1 illustrates the use of a thermal insulator for a building material according to the invention, a

Figure 2 shows the use of the building material according to the invention as a residual spacer for the formwork, a

Figure 3 shows a detail of a pipe insulating cover made of a building material according to the invention, and

Figure 4 shows a detail of a sandwich panel made using a building material according to the invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION

In FIG. On the side of the thermal insulation layer 3 opposite to the masonry 1, an external noble plaster 4 is optionally applied.

Figure 2 shows a hot-dip galvanized steel holder 7 between the formwork panels 5 and 6. The distance between the formwork panels 5 and 6 is provided by the remaining spacers, of which only one spacer 8 is shown in the figure, which is provided with 9 holes. The spacer 8 is made of a heat-insulating building material of sufficient strength according to the invention

-11 prepared. The hole 9 is used to pass through a fastening screw (not shown). Between the formwork panels 5 and 6, the liquid building material according to the invention is poured. After solidification, the screw is loosened and the formwork panels 5 and 6 are removed, and the hole 9 is also filled with the liquid building material according to the invention. Thus, the molded building material, the remaining spacers and the material filling the holes form a homogeneous structure of the thermal insulation building material according to the invention, which is advantageous for thermal insulation, since no thermal bridges can be formed.

Fig. 3 shows a detail of the heat-insulating cover 11 of the pipeline 10, which is in the form of a half-cylindrical shell and is made of a heat-insulating building material according to the invention. The other half of the insulating cover 11 is not shown in the drawing.

Fig. 4 shows a detail of a sandwich panel 14 consisting of a metal trapezoidal sheet 12 and a thermal insulation layer 13 applied to one side thereof, which thermal insulation layer 13 is made of a building material according to the invention. The sandwich panel 14 may also be a delimiting wall of buildings, in which case it may be fastened to a metal support structure (not shown) by means of screws (not shown) passing through the heat-insulating layer 13 and the trapezoidal plate 12.

The process according to the invention will now be described with reference to exemplary embodiments.

Example 1 A liter of high solids hydrophobic linseed oil was mixed into an emulsion solution with 0.1 liter of denatured alcohol in a closed vessel, and the emulsion solution was soaked in 9 to 10 kg of quicklime. After evaporation of the denatured alcohol, which helps to soak the linseed oil into the lime, which takes place in a few minutes, the substance is added by continuous addition of water (hydration) for approx. grown to one and a half times the volume. The hydrated material thus obtained is approx. It will weigh 11-12 kg.

This special lime hydrate is responsible for the fire resistance of the finished building material and promotes the adhesive strength of the building material. During hydration, it is important to ensure that the high-dry emulsion solution is evenly soaked in the lime and that it is perfectly hydrated without burning.

The approx. To 11-12 kg of lime hydrate is then mixed with 4 kg of sodium bicarbonate as a blowing agent, which is partly good thermal insulation of the finished building material.

- It is responsible for its value of 12, partly for its fire and heat resistance and for the processability of the material. The hydrophobic material thus obtained is treated as an additive, which can be very advantageously used for the production of a building material with good thermal insulation.

125 kg of cement 42.5 R are then added to the additive as a hydraulic binder. If an isocyanate-based binder is used in whole or in part instead of cement, the strength of the finished building material will be higher and its sound insulation can be affected. The quality of the cement can also affect the setting time and the thermal properties of the building material. The easiest way to adapt the building material to the desired use is here.

To the resulting powdered additive binder, 1000 liters of expanded polystyrene additive (polystyrene powder or polystyrene beads) was added as a bulking agent and mixed evenly with 140-160 liters of water for at least 15 minutes. Mixing can be done in a conventional concrete mixer or mixer car. Various other additives (eg quality enhancer, setting accelerator, antifreeze, colorant) can also be added. During the mixing, the expanded polystyrene additive is impregnated with the hydrophobic vegetable oil in the added binder, and thus, in the case of condensation in the thermal insulation building material obtained after solidification, less vapor enters the polystyrene material. This greatly contributes to maintaining the good thermal insulation properties of the built-in building material over a longer period of time. The expanded polystyrene additive can be replaced e.g. with mineralized organic matter (straw, cork), but changes in the thermal insulation value must be taken into account. The resulting building material is approx. It has a volume of 1 m ³ and a mass of between 194 kg and 198 kg after complete solidification.

The technical characteristics of the facade thermal insulation plaster prepared according to Example 1 are given in Table 1.

Table 1

Body density individual value: 194-198 kg / m ³ average: 196 kg / m ³ MSZ EN 1015- 10: 2000 Thermal conductivity At an average temperature of 10 ° C λ = 0.055 W / mK MSZ EN 12667: 2001

Vapor diffusion factor _{pá ti} = 4.59; S _d = 0.159 m MSZEN 1015- 19: 2000 Capillary water uptake C = 0.40 kg / (m ² min ⁰ ' ⁵ ) MSZ EN 1015- 18: 2003 Compressive strength (at 28 days of age) individual: 9.57-9.78 N / mm ² average: 9.68 N / mm ² MSZ EN 1015- 11: 2000 Adhesion strength on natural concrete surfaces average: 0.02 N / mm ² (FP: A) MSZ EN 1015- Adhesion to washed concrete surfaces average: 0.02 N / mm ² (FP: A) 12: 2000 Flexural strength (at 28 days of age) individual: 2.11-2.23 N / mm ² average: 2.17 N / mm ² MSZ EN 1015- 11: 2000 Fire classification Material alone A2-s1, dO MSZ EN 13823: 2002 Fire classification As a thermal insulation system It belongs to the fire protection class A2-s1, dO in the system with the cover plaster classified in the fire protection class. It belongs to fire protection class B-s1, dO with a cover plaster classified in fire protection class B. MSZ EN 13501- 1: 2007 MSZ EN 13823: 2002 MSZ EN ISO 11925- 2: 2002 Facade spread limit Th> 45 min 2/2002 (I.23.) BM Decree 5 Annex I / 3. Chapter MSZ 14800-6: 1980 9/2008. (II.22.) ÖTM Decree Part 5 I / 4. Chapter M1 Annex 3.6.9.1. point Air content (V / V%) 16% MSZ EN 1015-7: 1999

Pot life 1 hour 45 minutes MSZ EN 1015-9: 2000 Durability (After 25 freeze-thaw cycles) - 4.9% (flexural strength) - 0% (compressive strength) ÉMI HSZ 66: 2005

Example 2

The production method is the same as in Example 1, but here the amount of cement added is 25% higher, i.e. approx. It was 156 kg. The resulting building material is approx. It has a volume of 1 m ³ and weighed between 281 kg and 323 kg after complete solidification. The technical characteristics of the facade insulation plaster according to Example 2 are given in Table 2.

Table 2

Body density individual value: 281-323 kg / m ³ average: 298 kg / m ³ MSZ EN 1015- 10: 2000 Thermal conductivity At an average temperature of 10 ° C λ = 0.067 W / mK MSZ EN 12667: 2001 Vapor diffusion factor pat = 4.59; Sd = 0.159 m MSZ EN 1015- 19: 2000 Capillary water uptake C = 0.40 kg / (m2 min0.5) MSZ EN 1015- 18: 2003 Compressive strength (at 28 days of age) individual: 4.25-4.31 N / mm2 average: 4.30 N / mm2 MSZ EN 1015- 11: 2000 Adhesion strength on natural concrete surfaces average: 0.07 N / mm2 (FP: B) MSZ EN 1015- Adhesion to washed concrete surfaces average: 0.03 N / mm2 (FP: A) 12: 2000 Flexural strength (at 28 days of age) unique: 0.16-0.18 N / mm2 average: 0.17 N / mm2 MSZ EN 1015- 11: 2000 Fire classification Material alone A2-s1, dO MSZ EN 13823: 2002

Fire classification as a thermal insulation system It belongs to the fire protection class A2-s1, dO in the system with the cover plaster classified in the fire protection class. It belongs to fire protection class B-s1, dO with a cover plaster classified in fire protection class B. MSZ EN 13501- 1: 2007 MSZ EN 13823: 2002 MSZ EN ISO 11925- 2: 2002 Facade spread limit Th> 45 min 2/2002 (I.23.) BM Decree 5 Annex I / 3. Chapter MSZ 14800-6: 1980 9/2008. (II.22.) ÖTM Decree Part 5 I / 4. Chapter M1 Annex 3.6.9.1. point Air content (VA /%) 15% MSZ EN 1015-7: 1999 Pot life 1 hour 45 minutes MSZ EN 1015-9: 2000 Durability (After 25 freeze-thaw cycles) -15.8% (flexural strength) - 5.4% (compressive strength) ÉMI HSZ 66: 2005 ___

Example 3

The production method is the same as in Example 1, but here, in addition to the expanded polystyrene additive, fiberglass fibers are mixed with the added binder, for example in an amount of 1 to 2 kg, during wet mixing (final mixing). This further increases the strength of the resulting building material. The liquid material thus produced cannot be applied to the surface with a horizontal screw plastering machine, because the transfer screw can become clogged with the collected fibers.

Example 4

The production method is the same as described in Example 1, but when used as facade insulation, a glass cloth mesh (e.g. 80-160 g) is placed on the entire surface in the outer third of the thickness of the thermal insulation plaster according to the invention applied to the wall. This method of application is primarily advantageous for the subsequent thermal insulation of panel buildings, as it avoids the possible cracking of the gaps between the panel joints.

Example 5

The method of preparation is the same as described in Example 1, except that the same amount of cork powder is used instead of the expanded polystyrene additive. Due to the thermal properties of the cork, the thermal technical factor of the finished building material is slightly modified and its density is approx. she grows one and a half times. This embodiment is mainly suitable for thermal insulation in very cold areas.

Claims (19)

-17Claims A process for preparing a building material, which comprises contacting an emulsion containing vegetable oil and a solvent with quicklime and then adding water and a binder to the quicklime impregnated with the emulsion, characterized in that 60-96% by weight of the quicklime is added to the emulsion. After evaporation of most of the solvent, the emulsified lime is hydrated by adding water to it 1.2 to 1.8 times, preferably 1.4 to 1.6 times, to a volume. a hydraulic binder comprising sodium bicarbonate and a cement and / or isocyanate-based binder is added in an amount such that 0.25 to 0.6 parts by weight of the blowing agent and 6.5 to 20 parts by weight of the hydraulic binder are obtained per 1 part by weight of the hydrated material. 2 to 12 volumes of bulking agent per 1 volume of dopant the resulting material is stirred evenly with additional water and allowed to solidify or solidify. Process according to Claim 1, characterized in that 75 to 90% by weight of the quicklime is impregnated with 10 to 25% by weight of the emulsion. Process according to Claim 1 or 2, characterized in that 0.3 to 0.4 parts by weight of sodium bicarbonate are used as the blowing agent per 1 part by weight of the hydrated material. 4. Figures 1-3. Process according to any one of claims 1 to 4, characterized in that the contacting of the quicklime with the emulsion is carried out by spraying the emulsion on the quicklime in a piece conveyed on a conveyor belt. 5. Paragraphs 1 to 4 Process according to one of Claims 1 to 4, characterized in that the vegetable oil used is linseed oil with a high vegetable solids content and the solvent is denatured alcohol or acetone. 6. Figures 1-5. Process according to one of Claims 1 to 4, characterized in that cement is used as the hydraulic binder in an amount such that 9 to 15 parts by weight of cement is present per part by weight of the hydrated material. 7. Figures 1-6. Process according to any one of claims 1 to 4, characterized in that the foaming agent and the hydraulic binder are added to the hydrated material in one step by dry mixing, in which the materials are mixed by mechanical and / or air-blown methods. 8. Figures 1-6. Process according to any one of claims 1 to 4, characterized in that the foaming agent and the hydraulic binder are added to the hydrated material in two steps by adding the foaming agent first and then the hydraulic binder, optionally together with the bulking agent. 9. Figures 1-8. Process according to one of Claims 1 to 4, characterized in that the bulking agent used is an organic or inorganic filler which does not chemically react with the additive binder, such as fibrous and / or granular paper, straw, cellulose or rubber, or a plastic mixture. 10. The method of claim 9, wherein the bulking agent is polystyrene beads in an amount such that 4-6 volume units of polystyrene bead per unit volume of dopant binder. 11. Figures 1-10. Process according to one of Claims 1 to 4, characterized in that other quality-improving and / or coloring additives are added together with the addition of the bulking agent. Process according to Claim 11, characterized in that the quality-enhancing additive used is a setting accelerator or antifreeze. Process according to Claim 11, characterized in that the quality-enhancing additive used is an alkali metal silicate, preferably sodium silicate, and / or calcium chloride. Process according to Claim 11, characterized in that a fibrous material made of metal, glass, plastic and / or organic or inorganic waste and / or a mesh made of such material is used to increase the strength of the building material. 15. Figures 1-14. Process according to one of Claims 1 to 4, characterized in that a building material with a mass density of 80 to 900 kg / m ³ , preferably 190 to 330 kg / m ³ , is produced in the solidified state. 16. Figures 1-15. Process according to any one of claims 1 to 4, characterized in that a liquid substance is uniformly mixed with the addition of further water - molded into the desired shape and solidified at a temperature of 22-80 ° C, preferably 40-50 ° C or allowed to solidify. 17. Thermal insulating plaster, characterized in that 1-15. It is made of a building material produced by a process according to any one of claims 1 to 4. 18. Thermally insulating lightweight concrete, characterized in that 1-15. It is made of a building material produced by a process according to any one of claims 1 to 4. 19. A thermally insulating shaped building element or shaped building auxiliary material, characterized in that it is made of a building material produced by the method according to claim 16. (2 sheets drawing, 4 figures)