DE1671267B2 - METHOD OF MANUFACTURING MICROPOROUS CONCRETE AND ITS USE - Google Patents

Description

The invention relates to a process for the production of light and stable, microporous concrete for construction and insulation purposes with particularly low water absorption and excellent nailability using water, foam-forming substances, cement and, if necessary, sand, with a specific weight below 1.0 a ratio of cement to sand of 1: 0 to 1: 1.5 and for a specific weight between 1.0 and 1.6 kg / dm ³ a ratio of cement to sand of up to 1: 1.7 used. The invention also relates to microporous concrete produced by the method and its

Use. Such a concrete contains pores of so-called Micro size, is extremely waterproof and

withstands a higher pressure than any of the known materials of this type The cause of this lies in many interacting factors.

The use of hollow spheres or granules of baked and porous clay in combination with a cement mortar is from the German patent

ic 8 14 860 known, but this mortar is not porous and the concrete becomes too heavy; it is not possible to produce concrete with a specific weight of less than 1.6 kg / dm ^{3 in} this known manner. It is therefore too heavy to be classified as lightweight concrete . To reduce the specific gravity, the German patent suggests that enough cement mortar be used that the spheres are just covered. However, this leads to the formation of cavities between the individual balls. In order to achieve the best possible insulation together with the lowest possible water absorption, attempts were made to mix larger and smaller spheres. But with little success, since the excellent properties of the balls, such as B. low

Is water absorption and good compressive strength not transferred to the mortar obtained in this way to a sufficient extent.

When all the spaces between the spheres or granules are completely filled with mortar of the porous concrete according to the invention, a material with a low specific weight is obtained. This avoids the disadvantages which are connected with the use of the concretes produced up to now using burnt and porous clay. These disadvantages include that the concrete must be covered with a thick layer of heavy mortar to prevent rain and wind from passing through, which in turn significantly increases the price of buildings.

In rainy areas you are reluctant to use this concrete on the outside of the houses that are exposed to rain and wind.

The difficulties of the previous, unsuccessful

4S attempts to manufacture microporous concrete have often consisted of the fact that the air or gas bubbles rise to the surface before the concrete has sufficient time to set. The pores are unevenly distributed and combine to form pores of different sizes, so that a concrete with poor insulating properties is produced. Even a concrete with a low specific weight, e.g. B. 0.70 kg / dm ^J , can be of poor quality in that the pores are interconnected and the concrete absorbs water and sinks or shrinks. Naturally, such concrete does not have good thermal insulation properties.

From the DT-AS 10 59 336 there is already a method for Manufacture of aerated concrete and porous moldings

(«J is known in which cement or other hydraulic binders with the addition of water, Foam compound and, if necessary, additives and stabilizers, an aerated concrete is produced is, wherein as foaming agent reaction products

<■> of cationic and anionic compounds be used. In this previously known process, however, the components are first mixed together and then in a fast-moving forced-

'b

shear or high-performance agitator or mixed by compressed air and foamed at the same time

It has now been found that by adding aqueous foam, which has the consistency of stiffly beaten foam, to mortar under certain temperature conditions, a microporous concrete can also be produced which has advantageous properties.

The method according to the invention is characterized in that a stable foam is first produced from water and a foam-forming agent and this is mixed with the other components, one or more of the components foam, water, cement and other additives being at least 15% before mixing ° C, but preferably to a temperature between -4 ⁰ C and 0 ⁰ C cools

Such an aqueous foam is produced by small amounts of a particularly suitable foaming agent is added to the water and the whole so long breaks down, until the volume of the aqueous solution five times up to twenty-five times, preferably eight times, the volume of water is increased. In relation to the weight of the water, the amount of foaming agent is about 0.5 to 0.7%. The foam must be stable and most of the known foaming agents, e.g. B. the commercially available higher, secondary sodium alkyl sulfates and sodium alkylbenzene sulfonates having 9 to 12 carbon atoms in the alkyl chain are not suitable for this purpose. They do produce enough foam; However, this has only a comparatively low stability or resistance and does not have the required near consistency of similarly stiff whipped cream. A foaming agent of a suitable type produces, for example, a profile. which, if left to stand at low temperatures, ie between 2 and 4 ° C, does not change for £ .0 minutes. If the foam is, however, allowed to stand at elevated temperatures such as 20 ° C, the resistance substantially decreases, so in most cases by more than half. It is very important that the foam be used immediately after it has been whipped. If the foam is left to stand, it can after z. B. still look very good for 30 minutes. This appearance is often deceptive because the surface is smooth and has small pores, but the foam may have deposited water on the bottom. Therefore, the foam must be used as soon as possible.

Foaming agents which produce stable foams are like that e.g.

Sodium lauryl sulfate, sodium lauryl ether sulfate, lithium lauryl sulfate, triethanolamine lauryl sulfate, Sodium alkyl benzene sulfonate,

Alkyl phenol polyglycol ethers and the like.

Some of these foaming agents give a foam of about 60 minutes resistance, other such 30 minute resistance or 15 or 10 minutes resistance, etc. All Sichaumbildner above ho mentioned yield foams of sufficient stability, but under otherwise similar conditions the one foaming agent must be selected , which results in a foam of the highest stability, ie the foam which is used to enlarge the pores. tion and settling of water requires the longest time. If such a good foam is mixed with cement immediately after whipping under the specified temperature conditions, an excellent mortar is obtained, ie a mortar with mutually separated pores of uniform size, which gives a concrete of similar structure

The smaller the pores, the larger the surface in the same volume. The surface of the pores or bubbles of 0.1 mm diameter in a certain volume of e.g. B. one liter is ten times the surface area of 1 mm diameter pores and there are thousands of such small pores in 1 cm ³ of porous concrete, so much more cement is used to cover the surface of the small micropores . The aforementioned foaming agents produce such small pores, so that it is essential, in addition to the other factors already mentioned, to be aware of this greater cement consumption and to take it into account. This is one of the reasons why it was not possible until today , sole! to produce a fine-pored concrete that meets the legally prescribed minimum compressive strength per cr.i ² . These legal requirements cannot be met in the production of excellent lightweight concrete of this type when using a cement-sand ratio with more sand than the mixing ratio 1: 1.5, for concrete with a specific weight below 1.0 and for Concrete with a specific weight between 1.0 and! 6 kg / dm ³ with more sand than the mixing ratio of 1: 1.7. The consequence of inadequate coverage of the i'oren with cement is inadequate compressive strength

For example, the mixture of dry matter and foam results in a concrete which is of poor quality in terms of its compressive strength. The cement is not sufficiently moistened if it is mixed directly with the foam, and this leads to uneven moistening with subsequent settling of the mortar in the formwork, which in turn results in a poor structure. accompanied by water intake. The highest compressive strength is achieved by first adding water and a surface-active agent together with a plasticizer or egg. Mixing aids to reduce the water requirement with the cement and processing the whole into a smooth mortar and then adding sand in small portions. The sand that is usually found is used, which has been ^{sifted through a sieve with 9 meshes per cm 2} or through a coarse sieve to remove the smaller stones.

Furthermore, according to the invention, the microporous Möilel can additionally contain particles of fired and Porcsem clay are added, either all or together with sand, the particles of Porous clay can be larger in diameter than the micropores or the sand particles, thereby creating Cement can be saved. According to the invention, a porous cement mortar without sand and can be produced without additional particles.

The resistance you according to the invention Lightweight concrete against water is better than any other type of aerated concrete.

According to the invention, granules can also be added which have a larger diameter than the micropores, in this way a greater compressive strength with the same specific weight using the same amount of cement or even using less

Amount of cement to maintain the same compressive strength a

Furthermore, it is possible according to the invention, only Use foam and cement to make a lightweight concrete that is neither sand nor spherical of baked and porous clay contains The mortar, which does not contain sand, can be used for the manufacture of New types of sawable, nailable, non-flammable, water-resistant panels for construction and insulation purposes light weight can be used by adding layers of organic material, such as. B. foamed polystyrene or the like pours after With this treatment, the sheets of polystyrene sheets adhere firmly to the concrete, or the finished sheets made of lightweight concrete are glued in the usual way with lightweight panels made of organic material

According to the invention, fibers of organic or inorganic material can also be mixed into the mortar, which increases both the compressive strength and the ability to nail .

Above it was mentioned that the foam can be formed by standing for a long time at relatively high temperatures, e.g. B. 70 minutes at 15 ° C, an increase in the pore volume suffers this way the foam is added to the mortar in two portions. According to the invention, in addition to the particles of calcined and porous clay, other light particles, the diameter of which is greater than the diameter of the micropores, can also be used.

In the following examples a foam used, which was beaten to eight times the volume of water. This is the ratio of the pores very stable. However, as previously described, foams that are five times or more can also be used are beaten to twenty-five times the volume of water. However, the pores are in one Foam whipped to twenty-five times the volume of water, very thin-walled, and many these are destroyed when the foam is mixed with the mortar.

Not only Portland cements can be used to manufacture the lightweight concrete products according to the invention but also blast furnace cements, aluminum cements and others.

The invention is illustrated in more detail by means of the following examples

The water absorption of the concretes according to the invention is given in the following examples for the fail, that they lay in water for shorter and longer periods of time.

example 1

The cube consists of 400 g Portland rapid cement, 300 g sand, 100 g granules of fired, porous Clay with a specific weight of 0.85 kg / dm *.

Example 2

The cube consists of 400 g Portland rapid cement (specific weight 0.70 kg / dm ³ ).

Volume of the cube 343 cm ³

Weight of the cube 240 g

Weight after 2 hours under water 2443 g

Weight after 24 hours under water 250 g

Water absorption after 2 hours

underwater 1.31%

Water absorption after 24 hours

under water 2.94%

Example 3

The mixture of the cube consists of 400 g Portland rapid cement. 50 g sand, 350 g granules of calcined porous clay of specific gravity 0.9 kg / dm ^J.

343 cm ¹ 305 g 314 g 319g

Volume of the cube

Weight of the cube

Weight after 2 hours under water

Weight after 24 hours under water

Water absorption after 2 hours

under water

Water absorption after 24 hours

under water

2.95% 4.6%

Volume of the cube

Weight of the cube

Weight after 2 hours under water

Weight after 24 hours under water

Water absorption after 2 hours

under water

Water absorption after 24 hours For comparison it should be mentioned that 266 g conventional Lightweight concrete absorbs 169 g of water if stored under water for only 15 minutes.

The following examples illustrate the production of lightweight concrete using sand and from Granules of baked or porous clay.

Example 4

400g Portland rapid cement. 132 g of water, 0.02 cm 'of a 30% solution of secondary sodium ^{alkyl sulfate as a surface-active agent and 10 cm 3 of} an aqueous solution of 2% sulfite liquor concentrate are kneaded together to form a pliable dough. To this, 9 liters of a foam are added, 4s which consists of a 0.7% strength aqueous solution of triethanolamine sulfate and which has been beaten to eight times the volume of water. The foam is carefully mixed with the dough until a porous mortar is formed. Then 250 g of the usual sand found in this way, which has been ^{sieved through a sieve with 9 meshes per cm 2} , is slowly added with constant stirring.

Weight 730 g, volume 847 cm ¹ , specific weight 0.85 kg / dm ³ , compressive strength 61 kg / cm ² .

Example 5

400 g Portland rapid cement. 132 g of water, 0.02 cm ³ of a 30% solution of secondary Natriumalkvl-I ". Sulfate as a surfactant, a 10cm ^J cm ³ 2% aqueous solution of Sulfitlaugcnkon / entrat

g become a supple dough.

g tet. 67 g of a foam made up of water are added

g with 0.7% sodium lauryl sulfate and aiii oas

'<- eight times the volume of water was beaten. Of the 1.1% foam is carefully processed with the Tt-ig up to a

Doröser mortar is obtained. Then 41 ¹ ^ ν of 2.3% fired and porous clayV ^ richci; ink. ·!> est: im '

added while stirring.

The weight is 895 g, the volume 959 cra ^J , the specific weight 0.93 kg / dm ³ , the compressive strength 122 kg / cm ² .

Example 6

The mixture has the same composition as in Example 1, but with an additional 2.5 g of polypropylene fibers added.

Specific weight 0.85 kg / dm ', compressive strength 72 kg / cm *.

Example 7

600 grams of Portland rapid cement, 600 grams of sand normally found, which was sifted ^{through a 9 mesh per cm 2 screen;} 180 g of water, 0.03 cm ^{3 of} a 30% solution of a secondary sodium alkyl sulfate as a surface-active agent, 20 ml of a 2% solution of sulfite liquor concentrate and the cement are kneaded together to form a pliable dough. Then 230 g of a stiffly whipped foam made of triethanolamine lauryl sulfate and water, which has been whipped to eight times the volume of the vessel, are added. In small portions and with constant stirring, 600 g of sand and 7.5 g of fibrous polypropylene, which has been cut into lengths of about 2 cm, are now added. Specific weight of the concrete obtained 0.95 kg / dm ³ . Compressive strength 50 kg / cm ² .

Example 8

600 g of Portland rapid cement, 1200 g of the usual sand found, which was sifted ^{through a sieve with 9 meshes per cm 2;} 180 g of water, 0.03 cm ^{1 of} a 30% solution of a secondary sodium alkyl sulfate as a surface-active agent and 20 cm ^{3 of} a 2% solution of sulfite liquor concentrate are kneaded together with the cement to form a pliable dough. 330 g of a whipped foam of triethanolamine lauryl sulfate in water are added to the dough. The foam, whipped to eight times the volume of water, is processed with the cement dough to form a porous mortar. The sand and 7.5 g of fibrous polypropylene cut into lengths of around 2 cm are now added in small portions with constant stirring: specific weight of the concrete 0.95 kg / dm ³ , compressive strength ίο 6 kg / cm ² .

Example 9

1200 g of Portland rapid cement, 360 g of water, 0.06 g of a 30% solution of a secondary sodium ^{alkyl sulphate as a surface-active agent, 30 cm 3 of} a 2% solution of sulphite liquor concentrate are processed together to form a pliable dough. Then 78 g of a foam of sodium lauryl sulfate are added. The foam is created by

zo 0.6 g of the foaming agent are whipped with water to eight times the volume of water. To the porous mortar obtained by processing the foam and dough, 7.5 g of polypropylene fibers about 2 cm in length are added in small portions with constant stirring. Specific weight of the concrete 0.7 kg / dm ³ , compressive strength 70 kg / cm ² .

Example 10

This example is similar to Example 7 with the exception that the fibers are absent. Specific weight of the concrete 0.7 kg / dm ³ , compressive strength 62 kg / cm ² .

Measured by the specific weight, the lightweight concrete according to the invention has better nailability than any other lightweight concrete on the market. This nailability extends to that of Wood.

709 522/1

Claims (6)

Patent claims: 1. A process for the production of light and stable, microporous concrete for construction and insulating veils with particularly low water absorption and excellent nailability using water, foam-forming substances, cement and optionally sand, with a specific weight below 1.0 kg / dm ³ a ratio of cement to sand of 1: 0 to 1: 1 J5 and for a specific weight between 1.0 and 1.6 kg / dm ³ a ratio of cement to sand up to 1: 1.7 is used, characterized in that first preparing of water and foam-forming agent a stable foam and this mixed using the other ingredients ♦ to give one or more of the components foam, water, cement and other additives before mixing to at least 15 ° C, but preferably to a temperature between -4 ° C and 0 ⁰ C cools 2. The method according to claim 1, characterized in that organic or inorganic fibers are added. 3. The method according to claim 1 or 2, characterized in that one of water and Cement existing mortar first a tough, stiffly beaten foam is added, whereupon one adding the sand or other solids. 4. The method according to any one of claims 1 to 3, (characterized in that the microporous Cement mortar particles with light weight nind a diameter larger than that Diameter of the micropores, clogs. 5. The method according to any one of claims 1 to 4, characterized in that the mortar is first added a larger amount of foam having small pores, and then an additional amount of foam with larger pores. 6. Use of a light weight produced by the process according to any one of claims 1 to 5 microporous concrete combined with lightweight organic or inorganic panels Material, where a connection has been made by casting or gluing, for the Manufacture of sawable, nailable, non-flammable, water-resistant panels for construction and Insulation purposes.