DE764819C - Process for the production of frost-resistant lightweight stone bodies of high strength - Google Patents

Description

Process for the production of frost-resistant lightweight stone bodies high Strength It is known that from finely divided calcareous and silicic acid-containing Substances that are processed into a casting compound by wetting large amounts of water and then with the formation of Cälciiuinhyclirosilat, preferably by steam under Pressure 'as well as subsequent drying can be solidified, Leichtsteinitnassen with Hoohporöseim the structure can be obtained, which are particularly favorable strength properties distinguish. You have it in your hand, by measuring the Wasiser Mengenin the initial raw mixture to adjust the volume weight of the end products nadb- request. It is also known in the context of this method of operation, the Veresfigungsvorgang in to subdivide two levels, d. H. First of all, a plasitic up to to gain granular, not yet finally solidified mass, then to deform it and to convert the shaped bodies into the final solidified state.

It is also known to produce Leilchtstein bodies in the manner that a mortar mass with cement or lime or heather as a binding material through Peäschen or equivalent mechanical treatment into a frothy Mass transferred, then deformed and the form bodies by the action of steam hardened or that with the same i working method in the lime mortar or cement mortar molasses a specially made shatim is incorporated. at This kind of lightest-weight bodies were made according to the previously known working methods Buildings are created, the pore space of which is largely made up of large pores, generated by mechanical means or by foam processing, was formed. -while the proportion of pores of the total pore space was only very small.

Both types of lightweight stone masses identified above corresponded the requirements of practice only inadequately. It is true that they own the first Place marked lightweight stones with a low spatial density a good imechanifszhe but they are strongly tainted with inner tensions and therefore suffer easily destroyed by the effects of temperature changes or frost. The two All treated, large-pored lightweight stone bodies are also not frost-resistant, moreover show only low mechanical strength.

It was surprisingly found that lightweight stone masses mitt very low density, high strength and complete frost resistance can be if the raw material consists of finely divided calcareous and silicic acid Substances are only mixed with such amounts of water that at least its volume weight is reduced of the hardened body from the substances mentioned from o.9 and that above In addition, the raw mass through the space after 5 to 40%. Vorztlewveise I0 to 3oV%, coarser pores, produced in the mass by gas separation. is enforced.

That it works out this way. to produce frost-resistant bodies. is surprising in the highest degree, because light stone masses with a density of 9, as they differ here as starting material, do not result in frost-resistant bodies, and light stone masses made porous by gas propellants are also in most cases not frost-resistant. The explanation for the surprising effect must be sought in the fact that the use of finely prepared starting materials creates a skeletal structure and the uniformly distributed macropores dissipate as soon as they occur. In addition, in the case of pourable masses, there is also the fact that the gas bubbles developing in the mass have a tendency to rise upwards, while the finely divided solid components, on the other hand, have the tendency to settle on the bottom, and that these counteracting tendencies of movement generally result in such a compensation It is created that it cannot come to the formation of a Uli even structure. The gene Gefüg b limit for the water content (Rauimgewich o.9) applies to the use of the starting materials in the fineness of the übli chen Portlaiilz2iiieiites In further driven fineness can gt erniedri dai density or are the water content of Rohmischungerhöht. if the coarser raw materials are used, the lower ones should be kept lower. So the volume weight has to be increased a little. The amount of gas propellant must also be adjusted accordingly. In the case of coarser raw materials, the amount of gas release agent should be selected higher. It can be kept lower for its starting materials.

But further is important and essential. that the formation of macropores in the mass by gas generation in the mass itself follows. Gas propellant, the erfindungsge bgt. Gas propellants to be used according to the invention are for example aluminum powder. Caleiumpullver. Altiminium alloy powder. Calcium carbide and Wasserstotistupleroxvd can still be used.

ba it is important to distribute the macropore2ni evenly in the mass. and on the other hand it is essential to keep the macroporous content on the whole within certain limits, and uniform and even distribution of the gas propellants is advantageous. An even, fine distribution is caused by the effect. that the gas stirring agents are combined with the other components of the raw mass or with part of these by intimate grinding. In the case of the addition of aluminum powder, for example, the quantities involved are in the range from 0.1 to 0.03%. By a couple of hours. z. B. with part of the sand to be used. the jMuininiuinpul # -er spread out on a large area of sand, namely at di, - the surface V-Irinahlung di eolleichzeit- even finer than it would be possible by grinding the aluminum powder alone, and it remains quite solid adhere to the surface of the ground material, so that even when this ground material mixture is mixed into the other constituents of the raw mixture, no separation or accumulation of the aluminum chip can occur.

Ill which way the shaping takes place, whether by pouring the raw mixture into molds, fluxing it up and smoothing or knocking off the mass rising over the edge of the mold, or by solidifying it by mass Zn n up to, rl-Zrüniel-od-erl, # -ornloiisistentti, nd subsequent deformation is in itself of minor importance. The first-mentioned procedure is more advantageous. In the second case, the deformation of a mass of crumb or grain consistency, it is advisable to incorporate this grain into a mass that consists of evus fine-grained substances containing silica and silica, tailored to the formation of calcium hydrosilicate, and containing small amounts of gas-evolving substances, or to mix the grain with other binders, such as cement or cement mortar, also lime or lime mortar, and then preferably to bring it into the desired shape while avoiding excessive deformation resistance.

Air limes, hydraulic ones, can be used as calcareous starting materials Limes, cements of all kinds, Portland cement, clay deconstructor. As siliceous Raw materials can be used sand, clay, pozzolan, swallow ,.

The solidification of the massie is preferably in closed vessels to be carried out with steam under pressure, at least that to be used at the end of the molding Solidification.

For one, stiffening of the mass for the purpose of removal from the molds, in particular When using Gießwefotrmung, it is recommended either as calcareous Ausganpstoffe to use a hydraulic lime or cement or a Geernisch of air lime and cement. It is sufficient if of the total amount of the calcareous, component io% Cement present stiad.

In this sense, eich works very favorably alongside and instead of cement also Si substance or a similar substance with a higher content of reactive substances Silica, e.g. B. ash or slag.

Finally, it should be mentioned that the raw mixture also includes coarse aggregates, e.g. B. with granular sand, can be gemafgert without that the quality of the products is impaired. For example, is a leaning of up to 30 to 50% of the weight of the solids is possible.

Claims (4)

PATENT CLAIMS: i. Process for the production of frost-resistant lightweight stone bodies high strength due to hydrothecrinic hardening made from vertebral lime and Silicic acid, tailored to the formation of calcium hydroxide Masses, characterized in that the pulpy, volumetric weight of the Final products of at least 0.9 coordinated raw sifting from solids of Cement fineness small amounts of gas-evolving substances are added. 2nd amendment of the method according to claim i, characterized in that when running out of substances greater fineness, alis slie commercial cement possesses, the mass to a lesser extent Basic rate imbalance is set by increasing the amount of water added. 3. Embodiment of the method according to claims i and 2, characterized thereby, that the gas-evolving substances voir the mixing in the raw mixture with a Part that mixes or mixes solid components of the raw mixture will. 4. Ausführungsiorm of the, method according to claims i to 3, characterized in that a grain is formed from a water-rich pulp, finely divided lime and silica-containing substances with the addition of small amounts of gas-developing substances by hydrothermal pasting and this with binders of any kind or with a mixture. finely divided lime and silica-containing substances and larger amounts of water are mixed, small amounts of gas propellants are incorporated into the mixture and then the mixture is deformed while avoiding greater pressure. 5. The method according to -den claims i bisi 4, characterized in that the raw material small amounts, for. B. ioO / o, Si-substance or similar substances with a higher content of reactive Kiesel-hem, z. B. slag or ash can be added. 6. The method according to claims i b-iis 5, characterized in that the raw material mixture with coarser lean substances, e.g. B. sand, is added. To delimit the subject of the invention from the prior art, the following 1) reprints are to be considered in the granting procedure: German, che patent specifications No. 6o2 248, 626 576, 635 559, 421 777, 453 245, 572, 259, 499 405-