DE3230227C2 - - Google Patents

Description

The invention relates to refractory or fire-resistant mortar or Putties containing binders and optionally other conventional ones Surcharges for refractory or fire-resistant light stones.

For the production of linings from stones is already the Known use of mortar and putty with which the joints between the individual stones that form the lining will. Such refractory or refractory mortars can also exist as so-called dry mortar, d. H. they will be just before their application with liquid, usually water or in water dissolved binder, added if the composition of the mortar longer storage is not possible.

As can be seen, for example, from Harders-Kienow, Feuerfestkunde (1960), Page 524, reveals the use of water glass in conjunction with Alumina hydrate, e.g. B. bauxite, in such a refractory or fire-resistant mortar already known. As can be seen from the associated Literature, Ogneupory, Vol. 15 (1950), pages 29-38, however  were found in these mortars in addition to the main ingredient Kaolin chamotte only maximum amounts of up to 10% by weight of bauxite or aluminum trihydrate, see Table III on page 32 this reference. Furthermore, it is from DE-PS 13 00 053 Already known for refractory mortars, which are relatively large quantities contain 75% orthophosphoric acid as a binder, too Alumina hydrates e.g. B. bauxite. How from the Examples of this DE-PS results in a maximum of 7 parts of raw bauxite used on 93 parts of calcined bauxite.

From Budnikov "Technology of Ceramic Products", Moscow 1950, Pages 382-386, refractory mortars are also known this u. a. May contain water glass as a binder. From this Literature shows that to stabilize the water glass an addition of alumina hydrate, Al (OH) ₃, can be made, but here the low porosity of the mortar and the low gas permeability for the mortar are highlighted as desirable properties.

The object of the present invention is to provide a new one fireproof or fireproof mortar or putty that does not Has shrinkage in terms of density Densities of those to be used for the production of the lining Materials or stones is adapted by suitable choice of Composition one of lightweight building blocks and in particular also Elongation, porosity and temperature resistance matched to fiber components has, so that the putty or mortar hardened in the joint Light stones do not pull out.

It has surprisingly been found that by using a certain minimum amount of alumina hydrates, as in the following will be described in more detail, mortar and putty produced can be, which in particular have a low shrinkage and form an elastic mortar or putty joint, so that the hereby In contrast, laid lightweight building blocks or fiber components in use  no more flaking and cracks in the prior art. In particular, however, the mortars or putties according to the invention form their application relatively pore-rich, low-shrinkage joints, so that Insulating ability of lightweight building blocks or fiber components in the area the joint does not show any or not very different values. This could previously be used for mortaring or cementing, relatively dense grouting levels cannot be achieved. Another Advantage of the mortars or putties according to the invention produced joints is that these are elastic and the to be installed Stones can be adapted in terms of strength and porosity, so that in addition to the better insulation capacity also a less material may be required for mortar or putty.

To solve the problem described above, the mortar or putty according to the invention, which are characterized in that they are at least 20 wt .-% of alumina hydrate, based on anhydrous and glow loss-free solids.

According to a preferred embodiment, the mortar or putty at least 40% by weight and in particular at least 50% by weight Aluminum oxide hydrate, based on anhydrous and glow loss-free Solids.

According to a further preferred embodiment, the Mortar or putty according to the invention as a binder, water glass or a phosphate with a pH greater than 5, measured in 1 wt .-% aqueous solution, or a colloidal Alumina hydrate, as will be described in more detail below.

According to a further preferred embodiment, the Mortar or putty according to the invention 0.5 to 10 parts by weight of binder, calculated as an anhydrous or ignition loss-free solid 100 parts by weight of the other solids present. A preferred one Binder is a water glass that has a SiO₂: Na₂O ratio of greater than 3.0 and in particular from 3.7 to 3.8.  

According to a further preferred embodiment, the mortar or putty according to the invention contain an adjusting agent, advantageously in an amount of 0.1 to 5.0 parts by weight Adjusting agent, calculated as an anhydrous adjusting agent, per 100 parts by weight of the present solids. A preferred actuating means is Carboxymethyl cellulose, however, is also the use of Polyvinyl alcohol or starch can be used as an adjusting agent. Through this The consistency of the mortar or putty can be adjusted in a suitable manner Set way, d. H. its plasticity or viscosity, so that this makes the workability of the mortar or putty special Applications can be adapted. In particular, such Adjustment means can also be prevented when painting the mortar or putty into the joint with the water contained in the putty or mortar can be quickly absorbed by the dry light stones, which is too could result in short processing times.

If necessary, in the mortars or putties according to the invention Containing additives are all usual additives like Fireclay, porcelain flour, kaolin and / or clays, however, is preferred the use of calcined bauxite and / or sintered or Melted corundum as a surcharge.

A particularly preferred mortar or putty according to the invention is made only from aluminum oxide hydrate or aluminum oxide hydrates and colloidal Alumina hydrate as a binder, so that this is a highly fire-resistant Groove can be obtained, which - after appropriate heating - out Al₂O₃ exists.

These mortars or putties advantageously consist of a mixture, the 2 to 10 wt% colloidal aluminum hydrate, calculated as anhydrous and glow loss-free solid, and the rest of one or several aluminum oxide hydrates, also calculated as anhydrous and glow loss-free solids.

It is also possible that the mortar or putty according to the invention instead of aluminum oxide hydrates entirely or partially from magnesium hydroxide and / or zirconium oxide hydrates exist. This makes it possible to  Grooves with regard to their chemical composition or required mechanical properties during operation adapting stones and special properties of the joints to reach.

The mortar or putty containing magnesium hydroxide and / or Zirconium oxide hydrates can also use additional aluminum hydrate contain.

The invention is described in more detail below, starting with the alumina hydrates, which are the essential Form components of the mortar or putty according to the invention.

As such alumina hydrates, both non-calcined, naturally occurring bauxite, possibly a very high bauxite chemical purity, or also monohydrates or trihydrates of Aluminum oxide in various modifications, e.g. B. as Gibbsite or hydrargillite, bayerite or boehmite can be used. At these aluminum oxide hydrates are water of crystallization, unstable connections in the thermal range, which become in contrast to anhydrous, d. H. calcined and inert oxides, the fiber components used to manufacture the lining and Adapt light bricks in all temperature ranges and result in permanent fire-resistant or fire-resistant bonds. By the exit of the hydration water or crystal water receive the Putties and mortar according to the invention the desired pore volume, you low weight and thus a higher insulation and a better stretching behavior and shrinkage behavior. Instead of the Alumina hydrates can also be magnesium hydroxide (brucite) and / or Zirconia hydrates can be used. The is also possible Use any mixture of these.

From these aluminum oxide hydrates, the magnesium hydroxide or the Zirconium oxide hydrates the water when the joints heat up Operation split off, for example the water is split off with aluminum trihydrate between temperatures of 270 to 620 ° C instead.  

The mortars or putties used in the invention Aggregates can be granular aggregates, clay minerals Substances, etc., depending on the content of aluminum oxide hydrate, Leave magnesium hydrate and / or zirconium hydrate and additives after drying the mortar or putty according to the invention at 110 ° C. and firing at 1000 ° C density from 0.6 to 1.5 g / cm³ to reach.

When using hydragillite and Boehmit is advantageously with a grain size of Agglomerates of less than 100 µm and possibly after grinding with a Grain size below 44 µm or particularly preferably below 10 µm used. By such grinding, i.e. H. Crushing becomes one better workability of the mortar.

As previously mentioned additives, tabular clay, Quartzite, zircon, zirconium dioxide and magnesia sinter, advantageously in a grain size below 2 mm, especially preferably less than 0.7 mm can be used. As a clay mineral Aggregates give better kaolin and refractory clay Processability and good strength.

As binders, all can usually be in refractory or fire-resistant mortars or putties used binders be the most suitable life of the already liquid enable offset mortar or cement, is particularly preferred however, the use of water glass, a phosphate with a pH greater than 5 or more preferably a colloidal Alumina hydrate, which is in the form of an aqueous slurry or an aqueous gel.

In the production of the mortar or putty according to the invention, the Individual components mixed together, with a suitable proportion of water may need to be added to either  Bring binder in solution or the finished mortar or putty to give the appropriate consistency. As before, however described, the mortar can also be called dry mortar are present, d. H. these must then be filled with the appropriate amount Liquid, usually water, to be put on before use be transferred.

This is preferred for the mortars or putties according to the invention phosphate used with a pH greater than 5 is either a sodium polyphosphate, for example with a degree of polymerization n between 3 and 10 or also monoaluminum phosphate with a organic base was brought to a pH of greater than 5. By using phosphates with a pH greater than 5 the storage period of the prepared mortar or Putty significantly increased.

The preferred colloidal alumina hydrate may be one aqueous, hydrophilic aluminum hydroxide gel, which in general a solids content of 10 to 30 wt .-% of alumina hydrate or Dry boehmite, Al0 (OH). This colloidal Alumina hydrate can be made as follows:

Boehmite, ie α- aluminum monohydrate, of high purity with a content of 70% by weight Al₂O₃, 0.008% by weight SiO₂, 0.005% by weight Fe₂O₃, 0.004% by weight Na₂O and a specific surface area of 170 m² / g As is the case with the Ziegler process for the production of short and long-chain fatty alcohols with a vessel of butanol, so much glacial acetic acid is added at room temperature in a kneader that the entire mass has a pH of 3.2 after 80 minutes of kneading . The mass obtained is then dried and a 20% by weight aqueous gel in the form of a colloidal, hydrophilic preparation is prepared from the dried product with the addition of organic or inorganic acids at a pH of 5.5. Glacial acetic acid is advantageously used as the organic acid. Suitable inorganic acids are hydrochloric acid or nitric acid.

According to a modified way of working, the boehmite is first also reacted with glacial acetic acid after drying the mass however, this is with aqueous ammonia solution at a pH of 8.5 processed into an aqueous gel.

Suitable aluminum hydroxide hydrates are also commercial products. The Weight percentages given relate - unless otherwise is specified - on water-free and glow loss-free solids, d. H. both the alumina hydrate, the colloidal Alumina hydrate as well as the magnesium hydroxide or Zirconium oxide hydrate, this information relates to either Al₂O₃, MgO or ZrO₂, d. H. without any water of crystallization, water of hydration or other chemical bound water.

The invention is illustrated by the following examples, the quantities always refer to parts by weight, if nothing else is specified.

Examples 1 to 4

The components listed in the following table were in mixed into a mortar using a conventional mixer. In the table is furthermore the liter weight, the bulk density after drying at 110 ° C and specified after a fire at 1000 ° C.

From these values it can be seen that by suitable composition the mortar density according to the invention between 0.75 and 1.2 can be achieved.  

Table I

Examples 5 to 8

According to the procedure of Examples 1 to 4, the the following ingredients mixed into mortar, using as a binder Commercial sodium polyphosphates were used in solution once a pH of 7.5 and the other time a pH of 5.5 surrendered. The composition of the mortar is shown in Table II below specify.  

Table II

Examples 9 to 12

The procedure of Example 1 was repeated, however Magnesium hydroxide was used instead of hydrated alumina. This magnesium hydroxide was after Material extracted from the seawater process. With the one used here Mg melted magnesite, which was added as an additive, was trading fused magnesia with a grain size below 44 µm. Through the Using melted magnesia can increase hydration during storage be counteracted.

The composition of the putty obtained is as follows Table III indicated.  

Table III

Examples 13 to 16

The procedure described in Examples 1 to 4 became repeated, but instead of alumina hydrate Zirconium oxide hydrate of the following general formula was used:

Zr (OH) ₄ · 2H₂O

In this case, burned zirconium dioxide was used as an additive used.

The composition of the mortar produced is given in Table IV below.

It should also be noted that those given in the examples Additional amounts of water refer to 100 kg of solids, whereby these solids as such and not as anhydrous and Solids free from ignition loss were calculated.

With the method according to the invention it is of course possible instead of an alumina hydrate also a mixture of Aluminum hydrates to use.

When using the examples described above described mortars or putties for grouting lightweight fire bricks excellent results have been obtained in all cases because the Mortar or putty compared to their higher porosity previously known kittens were very elastic and none on the stones Cracks or flaking caused.

Claims (14)

1. Refractory or fire-resistant mortar or putty, containing binders and possibly other usual additives for refractory or fire-resistant light bricks, characterized in that they consist of at least 20 wt .-% of aluminum oxide hydrate, based on water-free and loss-free solids. 2. Mortar or putty according to claim 1, characterized in that it at least 40% by weight of aluminum hydrate, based on anhydrous and glow loss-free solids. 3. Mortar and putty according to claim 1, characterized in that it at least 50% by weight of aluminum hydrate, based on anhydrous and glow loss-free solids. 4. Mortar or putty according to one of the preceding claims, characterized characterized in that they are water glass or a binder Phosphate with a pH greater than 5 or a colloidal Alumina hydrate included.   5. Mortar or putty according to one of the preceding claims, characterized characterized in that they have 0.5 to 10 parts by weight of binder Contain 100 parts by weight of the present solids. 6. Mortar or putty according to claim 4, characterized in that it as a binder water glass with a ratio of SiO₂: Na₂O of greater than 3.0 included. 7. Mortar or putty according to one of the preceding claims, characterized characterized in that they also contain an adjusting means. 8. Mortar or putty according to claim 7, characterized in that it 0.1 to 5.0 parts by weight of adjusting agent per 100 parts by weight of the present solids. 9. mortar or putty according to claim 7 or 8, characterized in that they contain carboxymethyl cellulose as a setting agent. 10. Mortar or putty according to one of the preceding claims, characterized characterized in that they contain calcined bauxite and / or contain sintered or fused aluminum oxide. 11. Mortar or putty according to claim 1, characterized in that it only from aluminum hydrate and colloidal aluminum oxide hydrate exist as a binder. 12 mortar or putty according to claim 11, characterized in that 2 to 10% by weight of colloidal aluminum oxide hydrate, calculated as water-free and loss on ignition loss, consist.   13. Containing refractory or refractory mortar or putty Binder and possibly other usual supplements for fireproof or fire-resistant lightweight stones, thereby characterized in that they consist of at least 20% by weight Magnesium hydroxide and / or zirconium oxide hydrates, based on anhydrous and glow loss-free solids. 14. Mortar or putty according to claim 13, characterized in that it additionally contains alumina hydrate.