DE3218446A1 - Binder for a construction material mix - Google Patents

Abstract

A binder consisting of a mix of a calcium aluminate is obtained by burning fine grains of calcium compounds and aluminium compounds, finely grinding the calcium aluminate and mixing it with anhydrite, calcium sulphate hemihydrate or calcium sulphate dihydrate and, as appropriate, further additives and processing it by making up with water to a pourable consistency.

Description

description

The invention relates to a binder for a building material mixture under Use of calcium sulfate compounds.

It is well known that apart from hydraulic binders Calcium sulfate compounds in particular with half a molecule of crystal water, however They are also free of water of crystallization, valuable, easy to process, clean binders, which have found widespread use in construction. Is to be mentioned in particular here calcium sulphate hemihydrate, which in its hardened form forms gypsum, and as such for the production of panels and similar moldings use finds, as well as in connection with aggregates as a plaster mix, to name but a few to name.

The anhydrous calcium sulfate, known as anhydrite, is used also mixed with calcium sulfate hemihydrate, for example for floor screeds or as a dam construction material in mining. These calcium sulphate binders are made from naturally occurring gypsum stone broken in nature and made by burning or found directly in nature.

On the other hand, today it is also common knowledge that such Calcium sulfate compounds in the form of anhydrite, hemihydrate and dihydrate in large Quantities in the production of phosphoric acid and in the increasingly more and more flue gas desulphurisation practiced. This generated by industrial processes Calcium sulfate compounds are natural, due to their creation and education loaded with a variety of foreign substances of active and inert character, the a use of such industrial plaster in contrast to those made of natural Make the occurrence of gypsum more difficult or even impossible.

In order to remedy this problem, many methods have become known, to treat industrial plasters or those from phosphoric acid production in such a way that that they can be processed like plaster from natural resources. Although these Treatment processes eliminate the polluting landfill of industrial gypsum want, they are only partially successful, so that still large quantities Industrial gypsum must be dumped in landfills. On the other hand, these are processing methods also disadvantageous because they are the correspondingly improved product more expensive in every respect, so that it is difficult to use them competitively is.

There has therefore been no lack of proposals and publications like such industrial plasters, used cheaply and advantageously without further treatment can be.

In particular, this is also where the present invention comes into play one by helping to solve a problem, especially industrial plaster in everyone To make the form, be it as hemihydrate, dihydrate or aniwdrite, inexpensively usable, in such a way that a binder is produced which is similar to that of all conventional binders of this Category can enter the competition that but also a possible use forms, for naturally occurring calcium compounds.

This task is solved by a binding agent made of calcium aluminate in fine grain, mixed with finely ground gypsum in the form of anhydrite, hemihydrate or dihydrate in an amount such that to 1 mole of alumina in the calcium aluminate 3 moles or more of calcium sulfate come in. This mixture becomes pourable with water Consistency transferred and processed.

This is how one goes e.g. for the production of the monocalcium aluminate (CaO.Al203) of calcium compounds such as calcium carbonate, calcium oxide or calcium hydroxide with a grain size im from, including naturally occurring calcium compounds, for example Calcite or arogonite can be used * As an aluminum compound is a natural Occurring or artificially created aluminum mineral with a high content used on aluminum hydroxide or aluminum oxide. It can contain minerals of the bauxite group used, for example diaspore or gibbsite, or mixtures of such substances, also with a very fine grind like the calcium compound. This quantity, which are mixed in the ratio of 1 mole of calcium oxide per 2 moles of aluminum hydroxide, are mixed with a flux made of iron sulfate and / or calcium fluoride and formed into pellets with a diameter of 4 to 10 cm with a little water and placed in a rotary kiln or similar firing units for 0.5 to 4 hours at temperatures between Fired 850-15000C, preferably between 900-12000C.

The calcium aluminate produced by the firing process is in a Grain size 4cm32 ßm for the production of the binding agent with calcium sulphate in the form of the Dihydrate, hemihydrate or anhydrite, or mixtures of these compounds mixed in such a way that amounts between 1-3 moles of CaS04 per mole of Al203 des Calcium aluminate come. The mixing water is added in such an amount that that you get a pourable consistency or at least so much that a Compound of the formula 3CaO.Al203.3CaS04.31H20 gives. this connection can Plaster of paris is also present in conventional form, i.e. as a dihydrate, in any amount. The building material mixture can be adjusted so that there is one in the finished product Contains portion of the above compound bearing the name Ettringit, as well Ettringite-like phases, a portion of gypsum and a portion of aggregates. These Aggregates can also be present in the form of already set plaster, or in the form of sand, fly ash and the like.

The amount of mixing water and the calcium sulphate compounds that can be added but can also be dimensioned so that as far as possible only the above-mentioned connection Ettringite forms. By means of this connection can be more advantageous according to the invention Way, also process a large amount of waste or industrial plaster, which is merely the calcium sulfate phase supplies and otherwise as a filler or as forming in situ Plaster of paris is present.

In addition to the additives mentioned above, vermiculite, Perlite, Natural stone, limestone, slag, etc. are processed, whereby the grains or the sieve curves are chosen so that depending on the use or application of the binder optimal conditions can be achieved.

According to the invention it is also possible to add fiber material to the binder mixture to be added in the form of natural fibers or synthetic fibers or glass fibers or Cellulose fibers, liquefiers and foams to loosen up the end product.

In the production of the building material mix can also, as per se known dispersants and wetting agents, reaction accelerators and reaction retarders can be used, cement can also be added. Depending on the setting of the Mixture, the setting time of the material is between 20 minutes to 48 hours, with the milling and firing conditions exert an influence.

The building material according to the invention can be obtained solely through the compound ettringite be connected or by a similar connection made by a similar above described manner arises and it is possible according to the invention by surcharges to lose weight up to 80%.

The density of one made from such a building material mixture Shaped body can be about the water-binding agent factor and about additives and others Additions can be varied within a wide range, so that the weight is between 0.05 g / cm3 - 2.0 g / cm3 can vary. The building material according to the invention is particularly advantageous in its application as a fire protection panel because of the relative high crystalline-bound water content. The incident caused by the release of the water Shrinkage of the building material itself, leading to the disintegration of a panel, for example can lead by incorporating a lot of mineral fibers, vermiculite, etc. be prevented.

The invention will now be explained in more detail on the basis of the following 5 examples explained. In these examples the calcium aluminate (CA phase) was made as follows: 5200 g Al (OH) 3, 5000 g CaC03, 200 g flux with a grain size c 63 m are mixed, Pelletized after addition of water and burned for 4 hours at t2000C in a chamber furnace. It arises approx.

6200 g of a CA phase, which with the help of a cross beater mill to 32 ßm grain size is ground. According to the X-ray diffraction analysis, the material passes mostly from CA phases.

Examples: Examples Water loss Examples of bending tension ball compression pressure WGF volume weight when heated. IR, Rö-Ana- festi @ k. 1000 ° C analysis Basic mix 100 g CA phase 1.9 - 2.6 50 - 75 20 - 40 0.54 1.2 - 1.5 30 - 35 sales CA- 318 g DH REA phase full constant Basic mix 2.2 - 3.0 60 - 80 30 - 50 0.54 1.4 - 1.6 20 - 30 Sales CA- leaned with phase full 20% CaCO3 constantly Basic mix leaned with 2.2 - 2.8 30- 40 10 -20 0.87 1.3 - 1.6 10 - 20 dto. 50% CaCO3 Basic mix leaned with 2.0 - 2.5 60 - 80 30 - 50 0.54 1.3 - 1.8 20 - 30 dto. 20% nature AII 100 g CA phase removed + 300 q REA-DH 10 - 15 40 - 50 - sucks 1.2 - 1.3 - dto. 40 g cellulose from Fibers 6-fa- chem Excess water

Claims (10)

Claims 1. Binder for a building material mixture using of calcium sulfate compounds characterized in that the calcium aluminate in Form of mono- to tricalcium aluminate in fine grain with finely ground plaster of paris in the form of anhydrite, hemihydrate or dihydrate mixed in such an amount is that for 1 mole of alumina in the calcium aluminate compound, 3 moles or more Calcium sulfate come, this mixture then with water in a pourable consistency transferred and processed. 2. Binder according to claim 1, characterized in that the calcium aluminate from a pelletized mixture consisting of calcium compounds such as calcium carbonate, Calcium oxide or calcium hydroxide with a grain size of 63 tim and aluminum compounds with a grain size of 63 µm by firing at temperatures between 850 - 15000C is. 3. Binder according to claim 1 and 2, characterized in that the mixing ratio of calcium compounds to aluminum compounds is 1 to 3: 2 Moles. 4. Binder according to claim 1 to 3, characterized in that the pellets are between 4 and 10 cm in size. 5. Binder according to claim 1 to 4, characterized in that the firing temperature of the mixture of calcium and aluminum compounds is preferred is between 900-12000C. 6. Binder according to claim 1 to 5, characterized in that the burnt product from the calcium and aluminum compounds <= 32 µm ground is. 7. Binder according to claim 1 to 6, characterized in that Aggregates are added to the binding agent in the form of hardened plaster of paris, sand and fly ash and that the gypsum preferably comes from flue gas desulphurisation. and some of the fly ash is contained therein as an impurity. 8. Binder according to claim 1 to 6, characterized in that the binder with aggregates such as vermiculite, perlite, natural stone grains individually or in a mixture, is mixed. 9. Binder according to claim 1 to 8, characterized in that fibers of natural or artificial origin are added to the mixture. 10. Binder according to claim 1 to 9, characterized in that the mixture is other known per se in the processing of calcium sulfate hemihydrate Contains thickening agents used, such as retarders, accelerators and hardeners.