DE966229C - Refractory basic materials - Google Patents

Description

Refractory basic materials It is known basic refractory Manufacture materials in such a way that burnt magnesite or dolomite is mixed with steel mill tar mixed in the warmth until it has a plastic consistency and then either into stones bruises that are put into the furnace in pre-baked, ter or unfired form, or that the mass as such is tamped into the furnace, e.g. in the case of steel mill floors. It is also known that there are surcharges such. B. of silica and / or Alumina and / or metal oxides and the like The temperatures required for firing or sintering these stones or masses are necessary so that they become sufficiently firm, are consistently higher than goo '°. However, it is known that these products despite the high firing temperatures are not always sufficiently chemically resistant, e.g. B. against infiltrating slag that they are also not sufficiently resistant to temperature changes are and also consistently - even at low temperatures - with water or steam, z. B. also combustion gases, react and become crumbly and disintegrate. For this reason, in addition to basic feed, certain foods are used in technical ovens Provide neutral or acidic feed, e.g. B. chamotte or quartz lining. Here is known to accept the disadvantage that at the transition point of the different Forage types premature destruction the furnace infeed occurs and repairs are often required at these points.

These disadvantages of basic materials are avoided if you use the Lean agent (coarse material) wholly or partially made of highly sintered alkaline earth oxide, z. B. sintered lime or sintered dolomite or sintered magnesite, so mainly from the oxidic components, -in dead-burned form and in fine material as an essential component finely ground limestone, dolomite stone and / or aridere Alkaline earth carbonates, e.g. B. Witherite (barium carbonate), preferably in crystalline, mineral form. A remainder of the fine material can consist of oxides or others Substances that are identified below exist.

The fine material is mixed with liquid and / or solid organic substances, z. B. hydrocarbon-containing substances, mixed as a binder. The binders can e.g. B. from tar or from Sulite waste liquor or other hydrocarbonaceous Substances exist. Furthermore, the stone meal can be used undried or one can Before adding the hydrocarbon-based binding agent, wash it with water (up to Mix to io ° / o-) or treat with steam below 30o °.

While it was previously believed that the presence of any Water is harmful, it has been found to be remarkable that both the sliding property of the material when pressing or tamping and also the hardness of the fired material and its density is much more favorable, alis when anhydrous materials are used as binding material. The cause of this The surprising and remarkable effect is probably that the cracking the carbonization components or the bituminous substances in a particularly advantageous manner Way is going on. An economic advantage of working according to the invention it is @ that you can get by with much lower temperatures for heating (30o up to 90o '°) than was previously the case (iooo to 14o0' °). In the oven with this one If the material is lined, the temperature can then be increased as required are up to an altitude of 170o to 2ooo °.

It is often an advantage to use stone dust in addition to small amounts of metal oxides or metals, e.g. B. iron, copper and the like, still small additions of finely ground Add silica or alumina or other substances that are adsorptive at the same time work and a particularly good one due to the strong binding of the binding agent and water Cause dimensional stability of the stones before and during heating and then at higher Temperatures with existing alkaline earth oxide and the like slag - and to a certain extent Form an inert protective glaze over the coarse material. It was found that the Stones are particularly dense and despite being heated at a low temperature have very good thermal shock resistance and also against the effects are resistant to water vapor.

Another feature of the invention is that one preferably uses the fine material such substances are added which lower the surface tension or act as mineralizers are known, e.g. B. chlorides, fluorides, borates, phosphates, chromates, vanadates, sulfates and the like, or their reduction stages, e.g. B. Borides. The latter can also be used when burning or are formed in later operation from corresponding oxidation stages or caused by rearrangements. Small amounts of these effective supplements are often sufficient the molar mixing ratio of aggregate to alkaline earth compound is preferably established in the fine material to the ratio i: 2 '.

Claims (3)

PATENT CLAIMS: i. Process for the production of refractory basic materials from alkaline earth compounds in the form of oxides and carbonates, characterized in that the coarse material in the main alkaline earth oxides, z. B. sintered lime or sintered dolomite, and used as fine material alkaline earth carbonates in finely ground form and subjecting the masses to a heating process after adding organic binders. 2. The method according to claim i, characterized in that that the fine material is moistened with water, for example up to io ° / aa, and with the organic binders, e.g. B. tar or Sulphitalrlauge, added and these Substances at temperatures below 300 °, possibly in a steam atmosphere, mixes and after mixing with the coarse material and optionally after shaping or a Pressing a heating process at temperatures higher than 300 ° and preferably subject to no higher than 90o '°'. 3. The method according to claim i and 2, characterized in that substances are added which lower the surface tension or are known as mineralizers, for. B. fluorides, borates, phosphates, sulfates and the like or their reduction stages; up to the molar ratio of aggregate to alkaline earth compound of the fine material of 1: 2. Considered publications: German Patent Nos. 582 311, 747 517 844 728 847 568; Sea; rle Reiracitory Materials, 1924, p. 398.