DE1278919B - Molded body for lining oxygen converters based on MgO - Google Patents

Description

Shaped body for lining oxygen converters on the basis of MgO Steel production in oxygen converters by means of the so-called Oxygen blowing has found widespread use in recent years and is increasingly displacing the traditional methods of steel production. at This process places extreme demands on the refractory materials the converter linings. The slag formed in the oxygen converter process is essentially basic and thus a basic refractory lining must be used Material to be applied.

The lining material commonly used in the United States and used in Europe is dead-burned dolomite, which is mixed with a non-aqueous Tar or pitch is bound. Such a mixture is either shaped into stones or pulverized into a monolithic structure. In other ways of working, fine and dead burned magnesium oxide for part of the dolomite as the fine fraction of the mixture replaced. This creates a mixture of coarse dolomite and fine magnesium oxide grains applied, which are bound with tar or pitch. It's common knowledge that Dolomite slightly hydrated when exposed to humidity. the The tendency to hydration is caused by the coating of the non-aqueous tar or Reduced pitch used as a binder. Applying magnesium oxide in the fine fraction instead of calcium oxide or dolomite improves the resistance of the masonry against moisture attack, since magnesium oxide is slower than Hydrated dolomite.

Masonry of this type produces good results in oxygen converters guided. It has sufficiently high fire resistance to withstand the unusually high To withstand and exhibit temperatures encountered during the blowing time good resistance to the corrosive effects of the slag. Such a thing Masonry is however in terms of mechanical strength, abrasion resistance and Resistance to abrupt temperature changes is not entirely satisfactory.

A brief description of the oxygen converter process shows that the molten pig iron and scrap (up to 50% scrap) in the vessel together with the slag-forming components such as calcium oxide and limestone will. Oxygen is blown onto the surface of the molten metal. After the conversion of the oxygen with the metal impurities to the end has come, the oxygen tube is removed and the finished steel from the vessel poured out.

A converter is expected to operate at least 200 times before the liner is replaced. It goes without saying that the refractory surface, on which the molten pig iron. and the scrap is given with each loading must have sufficient mechanical strength to withstand repeated impact to withstand these materials. Furthermore, these surfaces must have a good Abrasion resistance to the imported materials as well as the movement of the molten Have steel during casting. After all, the refractory material must face to be resistant to abrupt changes in temperature caused by the sudden Result in temperature changes during charging, blowing and pouring.

The previously known relevant refractory materials were able to to meet these increased requirements in a satisfactory manner. One has such refractory bricks or molded bodies made of sintered or melted dolomite by intimately mixing the ground dolomites, sieved to size, with tar, Processing of the mixture into bricks under high pressure and subsequent firing the briquettes produced, the procedure being specifically so that the firing of the briquettes by placing in one preheated to about $ 001C Furnace and Afterburning is carried out in a strongly reducing atmosphere at a temperature of over 1350 ° C will. In other words, the dolomite is bound into a stone with tar, which is then coked. The stone product thus obtained can optionally be mixed with liquid Bad luck to be covered. However, these are not ceramically bonded Magnesite bricks impregnated with tar.

It has also become known, refractory moldings on the basis of sintered dolomite or similarly behaving minerals against you through hydration to protect conditional decay by immersion in a tarry protective mass, whereby a pitch is used as a protective mass, which either consists of anhydrous coal tar or coal pitch with a high softening point and a content of free Carbon consists of over 55%. Here, too, lies in the finished, for the application provided molded body before no ceramic bond.

It has also become known, moldings based on Manufacture magnesium oxide, the same optionally impregnated with tar and the Mg0 content is of the order of 910/0.

Also the use of tar-bound and tar-impregnated magnesite stones is known from the prior art in which a synthetic magnesium oxide, that is obtained from seawater is used and the content of MgO 97% lies. A ceramic one, however, has not become known in this context Bond, with an extraordinarily high bulk density and porosity.

With regard to fired basic masonry, it is known that the same is true often a significantly greater mechanical strength than unfired masonry due to the ceramic bond formed during firing. There is usually a direct relationship between mechanical strength the masonry and the abrasion resistance. Thus, as the mechanical increases Strength of the masonry also increases the resistance to abrasion. However, it is also known in the relevant industry that a fired basic masonry generally experiences chipping or chipping much more easily than chemically bonded or not fired masonry is the case. -This inclination to a flaking makes it still necessary for the new linings a A burn-in or heating-up time of 10 to 12 hours should be provided, while the with Tar-bound, unbaked masonry linings are safe in 1 to 5 hours can be heated.

The invention is based on the object of providing molded bodies for building up for the clothing of oxygen converters in the form of masonry, by means of which the disadvantages dealt with in the prior art are avoided will. The relevant experience has shown that increasing only the Magnesium oxide content compared to a certain percentage not in a linear manner or predictable increase in all properties. So shows the relevant Experience that when the degree of purity of the magnesium oxide is increased, this results in it becomes very difficult to achieve increased density. The experience continues has shown that, especially at room temperature, a reduction in the magnesium oxide content tends to increase mechanical strength. There are thus contradicting one another Results that cannot be predicted in the form of an extrapolation.

According to the invention, a molded body of the specified type for Lining of oxygen converters created on the basis of MgO, which thereby is characterized in that the MgO content of the body is at least 96 Qlo and the rest consists of common impurities and the body is impregnated with tar is.

A molded body constructed in this way now has with respect to Sum of the technical properties of interest, such as strength, slag resistance, Chipping resistance and density values are based on lower percentage magnesium oxide contents can not be derived linearly, but rather asymphtotic in the range of over 96 Q / o increase.

The moldings of the invention are particularly suitable for those Parts of the lining of oxygen converters that are particularly sensitive to impact, abrasion and Chipping are claimed.

A lining built up from the molded bodies can in particular- find application where the feed materials fall into the vessel, as well as the cone section that was previously used during the loading and pouring of the hot metal was subject to severe abrasion, which continues through mechanical damage in the removal of unwanted accumulations Materials revealed. By applying the brickwork in these places will be its excellent properties made use of, and the destruction of the lining material due to the effects of impact forces, abrasion and chipping is reduced. This means that the lining does not need to be replaced or repaired as often, as has been the case so far. The brickwork according to the invention is made from dead-burned Magnesium oxide produced synthetically from seawater. The thus obtained Magnesium oxide can be obtained with the high magnesium oxide content required for the Practice of the invention is critical while natural magnesite is in deadburned State does not have the important magnesium oxide content. The remaining part The brickworks generally consists of silicon dioxide, iron oxide, aluminum oxide and calcium oxide.

The magnesia brickwork can be according to any of the currently for The production of refractory products can be obtained using methods. So z. B. the brick molds pressed, hammered, stamped, extruded or deformed by any other known method. That to manufacture Magnesium oxide used in the brick attachment is a high degree of purity and high density dead burned magnesium oxide. A particularly satisfactory one for this purpose Grain can be produced by dead burning of calcined magnesium oxide at an elevated temperature of about 1600 ° C or above can be obtained in a rotary kiln. Optionally can the calcined magnesia dry into small compacted bodies at a pressure deformed by at least 1400 kg / em2. Then -be condensed Body burned to death at a high temperature, preferably at one temperature above 1870 ° C or even up to 2320 ° C, e.g. B. in a shaft furnace. The thus obtained very dense grain is crushed and classified to make an appropriate material conventional screen size for brick production. In the approach will a temporary binding agent incorporated and then the brickwork from it shaped. A particularly useful way of working to obtain a very pure, dead-burned magnesium oxide, which is used in the manufacture of brickworks, is given in U.S. Application Serial No. 847,864.

The brickworks are then burned. A traditional way of working is to heat the same to a temperature of about 1600 ° C and this Maintain temperature for an extended period of about 10 hours. After cooling down the brickwork is impregnated with tar or pitch. This will take about half an hour Immersion of the fired brickwork in liquefied pitch achieved, which in general is heated to a temperature of about 200 ° C. Surprisingly, it penetrates Pitch completely, and there can be practically the same amount of pitch in a brickworks be incorporated in this way, as done by means of tar binding under Apply can be achieved by liquefied pitch. For this purpose it can be more commercially available Tar or pitch based on petroleum or coal can be used. Generally will a coal-based pitch with a softening point on the order of 65 ° C applied.

The invention will be further elucidated below with reference to the examples explained. Example 1 In this example dead-burned magnesium oxide is used, synthetically produced from seawater. This magnesia has expressed in percent by weight, the following composition: 5402 .................... 0.9 A1203 ................... 0.4 Fe203 ................... 0.3 Ca0 .................... 1.1 Mg0 .................... 97.3 The dense grain was crushed and a sieve analysis which, expressed as a percentage by weight, gives the following result: -4 + 10 . . . . . . . . . . . . . . . . . 40 -10 + 28. . . . . . . . . . . . . . . . . 15th -28 + 65. . . . . . . . . . . . . . . . . 15 -65 ...................... 30 There will be about 5 weight percent concentrated waste sulfite liquor used as a temporary binder is added to the approach and then the brickwork at a pressure of 560 kg / cm2 pressed. The brickworks is fired at a temperature of 1600 ° C and Maintained at this temperature for 10 hours. Heated to a temperature of 200 ° C Pitch is then used to impregnate this brickwork, and this is done through half-hour immersion of the same in the liquid pitch achieved.

For comparison purposes, a brickwork is produced with an analysis that is outside the limits of the mass according to the invention. Example 2 According to the procedure given in Example 1, brickworks are produced from dead-burned Austrian magnesite with the following composition: Si02 ..... ............. 0.6 A1203 ...... ............. 0.6 Fe203 ................... 6.5 Ca0 .......... .......... 3.3 Mg0 .................... 88.7 A brickwork of this composition has been used in oxygen converters. It was found, however, that both reduced fire resistance of the brickwork and chipping were significant problems which could not be overlooked. Example 3 In order to show the critical value of the magnesium oxide content, and this to distinguish it from the initial source of the magnesium oxide, brickwork is formed from synthetic, dead-burned magnesite, which is obtained from seawater and in the dead-burned state, expressed in percent by weight, has the following composition: S402. ................... 4.7 A1203 ................... 0.3 Fe203 ... ................ 0.7 Ca0 .................... 1.4 Mg0 ...... .............. 92.9 This brickwork is manufactured according to the procedure given in Example 1. Tests on this brickworks carried out on an industrial scale indicate that chipping is a serious problem.

In addition to the above examples, brickworks are manufactured in the following manner, containing calcium oxide in an amount of at least 5 percent by weight and generally obtained by known procedures. Example 4 Dead-burned, very pure dolomite and synthetic magnesium oxide of the following composition are used: Dolomite magnesium oxide ° / o ° / o 5402 ................ 0.14 2.8 A1203 ............... 0.25 0.3 Fe203 ..... .......... 0.09 0.6 Ca0 ................ 57.75 1.5 M90 ................ 41.74 94.8 The dolomite and magnesium oxide are crushed and classified in accordance with conventional practice and combined to yield a 60:40 weight percent mixture. This material is then heated to a temperature of about 110 ° C. and about 2.5 percent by weight of molten paraffin is mixed with the batch. Bricks are then pressed from the batch at a pressure of about 560 kg / cm2. This brickwork is placed in a kiln and the temperature is quickly increased to about 1480 ° C and then held at this temperature for 5 hours. The fired brickwork is then boiled in tar to impregnate it. The fired brickwork has the following composition: 5102 .................. 1.2 "/ p A1203................. .. 0.2 "/ a Fe2O3. . . . . . . . . . . . . . . . 0.4 "/ o Ca0................... 35.4" / o Mg0. . . . . . . . . . . . . . . . . 63.0n / 0 90 parts by weight of very pure magnesium oxide and 10 parts by weight of very pure calcium oxide of the following compositions Calcium oxide magnesium oxide ° / o ° / o 8i02 ... ............ 1.6 1.6 A1203 ............... 0.3 0.3 Fe203 ............ . 0; 8 0.6 Cä0. . . . . . . . . . . 96.3 1.4 MgO .......... ..... 0.9 96.1 mixed together on a non-ignition basis as the refractory formulation. Bricks are then produced therefrom in the manner indicated in Example 4.

An analysis of the fired brickworks shows the following result: 8i02. . . . . . . . . . . . . . ,. . . 1.60 / 0 A1208. . . . . . . . . . . . . . . . 0.3 "/ o Fe 2 O 3.................. 0.6" / o Ca0. . . . . . . . . . . . . . . . . . 10.8 "/ o Mg0..,.......,........ 86.6" / o brickwork according to each of the above examples is then tested using standard tests. The physical properties of the bricks of these examples before impregnation are shown below: example 1-. @ 2 [3 j. _ - 4 .. Density, g / cin3 ............................. 3.172 2787 2.771 2.659 2.804 Modulus of rupture, kg / em2 ... ... .... .... ... . .. 217 153 204 147 189 Panel chipping test (AS-IM C-122), 1650 ° C preheating, weight loss during exertion tests 1.75 cm2, "/ o........................... 0.0 41 34 Destruction temperature, ° C. . . . . . . . . . . . . . . . . . 1760 1410 1640 1730 1700 * ASTM C-122 requires one. Air-water mist stream. In Examples 4 and 5, in which free calcium oxide is present, hydration occurs so easily that no valid results could be obtained from this test. These numerical values show the superiority in the physical properties of the brickworks according to the invention compared to brickworks that have been manufactured according to the prior art. The density and mechanical strength show an improvement that is just as pronounced as the fire resistance. The resistance to abrupt temperature changes, as it is proven by a 0.0% chipping loss, makes the brickwork according to the invention together with its great mechanical strength particularly suitable for use in those places where there is mechanical abrasion and rapid temperature fluctuations. Although Samples 4 and 5 could not be subjected to the panel chipping test. --but practical experience has shown - that they tend to splinter.

It thus follows that, according to the invention, a brickworks can be produced can that in a unique way for use in those zones of an oxygen converter or other vessel is suitable where abrasion resistance, great mechanical strength and resistance to chipping are required. These properties are in the bricks according to the invention by the disclosed composition and not so much due to the manufacturing process. Thus the invention is particular advantageous, so that the same with relevant skilled workers and available Materials can be done. Unless otherwise noted, all are specified Understand percentages based on weight.

Claims (1)

Claim: "@ Shaped body for lining oxygen converters based on Mg0, characterized in that the Mg0 content of the body is at least 96" / o and the remainder consists of usual impurities and the body is impregnated with tar. Documents considered: German Patent Specifications No. 829 419; 930 016; Austrian Patent No. 202 920; Haeders-Ki, enow, "Feuerfestkunde", 1960, 8 . 738, 769, 810, 811, 740, Tab. 150.