LU82554A1 - FIRE-RESISTANT, GAS-PERMEABLE CONSTRUCTION - Google Patents

Description

• _

Refractory / gas permeable structure.

The invention relates to refractory, gas-permeable structures for blowing a gas into a metal treatment vessel through its lining.

The oxygen-blowing process used for pig iron freshening, which are known under the names "LD", "LDAC," OLP "," BOF "processes, have recently been improved metallurgically 10 so that secondary gases such as Nitrogen or argon, can be blown in controlled. In other metal treatment vessels, such as pans for post-treatment of steel or electric arc furnaces, the blowing of gas into the metal bath through the vessel bottom or the lining of the vessel walls can also be considered.

The gas-permeable refractory 20 stones to be inserted into the lining of the base or the side walls of the vessel, through which the gas is introduced, is required to have a durability which corresponds to that of the other refractory lining, since a replacement of worn gas bubbles in the hot state, for example in one Converter floor is difficult. Furthermore, the introduction of gas should be possible both continuously and in particular discontinuously; i.e. the vessel should also be operable without introducing gas and after switching on the gas supply again> the stones should be permeable to gas in an unchanged manner. In addition, the gas permeability of the 30 stones should be over their service life, i.e. over an entire kiln trip, remain essentially the same.

The previously known gas-permeable stones made of porous refractory material do not meet these requirements. Their shelf life in fresh containers is much lower than that of the surrounding lining material. Porous stones installed in an oxygen converter in the floor can withstand less than 100 batches, while the rest of the lining provides a shelf life of 500 batches and more. Furthermore, discontinuous gas supply is not possible with - 2 - porous stones. If these stones are operated without the passage of gas, metal penetrates into the pores of the stones and solidifies there. When the gas supply is switched on again, the 5 stone is no longer sufficiently gas permeable.

In patent application LU 81.208, the applicant has shown a device for blowing a treatment gas into, 10 a metal bath which is intended for insertion into the bottom of a metal treatment vessel and which essentially consists of a refractory, gas-permeable structure, one in the refractory material in the axial direction A plurality of planar, corrugated, tubular or wire-shaped metallic separators of small wall thickness is embedded.

It is an object of the invention to improve the structure of such structures in such a way that simplified production is possible, that the required amount of gas can be blown through the structure and that the structure has a high durability.

This object is achieved in the case of a refractory, gas-permeable structure according to the invention in that in the 25 of refractory, unfired, e.g. with a carbon carrier-bound or chemically bound material, at least one pair of adjacent metal inserts, between which a gas passage is possible, and that at least one connection and a distribution space for the gas supply are arranged on an end face of the building body.

The structures according to the invention have sufficient gas permeability, the extent of the gas permeability being able to be varied by the number of pairs of inserts arranged in a structure. Since the refractory material used for the building structure is similar to that of the other - 3 -

Lining can match, the structures have the same durability as the surrounding lining. An early renewal of the gas passage stones is not necessary.

5

As has been shown, the structures can also be operated without gas supply. Although some metal penetrates into the narrow gap between the inserts of a couple, when the gas supply line is switched on again, this penetrated metal is flushed out of the structure and the original gas permeability is restored. This remains essentially the same over the entire service life of the structure.

15 It is particularly expedient if the metal inserts, which can consist of sheet metal plates, are also pressed together with the refractory material of the structure. In this case, the structure can be produced in a simple manner by first introducing part of the refractory material into the press mold, then the pair of inserts, which extends over the entire

The length of the stone, however, only extends over part of the width of the stone, is inserted and finally further refractory material is poured in. If the structure is to have more than one pair of inserts, this process is repeated accordingly. So-25 then the pressing pressure is applied perpendicular to the inlays and the structure is shaped. After removal from the press, the inserts on the end faces of the building are exposed to allow gas to pass through.

30 Instead of a pair of plates, a folded sheet or a compressed pipe can also be used. Steel is particularly suitable as the material, which can have a thickness between 0.5 mm and 3 mm and which is optionally provided with a surface protection.

35

In order to ensure sufficient gas permeability, the metal insert pairs can, depending on their deformability, with the interposition of spacers, as shown in FIGS.

Inserts shaped beads or nubs, wires, sheet metal strips, combustible or vaporizable inserts or the like, can be embedded in the refractory material.

5 If structures with a large cross-section are required, it is recommended that the structure consists of several segments or partial bodies, each of which has at least one pair of metal inserts, and that the segments are combined by a common metal housing.

10th

In order to avoid faulty gas conduction along the metal housing, it is recommended that the segments lie tightly against the metal housing, possibly with the interposition of a layer of mortar.

15

Metal plates or pairs of metal plates can be arranged between the segments, along which a gas passage likewise takes place. In the case of pairs of metal plates, these can be mortared between the segments. The segments can be provided on at least one side surface with metal supports which are pressed in during manufacture, along which flow zones are located in the assembled bodies.

The invention will now be explained in more detail with reference to the drawings. 1 shows a structure according to the invention; 2 shows a segment as it is inserted into the structure according to FIG. 1, and FIG. 3 shows an embodiment of an insert on an enlarged scale.

30 The structure 1 has a metal housing 2 which surrounds four segments 3. These four segments 3 lie with their U-shaped co-pressed metal supports 4 against each other, whereas the unreinforced long sides of the segments 3 lie against the inside of the housing 2, which e.g. is made from welded plates.

The segments are spaced from the end face of the metal housing 2 by means of two strips 5, which are arranged on the inside of the metal housing 2 and are preferably attached to the latter by spot welding. On this end face of the metal housing 2, which forms the cold side of the structure, a plate 6 is welded tight, 5 which is provided with a pipe connection 7, via which the gas can be introduced into the space remaining between the plate 6 and the end faces of the segments 3 .

In the area of the opposite, fire-side end face 8 10 of the structure, a bracket (not shown) can be attached, which projects over this face 8 and enables the structure 1 to be fastened to a crane hook.

Each of the segments 3 is provided with a U-shaped metal support 4 15 and pairs of sheet metal inserts 9, which extend over the entire length of the segments 3. Depending on the desired gas permeability, the inserts 9 can be designed as smooth sheet metal plates or as sheet metal plates provided with spacers, such as beads or grooves 10. To improve the connection between the stone mass and.

the inserts 9, the latter can be provided with claws 11.

The structure can e.g. from a tar-bound Magnesia-25 mass with the following composition and the following grain structure: ♦

Sintered magnesia

Grain sizes 30 MgO 96.2% by weight 5-8 mm 20% by weight

Fe20g 0.2% by weight 3-5 mm 15% by weight Α1202 0.1% by weight 1-3 mm 20% by weight

CaO 2.5% by weight 0-1 mm 20% by weight

Si02 1/0% by weight 0-0.1 mm 25% by weight 35

4% by weight of coal tar pitch are added to the sintered magnesia as a binder. Other tars, pitches, synthetic resins or the like also come as binders. into consideration.

* * - 6 -

Another refractory composition suitable for producing a structure according to the invention has the following composition and the following grain structure: 5 Pre-reacted chrome ore

Magnesia chrome ore sintered grain

MgO 63/8% by weight 17.1% by weight 19.2% by weight 53.2% by weight

Al203 4.2% by weight 10.4% by weight 10 Fe203 9.8% by weight

FeO - 15/9 wt%

CaO 1/8% by weight 0.1% by weight

Si02 1/2% by weight 3.3% by weight 15 grain sizes

Sintered grain 3-5 mm 20% by weight

Sintered grain 1-3 mm 25% by weight

Sintered grain 0-1 mm 25% by weight 20 sintered grain 0 - 0.1 mm 20% by weight

Chrome ore 0 - 0.7 mm 10% by weight

The components are mixed with 3.7% by weight of kieserite solution with a density of 1.22 g / cm for chemical bonding.

25th

However, the invention is not limited to the refractory materials mentioned. Other refractory materials, e.g. Mixtures of magnesia and chrome ore, tweeter material iai, are used.

30th

Claims (8)

1. Fireproof, gas-permeable structure for blowing a gas into a metal treatment vessel through its lining, characterized in that in the fireproof, unburned, e.g. at least one pair of adjacent metal inserts is embedded between a structure bound with a carbon carrier or chemically bound material, between which a gas can pass, and that at least one connection and a distribution space for the gas supply are arranged on an end face of the structure. 2. Building structure according to claim 1, characterized in that the metal inserts with the refractory 15 material of the structure is also pressed. 3. Building structure according to claim 1 or 2, characterized in that the metal inserts are plates made of sheet steel, which is optionally provided with a surface protection. 4. Structure according to one of claims 1 to 3, characterized in that the metal insert pairs with the interposition of spacers, such as beads or knobs formed in the insert, wires, sheet metal strips, combustible or evaporable deposits or the like. , are embedded in the refractory material. 5. Structure according to one of claims 1 to 4, characterized in that it consists of several segments, each of which has at least one pair of metal inserts, and that the segments are combined by a common metal housing. 6. Building structure according to claim 5, characterized in that the segments lie tightly, optionally with the interposition of a mortar layer, on the metal housing. .- - 2 - im 7. Structure according to claim 5 or 6, characterized in that metal plates or pairs of metal plates are arranged between the segments, 8. Building structure according to one of claims 5 to 7, characterized in that the segments are provided on at least one side surface with metal supports pressed in during manufacture. * c