DE1956012A1 - Fireproof hollow body - Google Patents

Description

Patent attorney A Qj 1

Dipl.-Ing. Walter Jackisch Π Jl

7 Stuttgart N, MenzetetraBe 40

UNITED AUSTRIAN IRON - NOV 6, 1969

UUD STAHLWERKE AKTIEFGESEIiSCHAFT in Linz (Austria)

Refractory hollow body

The invention relates to a refractory hollow bodies per g, and in particular for the protection of submerged in molten media probes or lances as Temperaturmeßlanzen having an internal cooling.

In the steel industry, lances and the like are used to an increasing extent, which have a fully or partially cooled measuring part and are immersed in molten baths in order to monitor the progress of metallurgical processes. Devices of this type are, for example, temperature measuring lances, in the measuring part of which a thermocouple is enclosed in a protective cover. The case with the thermocouple must be protected by a refractory shell against the action of slag and metal, wherein, in application of such tempera- _t peraturmeßlanzen f in LD converters u. Like. Durability j of the device while a greater number of batches to seek is . The fire-resistant protective jacket of a measuring lance is required to be able to withstand the special thermal stresses that result from the high temperature gradient from the hot outside to the fully or partially cooled inside; that it withstands chemical attack by liquid slag and metal, has a maximum degree of fire resistance and good thermal shock resistance. The temperature gradient at a sol- ^! Because of the described temperature difference between the outside and the inside and the relatively small wall thickness that such a jacket can have

009823/1295

borrowed, larger than the refractory bricks used for the brickwork a Siemens-Martin furnace or a converter can be used; due to the relatively short residence time of the Measuring lance in the bath, e.g. 20 - 25 minutes during a fresh batch, after which the measuring lance is pulled out again even a steady temperature distribution never occurs. It is therefore understandable that the requirements that be placed on the refractory casing of the measuring part of a lance, are much higher than the most highly stressed arched stones and the like, it has not yet been possible to obtain satisfactory durability and resistance of To achieve protective jackets for measuring lances. Fired alkaline stones are chemically well resistant, but they are sudden changes in temperature when immersed in highly heated metal baths cannot cope with the large temperature gradient not from; they are prone to cracking and flake off. Graphite stones, which are characterized by a high degree of thermal shock resistance have also proven to be unsatisfactory, partly because of the chemical attack of the liquid steel on the graphite material. A shelf life of the protective jacket was over a plurality of lots not yet achievable.

The invention aims to avoid the disadvantages and difficulties outlined by creating a refractory hollow body, in particular to protect probes or lances, such as temperature measuring lances, that are immersed in molten media j which have internal cooling, and is characterized in that the hollow body consists of an inner layer unsintered refractory mass and a dense, sintered outer layer of the same material.

The dense outer layer of the hollow body according to the invention is resistant to chemical and mechanical attack by liquid slag and liquid steel at temperatures up to about 170O ⁰ G and even above "the inner layer ungeeintert and transmits the outer layer is

009823/1295

deformable and can thereby reduce the thermal stresses that occur due to thermal shock, follow. Because of this deformability, the emergence avoided from cracks. With the hollow body according to the invention, a durability of the lance during a large number of Fresh batches, e.g. more than 10, can be achieved.

The thickness of the sintered outer layer should have a certain ratio to the wall thickness of the inner layer. In any case, the inner layer must be considerably thicker than the outer layer. The thickness of the sintered outer layer is preferably 1/4 or less of the wall thickness of the entire hollow body, in particular 1/6 - 1/10 of the same. In connection with this, it is essential that the inner layer has a certain degree of porosity, because only then does it remain deformable and, so to speak, suitable as an elastic carrier for the dense outer layer. The best results are achieved when the total porosity of the hollow body is 15-20 % .

The invention further comprises a method for producing the refractory hollow body described, which is that formed of a granular refractory material with the addition of water and compacting by vibrating a cylindrical shaped body, drying the shaped body and its ä outer layer be'i a sintering temperature exceeding temperature is tightly burned while its inside is cooled by a coolant. Suitably, the drying is of the shaped body in two stages, u zw by drying in air at room temperature and by post-drying at an elevated temperature in the range of 200 -.. 65O ⁰ O, preferably 400 - 45O ⁰ C. In the shaping can reinforcing bars -drahte or nets are inserted into the molded body.

The grain size of the mass from which the hollow body is made is also important: The refractory mass should have a fine fraction with a grain size of up to 0.10 mm

009823/1295

25 - 35 f> and a coarser portion with a grain size of 2.5 - 5 mm from 30 - 40 f » .

In the drawing is the hollow body according to the invention and the process for its production or a device for carrying out the process is explained in more detail.

Fig. 1 shows a vertical longitudinal section through the refractory hollow body according to the invention, which the measuring part a temperature lance. In

Fig. 2 shows an apparatus for producing the hollow body.

The hollow body 1 according to the invention has a central one Bore that is widened approximately in the upper third, i.e. has a larger diameter there, around the probe head 11 to include. The probe consists of three concentric tubes 7, 8 and 9, with the compensating line in the inner tube 7, namely two enclosed in a sleeve 10 conductors are arranged, which are used to connect the in the wet part of the device existing thermocouple legs serve to the outside. The tube 8 ends a bit in front of the probe head. It represents a guide scope to form a coolant circulation. The measuring part, which can be connected to the probe head, is indicated generally at 12 in FIG designated. It consists of the protective tube 13 in which the thermocouple 14 is enclosed with its hot solder joint 15 and the hollow body 1 according to the invention enveloping the protective tube, which, when the measuring lance is inserted into the bath, is located in the area of the slag layer 3 floating on the bath 2. It is known that the greatest stresses occur in this area of the slag layer. Sticking out to the bottom the hollow body 1, the tip 4 of the measuring part in which the hot soldering point is located.

As can be seen, the hollow body 1 consists of a Inner layer 5, made of unsintered, refractory, grained Composed of mass, and of the dense sintered outer layer 6 made of the same material. A suitable refractory mass is

009823/1295

BATH ORIGINAL

basic rammed earth with preferably the following composition:

4.0 - 6.0 fo Fe ₂ O ₅ 20.88 fo 83 88 fo MgO 7.90 fo 2 "* ζ c · ' GaO 3.92 fo 0.4 - 0.6 fo SiO ₂ 6.40 ^c / o 3.5 - 3.7 "/ o Al ₂ O ₅ 10.78 fo approximately 1.20? B 13.34 fo analyze the the following 36.26 fo under 0.05 0.52 fo. 0.05 0.10 0.10 0.20 0.20 - 0.50 Loss on ignition, 0.50 1.00 is: 1.00 2.50 mm 2.50 5.00 mm above 5.00 mm mm mm mm mm mm

The bulk density of such a mass is, for example, 1.85 g / cm.

The production of the hollow body is carried out such that the mass after the addition of 5-7 wt. -Fo water under gentle agitation filled into a mold and is compacted therein by another, stronger vibration. A reinforcement body made of steel wire can be introduced into the mold. The hollow body is predried first at room temperature for 24 hours in the ^: g mold and then outside the mold for 48 hours. A further drying process is then carried out at temperatures of around 450 G for around 48 hours, during which the hollow body is suspended in the oven. "After these two drying processes, the hollow body has the following properties: density on average 2.848 g / cm

Specific Weight "3.320 g / cm ⁵

Total porosity "14.22 9b

Open Porosity "11.02 fo.

The dense sintered outer layer is produced by firing the hollow body at a temperature of about 1600 ^° C. for about two hours. The device according to FIG. 2 can be used for this purpose. The pre-dried hollow body 1

009823/1295

is suspended from a water-cooled support 16, the Shape corresponds to the inner contour of the hollow body, and introduced into the combustion chamber 17 of a furnace 18. The combustion chamber is covered by the cover 19. The water supply and discharge is indicated by arrows. During the sintering of the Outer layer, the inside of the hollow body is continuously cooled. Instead of water, air can also be used as a coolant will. The total wall thickness of a manufactured according to the invention Hollow body can be, for example, 60 mm, with the thickness of the sintered outer layer being about 10 mm.

Hollow bodies according to the invention have proven themselves very well in practical testing. In the LD converter, shelf lives of more than ten batches were achieved without difficulty, the measuring lance being in use during the entire blowing time and being exposed to air cooling during the blowing pauses. This corresponds to the strictest conditions that can occur in a steel mill. If one brings the measuring lance in the Blaspausen instead be subjected to a cooling by air into a holding furnace, which is maintained at a temperature of about 1000 ⁰ C, so considerably improved shelf life -eg can be achieved with the inventive hollow body, a shelf life of more than twenty batches.

009823/1295

BATH ORIGINAL

Claims (8)

Patent claims ϊ 1. Fireproof hollow body, especially to protect in probes or lances immersed in molten media, such as temperature measuring lances, which have internal cooling, characterized in that the hollow body (1) consists of an inner layer (5) of unsintered refractory mass and one dense, sintered outer layer (6) of the same material. 2. Hollow body according to claim 1, characterized in that the refractory mass has a fine fraction with a grain size of up to 0.10 mm from 25 - 35 P and a coarser fraction with "a grain size of 2.5 - 5 mm from 30 - 40 ° / o owns. 3. Hollow body according to claims 1 or 2, characterized in that that the thickness of the sintered outer layer (6) is at most 1/4 of the wall thickness of the entire hollow body (1), is preferably 1/6 to 1/10 of that. 4. Hollow body according to claims 1 to 3, characterized in that the total porosity of the hollow body (1) is 15-20 Jo. 5. A method for producing a hollow body according to the An d Proverbs 1 to 4, characterized in that a cylindrical shaped body is formed from a granular, refractory mass with the addition of water and compaction by shaking, the shaped body is dried and its outer layer in one, the Sintering temperature exceeding temperature is fired tightly while its inside is cooled by a coolant. 6. The method according to claim 5, characterized in that the drying of the shaped body takes place in two stages, u. Between. By drying in air at room temperature and by post-drying at an elevated temperature in the range of 200-65O ⁰ C, 009823/1295 preferably 400 - 45O ⁰ C. 7. The method according to claim 5, characterized in that in the shaping of reinforcing rods or nets in the molded body be inserted. 8. Device for performing the method according to claims 5 to 7, characterized by one in a Combustion chamber (17) insertable carrier (16) for the molded body (1) with a cooling device for the inner wall of the molded body. 009823/1295 Blank