DE7030846U - FLOOR FLOOR WITH RING SLIT NOZZLE. - Google Patents

Description

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PATENT LAWYERS * * ^^

β MUNICH 22 · WIDENMAVERSTRASSE 40 1 BERLIN-DAHLEM 33 ■ PODBIELSKIALLEE ββ

BERLIN: DIP '.- ING. R. MÜLLER-BÖRNER MUNICH: DIPL.-ING. HANS-H. WEY

23 30 ^ A

Neunkircher Eisenwerk AG-vorm. Brothers 3tumm

Nerinkirchen / Saar

^ Dtiseixs fcockb jden with annular gap nozzles, for steel converters "/>

The invention relates to a nozzle atock base with annular space nozzles for steel converters by which the development of brown smoke when refining pig iron using pure oxygen is to be prevented, with the oxygen stream emerging from an annular gap nozzle on the one hand from a Jacket made of a dissociating endothermic protective gas is surrounded, on the other hand itself a central ray of the same or another endothermic reacting or otherwise enveloped cooling protective gas.

It is known that when pure oxygen is blown onto a metal bath in a fresh vessel, that is preferred Iron contains, at the point of impact of the beam on the bath, that so-called focal point, so high temperatures arise that

BERLIN: TELEFON (O3O) 8319088 MUNICH: TELEFON (O 8S) 22BS9B CABLE: PROPINDUS ■ TELEX OI 84Ο « _ή Λ Λ Λ i ί» CABLE: P ROPI N DU 5 ■ TELEX OB 3424 *

Iron evaporates and oxidizes. These iron oxides form solid parts which are discharged from the Frisohgefaß with the exhaust gas and form the well-known brown Rauoh, to its Removal for reasons of keeping the air clean, complex and costly measures must be taken.

On the basis of Vttrsuohen it was recognized that the development of brown smoke can be reduced by adding gaseous or liquid hydrocarbons and other gases, such as water vapor or CO ₂ , to the oxygen jet.

These additives cause the focal point to be cooled, whatever the iron evaporation and thus the formation of brown Rauoh is reduced. This cooling takes place either duroh Dissociation of the additives supplied or, alternatively, an abundant supply of a non-dissociating gas, that is either by absorbing heat for dissociation or by purely physical heating.

When refining pig iron according to the classic wind-frisoh process, fresh gas is blown into the bath through openings in the bottom of the Frisoh container. Here sioh forms over the Gas inlet opening a cavity, the entire surface of which is to be regarded as a focal point.

In the classic Thomas process, air is used as the blowing agent used, the nitrogen contained in this is sufficient, in order to keep the focal point temperature so low that iron evaporation largely does not occur during decarburization. As a result, one observes the Thomas method hardly any brown smoke on during the decarburization period Converter outlet.

At the beginning of the dephosphorization, however, a very strong smoke development begins. At this point the temperature is of the metal bath in the converter and thus also the heat content so high that during the phosphorus combustion and the resulting Heat influx caused the cooling effect of the blown in The nitrogen contained in the air is no longer sufficient to prevent iron evaporation in the focal point. The one with The nitrogen blown into the air then acts as a "gas lift" for the iron that has evaporated from the action of oxygen formed iron oxide and carries it through the bath from the converter into the atmosphere.

If, using the classic Thomas method, the oxygen content of the wind blower3 is increased to approx. 30 to kO% and this increased oxygen content is blown with the start of decarburization, the Breunfleck temperature is so high from the outset that iron evaporation begins and brown smoke can arise. With the onset of dephosphorization, an intensive increase in smoke development is observed due to the temperature increase in the bath as described above.

At the end of the 1940s, attempts were made to prevent increased nitrogen uptake by the Metal to blow pure oxygen through the bottom of the fresh vessels, and methods have been developed for which Mixtures of oxygen and water vapor or oxygen and carbon dioxide mixtures are blown into the bath using a single nozzle became. A considerable reduction in the formation of brown roughy was observed because of the cooling effect as a result of the dissociation of these gases was considerably stronger than the cooling effect of the nitrogen contained in the air.

In the recently developed bottom blowing method, annular gap nozzles are used, whereby through the central pipe these nozzles pure oxygen and through the. Ring gap a dissociating protective gas is blown into the pig iron bath. The protective gas surrounds the otwa conical Outer surface of the oxygen jet and thus prevents that in this area a reaction occurs between the oxygen bath and the pig iron bath. The protective gas causes however, no cooling of the focal point surface that of the nozzle is directly opposite, and is therefore exposed to pure oxygen. One therefore observes in these processes in contrast to the classic wind-freshening process When fresh, brown smoke develops because of the focal point area not exposed to the protective gas pure oxygen comes into contact with the pig iron bath and reacts with it, releasing such amounts of heat that that iron evaporates. The iron vapor oxidizes to solid iron oxide of the smallest particle size, which with the carbon monoxide or carbon monoxide resulting from carbon combustion Carbon dioxide bubbles reaches the bath surface. Burst here the gas bubbles and release the solid iron oxides into the atmosphere as brown smoke.

The smoke development decreases considerably the moment the phosphorus deposition begins. That has its cause in that, in contrast to the classic Vindfrisoh method and for freshening with oxygen-enriched air after the end of the decarburization and with the beginning of the dephosphorization the nitrogen of the blowing wind as a transport gas for the The iron oxide formed in the focal point is used in the bottom blowing process with pure oxygen with the addition of protective gas de.i. There is no nitrogen as a transport gas. The dissociation of the protective gas, e.g. from water vapor or hydrocarbon

substances, resulting products liagf · ;. atomic before. The hydrogen the dissociated gases are preferentially dissolved at the prevailing temperatures and do not come as a "gas lift" into consideration.

The sequence outlined above explains why the oxygen bottom blowing process explained last has a weaker development of brown smoke can be observed than when freshening with oxygenated Air, but stronger than in the Hassische Thomas process.

The invention is based on the object of the previously known nozzle assembly bases of steel converters for refining pig iron to the effect that on the one hand the production of high quality steel is guaranteed and on the other hand the development of brown smoke is prevented with certainty, so that expensive filters and. Dust collectors can be omitted.

To solve this problem, it is proposed according to the Erfirixtng, dali the annular gap nozzles that can be inserted in the nozzle assembly base are designed in such a way that a dissociating, endothermic tube in the tube carrying the central oxygen stream reacting gas leading pipe opens or extends in this up to the mouth of the pipe.

The mingling of the central stream of oxygen with one endothermic reacting coolant, such as water vapor or carbon dioxide or © in inert gas, each alone or in any Mixing with each other, due to the proposed measures, has the consequence that also in the the nozzles directly opposite area of the metal bath a

• * a »■ ·

Exposure to dissociating; Coolant guarantees is so that such temperatures.! the to the ice ^ verdasipii-ng could certainly be avoided.

When using the nozzle stock base designed according to the invention Care should be taken that the pressure of the oxygen blown into the metal bath is less than 10 atmospheres is over

1. a smooth blowing process, and possibly

2. The lowest possible floor wear

to ensure »If steam is used as the coolant, see this the vapor pressure should be approximately equal to half that of the acidic be off pressure * This ensures that the oxygen jet a suction effect on the central and the peripheral Exerts steam jet. This ensures good mixing of the ring-shaped oxygen jet with the coolant ensured. For a 30t converter, for example, the Oxygen pressure should be around 9 atmospheres.

As a particularly two-dimensional nozzle for the nozzle stook base proposed an annular gap nozzle which, in a known manner, consists of an outer jacket tube and a central oxygen supply pipe exists, but is designed in such a way according to the invention that within the oxygen supply pipe nooh another central tube for the introduction of a coolant gas flow into the middle of the oxygen current is provided. The construction of such a blow nozzle is shown on the basis of a preferred embodiment in Fig. 1 of the drawings, which an Axialsohnitt through a nozzle consisting of three tubes.

By doing . sitting nkopf 3I, the three coaxial increases and reciprocally Ij ν _o nozzles pipes 32, 33 and Jk * The inner tube 32 passes through the nozzle head 3I and is connected with its outer or rear end of a Verbindungaieitung 35 to the coolant gas supply Jb. Optionally, ± 35 may be arranged n the connecting line nor a control valve. The nozzle tube 33 opens into the cavity 37, the rear portion 38 of the nozzle head 3I, into which the oxygen line 39 is inserted. The oxygen can flow from the space 37 into the annular gap kO between the two nozzle tubes

32 and 33 enter and flows through this to the nozzle opening. The outer nozzle pipe Jk surrounds the pipe 33 and ends in the section 41 in which the connecting line 42 to the coolant gas supply line Jb opens, in which the control valve kj is arranged. The second coolant gas stream is thus t kk through the ring gap between the nozzle pipes

33 and Jk passed to the nozzle orifice.

Is duroh the three-pipe nozzle according to the invention as a cooling gas For example, steam and oxygen are blown into the metal bath, so should the central nozzle pipe 32 for steam one Have an inner diameter of approx. 7 mm. AIa pipe material is it is preferable to choose a non-scaling steel. The nozzle pipe 33 supplying the oxygen has an inner diameter of approx. 16 mm 0, so that an annular gap of approx. 3 mm width is available. From this it is calculated

2 for 18 nozzles a total area of approx. 22 om; thus stands a Durohrittsquerschni ^ t available to the oxygen, the the desired oxygen blowing pressure of approx. 9 atm for one Throughput of 100 Nm / min guaranteed. The oxygen nozzle tube 33 is made of the same steel as the central one Steam wand 32.

The outer steam of the enr ohr 3 ^ · has an inner diameter of approx. 25 now 0, so that there is an annular gap of approx. 2, j now, and

2 with 18 nozzles gives a cross-section of approx. 3 ^ fS ° m. Including the central nozzle pipe 32, the steam has a total qu
coincidence

2 18 nozzles give a cross-section of about 3 ^ fS om . Under

? ear 32 is the dam

2 2 2

velvet cross-section of 6.9 cm + 31.8 cm = 38.7 cm for

The amount of steam supplied to the outer nozzle pipe 3 ^ - can be by means of the control valve 43, preferably to a fixed ratio from about 4-5 * 1 to the through the central nozzle tube 32 regulate the amount of steam conducted.

As extensive experiments have shown, haban does, however, come also on the distribution of the blower nozzles in the Bot'317. Ues converter on to ensure success.

If, for example, an oxygen throughput of approx. 100 Nm / min is used, then it is sufficient to set the required Blowing pressure 18 from nozzles D, which are advantageously arranged in the manner shown in FIG. 2 of the drawing are. This nozzle arrangement ensures a very uniform application of the metal bath. Where *, are in That part of the floor which, when the converter is lying down, has no nozzles arranged in the lower floor field. The area F free of nozzles D has a height of. approx. 1/4 up to 1/2 of the diameter of the bottom B. This avoids that nozzles through charged scrap or through liquid Licks get damaged. The distribution of the The nozzle also ensures that the pieces of scrap cover only one nozzle when the converter is charged can and in the extreme case at the start of blowing, a temporary deflection or deflection of the oxygen or water vapor jet cause.

Claims (7)

Protective test 1. Nozzle stook base with annular gap nozzles for steel converters whereby the od from an annular gap nozzle. The like Oxygen beam from a pipe, a dissociating, endothermically reacting protective gas-carrying jacket pipe is surrounded, characterized in that, that in the leading the central oxygen flow Tube a, a dissociating, endothermically reacting gas leading Rchr opens or in this up to extends to the mouth of the pipe, 2. Nozzle holder base with annular gap nozzles for steel converters according to claim 1, characterized in that a tubular jacket leading the oxygen flow into a ring or more steam and bsw. or carbon dioxide and / or pipes carrying an inert gas open. 3 · Nozzle stook base with annular gap nozzles for steel converters according to claim 1 or 2, characterized in that in the nozzle tube which introduces the oxygen into the metal bath (33) a further nozzle tube (32) carrying protective and cooling gas is arranged centrally. k. EUsenstookboden xä.% Annular gap nozzle for steel converter according to Claim 1, 2 or 3, characterized in that in at least one of the supply pipes (351 ^ 2) of the cooling and protective gas to the central nozzle pipe (32) or to the outer nozzle pipe (3 * 0 a control valve or slide (O) is arranged. 5. Nozzle stook base with ring gap nozzle for steel converter according to one of claims 1 to k, characterized in that the sum of the areas of the ring rail between the central tube (32) and the surrounding tube (33) of all 2
Nozzles an area of wa. 22 cm. 6. nozzle assembly base with annular gap nozzles for steel converter according to one of claims 1 to 5 »characterized in that the sum of the areas of the annular gaps between the outer tube (3 ^) and the central tube (33) and ^the areas of the central tube (32) of all Nozzles about 2
38 cm. 7. Nozzle block bottom with annular gap nozzles for steel converter according to one of claims 1 to ό, characterized in that? El < ^{r in} that in the tilted converter down ? ..e & end area (F) of the nozzle assembly base (b) no nozzles (d) are arranged. B. nozzle assembly base with annular gap nozzles for steel converter according to claim 7, characterized in that the nozzle-free area (F) of the nozzle assembly base (b) has a height of about 1/4 to I / 3 of the diameter.