DE2326706A1 - PROCEDURE FOR MONITORING AND REGULATING THE FOAMING OF SLAG FROM REFRESHING STEEL PROCESSES IN METALLURGICAL VESSELS - Google Patents

Description

326706

FRIED. KRUPP SOCIETY WITH BSSCHR ^ IiLTEIi LIABILITY IN ESSSIJ

Process for monitoring and regulating the slag sludge from steel refining processes in metallurgical vessels

The invention relates to a method for monitoring and regulating the foaming of the slag from steel refining processes in metallurgical vessels, in particular in oxygen top-up converters, by changing the distance between the blowing nozzle and the metal bath surface, the blowing oxygen flow or the dosing of the additives, one at a time or in any combination ei "Use of the continuously measured values of the exhaust gas analyzer line, if necessary of the exhaust gas flow.

It is known that the occurrence of a high foaming slag in such processes with associated with a number of advantages »The aim is therefore to get this operating status as early as possible to reach. The regulation of a constant tube height and in particular the slowing down of the foam formation at the beginning of the process, however, often prepare considerable amounts Trouble.

The methods previously used for monitoring the formation of slag in the oxygen-blowing .dosieren generally lies either on the solution of the blowing; rex ^- är.gcjjCS or structure-borne noise of the converter

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(Stahl 'and Eisen 9O "1970", pages 789 to 795) or on the measurement of the electrical conductivity of the GasatnoSphere between the melt and an electrically isolated measuring probe (DT = PS 1 290 557). Both methods require _{additional plant and maintenance costs,} especially when using automatic control of the process sequence. In addition, the measurement results of the sound measurement are often falsified by extraneous noises, and the conductivity measurement, with which other values are also determined, often does not provide unambiguous results with regard to the slag surge.

It is also already known for automatic Regulation of the metallurgical process, the continuously measured values of the exhaust gas analysis and the exhaust gas torrent to be consulted and to be based on the automatic regulation, which stands by -changing the Ah and it the Blow nozzle from the metal bath surface, the change des.Blass Oxygenstromes and in the dosage of Additives as manipulated variables (so-called, dynamic Process management) takes place »

The invention is based on the object ₉ of creating a method for monitoring and regulating the foaming of the slag from fresh steel processes in metallurgical vessels, in particular in oxygen top-up converters, which, compared to the known methods, is characterized by greater simplicity and operational reliability and, in particular, for automatic gelation is better suited »The invention consists in that a parameter for the Eisanoxydsta-uhentwicklung is calculated and used for the control or regulation.

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The method of the invention promotes one optimal management of the metallurgical process and is characterized by a large an = adaptability and versatility so that the most varied, respectively desired process management can be carried out «,

It is particularly voi-part if as a parameter a value

VOC = ° ' ^{5 C0} * ^C0 2 ⁺ ° 2 ~

CO + CO

eft

or «, a value derived from this equation is used. CO ₉ CO ₉ 0 _o5 II _O and N are the

Ct C * CU Ct.

by analyzing the afterburned exhaust gas concentrations in percent by volume ^ The hydrogen content in the exhaust gas "only needs to be taken into account if the hot, reactive exhaust gas - z _o 3 _o when using so-called» block steam - larger amounts of steam enter » In most cases, the value

_B 0.5 CO »CO ₂ + O ₂ - 0.269 N ₂

• co ψ co

g find _o The Ifert represents the volume. "= ratio of the oxygen bound to Kolienstoff to the CC / CG _o ^ G _aS g- _en isch äa: ro It was found ₉ that this value is a measure of the elsenic oxide dust in the exhaust gas and through this Property can be used as a parameter for the slag height in the converter.

4098 5 1/043 8 g _ÄD

It w-rucn. following Zunarincnhari ^ e ormittelts

The T'iert VOC must be if only CO is present in the exhaust gas = 0.5 and if only CG _{0 is present in the exhaust gas.}

Ci

lies = 1.0. In practice: ni ^r ', the VOC-T' / places are between 0.55 and 0.6 when the exhaust gas is afterburned, cn the ratio CO / (CO + CC ₀ ) based on experience between

UJ

about 0, o r.:ad 0.9 lies »But it was determined that VOC is at times well below 0.55 »In the first blow pipes even values up to see below C, 2 on »This is because part of the Oxygen is not recorded by the analyzers »This is essentially the oxygen which "binds to escaping iron dust and is filtered off as iron oxy dust before sampling will. If you take this percentage of oxygen into account must be the equation of the volume ratio of the oxygen bonded to carbon 3Uin CC / CO exhaust gas mixture read as follows!

0.5 CO + CO +0 _o - 0 _s 269 M _Q % _e

V ° ^ca ___ 2 2 ^{8 2} * ^e dust

(CO ψ CO ₂ ) k. (CO ₊ CO ₂ ) et

In the equation, M ^Fe _stau b means the mass of the iron contained in the dust per unit of time ₉ V the exhaust gas flow and k is a constant of proportionality »The equation can also be written as follows

VOC = VOC + ^{k F} <2

k. (CC ₊ CO ₂ ) Λ

BATH ORIGINAL

409851/0436

This equation does not mean that the difference between VOC ^{9 and} VGC is proportional to the load of the converter gas with evaporated iron "

The mass flow of ice oxide dust can also be used as a parameter for the control or Hegeliing. The corresponding equation would be s. _O 3 _o

Si Fe, .β Ä VOC ο V „(CO ψ CO ₀ )„ Is.

In this equation, Q VOC means the difference between the target value for VOC ⁹ and the measured actual value of VOCo. If the target is a high slag level, the target value of VOC ^{5 is} as large as possible, ZcBo as stated above, approximately between 0.55 -5- O ₉ The value for the proportionality constant L depends essentially on the particular system "and is generally between 9 _s 5 and to ο When using this parameter, as can be seen from the equation, the ASaga.s = - current V can be determined »This determination could be omitted, however. Ϋ is almost constant »

Instead of the expression (CO -sOO ^.) In the above equation , the value for the decarburization speed ί dC | used as this

I dt I ■

in many fresh processes it is determined anyway »In this case the proportionality constant ic can of course be modified accordingly »

In the drawing are shown in Figures 1 and 2 as a starting _o = exemplary embodiments, the values of two comparative experiments in each case two pairs of curve shown "

In both cases it is tied around the Ez-seuguns of molten steel going into a 110-ton converter were blown. Curve A shows the measured VOC values and curve B shows the measured ^ sound intensity comparison values "

When trying corresponding to FIG _o i low-phosphorus pig iron into steel - fade. The sound measurement according to curve B shows a constant value of 100 % in the first 4 "5 blowing minutes, because" due to the lack of foamed slag - the sound level is above the upper measuring range limit CiOO %) "The VQG values (curve A) show - outputting low values ~ from the start. a generally rising trend ,, the slag to build a foam "reflecting and achieve in five · = th minute a value of O ₅ 57 ° before reaching this value can werdea already unchecked ₈ where, however, the curve B by sharp decrease until fifth minute of the presence of the foam = "slag registered in the further course of the two curves show that the slag to the ninth minute as consistently good foam (Schallwerteg 10 to 12% l VOC values as O ₉ 57) ₉ then low = fügig to Height begins to lose and gradually begins to collapse around the fourteenth minute. The slag reaches a low point around the fifteenth minute and then builds up again around the seventeenth minute ο The decrease in foaming is also announced a little earlier in curve A than in curve B.

1 shows, however, that the tendencies of the two opposing curves largely coincide and the VOC values the changes in the foamed slag height at least as good as the

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Sound intensity measurements with me - own = Xn process run diesel - C'ir.rge was the blow nozzle; ^; At the end of the fifth minute of blowing, I moved a little - from the highest to the lowest position - in which it was lost during the entire course of the pus

In Figo 2, the fourth is recorded is recorded in the blowing of a charge-phosphorus pig iron to steel., The respective course of the two curves confirms the main Erläuteruiigeiio The restless course of the curves given to Figo i, particularly the curve B ⁰ with strong pronounced llaxima and minima is due to multiple raising and lowering of the blower nozzle, which was necessary for control due to the foaming behavior of the slag between the probe tip and the slag level j is displayed so that the sound curve B ^{0 increases} both when the slag level falls and when the blower nozzle is raised ο

If the foaming of the slag is to be regulated manually wgr = den ₀ , this regulation is expediently carried out on the basis of a curve of the VOC curve recorded by a line recorder

In the case of the preferred monitoring of the foaming of the slag by an automatic control device, this requires at least one desired target value for the VOC ₀ This value is expediently determined empirically from previous melts.

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no ^ jf'ex's r: c te XIt :. · ■■; '_. · _; v.pi 2rf orcernisseii adapted fourth. If π "3" a Schmelr.e: iit irux ~ low-foaming slag done who-Deii, it is easy to reach, indane the Ilegeleiiirichtitng a reference is given, the wait correspondingly below the VGC-Grenswertes, ie below 0.55 lies. Ξοοιιΐ, αΐΐε a changing with the inflation time tion of the setpoint can be entered into the computing device

To the fiegeliuig of foaming bcw. the Sch aunschla ckenhöhe.werdon from the so-called, dynamic. Proseljrülirnng known stollen sizes are used. Preferably, the procedure is such, C. & Si the on olacen üiit large distance between the starting ülasdüso of DER i-ietail ^ ndoberfläche ■ and the nozzle it is in small steps in the liar) ο abgsscnlzt, in which the VOC curve approaches the setpoint. A Sel · .Ir.chcii-Ausvnir dez ~ in this AniCangsphnse des i ^T riscI: ens bcäbneLors easily axiftr-itt, is an? dioce Vfcise uirkcsn encountered. On the other hand, a quick dissolution of the all-Ts unc ";'is provided for the picture: unreelztionable slag. In the further course of the refining process, the aim should be that - at least for a long time - the VGC is produced setpoint corresponds to -. the blast nozzle in the lowest position remains should VOC deix exceed setpoint, lcann CIIR Verneid ^ iig of ejection zweckinäßlgeiTJeise the Pale Auer st be off current decreases Zrur support of countermeasures Icönnen, if necessary, the known Flußnittel for Pb "rdoT. "Ung the foam loop formation or cooling additives to dampen the foaming.

The method of the present invention can also be used in taps and in support of others known Process for automatic regulation of the oxygen bottle process, especially with the so-called, dyn.ar.ii- »

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326706

already Frose-Oiuhrxaiii;:, oi ^ ecetst "earth. D'or value:? Ür VCC I: aim in general for these versions. r.iit "den voi ~ liancle2ieii lie-GeirLrichtnii ^ cn. "bcs'fcinni'i; lincl as a signal "Γΐϊχ · tias Scnä \ iiriVe3rIjal" terL the Sclilaclio Flocks.

Partial claims:

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BATH ORIGINAL

Claims (1)

Patent claims: 1. Procedure for practice? a cluing and regulation of the Foaming of slag from fresh steel processes in metallurgical vessels, especially in Oxygen on blow converters, through change the distance between the nozzle and the surface of the metal bath, the flow of oxygen or the dosage of the additives individually or in any combination using the continuously measured values of the exhaust gas analysis and - if necessary the exhaust gas flow, thereby indicates that a parameter for the iron Oxyd dust development in the exhaust gas is calculated and used for open-loop or closed-loop control. 2. The method according to claim 1, characterized in ;; e7: c; i_a.-3i paves, that as a constant a "fourth 0.5 CO + CO + ₀ _ ο ₅ "_ ο VCC = ■ ^ 2 ° i? ^U 2 ° CO + C0 _Q t> 2W. a value derived from this equation is used. 3. The method according to claim 1, characterized in that that as a parameter the liassenstrom of the iron oxide dust is used. EV 5V72 AK / Ko - 10 - 40985 1/0436 bad original ! 326706 h _m The method of any of claims i to 3s dacturcli ^ elcGiirxseichnet that, for the control scheme barren a elektroniscbes Rechengex ät ^ is used. 5. Verfaßren according to claim 3 or 4, thereby gelienn?; Eichnct _s that as a value for the i-iascenstroia of Eisenoicyclstaubes a value Fe - _T ε ü VOCoVo (GO lasw. a value derived from this equation. • uses iiird, vrorin ο VOC the directives from the target and dom Istwearfc of VOC _s V the exhaust gas flow - and no constant means _o 40985 1/0436. -. . BATH ORIQINAW Blank page