DE2135245C2 - Method for measuring the amount of exhaust gases that escape from a steel melt during controlled decarburization - Google Patents

Description

The invention relates to a method for measuring the amount of exhaust gases emitted from a steel melt exit with regulated decarburization, which is supplied with an oxidizing agent and argon in certain quantities in which the concentration of the conversion products contained in the exhaust gas is determined.

In such a known method (DE-OS 21 09 676), in which the decarburization of the steel melt in takes place in a closed vessel, the argon is first used before the supply of the oxidizing agent Purge gas introduced into the closed boiler and then decarburization by means of a mixture of the Oxidizing agent and the argon carried out, the argon as a diluent gas a relatively large Takes part, whereas the oxidizing agent only with a small percentage of, for example 5 to 10 percent is added. So while in this known method the argon is the largest part the amount of gas applied to the molten steel and serves as a flushing or dilution gas it is necessary to measure the quantity required for monitoring and controlling decarburization, Measure both the flow rate of the gases fed into the boiler and samples of the exhaust gases to be taken from the boiler. The extraction of the exhaust gas samples from the boiler is known Procedure necessary to avoid the risk of measurement errors due to those entering the boiler during sampling Reduce fresh air. This method is therefore disadvantageous on the one hand in terms of its process sequence costly and, on the other hand, prone to errors. There is an important difficulty with such a process furthermore, that a determination which satisfies the requirements of practice with regard to its accuracy of the carbon content of the steel melt, the measurement of the amount of exhaust gases with a measurement error of a maximum of 10%. The achievement of this measurement accuracy is encountered, however, especially in modern Steel works, in which a recovery of the own heat and the heat of combustion of the The gases exiting the converter are provided by saturation steam or superheated steam boilers, considerable Obstacles. A particular disadvantage is the long response time that takes place until the measurement is determined

result elapses.

In particular, one encounters in this context a flow measurement and analysis of the exhaust gases very high and variable values of the total response time (transport and conditioning time of the sample, delay at the analyzers), difficulties in determining the carbon input by the fuel used in the saturation steam boiler and a change in the gas co-heating due to the absorption of CO2 by the smoke flushing water and the possible mixing of Flue gas of various origins as a result of a leak in the cutting flap of the flues in parallel operated converters.

On the other hand, a flow measurement at the chimney and analysis at a point of the flue that is as close as possible to the converter enables a reduction in the analysis response times. However, it requires special care in order to avoid that a non-homogeneous core is checked because of the combustion of CO and CO2 that is currently taking place. This source of error does not occur if a recuperator without combustion is used.
Finally, an analysis of the exhaust gases at the mouth of the converter and further analysis and flow measurement at the chimney, in which case the flow rate of the exhaust gases emerging from the converter must be determined, would result in a reduced analysis response time and increased accuracy. But here the need to correct the data based on different simultaneously preferential phenomena, which are shifted to an inconstant amount in the assumed complicated system, would cause considerable difficulties.

If one also wanted to control the distribution of oxygen between the bath and the slag (dynamic Control method through uninterrupted balance of oxygen), then the requirements would be a reduction in the response time is much more severe. Because the oxygen distribution is effectively controlled a delay of 15 seconds could have an adverse effect.

Furthermore, a method for measuring the amount of exhaust gas discharged from a blast furnace is known (FR-PS 14 91 118), which is based on the constancy of the nitrogen balance of the is based on the wind blown into the furnace. The nitrogen content of the furnace exhaust gas is measured here and based on the nitrogen content of the blown wind, which is approximately 79%, the total amount of exhaust gas emitted is calculated. This is possible because the nitrogen does not react through the Blast furnace passes through. Such a method is of course only in connection with blown Combustion air applicable, while an application to an oxygen converter is out of the question comes.

It is also known (US-PS 34 00 585) for determining the amount of exhaust gas from a vacuum melted Metal to add a portion of N2O as tracer gas to the exhaust gas sucked off by the vacuum apparatus and then determine the partial pressure of the tracer gas and the exhaust gas to be measured. From the relationship these partial pressures can then be calculated on the assumption that the

b5 given exhaust gas does not originally contain the tracer gas, Calculate the amount of exhaust gas because the amount of tracer gas can be controlled. This procedure is suitable to control the gas content of semi-killed steels,

with which only relatively small amounts of exhaust gas have to be dealt with, and uses a closed system in advance. This is known for measuring the large amounts of exhaust gas occurring in oxygen converters However, there is no procedure foreseen.

Another known method for determining the exhaust gas content of the vacuum melt of a metal (US-PS 35 20 657), in which a side stream of the exhaust gas is pumped out of the vacuum system and also _{mixed with a metered amount of N 2} O as a tracer gas and in which also the The amount of exhaust gas is calculated from the measured patrial pressures of the exhaust gas withdrawn and the tracer gas, additionally uses argon as the transport gas. However, the argon transport gas is not involved in the measurement of the amount of exhaust gas, but merely serves to support the upward flow of the evacuated metal melt into an evacuated degassing vessel.

Finally, a chromatographic method is known (US-PS 34 35 660), in which gas samples to be measured are added to a carrier gas, for example helium are, and in which the flow rate of this carrier gas by means of a tracer gas that is also added, for example Nitrogen, is measured. In this case, too, the flow rate of the entire gas stream can be omitted Calculate the measured partial pressures of the carrier gas and the tracer gas, as the amount of the added Tracer gas is known as this process also with only small amounts of gas and in a closed one If the system is able to work, an application to oxygen converters in steel processing appears locked out.

The invention is based on the object of avoiding a method of the type mentioned at the beginning of the aforementioned disadvantages in such a way that the measurement of the amount of exhaust gases in a steel converter can be carried out with greater accuracy while reducing the response time.

This object is achieved according to the invention in that, for measurement in steel converters with an oxygen lance the argon is the oxygen blown into the converter by the lance in a concentration of less than 5% is supplied as tracer gas and that also the concentration of this tracer gas in the exhaust gases is determined by analyzing the gaseous products withdrawn from the converter mouth.

Since the argon as tracer gas does not undergo a chemical reaction in the converter but passes through it unhindered, the exhaust gas flow rate Vp (NnVVMm) can be determined in the method according to the invention according to the equation Vf = Qa ^ Ca , where q * is the flow rate of the tracer gas in Nm ³ / min and Ca is the concentration of the tracer gas emerging from the converter mouth. The noble gas argon as a tracer gas in low concentration is particularly suitable for achieving precise results. Even if a sample is taken at a point where outside air can enter above the converter mouth, which mixes with the exhaust gases and thus influences the measurement result, this influence can be eliminated because the argon content of the air is predetermined. Furthermore, the method according to the invention has the short response time required for timely control of the decarburization. The solution according to the invention is distinguished by its simplicity.

The method according to the invention can advantageously also be used in steelworks with auxiliary combustion. It enables a dynamic control of the oxygen distribution that is expanded in terms of its control options. It is possible to do a quick analysis of the carbon content of the melt to control steels carry out, the conversion of which is stopped when the carbon content is still high.

Furthermore, yeasts use the method according to the invention also a simplified control for steels with low carbon contents.

In the method according to the invention, the tracer gas can either during the entire blowing time or are only added during partial sections of this blowing time, in particular towards the end of the blowing process. When casting low-carbon mild steel or medium-carbon mild steel, the addition of the tracer gas expediently limited to the last minutes of the blowing process. In connection with the pouring of With high-carbon and medium-carbon mild steel, the tracer gas is added for control purposes the carbon content during the post-blowing with oxygen.

Because of the small amount of argon required, the operating costs of the process according to the invention are relatively low. For example, the tracer gas can be added in a ratio of 1% or less in systems of a '50-t steelworks, with the tracer gas during the casting of low- and medium-carbon steel during the blowing in of the last 2000 Nm ³ O ₂ and during Casting of high-carbon steel is carried out in the course of the programmed re-blowing. With a proportion of 1%, only an average of 20 Nm ^{3 of} argon have to be used per casting.

The values of the total exhaust gas flow rate Vf (Nm ³ per minute) measured by the method according to the invention enable evaluation in an integral carbon measurement as well as a differential carbon measurement.

In the case of integral carbon measurement, the during all or part of the blowing time Amount of carbon c (kg) removed from the steel melt between two times 1 and 2 according to the integral formula

2 2

J l £ di = -L · J (co + 1 1

determined, where dc / df (kg / min) means the rate of decarburization, i.e. the amount of carbon removed from the steel melt and transferred into the exhaust gases in the unit of time. In the above equation, (CO-HCO ₂ ) also denotes the percentage volumetric concentration of these gases in the exhaust gas, these gases being formed by the decarburization reaction under the action of oxygen on the molten steel, and K is a dimensional constant, the numerical value of which is K = 186, 7 (NmVKg) is Expressed by the percentage carbon concentration Co at the start of the blowing process and the percentage carbon concentration Ci at the end of the blowing process is the above equation

Cq

-J

(CO + CO ₂ )
186.7

Vf dr = W ₁₁ C ₁ .

where HO is the mass of the pig iron and W is the mass of the steel melt at the end of the blowing process.

The percentage concentration Q results from this according to

<& gS®Ltyw _a . (2)

In contrast to the integral carbon measurement, the decarburization speed is used in the differential carbon measurement Determine dc / d / as derived quantity L.

As a first approximation, a linear relationship between the decarburization rate and the percentage carbon concentration Q of the molten steel is shown according to

f. »· C, (3,

assumed, where b (kg / min) represents a constant of proportionality. The above equation again allows the carbon concentration to be represented by the measurement result VV of the method according to the invention as

C ₁ = ^ - Jr Vf (CO + CO ₂ ). (4)

In an advantageous embodiment of the invention In the process, the concentration is determined using a mass spectrometer. In this In this case, both the information on the composition as well as on the flow rate of the from are provided at the same time the converter escaping exhaust gas, so that all types of measurement by the same analyzer, namely the mass spectrometer, can be determined. Measurement errors that would otherwise be caused by different recording devices can be caused are thereby excluded in an advantageous manner.

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Claims (2)

Patent claims: 1. method of measuring the amount of exhaust gases, which emerge from a steel melt with controlled decarburization, an oxidizing agent and argon be supplied in certain amounts, at which the concentration of the contained in the exhaust gas Conversion products is determined thereby characterized in that the argon used for measuring steel converters with an oxygen lance is that of Oxygen blown into the converter in a concentration of less than 5% than the lance Tracer gas is supplied and that also means the concentration of this tracer gas in the exhaust gases Analysis of the gaseous products removed from the converter mouth is determined. 2. The method according to claim 1, characterized in that that the concentration is determined with a mass spectrometer.