DE763817C - Process for refining iron ores mixed with solid fuel and additives in a blast furnace - Google Patents

Description

It has already been suggested mixed with solid fuel and aggregates To smelt iron ore or briquette from these materials in the blast furnace in such a way that in these a substantial part of the required heat of reduction and fusion in the form of a hot gas mixture is introduced in a combustion chamber upstream of the blast furnace through complete combustion of any fuel with excess cold or preheated oxygen or oxygen-enriched air was produced in the presence of water vapor and

from carbon dioxide, water vapor, excess oxygen and possibly some nitrogen consists. In this known method, the gases introduced are set with the glowing one Carbon in the feed in such a way that the free oxygen with some of the carbon the charge forms carbon dioxide, the water vapor forms hydrogen, and the carbonic acid be wholly or partially reduced to carbon monoxide.

It has now been found that this known method can be significantly improved thereby can that one the composition of the with

high temperatures (iooo to 2000 ⁰ C) to be introduced into the blast furnace gas mixture in relation to the amount of carbon in the charge so adjusts and regulates that in the blast furnace the free oxygen causes the combustion of part of the carbon of the charge to carbon oxide, the water vapor with the remaining part of the same, at least partially, converts to hydrogen and carbon oxide, which

to carbon dioxide introduced into the furnace, on the other hand, by the blast furnace, giving off a considerable amount Part of their sensible heat flows through essentially unchanged. This invention is based on the knowledge that one can see the difference in responsiveness after the introduction of the hot gas mixture of oxygen, water vapor and carbonic acid playing in the blast furnace Operations:

C + O = CO 4 ~ 29 160 kcal (1)

C + H ₂ O = CO + H ₂ - 28 880 kcal (2) C + CO ₂ = 2 CO - 38 S80 kcal (3)

to a particularly favorable influence on these processes themselves and thus also on all can take advantage of other processes in the blast furnace that are dependent on them.

The reaction Ci) is exothermic, while the Reactions (2) and (3) are endothermic. The resulting from the exothermic reaction (1) The amount of heat alone would not be sufficient to melt the insert and to Reduction of the iron oxide required heat as well as the heat input of the endothermic To cover reaction (2) or even that of the likewise endothermic reaction (3); This additional heat requirement is covered by the blast furnace due to the highly heated gas mixture supplied amount of heat.

Whether and to what extent, in addition to reaction (1), reaction (2) or (3) also occurs now depends on the amount of free oxygen supplied from below, provided that a certain amount of carbon is charged into the furnace from above. Namely, the more carbon for the reaction (1) is consumed, d. H. the less carbon is left for reaction (2) or (3) so less water or carbonic acid will suffer a conversion. In a theoretical Limiting case, then, in which for reaction (1) all of the fixed carbon in the charge is consumed, d. H. as much free oxygen is supplied from below as for conversion the total amount of fixed carbon in carbon dioxide is required for the reactions (2) and (3) no longer have a fixed carbon present, so that the latter reactions

6a cannot go on at all. If this is the case, water and carbonic acid become pass through the furnace unchanged, releasing their sensible heat. In the other theoretical limiting case, however, the total amount of the introduced from below is used Water and carbonic acid implemented. There are innumerable possibilities between these borderline cases. By regulating the Components of the gas mixture to be introduced from below are now completely in accordance with the invention in hand, the blast furnace operation depending on the requirements with regard to the ore to be processed and the heat consumption of the process, to the maximum temperature required in the blast furnace, to the desired composition of the furnace gases etc. to be adjusted to the most favorable procedure in each case.

It has been found that it is most expedient for the normal case, the blast furnace process by adjusting the excess oxygen in relation to the fixed amount of carbon in such a way that in addition to reaction (1) at most reaction (2) takes place, reaction (3) on the other hand no longer comes into play. This means that all the carbonic acid remains unchanged passes through the furnace and only serves as a heat transfer medium, the water however, according to reaction (2) is completely or partially decomposed. These effects of the invention The proposed measures are possible because first the combustion of carbon of the feed to carbon oxide takes place., only then does the decomposition of the water, which is endothermic, begin, and after this only the also endothermic, but an even higher heat consumption than carbonic acid decomposition exhibiting water decomposition.

If one compares the processes in the method according to the invention with the usual blast furnace operation, the following fundamental difference arises: In the normal blast furnace operation, the preheated wind is introduced into the frame at a temperature of about 600 to 800C, where it produces carbon of about 1500 ⁰ C and burns this partly to carbon dioxide, partly to carbonic acid. The carbonic acid is reduced to coblene oxide by the glowing carbon.

In the case of the invention, on the other hand, a flue gas mixture with excess oxygen at a temperature of over 1000 ^° C. is introduced into the frame of the blast furnace. If the rising mixture hits the carbon directed from above, this can with the free oxygen of the mixture due to the high temperature according to the equation

C + O = CO (i)

only burn to carbon dioxide. In addition to this reaction, a partial reduction of the

highly heated water vapor introduced after. the equation

H ₂ O + C = CO + H ₂ (2)

take place. In the zones where these reactions take place, there would also be a reduction in the introduced carbonic acid go ahead, if this is free carbon and the necessary amount of heat would be present. But just according to the invention, the operation is set so that to for this purpose no carbon remains, so that the reaction

C 4- CO ₉ = 2 CO

(3)

can not use.

Above the zone where the oxygen in the mixture introduced has already been completely consumed, the temperature in the blast furnace suddenly drops so far that the reduction in the increasing carbonic acid cannot take place because neither the temperature nor the heat conditions are available for this . The carbonic acid probably finds unburned carbon, but can in no way react with it because this reaction can ^{practically not take place below about 900 0} C, if one also takes into account the important fact that the gas mixture introduced the blast furnace in about a Second, so that in the colder zones, where the reactions are significantly slower, the carbonic acid has no time to react with the carbon.

^{To further explain the subject matter of the invention, the following should be mentioned: 1} Za molecule, ie 11.2 m ⁸ O _{8, is} required for the combustion of one molecule, ie 12 kg of C to form one molecule of CO. This amount of oxygen is supplied by the gas mixture supplied to the blast furnace, consisting of oxygen, water and carbonic acid, according to the following list:

-Hi ³ O ₂
²

ii, 2 m ³ O ₂ (-ym ³ H ₂ O
ζ m ³ COo

• Gas mixture

Whether this amount of oxygen is only due to the free oxygen content of the mixture or also supplied by the bound oxygen of the water or of the water and the carbonic acid depends only on the composition of the gas mixture. It can thus operate actually by setting the individual quantities in the blast furnace accordingly supplied combustion gas mixture, or the individual quantities in the upstream combustion chamber imported substances, namely primary fuel, oxygen and water vapor, in relation to the fixed ones directed from above Carbon (secondary fuel), can be easily performed so that the combustion of the fixed Carbon in the blast furnace from the components of the gas mixture supplied the free oxygen and the bound oxygen of the water vapor, the latter partially or whole, are consumed, but the carbon dioxide introduced is not consumed in the combustion participates.

The method according to the invention has compared to the initially described and the Other known methods have the main advantage that this reduces the consumption of coke of the blast furnace per ton of pig iron can be significantly reduced. That illuminates without further from the fact that no coke is used to decompose the carbon dioxide introduced becomes what otherwise represents a significant proportion of the coke consumption. However, the The calorific value of the furnace gases is somewhat reduced by the undecomposed carbonic acid, but also this loss is outweighed by other benefits. The amount of blast furnace gases produced This is because it is considerably reduced, which reduces the dimensions of the furnace and the furnace gas line and the other device turn out to be smaller, which in turn is smaller plant and Has operating costs.

There is also an advantage of the method according to the invention that should not be underestimated in that this increases the throughput of the blast furnace quite considerably, because the throughput time is only 2 to 3 hours, compared to that in the case of fast-working blast furnaces up to now achieved throughput time of 7 to 10 hours. This benefit also works in that sense favorable from the fact that the performance of the blast furnace is significantly greater.

The process also has the following advantages: The excess water introduced into the frame converts the carbon dioxide from the top gas into carbonic acid. Since the gases rising in the blast furnace also contain water vapor, a conversion to carbonic acid corresponding to the enrichment also takes place in the zone of the upper half of the blast furnace, namely in the zone around 500 ^{° C.} This is exothermic, so that quantities of heat are released which enable the coke rate to be reduced.

In addition, the beneficial catalytic effect of water vapor and of hydrogen in the indirect reduction of ore by carbon dioxide.

Furthermore, the presence of water or hydrogen in the furnace gives a Desulfurization of the coke by partially carrying the sulfur with the exhaust gases. Tests have shown that up to 40% of the coke sulfur in the furnace gases is more volatile Form are included. If you take into account that

the process can achieve set coke savings in any case, which are between 40 and 50 ⁰ Z ₀ and thus also bring correspondingly lower amounts of sulfur into the shaft furnace, this desulfurization means an extraordinary improvement compared to the generally common blast furnace operations.

For this reason, the process is also particularly suitable for acidic melting and for the smelting of poor ores. It saves significant amounts of what would otherwise have to be desulphurized desulfurizing agents required for acid smelting of pig iron, such as soda, Bauxite, etc.

The new method also saves lime because, because of the elimination of the half the amount of set coke also only half the amount of sulfur and half the amount of coke ash is introduced into the furnace, the latter consuming lime because of their silica content would.

Particularly favorable embodiments of the new method arise when one in an in a known manner in one or more zones of the rest or the shaft of the blast furnace introduces additional amounts of heat through combustion gases in one or more additional upstream combustion chambers were generated in such a way that their temperature corresponds to the furnace temperature prevailing or required at the point of introduction substantially equals or exceeds.

This provides good preheating and preparation of the descending charge and thereby also a corresponding saving of set coke. In particular enables this supply of additional amounts of heat in the upper part of the blast furnace the use of calcium carbonate also in the case of the smelting of poor ores without increasing the need for coke.

The advantages of the method according to the invention will be given with reference to a few comparative figures for example. All other things being equal, the Smelting (I) with the usual method and (II) with the method according to the invention the following results for the consumption or for the furnace gases per ton of pig iron:

Ore (oxyd. Iron ore)
coke

Furnace gas quantity.

calorific value
the furnace gases ...

2.2601 0.9801 4.100 m ³

1023

II

2.2601

00411 1,700 m ³

945 units / m ³

The r 700 m ³ furnace gas from 945 WE ™ ^{3 is} sufficient as the first gas to carry out the process and still results in residual amounts of heat that are sufficient to generate the water vapor required for the process. The process can therefore be carried out as a self-closing process.

When carrying out the method according to the invention, it must be determined by calculation how much oxygen, water and carbonic acid each with the combustion gas mixture from below ι kg of carbon of the solid fuel straightened from above is to be introduced so that, firstly, the Fixed carbon is burned to carbon oxide, secondly, the water is partially or completely decomposed and thirdly the carbonic acid remains unchanged, d. H. for the reduction of Carbonic acid no fixed carbon is present. Here must of course also for this Care must be taken that appropriate amounts of heat are available in the blast furnace, in order to be able to and must maintain the required temperatures in the various zones accordingly that temperature can be determined at which the combustion gas mixture is to be introduced.

But it can sometimes happen that the relatively small amount of the in the blast furnace upwardly flowing furnace gases are insufficient to maintain the required temperature in the different higher zones of the blast furnace go to maintain and use (ores and Additives) to preheat and degas. In these cases, as I said, it can be beneficial be to introduce additional combustion gases into one or more higher zones of the blast furnace, generated in this way in one or more additional upstream combustion chambers that their temperature is essentially the same as that at the insertion section corresponds to or exceeds the required furnace temperature. Through this additional Combustion gases will increase the amount of gases flowing upwards with the introduction of additional ones Amounts of heat increased, resulting in the safe and smooth implementation of the procedure can contribute according to the invention.

Regarding the state of the art, it should also be noted that various processes are already known are in which the blast furnace in addition to air or oxygen and possibly other gases either carbon dioxide or carbonic acid is supplied, but in the case of soft, in contrast to Process according to the invention, the carbonic acid fed to the blast furnace or formed there, at least partially, is reduced in the furnace itself.

It has already been proposed to return the furnace gases to the blast furnace as fuel and to blow in oxygen through special lines.

It was also suggested that a mixture of carbonic acid and the blast furnace should be used

To supply water vapor in a gas generator connected upstream of the blast furnace in this way is formed that both in the lower and in the upper part of the gas generator Air-steam mixture is blown in, the gas generator by means of the blown in below Mixture of carbon dioxide formed by the mixture blown in above in carbonic acid is converted.

ίο It was also suggested that iron ores should be reduced in the blast furnace, at least in part, by carbon dioxide, which is produced in such a way that in the blast furnace itself or in a special furnace a mixture of carbonic acid and oxygen and, if necessary, steam Glowing coal is reacted, the proportions being chosen so that the carbonic acid and optionally the water vapor serve as a diluent for the oxygen and as a coolant in order to avoid excessively high temperatures (over 1000 ⁰ ) in the blast furnace.
These known methods therefore differ from the method according to the invention precisely in the essential measures and objectives.

Claims (2)

PATENT CLAIMS: i. Method of smelting mixed with solid fuel and aggregates Iron ores in lump or briquette form in the blast furnace, in which part of the required Reduction and heat of fusion is introduced by means of a hot gas mixture as a heat transfer medium, which is in one of the Combustion chamber upstream of the blast furnace through complete combustion of any fuel with excess cold or preheated oxygen or oxygen-enriched air in the presence of water vapor and consisting of carbonic acid, water vapor, excess oxygen and possibly some nitrogen, characterized in that the composition of the ^{gas mixture at least 1000 0} C in relation to the carbon of the charge is adjusted and it is regulated that in the blast furnace the free oxygen causes the combustion of a part of the carbon of the charge to ore-reducing carbon oxide, the water vapor reacts wholly or partially with the remaining part of the same to ore-reducing and sulfur-binding hydrogen and ore-reducing carbon oxide, the carbonic acid of the introduced gas mixture on the other hand flows through the blast furnace essentially unchanged while releasing a considerable proportion of its sensible heat. 2. The method according to claim 1, characterized in that in one or more Zones of the rest or the shaft of the blast furnace additional amounts of heat are introduced by combustion gases, the generated in this way in one or more additional upstream combustion chambers that their temperature corresponds to that prevailing or at the point of introduction. required oven temperature substantially corresponds to or exceeds it. To differentiate the subject matter of the invention from the state of the art, the granting procedure the following publications have been considered: French Patent No. 466 241; U.S. Patent Nos. 874,336, 1742750. 9531 7.