DE3708730A1 - Method for recycling precipitator dusts - Google Patents

Abstract

The precipitator dusts which arise in large quantities in steel manufacture and which are separated off in precipitator installations, have a high iron content and should therefore be recycled to steel manufacture. Since these dusts tend to form lumps because of their fine grain size, they are blown by a carrier gas into the metallurgical vessel, namely with the aid of nozzles arranged in the bottom of the vessel. Preferably, they are blown in through the same nozzles through which carbon carriers are also blown into the vessel.

Description

The invention relates to a method for reuse of filter dusts with usable contents for the steel workers position.

In the manufacture of steel, in blast steel processes as well in the electrical steel production process and in the AOD process, very large amounts of dust accumulate, which together with the exhaust gases emerge from the metallurgical vessels and then in secondary switched filter systems, especially electrostatic precipitators that will. In the steelworks of the Federal Republic of Germany alone In this way, it is estimated that the country falls approximately every year 600,000 t of filter dust.

These filter dusts can contain up to 90% iron have, so this is a very ferrous one Commodity. These filter dusts are still common today still stored in hazardous waste landfills.

However, it is also known to use this filter dust at Manufacture of steel to reuse the existing in it those to use iron content.

At the 2nd International Trade Fair for Metallurgy with Congress and exhibition seminar METEC 84 (22.-28.6.84) is a Lecture entitled "Converter-Dust-Recycling by Pneumatic Conveying Technique "has been held, and that is the thought has been expressed, filter dusts by pneumatic conveyance to be fed back to the converter without special treatment. In this however, it is expressly pointed out that this is technical is not easy and it goes on to say that the steel industry therefore mechanical conveyors, e.g. Chain conveyor be prefers.  

It is made of steel and iron 107 (1987) No. 2, pages 80-84 also already known, the reuse via a so-called to carry out the named hot briquetting process. In doing so the filter dust to a required hot briquetting temperature heated from about 600-700 ° C and then filter dust bri chains pressed, which in the Oxigenstahlwerk instead of cooler ore or cooling scrap are used. This procedure has ever but the disadvantage that for this hot briquetting of filters dust a large briquetting plant must be built, so that the hot briquetting of filter dusts is quite a is complex and expensive process.

The invention has for its object a method for Reuse filter dusts, where the Dusts without special prior treatment directly from the Filter systems are processed back to steel.

This object is achieved by the in the labeling Part of claim 1 specified features solved.

Preferred embodiments of the inventive concept are themselves in the subclaims.

It is known that those separated in the filter systems Filter dusts are very fine-grained, namely approx. 90% are smaller than 1 µm, large proportions are even smaller than 0.1 µm, so that they are very easy to form clumps and thus during conveying tend to clog pipes.

When it came to the idea of the invention, however, it was completely surprising shown the way that the technically very problematic pneu Then, in practice, there is no difficulty in promoting them tet when the filter dust is transported by the carrier gas the one that also has fine-grained carbon carriers or the like, pneumatically well conveyable materials and if you fer ner this carrier gas, the fine-grained carbon carriers feeds and the carrier already loaded with carbon particles gas then only adds the filter dust. Then no kick Clumping of the dust and no more clogging of the lines on.  

There is a possibility that you look at this completely surprising effect can explain that on its own entire surface of very rough small filter dust particles then so in the one already loaded with the larger carbon particles Carrier gas are distributed and swirled so that they do not interlock more and lead to clumping and constipation of the lines, but in a way so far from each other held or in the carrier gas between the carbon particles be distributed that this disadvantage with bordering security Probability no longer occurs, but a reliable one working method is developed.

This distribution of the filter dust in the carrier gas brings out which also very favorable conditions for the quick opening solution in the melt with it, and further by that both the carbon and the filter dust practically on and get into the melt at the same point very early a reduction in filter dust, which also includes metal oxides included, achieved.

The invention has thus shown in particular that it is not enough the filter dust to the con in any way verter supply, as this in the ge to the prior art mentioned lecture has been hinted, but that it is here Difficulties exist by the inventors not just in detail have been recognized, but also in a reliable manner working way.

However, the invention has not only the advantage that on this Show the introduction of the filter dust into the melt metallurgically particularly advantageous manner, but a there is also a very significant advantage of the inventive concept nor in the fact that not only tipping over to hazardous waste landfills not applicable, which is largely because of their already are still unsettled environmental influences, but it can also dispense with expensive warehousing, and in particular, it does not require any complex special pre treatments more, like this one for example at the moment hot briquetting still published.  

It can even be said that the one with the practical reali Sation of the invention related technical effort the current state of the art is impressively low, so that this process is particularly economical Is promised.

But it is not essential that the nozzles for the joint supply of carbon and filter dust in the Bo those of the converter are arranged, but they can also are located in the side of the converter wall. However, it is important that the filter dusts are not blown onto the melt, but that the blowing into the molten steel takes place So nozzles are located below the bath surface.

Nitrogen, argon or natural gas, for example, can serve as the inert gas.

The method is particularly for those known in the art Steel manufacturing process KS and KMS suitable, in which the Steel production from scrap and sponge iron as an iron carrier (KS) or liquid pig iron and scrap as an iron carrier (KMS) takes place and through floor nozzles oxygen and lime as well as fine granular carbon can be fed directly to the bathroom because these so-called bottom-blowing steel manufacturing processes technically particularly advantageous by the invention and be supplemented economically, because the resulting filters dusts can be processed directly, i.e. without preparation, and continuously Lich processed back to steel.

Because of their high specific surface area, dusts in the melt can also be dissolved particularly quickly, where is given by a further particularly advantageous effect.  

The pneumatic introduction of dust and dust removal the dedusting system can advantageously be a form a closed system that operates under protective gas can be. Further advantages of the process are that with the dusts an intermediate screening the setting of a allows predetermined sieve analysis, and it can grain fractions are rejected due to their chemical combination setting should not be returned to the process.

In this way, that's only from the point of view of Stahlher position already very advantageous method also the white tere advantage that due to the different grain fractions certain metals excreted, collected and again can be used, so that also with respect to this Me recycling can take place.

Another advantage of the method is that that the stream of carrier gas, carbon carriers and filters dust can also be mixed with other substances that are fine-grained and can be conveyed pneumatically.

Claims (18)

1. A process for the reuse of filter dusts with useful contents for steel production, characterized in that the filter dusts are blown into the molten steel below the bath surface. 2. The method according to claim 1, characterized, that blowing through the bottom of the metallurgical Ge barrel is done. 3. The method according to claim 1, characterized, that blowing through the side wall of the metallurgical Vessel. 4. The method according to claim 1, characterized, that the blowing is carried out with the aid of a carrier gas. 5. The method according to claim 1-4, characterized, that the blowing takes place through nozzles. 6. The method according to claim 1-5, characterized, that the injection takes place through the same nozzles through which also carbon carriers, such as fine-grained coal or coke varieties, are blown.   7. The method according to claim 1, characterized, that the filter dust is removed directly from the filter system becomes. 8. The method according to claim 4, characterized, that the filter dust the mixture of inert gas and Koh lenstoffträger is supplied. 9. The method according to claim 8, characterized, that the filter dust through the inert gas with the already added carbon carriers is entrained. 10. The method according to claim 9, characterized, that uses nitrogen, argon or natural gas as the inert gas becomes. 11. The method according to any one of the preceding claims, characterized, that before blowing into the converter an intense The carbon carrier and filter dust are mixed. 12. The method according to any one of the preceding claims, characterized, that besides carbon carriers also other fine-grained, pneu Substances that are easy to convey are used as admixtures can. 13. The method according to any one of the preceding claims, characterized, that the pneumatic introduction of the filter dust as well the dust discharge of the dedusting system is a closed one Form a system.   14. The method according to claim 13, characterized, that the closed system is operated under protective gas. 15. The method according to any one of the preceding claims, characterized, that the filter dust after separation in the fil an intermediate screening takes place. 16. The method according to claim 15, characterized, that in the intermediate screening the setting of a be agreed sieve analysis is done. 17. The method according to claim 15 and 16, characterized, that grain fractions are removed during intermediate screening that are not returned to the process should. 18. The method according to claim 15 to 17, characterized, that the intermediate screening for the production of metals he follows.