DE281311C - - Google Patents

Description

IMPERIAL

PATENT OFFICE,

GREAT. 18 «. GROUP 18. / 01

Heat is supplied from the outside.

In the oxidation of iron to iron oxides, of carbon to carbon oxides and Carbonic acid is known to develop heat, and that is what happens in each case Amounts of heat known with sufficient accuracy through exact tests; they are currently being traced in the scientific literature the values given in Table I below, which relate to the kilo. ίο grams of those to be oxidized by oxygen Relate substance.

Table I.

Amounts of heat, which when burning ι kg of substance with the required Amount of oxygen to be released:

Fe to Fe O.
Fe to Fe ₃ O ₄
Fe to Fe ₂ O ₃

W.E.

• 1350
.1650
. 1800

C to Co. C to Co ₂ . Co to Co ₂

W.E. . 2470, 8080

These values are in terms of the amounts of energy that are released during this reaction .set, are not readily comparable, because the standards by which they are measured are, the kilogram of iron and the kilogram of coal, not without further ado appear comparable. A clear evaluation of these amounts of energy is made possible however, if they are calculated on the same scale of 1 kg of oxygen each, what amount of substance in all reactions under consideration here as with Iron or carbon or carbon oxide can be assumed to be reactive.

Which then correspond to the quantities of the bodies reacting with one another, freely The heat quantities to be generated have been entered in Table II. The numbers emerge by simple rule tri calculation from the figures in Table I.

Tabel. II.

Amounts of heat generated in the reaction of ι kg O can be delivered with the required amount of substance:

W.E.

C to CO 1852.5

C to CO ₂ 3030

CO to CO,

4200.

3149I

W.E.

Fe to Fe O .... 4725
Fe to Fe ₃ O ₄ ... 4331
Fe to Fe ₂ O ₃ ... 4200

Calculated from this:

FeO ZuFe ₃ O ₄

Fe ₃ O ₄ to Fe ₂ O ₃ ... 3152J

Since for the reduction of a body, for example of iron oxide to metallic iron, the same amount of heat must be expended as in the oxidation of iron Iron oxide is obtained, the numbers in Table III, obtained by a

mean: 3150.

55

multiple addition and subtraction of the relevant values from Table H, a clear representation of those heat movements that result when the various iron oxides are reduced by carbon or carbon oxide, assuming that the applied carbon becomes carbon oxide and the applied Carbon dioxide burns to carbonic acid. The relevant figures resulting per ι kg of reacting oxygen are entered in Table III.

Table HL

Heat movement in the reduction of Iron oxides calculated by C or CO per ikg of reacting O:

through C: through C O:

Fe O to Fe 2872.5 W. E. 525 W. E.

Fe ₃ O ₁ , to Fe. 2478.5 WE 131 WE

Fe ₂ O ₃ to Fe ..... 2347.5 VV. E. 0 WE Fe ₂ O ₃ and Fe ₃ O ₄

for Fe O 1297.5 W. E. 1050 W. E.

bisbcj "- at least, completely · 'unnoticed Tat \ thing is that during the reduction of iron oxide to iron by carbon monoxide neither a heat effort is required is still taking place, a heat delivery.

From this result is. to deduce the conclusion that iron oxide can be reduced to metallic iron by carbon oxide without a change in temperature of the reacting bodies, provided of course that the required reaction temperature is present and that the other conditions for the course of the reaction also apply in this direction - ¹ are given.

This knowledge is extremely important because, firstly, the most favorable reaction temperature for the course of the above reaction is about 700 to 800 ° C and there is generally at least at this temperature The ores occurring in nature do not yet tend to sinter.

It is known that sintered or slagged iron oxides are no longer due to gases are reducible, and this fact can be explained very simply from the circumstance that as a result the A '* slagging the iron oxides are no longer accessible to the gases. Slagged Iron oxides can therefore, for example in the blast furnace process, only then only react with carbon when they have gone into solution in the melt flow and then in this state with that which is also in solution in the slag Able to react with carbon.

All iron oxides are not slagged

I against how experience has taught by (Ja.se reducible.

It consists, so far, in the scientific Welt the general view that when reducing gases act on Iron oxides a gradual breakdown of the oxygen takes place, so that Eisenoxytl initially in iron oxide, this in ice-carbon and the latter finally in metallic liisen would be converted. As several years of studies by the inventor have shown, this is The view, however, is not always correct, but when the appropriate reaction conditions are given, d. H. sufficiently high temperature and appropriate ratio of the existing Amounts of carbon dioxide and carbonic acid to one another, the reduction proceeds of iron oxide through carbon oxide directly from iron oxide to metallic iron, also this is observation. of crucial importance for 'the possibility in large farms To reduce iron oxides to metal by means of gases without the need for a cutting operation ... '

ι required. will. ,, · · ,, ... , ■. _i ,, $ 5

It would inevitably be necessary to supply correspondingly large quantities of heat through the masses of the ore in order to carry it out. For this purpose, any other means than carrying out the blast furnace process would appear inapplicable. If the reaction were exothermic, the temperature would soon rise to such an extent that sintering of the ores would be inevitable, and further action of the gases on the iron oxides would be excluded.

Would the breakdown of oxygen from iron oxide in the paragraphs mentioned above If the reaction occurs initially, according to the figures in Table IH, the reaction would be strong be exothermic, thus again conjuring up the danger of sintering, and in the end are considerably endothermic during the conversion of the icnoxide into metallic iron, d. H. thus, lower the temperature of the ores so much that the reaction temperature very soon be below and therefore the completion of the reaction will not take place would. ..

Only the previously neglected fact that the reaction fixed by the above equation neither exothermic nor endothermic enables a rational to be carried out Conversion process of the iron oxides present in the ores into metallic iron, without, as in the blast furnace process, having to go to the melting of the gang.

The process is carried out as follows:

They move in a shaft furnace

reducing ores downwards, while the reducing gases flow upwards towards them. . Both the ores and the gases have before they enter the Schächtofen .. to the reaction temperature, generally from 700 to 900 ⁰ C, preheated. If the ores are of favorable nature, if the pieces are not too large, a few hours of contact between the gas and the ore is sufficient to bring about a conversion of the iron oxides into metallic iron through the whole mass of the ore, with simultaneous moderate carbonization of the same.

The ores are preheated appropriately in special ovens, e.g. in the well-known rotary kiln, as they are generally in have found application in the cement industry. Your heating becomes appropriate . through the furnace gases of the reduction shaft

ao ofens exercised. For reasons of the rational use of the heating gases, it is desirable to make the flame oxidizing; one thereby achieves the Advantage of adding iron oxide or oxide compounds present in the ores To oxidize iron oxide. '

Either generator gases or coke oven gases, natural natural gases, can be used for the reduction. Petroleum gases and the like are used; it is only necessary to preheat these gases to the temperature of about 900 ⁰ before entering the reduction shaft furnace, since of course these gases with that excess of heat. have to carry into the reduction furnace, which is required to

the that

unavoidable broadcast losses
Keep balance.

These gases can be preheated in a simple manner in the known Cowper apparatus take place, which in turn are heated again by furnace gases from the reduction furnace.

The emerging from the reduction furnace bottom ores are cooled by Vorbcigleiten to water-cooled iron surfaces and intentionally cooled down to the end by a small injection of water, that they are not heated more higher than about 150 ⁰ in contact with the atmospheric air. It then passes, as experience has taught a Wiederoxydation of the metallic, finely divided iron does not, and the material may without further \ ^r orsichtsmaßregeln a dry or wet separation or magnetic separation are fed. The experience can also be used in an analogous manner for the deposition of other metals such as nickel, cobalt, copper, tin, etc.

A large number of processes have already been described in the literature or in patents.

been used to produce metallic iron from oxidic iron ores without using ilen iTo for this purpose; ^- To have to use the court process.

What all these processes have in common is that they treat the iron ores with the aid of reducing gases in rotary kilns or shaft furnaces; however, there are differences depending on the type of apparatus which is intended to be used

the mode of action.

When using rotary kilns, a reducing flame formed from generator gas, which is then renewed in the upper part Air supply should be given an oxidizing character. Especially through education However, the reducing flame will inevitably have a high carbonic acid content Gases caused in the upper part of the. Reduction room unalterable, if at all an effect occurs, bringing about a gradual breakdown of the iron oxides got to. As a result, the presence of considerable in the lower space of the reduction space Amounts of iron oxide, its reduction by carbon oxide, as set out in detail above - \ vorden, requires a large amount of heat. This heat requirement can only be brought about by the radiation effect of the generator gas flame and this inevitably means a thorough sintering of the Ore masses are effected. '

From the patents of all inventors it is therefore unquestionably clear that the The masses obtained in this process are sintered and have to be subjected to a subsequent crushing and fine grinding operation in order to achieve i °° at least to some extent to separate the formed iron granules from the slag. Inevitable However, significant amounts of those present in the ores occur during sintering Iron oxides in chemical bond with the silica of the gangue, go for the intended one Purpose itself lost and envelop considerable amounts of iron oxides, which are thereby the reducing effect of the Withdraw gases. The process also becomes economical.

It is not known that even one of these \ ^r erfah'ren in really- 'ness successful practical application would have found.

If the formation of a flame in the Tried to avoid rotary kilns by removing the gap between the rotating part seal the furnace and the fixed chambers below if possible, so the generator gases only occur with,

that temperature that is inherent in them from the generator process (ie with about 400 to 500 ⁰ ) into the rotary kiln, and therefore an appropriate reduction of the ores cannot be effected at all. With this arrangement of the apparatus, the fact that, as is well known, the reducing gases do not penetrate the ore mass in rotary kilns, but that the gases flow only superficially over the ores rolling towards them in the furnace, makes this arrangement of the apparatus more difficult. Compared to the proposed method, these arrangements also lack the moment to preheat the reducing gases to the required temperature of about 900 ^° .

Such fundamental deficiencies also have those procedures in which the treatment of ores by reducing gases in shaft furnaces of relatively high altitude has been proposed. In most cases the intention here is to create an oxidizing flame in the upper part of the shaft furnace, to preheat the ores to high temperature, and then it is suggested to put in the lower part of the shaft furnace generator gases 0. In all of these forms the apparatus was not taken into account that during the whole Contact time between the ores and the reducing gases determine the chemical composition the latter in relation to the relation between carbonic acid and carbonic oxide must be kept in such a way that a gradual breakdown of the iron oxides does not occur can. Everywhere attempts are made to work with a relatively large shaft height. Besides neither does any of these processes show the

■ 40'nung that the reducing gases are preheated to about 900 ⁰ introduced into the shaft furnace.

In a further form of training, the basic idea common to all of these processes it is proposed that the ores in the furnace chamber be intermittent, only with oxidizing

. Flame, then with reducing gases, to treat those amounts of heat that for the reduction are required to store within the ore masses. Here too the intended purpose cannot be achieved because the required amount of heat are so great that they are inevitable during the application of the oxidizing flame a thorough sintering of the ores is brought about.

■ The inventor himself iron ore has finally protected it a process by which patent 203,086, below the sintering temperature reducing gases to loading., Act by the ores in a // 1

Shaft furnace at such a low temperature that reducing gas is generated so that the iron reduced in a higher part of the furnace is able to deposit carbon from the gas. The purpose of these proceedings is therefore quite different from that of the present proceedings. It is only intended to deprive the reduced metal of the property of self-ignition / flammability which it otherwise easily possesses when it comes into contact with atmospheric air after the end of the process. Therefore, the method of the patent 203086 is an addition of the present \ ⁷ crfahrens. It was only when the process according to patent 203086 was carried out that it was recognized that a thorough reduction of the iron oxides can only be achieved if the entire mass of the gas 80 used for the reduction effect has previously been heated to reaction temperature outside the furnace.

It has already been suggested repeatedly that those given in the introduction to the description Figures to make the reduction by preheating gas and ore to such an extent that the intended implementation could proceed without further supply of heat in order to achieve the reduction at a constant temperature below the sintering temperature perform.

The means with which one has hitherto attempted to carry out such proposals but were not suitable for the heat release result achieved in the tables listed above to arrive, d. H. Reduce iron oxide directly to metallic iron. It had been overlooked that when using higher layer heights and when using the Material in such pieces, either due to their size, only a gradual implementation allowed, or were too dense for rapid penetration by means of the gas that Reaction is too slow and, which mainly applies in the case of a high layer height makes, the reducing gas eventually becomes increasingly enriched with carbonic acid. Such a carbon dioxide enriched with carbonic acid is from the point of view of the thermal equation a completely different reducing agent than the one practically carbonic acid-free Reducing gas, so that in this case too the reaction differs from that with direct formation of iron runs from iron oxide.

The method can only be carried out in such a way that the grain size is selected appropriately of the material by moving the material appropriately to achieve good penetration with gas and by limiting the layer heights, the ideal conditions are attempted almost come that the entire mass of ore at the same time with the entire mass of gas

■ WWii-uiiJWy-Ί: = ■ "...

reacted. This can be practical for example done by using reduction furnaces in which the material is in thin layers while changing the surface as permanently as possible, and the it allow the exhaust gases to be discharged at several points or fresh gas at several To supply bodies. If these conditions are observed, it is possible to do so as far as possible Avoidance of the intermediate stages of iron oxide to get directly to the iron without sintering the material.

Claims (1)

Patent Claim:. Process for the extraction of metallic Iron by reducing the iron oxide contained in the ores by means of colonic oxide or carbon-containing gases at a constant level, below the sinter tion temperature lying temperature under so extensive preheating '' of > ■ • Gas and ore that the intended implementation without additional heat from runs outside, characterized in that the reduction of the iron oxide is direct to iron while avoiding intermediate stages through a relatively short exposure time of the flowing through Gases on the ore charge and by limiting the ratio of carbonic acid to carbon oxide in the exhaust gases on one the insistence of metallic iron permitting maximum value is effected.