DE817655C - Method of extracting lead - Google Patents

Description

Process for extracting lead from the usual smelting methods of sulphidic lead ores, such as galena, settling or flotation concentrates, by means of roasting reduction or roasting reaction work, precipitation work is also known, in which metallic lead is obtained directly from the lead sulfur ore through iron: with simultaneous formation of iron sulphide will. However, this process is no longer carried out in practice, since the lead discharge is only incomplete and the stone produced holds not insignificant amounts of lead and silver derived from the galena. Furthermore, the reaction, Pb S + Fe -, - Fe S + Pb is reversible, so that a considerable proportion of the lead sulfide always remains decomposed and is absorbed as such by the stone. The amount of stone produced is relatively large and has to be processed further for the purpose of recycling the iron content, which also results in high fuel consumption. Compared to this disadvantage, the advantage of not having to use a roasting system is irrelevant, since the stone produced is in most of them. Cases must be roasted anyway.

As part of this process, it is also already known as a reducing agent to use iron alloys, such as ferro-alumina or ferroaluminum, instead of iron, the possibility has already been considered theoretically (see patent 195 793) to drop the iron content in these alloys to zero and for the Reduction, for example, to use metallic aluminum alone, however, was this was viewed as too expensive or no possibility was seen in the reaction work up resulting aluminum sulfide in an economical manner; Furthermore the action of the pure aluminum was considered too energetic, so that the Procedure was described as hardly applicable in practice.

In contrast to this prejudice, it has been found that lead sulfur like lead luster or sulfidic lead concentrates, metallic lead in more economical and in terms of equipment it can be obtained in a more favorable manner by the fact that the ore is in suitable Furnace with waste aluminum or aluminum alloys or with intermediate products of all kinds, e.g. B. turning or drilling chips, Seiger residues, dross, scrap, for example Aircraft scrap or the like., Implements. In this case, 3 Pb S + 2 Al are formed accordingly = 3 Pb + A12 S3173 60o kcal / kg mol in addition to a slag containing aluminum sulphide metallic lead, which is part of the alloy metals from the waste absorbs, while another part of it, especially the stone-forming ones Heavy metals such as copper. Iron, nickel, cobalt, etc., as sulfides in the slag can be solved. This process is an aluminothermic one Reaction which takes place with high exothermicity, so that a fuel expenditure for the execution of the method according to the invention not or only to a very small extent Dimensions is necessary. Furthermore, as was further found, the reaction is possible to take appropriate measures in such a way that the process proceeds in a regulated manner is going.

It is already known metal-sulfur compounds, among these too Sulfur lead, using calcium and aluminum either as a mixture or alloy to reduce, whereby a regular deposition of the metal should result. Here, however, the calcium is an integral part of the reducing agent used, the calcium thermite used must be relatively large amounts, e.g. B. 16% and more Calcium.

When carrying out the method according to the invention, in addition to flue dust, two products are produced, namely a slag containing aluminum sulfide and metallic B1ei. The slag can be processed by decomposition with water. The lead obtained has a lead content that depends on the content of the aluminum waste used for the reduction in alloy components and at least 99.0 to 99.50 / 0, in many cases. Cases more, amounts to. It is contaminated with copper, iron, zinc and traces of arsenic and can be processed using known refining methods. The aluminum content of the lead produced is also very low, since aluminum and lead in the liquid state have an almost complete miscibility gap.

The oldiminothermal character of the process according to the invention as well as the resulting high amounts of heat require precise monitoring the process flow. In addition, it must be ensured that an uncontrolled Oxidation of the aluminum by the oxygen in the air is avoided. Since furthermore the Reaction speed with the - \ `experienced according to the invention, as has been found, depends to a high degree on the grain size of the reaction participants are for the When carrying out the procedure, the main points to be observed are the following: i. the The reaction rate is expediently adjusted so that the temperature rise in the melt is not so high that significant evaporation of the formed lead takes place; 2. On the other hand, a temperature should be maintained, in which the aluminum sulphide-containing slag produced separates well from the lead and can be withdrawn from the reaction chamber; 3. There should be a neutral atmosphere above the estate must be adhered to in order to avoid uncontrolled oxidation of the aluminum.

The speed of the reaction taking place can be, for. B. thereby regulate that the starting mixture by means of neutral, not participating in the reaction Admixtures are diluted, or you can also choose them by choosing appropriate grain sizes the reactant degrade. Since the introduction of reaction-inhibiting substances in usually with a view to a mostly undesirable dilution of the reaction mixture appears less convenient, the second option is generally preferred be. In addition, the aluminum-based waste is already in coarser pieces arise, so that when using coarse-grained scrap, shredding costs are saved can be.

In order to target the slag liquid at the conversion according to the invention to be able to, you can optionally let the temperature rise accordingly high or also carry out the process in such a way that one is on before the slag targets heats up a corresponding temperature. A partial oxidation of the aluminum sulphide to oxide cannot always be avoided, however, either with the reaction mixture atmospheric oxygen stored therein is introduced or the furnace closure is not The edges must be kept so tight that any air entry is avoided.

However, in order to prevent uncontrollable oxidation of the aluminum and the To avoid aluminum sulfide to oxide, it is advisable to place over the reaction mixture to maintain a neutral atmosphere.

The amount of the reducing agent to be used in the present invention is very small in relation to the quantity of ore, since the atomic weights of lead and aluminum are very different. Theoretically, the amount of aluminum is about 7.5% Lead sulfide throughput. Taking into account the different high-alloyed wastes of aluminum alloys, the amount of reducing agent required in the Usually about 9 to i t% of the ore throughput, but it can be depending on the existing Losses are also higher or lower.

A content of the aluminum scrap to be used according to the invention \ lagnesium proves to be favorable in many cases, since the heat of formation of the Pb S + Mg = Pb + Mg S 57zooo kcal / kg mol of l @ lag-nesiumstiltids b: (lit. lier than that of ancient titanium sulfide. The magnesium contained in the scrap thus takes an active part in the implementation and is suitable in many cases for the heat balance to influence the process in a favorable manner. It is found after completion the reaction neither in the lead nor in significant percentages in the altitnitiiutnstilfidlialtigeti Slag, but goes into the 1-laup thing in the fly ash.

For carrying out the method according to the invention one can, for. B. use a hearth furnace, the lining of which, however, is usually not made of tctnerde- still - silica-containing material should consist of both of these from the slag attacked «- earth. It is more advantageous to line the furnace with graphite stones or. equipped with graphite. However, the use appears to be the most appropriate of dolomite or magnesite bricks or rammed earth, which the slag attack on best resist. Carbide material can also be considered under certain circumstances. tla this in the process according to the liquid on (: around its liolien thermal conductivity Most likely, any excess heat of reaction is reversed to dissipate.

The oven can be loaded in relatively small portions take place, the entry of air is advantageously avoided. It is the same in generally expedient to keep moisture away from the process and therefore the one to be reduced Lead ore to dry before use. Man -], poor but also ore and reducing agents, after this has been brought to a suitable lunar sound, mix first and then by drying to free them from the adhering impermeability or something similar Proceed wisely.

The amount of added starting material is advantageously readjusted the prevailing temperature in the furnace and adjusts it appropriately so that the Furnace temperature z. B is between about goo to iooo` C. Since the implementation in a short time As time goes on, you can achieve a sufficiently high throughput even with a small furnace achieve, which is also made possible by the fact that the resulting sales Lead accrues in liquid form and continuously, z. 13. in a preliminary, collected, and from this can be shed. That still has the advantage, because the lead exposed to the high temperatures only briefly and evaporation losses thereby reduced to a minimum.

Compared to the amount of liquid lead formed, the amount of slag containing aluminum sulphide is relatively small and therefore does not need to be continuously drawn out of the furnace. One can in such Betriebswcise de. Furnace (las charging interrupt to the slag Drag and the furnace temperature by additional heating aoo to about r to 1 300 'C bring to stab a gutflüssige slag for the same purpose but it is also briefly larger amounts Charge the material in order to bring the furnace temperature to the desired level due to the higher amounts of heat generated.

For carrying out the method according to the invention, one of the known short drum furnaces are used, which is also advantageous with 'llagnesit- or dolomite stones lined or magnesite or dolomite mass stamped out canine. It is also possible to use the lead sulfide-containing material in molten aluminum scrap to be entered in portions and to react therein. It is useful to to avoid the admission of air if possible, e.g. B. by, in closed vessels, possibly also under an inert gas atmosphere, is working.

It has been found to be beneficial to reduce the amount of fly ash again in .dgn process, whereby an agglomeration of the dust in general is not necessary. The system for separating the fly ash 'can be electrical Gas cleaning or also be designed as a condensation chamber, which is only small Need to have dimensions, since the amount of exhaust gas produced is usually only small are. However, this cycle also includes zinc, arsenic, antimony and silica enriched in the airborne dust, which as a result from time to time a separate Work-up is fed.

The economical side of the process according to the invention in most cases extremely favorable, as on the one hand as a reducing agent cheap aluminum scrap is used, which is available in large quantities, and its processing in and of itself great difficulties. power. on the other hand the fuel consumption is proportionate because of the fled heat of the implementation very low or practically zero, while at the same time the previously with the metal losses in the shaft furnace slag occurring in the usual lead extraction processes, the processing of which is often problematic and complicated, can be omitted entirely. The recovery of sulfur from the resulting in the process according to the invention Aluminum sulphide-containing slag can, as mentioned, without the use of a roasting process take place in a simple manner, the resulting hydrogen sulfide, for example: either for the production of sulfuric acid or liquid sulfur dioxide or also can be used to extract elemental sulfur while the resulting After drying and calcination, aluminum oxide hydrate is a pure raw material for the Production of aluminum, e.g. B. by fused salt electrolysis represents. For the In addition, lead division is the fact that the lead gain is significant in the case of smaller furnace units can be increased, reducing the cost per ton of lead significantly lower can be held. The delivery costs are relatively low, the same thing is the case for wages and materials.

Claims (7)

PATENT CLAIMS: i. Process for the recovery of lead from sulfur lead ores, such as galena or sulfidic lead coincentrates, in which the lead is freed from its compound mainly by aluminum, characterized in that waste full of aluminum or aluminum alloys or intermediates of all kinds, e.g. B. Turning or Bdhrspäne, Seiger residues, Krätze.n or scrap, such as aircraft scrap, can be used. 2. Process @nmch Claim i, characterized in that the reaction is carried out at temperatures in which, on the one hand, only insignificant evaporation of the lead formed takes place, but on the other hand the resulting aluminum sulfide-containing slag easily from the lead and withdrawn from the reaction chamber. 3. Procedure. according to claim i and 2, characterized in that the speed of the reaction by adding thinning reaction-inhibiting substances or by the grain size of the reactants being affected. 4. The method according to claim i to 3, characterized in that is carried out with the exclusion of air or compliance with an inert gas atmosphere. 5. The method according to claim i to 4, characterized in that to achieve a good liquid slag the temperature briefly by charging relatively large amounts of Beschic'kttngsniaterial is increased to about 1200 to 1300 ° C. 6. Oven, preferably hearth or short drum oven, for the method according to claim i to 5, characterized in that it is made with dolomite or magnesite stones or ramming masses is lined. 7. The method according to claim i to 5, characterized in that the resulting fly ash is returned to the process or a separate processing is subjected. B. The method according to claim i to 5 and 7, characterized in that that the lead is continuously withdrawn from the furnace used for the reaction.