SE413105B - RABLY REFINING PROCEDURE - Google Patents

Description

_- 7807358-2 substances must therefore be removed from the crude lead. Also usually included also gold and silver in the raw lead.

Irrespective of the production method of crude lead, this lunda is refined to a sufficiently clean final lead shall be obtainable. Usually the refining takes place in so-called pots of various types, specially designed for refining on said pollutants. A special problem in such a refining constitutes copper contained in the crude lead, but also Current arsenic and antimony can cause problems. Arsenic and antimony, may be present in amounts up to about 15%, leading to formation of very large amounts of solid powder products such as floats up to the metal surface during refining. This so-called dress, complicates the further handling of the raw light melt.

In cases where larger amounts of copper are included in the lead raw materials, it is important to be able to effectively remove the copper at an early stage stage in the process of not making it more expensive by it complicates the further treatment of lead to refined lead and because the copper content represents a significant metal value.

According to the invention, crude lead is produced from copper-containing lead articles of metallic, oxidic, sulphate or sulphide type by melting in an oven in which turbulence of the contents can produced, whereby the lead raw material is melted in the presence of slag-forming re and reduced, after which a slag is removed. The new procedure it is characterized by the fact that the crude lead melt formed during strong turbulence 1 said oven after slag removal is cooled to a temperature above the liquidus point of the lead melt but below about 700%, preferably below 500%, after which copper is separated on cooling. rich phase and the crude lead melt are separated.

When smelting lead raw material containing e.g. arsenic, antimony and copper, arsenic and antimony can be extracted as a spice. One "speiss" is a compound of arsenic and / or antimony with iron metals and copper, ie a "speiss" may consist of arsenides and / or antimonides of one or more of the metals copper, 7807358-2 iron, nickel and cobalt. Possible contaminants of arsenic or antimony is therefore removed by adding to the melt below heavy turbulence is carried iron in metallic, finely divided form or caused to form in situ, after which it in the lead melt formed insoluble iron stove is separated from the crude lead melt in direct connection to a gravitational separation of speiss and crude lead, after which copper is separated and separated. If so iron in the form of powder, shavings or finely divided pieces a practically insoluble iron in the lead melt will arsenic or iron - antimony - speiss to form. With iron in finely divided form is meant metallic iron in such a form that a good contact surface against the lead melt can be obtained and that the iron can is added to the lead melt in a simple manner. Speissen, that is practically insoluble in lead at prevailing temperatures, easily and can be peeled off, preferably at a temperature of 850-1200¶. The iron can also be added as an iron alloy containing 60% iron or more. The iron additive can do this adjusted so that only a part of the arsenic content forms one iron ore and an amount of arsenic are left in the lead melt corresponding to a molar ratio of copper to arsenic of at least 1.17 in order for copper to be able to form a copper fireplace, which is light can be treated for the extraction of copper and arsenic. Here came. more possibly present tin to remain in the crude lead melt.

However, the copper content of the lead raw material is greatest the part to remain in the crude lead melt but can as mentioned above after cooling the melt under strong turbulence to a temperature above the melting point of the lead melt but below about 700% separated in the outstretched form, as metallic copper and / or speiss after which raw lead is drained and recovered.

The cooling of the crude lead melt can take place by adding samples. additional oxidic or sulphate lead raw material or crushed iron silicate slag. Also addition of slag formers for a subsequent melting cycle can be used to cool the crude lead melt.

The cooling can alternatively take place by adding water in liquid, fine distributed form is sprayed directly onto it during turbulent stirring being the crude lead melt. _ 7807358-2 It is not necessary to cool the raw lead melt every time as one new batch of lead raw material melted down, and removal of slag as well any iron-arsenic-speiss occurred. You can thus fill the oven with a crude lead melt and then extract the copper-containing phase, after which the furnace is poured on crude lead and copper-containing phase tages.

The melting, possible spice formation and copper precipitation takes place in an oven, where the melt can be processed under heavy turbulence.

Such an oven is suitably a top-blown rotatable converter, e.g. pelvis and s.k. called TBRC? or a cold furnace. A TBRC or cold oven can be rotated at a speed of 10 to 60 revolutions per minute and the selection of the appropriate rotational speed is controlled by the oven diameter. A suitable turbulence is obtained if the inside of the furnace moves with a peripheral velocity of 0.5 - 7 m / s, preferably 2 - 5 m / s, which enables the melt to follow the rotation of the furnace inside and falls to the bathing surface like a drizzle, which leads to a very good contact between solid phase, liquid phase and gas phase. Such good contact is a prerequisite for fast chemical and physical processes, such as reduction processes, cooling separation and excretion. Dust formation is surprisingly avoided to a large extent by the drizzle raining down dust which otherwise would go out of the furnace with reaction gases.

Example 1 30 tonnes of oxy-sulphate lead raw material pellets originating from copper converter dust with the following analysis, Pb 35%, As 3.5%, Cu 1.15%, S 6.0%, Bi 1.20%, Au 0.5 mg / kg, Ag 3.38 mg / kg, melted together with 9.6 tonnes of granulated fajalite slag (iron-silicate slag from a copper slag incinerator) and 3.5 tonnes of fine distributed limestone in a top-blown, rotating converter of cold type with an inner diameter of 2.5 m by means of an oil-oxygen burner to form a raw bath and slag. After melting The slag and crude lead bath were reduced by an additional 1.9 tonnes of coke its lead content in the slag was about 1.5% at a temperature of about 1100%, after which the slag was dropped. IN * (Top Blown Rotary Converter) 7807358-2 During severe turbulence, 2.25 tonnes of crushed iron were then added. silicate slag at which the crude lead melt temperature, for a period of time of 60 minutes, was reduced from 1100¶ to about 850% with a copper-containing phase was separated. This phase was then separated from crude lead melt, the copper content of which was thereby reduced from 5% to 1.5% - A part of the crude lead melt thus obtained was continued to be cooled strong turbulence further down to 400%, with further copper-containing phase could be separated and separated. In the crude lead melt a copper content of 0.2% was obtained. Example 2 30 tonnes of pellets of oxidic-sulphate lead raw material with the same composition as in Example 1, was melted together with 9.6 tonnes of zeroed faience slag and 3.5 tonnes of finely divided limestone in a top blown, cold-type rotary converter with an inner diameter of 2.5 m by means of an oil-oxygen burner to form a raw lead bath and a slag. After melting, the slag was reduced and the crude lead bath with 1.9 tonnes of coke until the lead content in the slag was about 1.5%, g at a temperature of about 1100%, after which the slag was dropped.

Water in finely divided form was then injected directly into it turbulently stirred crude lead melting, its temperature below one time of 60 minutes was reduced from 1100% to about 650% and whereby a copper-containing phase was separated. This phase was separated from the crude lead melt, whereby the copper content was reduced from 5% to 1.5%.

Example 3 30 tons of pellets of oxidic-sulphate lead raw material with composition according to Example 1, was melted together with 9.6 tons of granulated fajalitslag and 3.5 tonnes of comminuted limestone in a top-blown, roto-type rotary converter with an inner diameter of 2.5 m using an oil-oxygen burner to form a crude lead. bath and a slag. a '7807358-2 After melting, the slag and crude lead bath were reduced by 1.9 tons coke until the lead content in the slag was about 1.5% at a temperature temperature of about 1100¶, after which the slag was dropped. 2.25 tons of crushed ferrous silicate slag was then added to the turbo1ent_ stirred the crude lead melt at its temperature for a period of time of 60 minutes was reduced from 1100% to about 850% and a copper containing phase was separated. Râbly melt, whose copper content decreased from 5% to 1.5% together with the iron silicate slag was retained in the furnace. Additional re 3O tonnes of oxidic-sulphate lead raw material and 3.5 tonnes comminuted limestone was charged and melted together with the copper was dropped, while the copper-containing phase phase and the iron silicate slag. The slag obtained and raw the lead bath was reduced by 1.9 tonnes of coke to its lead content in the slag was about 1.5% at a temperature of about 1100¶, after which the slag was dropped. During vigorous turbulent stirring of the crude lead melt obtained was added an additional 2.25 tonnes of crushed ferrous silicate slag, at which the crude lead melt temperature, below one time of 60 minutes, was reduced from 1100¶ to about 850% and a larger amount of copper-containing phase was obtained. This larger amount copper-containing phase could be separated from the crude lead melt with less lead losses than when only a freezing with iron silicate slag was performed. A significant time saving per tonne of lead produced was also done because only one freeze was required.

This process of retaining the copper-containing phase should, of course, continue until one takes into account the conditions appropriate quantity of copper-containing phase was obtained.

Example 4 30 tonnes of oxidic-sulphate lead raw material with a composition according to Example 1, was fused together with 9.6 tonnes of granulated fajalite slag and 3.5 tonnes of comminuted limestone in a top-blown, rotating the kaldo-type converters with an inner diameter of 2.5 m with using an oil-oxygen burner to form a crude lead bath and a slag.

After melting, the slag and crude lead bath were reduced by 1.9 7807358-2 tons of coke until the lead content in the slag was about 1.5%, at a temperature of about 1100%, after which the slag was dropped.

The crude lead thus obtained held 7% As and 3% Cu. 3 tons of iron in metallic, finely divided form was added to the turbulently stirred crude lead melt for the formation of an iron stove at about ~ 1000% which was then dropped off in liquid form.

Then crushed ferro-silicate slag was added vigorously turbulence of the crude lead melt as in Example 1, the temperature immersion was obtained, the copper-containing phase was separated and separated from the raw lead melt. A

Claims (12)

a '7807358-2 10 20 25 30 35 PATENTKRAV Process for the production of crude lead from copper-containing lead raw materials of metallic, oxidic, sulphate or sulphide type, by melting in an oven, in which turbulence of the contents can be effected, the lead raw material being melted in the presence of slag formers, and reduced, after which a slag is deduced, characterized in that the lead melt is cooled under high turbulence in said furnace after the slag removal from melting temperature to a temperature above the lead melting point of the lead melt but below about 700%, after which the copper-containing phase separated during cooling and the crude lead melt are separated. A method according to claim 1, characterized in that the lead melt is cooled to a temperature below about 500%. Process according to Claim 1, characterized in that an oxidic or sulphate lead raw material or crushed iron silicate slag is used as coolant. 4. A method according to claim 1, characterized in that said slag former is used as coolant for a subsequent melting of lead raw material. 5. A method according to claim 1, characterized in that the cooling takes place by spraying water in liquid, finely divided form directly against the crude lead melt present during turbulent stirring. 6. A method according to claim 1, characterized in that separated copper-containing phase is retained in the furnace for at least one further melting cycle. 7. A method according to claim 1, characterized in that melting and copper elimination take place in a rotating, inclined kiln of Kaldotype. 10 15 20 25 7807358-2 Process according to claims 1-7, characterized in that any impurities of arsenic in the lead raw materials are at least partially removed by, after slag removal to the melt under heavy turbulence in said furnace, iron is introduced into metallic, atomized form or caused to form in situ , after which the insoluble iron stove formed in the lead melt is separated from the crude lead melt in direct connection with a gravitational separation of the lead and raw lead, after which copper is separated and separated. 9. A method according to claim 8, characterized in that iron is added in the form of chips, powder or finely divided pieces. 10. A method according to claim 8, characterized in that the iron is added in the form of an iron alloy containing more than 60% iron. 11. A method according to claim 8, characterized in that the iron is formed in situ by the addition of silicon, silicides, carbon or ferroalloys with silicon or carbon in such an amount that iron present in the slag is extruded in metallic form before the slag is peeled off. 12. A method according to claim 8, characterized in that the tip is peeled off at a temperature of 850-1200%. vàovzss-2 Abstract Process for refining crude lead from copper-containing, possibly also arsenic-containing lead raw materials of metallic, oxidic, sulphate or sulphidic type in an oven in which turbulence of the contents can be produced, preferably in a top-blown rotary converter, for example of cold type. According to the invention, it is cooled to a temperature below about 700% in the crude lead melt after reduction and slag removal under heavy turbulence to precipitate a copper phase or a copper fireplace. Oxydic or sulphate lead raw materials, crushed iron-silicate slag, slag builders and as a preferred process water in liquid finely divided form can be used as coolant. Larger amounts of arsenic can be removed before cooling by forming an iron stove by adding or forming in situ iron in the crude lead melt.