RU2181781C2 - Method for complex processing of polymetallic raw materials - Google Patents

Abstract

FIELD: non-ferrous metallurgy, possibly processing of plumbum, antimony, polymetallic and gold-containing sulfide concentrates. SUBSTANCE: method for complex processing of polymetallic sulfide raw materials of heavy, non-ferrous and noble metals comprises steps of their separate melting in furnace with deep bath at presence of mixed salts of alkali metals and carbon-containing reducing agent for receiving rough metals to be further processed by well known methods, slag, matte or slag-matte melts; using slag-matte melts after melting plumbum raw material as flux for melting antimony raw material; using matte or cake after leaching matte of melting antimony raw material as raw material at melting plumbum or noble metal raw material; blending plumbum raw material and raw material of noble metals with mixture including soda ash and(or) potash; feeding it for melting in order to produce crude plumbum concentrating noble metals, and slag-matte melt supplied for melting antimony raw material; blending antimony raw material with slag-matte melt after melting plumbum raw material and feeding for melting in order to receive slag, matte and crude antimony; feeding matte for melting plumbum raw material. Antimony raw material also may be melt to slag and matte. Matte is subjected to processing by well known methods for receiving solution of antimony and cake fed for melting plumbum raw material. Plumbum raw material may be blended with soda ash; produced slag-matte melt is supplied to ore cycle at plumbum-zinc flotation. Plumbum raw material may be also melt in mixture with potash; and then produced slag-matte melt is fed for obtaining sulfatepotassium fertilizers. EFFECT: enhanced ecology, increased degree of complex use of raw materials, improved economical factors of processing antimony raw material. 6 cl, 5 tbl, 9 ex

Description

 The invention relates to the field of metallurgy of non-ferrous metals, in particular to processes for processing lead, antimony polymetallic and gold-containing sulfide concentrates.

A known method of processing sulfide lead concentrates (1), according to which the processing of concentrates is carried out by electric melting with an alkali metal salt and coke when the melt is heated in a furnace with a coke layer 5-20% high of the melt height at 900-1000 ^o C for 10-20 minutes. As a result of processing high-quality lead concentrates by this method, crude lead (metal) and slag matte are obtained. Raw lead is subjected to refining by known methods with the release of concentrates of valuable components of rough lead and obtaining branded lead.

 The disadvantages of this method include the lack of methods for the disposal of slag matte melt with the extraction of valuable components, in particular zinc and water-soluble compounds of alkali metal, which leads to environmental degradation in the area of storage of slag mattes.

A known method of processing sulphide antimony concentrates and antimony intermediate products (2), according to which the processing of antimony raw materials is carried out by smelting with soda ash and a carbon-containing reducing agent at 1100-1200 ^o C for 20-40 minutes As a result of the processing of antimony raw materials, rough antimony (metal), slag and matte are obtained. Antimony is subjected to refining by known methods to obtain branded antimony and the allocation of concentrates of antimony.

 The disadvantages of this method include the lack of methods for the disposal of slag and matte containing water-soluble components and sent to the dump, which leads to environmental degradation in places of storage.

There is also a method of processing antimony raw materials (3), according to which the processing of antimony raw materials is carried out by melting with sodium sulfate and a carbon-containing reducing agent at 1100-1200 ^o C for 20-40 minutes As a result of processing antimony raw materials, slag and matte are obtained. Slag concentrating waste rock components is sent to the dump, and matte, into which sulfides of heavy non-ferrous and precious metals are transferred, is sent for processing by known methods associated with leaching antimony into a sulfide-alkaline solution. The resulting solution is sent to the electroextraction of antimony, and the cake containing the remaining non-ferrous and precious metals is sent for processing together with lead raw materials.

 The disadvantage of this method is the need to use sodium flux sulfate as a flux with an additional consumption of a reducing agent to reduce sodium sulfate to sulfide, which affects the economic performance of the process.

 The objective of the invention is to develop an effective method for complex processing of polymetallic raw materials.

 The technical result achieved in the method consists in improving the environmental situation, increasing the complexity of the use of raw materials and economic indicators of the process of processing antimony raw materials.

 The specified technical result is achieved by the fact that in the method of complex processing of polymetallic sulfide raw materials of heavy and precious metals, including separate melting of lead raw materials in a mixture with precious metal raw materials in the presence of an alkali metal salt and a carbon-containing reducing agent to obtain subject to further processing of crude metal, slag, matte or slag matte melt, slag matte melt from smelting lead raw materials in a mixture with precious metal raw materials is used as a flux for melting su myanogo raw material and the matte or cake obtained from the leaching of smelting matte antimony raw material, used as raw materials in the smelting of lead in admixture with dragmetallnym feedstock. At the same time, lead raw materials, together with precious metal raw materials, are blended with soda ash or potash before smelting and fed to smelting to produce crude lead concentrating precious metals and cinder matte directed to the smelting of antimony raw materials.

 Before melting, the antimony raw materials are blended with slag matte from the smelting of lead raw materials and fed to the smelting to produce slag, rough antimony and matte directed to the smelting of lead raw materials. Antimony raw materials are also smelted and matte leached to produce an antimony sulfide-alkaline solution of cake and cake directed to the melting of lead raw materials mixed with precious metal raw materials.

 As lead raw materials, lead zinc-containing raw materials are used, which are blended with soda ash and fed to the smelting to produce crude lead and stein slag melt, sent to the ore cycle of lead-zinc flotation. Lead raw materials are also laden with potash and fed for smelting to produce rough lead and cinder mat slag sent to the production of sulfate-potash fertilizers.

 The proposed method is as follows. Sulphide concentrate of precious metals is mixed with sulphide lead concentrate or with secondary lead-containing raw materials (oxide-sulphate fraction from cutting batteries, paste for coating battery plates, charcoal, alkaline alloys from lead refining and other removals).

The resulting mixture is blended with soda or potash, a reducing agent (coke) and served for melting in a reflective or electrothermal furnace at 900-1100 ^o C.

 The consumption of soda or potash in relation to raw materials is regulated depending on the content of sulfur and slag constituents in the raw materials. The reducing agent (coke) is fed based on maintaining at least 40 mm thick a recovery layer on the surface of the liquid bath.

 In the smelting process, lead is reduced from raw materials to metal, collecting precious metals and bismuth.

 A metal with a high specific gravity is lowered into this part of the furnace - on the bottom, and the slag constituent components of raw materials and sulfur in the form of alkali metal salts form a lighter phase - a cinder mat located above lead. After the liquation is kept in the melt at a given temperature and time, separate release of lead and slag matte is produced.

The resulting slag matte melt, depending on its composition, is directed:
- On the charge before smelting antimony raw materials with the production of slag, rough antimony and matte, sent to the smelting of lead raw materials in the case of melting low-sulfur lead raw materials. In this case, the slag matte fed to the batch contains carbonate-sulfate salts of alkali metals.

 - On the charge before the antimony raw materials are melted, the melting is carried out on slag and matte (antimony thiosalt melt), which is leached to obtain an antimony sulfide-alkaline solution (directed to the electrodeposition of cathode antimony) and a cake containing lead and noble metals, which is fed for smelting lead raw materials. At the same time, the slag stein supplied to the batch contains alkali metal sulfides, which are formed during the smelting of high-sulfur precious metal and lead sulfide raw materials.

 - In the ore cycle of lead-zinc flotation in the case when lead zinc-containing raw materials are used as lead raw materials. Zinc contained in the melt in the form of zinc sulfide passes into zinc concentrate, sodium sulfide works as a sulfidizer of oxidized metal ore. Components of waste rock and soda in the form of pulp with a high pH value (above 10) are sent to the tailings to increase the pH and reduce the content of lead and copper in waste water and eliminate cyanides and rhodanides.

 - For the production of sulfate-potassium fertilizers in the case when lead raw materials are mixed with potash before smelting. The resulting potassium sulfide melt is treated with sulfuric acid, arsenic and antimony trisulfides are planted and separated, and a potassium sulfate solution is used as fertilizer.

 Examples. The compositions of sulfide lead concentrates of the Salair and Gorevsky GOKs, antimony concentrate of the Sarylahsky GOK, gold-containing flotation concentrate of the Salair GOK, secondary lead-containing raw materials in the form of oxide-sulfate fraction from the cutting of scrap batteries are shown in table 1.

 Lead concentrates and flotation concentrate together with the oxide-sulfate fraction were melted in a mixture with technical soda ash from nepheline raw materials, or with technical potash.

Soda ash has the following chemical composition (wt.%): Na ₂ CO ₃ - 92.8; K ₂ CO ₃ - 3.8; Na ₂ SO ₄ - 2.8; Cl is 0.5.

Potash (wt.%): K ₂ CO ₃ - 94.0; Na ₂ CO ₃ - 3.6; K ₂ SO ₄ - 2.1; Cl is 0.3.

 Metallurgical coke with an ash content of 14 wt.% Was used as a reducing agent.

The melts were conducted in a crucible resistance furnace with a graphite-chamotte crucible with a diameter of 500 mm and a capacity of 60 dm ³ .

 The smelting included a set of bathtubs, refinement of the melt at a given technological mode, and separate release of lead and slag matte melt. The resulting melt was poured into steel molds, crushed into pieces of various sizes and packed in airtight containers.

 The parameters of the swimming trunks and their results are shown in table 2, the content of alkali metal sulfides and their oxides in slag matte floats from the melting of lead raw materials is also shown there.

 The resulting slag matte floats from swimming trunks 1, 2, 3 were lined with antimony raw materials for melting on rough antimony or on antimony matte.

 The smelting was conducted in the same furnace as the smelting of lead-containing raw materials. The smelting included a set of bathtubs, refinement of the melt at a given technological mode and separate release of slag, matte and, if available, rough antimony. The resulting matte was poured into steel molds, crushed into pieces of various sizes and packed in sealed containers.

 The parameters of the heats and the results are shown in table 2.

The matte from smelting antimony raw materials to antimony matte 7 was crushed into pieces with a particle size of 20-40 mm and leached in a sulfide-alkaline solution containing Na ₂ S - 100 g / dm ³ and NaOH - 40 g / dm ³ , at 80-90 ^o C and the ratio T: W = 1: 3. The resulting pulp was filtered off to obtain a solution of antimony and cake. The yield of the latter was 39.5% of the initial matte.

 The cake from leaching of matte from smelting 7, or the matte from smelting 6 was smelted together with lead concentrate of Gorevsky GOK for draft lead and cinder mat. The results are shown in table 2.

 The experiments on the processing of slag matte from melting lead concentrate of the Salair GOK mixed with soda ash were carried out in the conditions of the research laboratory of the Salair GOK on real pulps of the plant with mixing in the ratios of the estimated annual product formation.

Pieces of slag stein melt measuring 20-40 mm were subjected to dissolution in hot water at 90-105 ^o C. The resulting pulp was fed to the flotation of the original lead-zinc sulfide ore in an amount determined by the technological mode of the process and the content of sodium sulfide in the pulp. The tailings formed as a result of flotation were sent to the tailing dump in the form of pulp, from which solution samples were taken.

 The results of the experiments are shown in tables 3 and 4.

 Table 3 shows the comparative results of experiments on flotation of lead-zinc ore using pure sodium sulfide and slag matte melt pulp as a flotation reagent, taken in an amount providing 70 g of sodium sulfide per ton of ore. In the case of using melt, a conditioned zinc concentrate with a content of 55% zinc was obtained with the recovery of the latter at the level of 89.28%, which is 2.4% higher than the “factory” flotation regime. Lead concentrate contains 4% more lead with almost the same recovery. The content of silver and gold in lead concentrate is higher by 260 g / t and 14 g / t, respectively.

 Table 4 shows the effect of the solution from the slag matte melt supplied to lead-zinc flotation on the chemical composition of the pulp solution sent from flotation to the tailings dump. The data indicate that when slag matte melt is supplied to the flotation in the pulp solution, the content of copper and lead decreases and cyanides and rhodanides are eliminated from it.

 The slag matte melt from smelting 4 lead concentrate mixed with potash was leached, the resulting solution was separated from the cake and treated with sulfuric acid to obtain white potassium sulfate. The parameters of the processing of slag matte melt into potassium sulfate, as well as the extraction of arsenic and potassium into processed products are shown in table 5. The contents of arsenic and potassium in the processed products are also given there.

 Thus, the data given in the text and tables show the attainability of the technical result indicated in the description.

Sources of information
1. Copyright certificate of the USSR 1747521, cl. C 22 V 13/02, publ. 1992

 2. Melnikov S.M. and others. Antimony, Metallurgy, 1977, p. 243-248.

 3. Polyvyany I.R. and others. Combined method of processing antimony raw materials. Proceedings of the IM&O Academy of Sciences of the Kazakh SSR, vol. XXI, Alma-Ata, Science, p. 65-75.

Claims (6)

 1. The method of complex processing of polymetallic sulphide raw materials of heavy non-ferrous and precious metals, including separate melting of lead raw materials in a mixture with precious metals in the presence of an alkali metal salt and a carbon-containing reducing agent to obtain subject to further processing of ferrous metals, slag, matte or slag matte, characterized in that the slag matte melt from the melting of lead raw materials in a mixture with precious metals is used as a flux for melting antimony raw materials, and matte or and cake obtained from leaching of matte from the smelting of antimony raw materials is used as raw material in the smelting of lead raw materials mixed with precious metals.  2. The method according to p. 1, characterized in that before melting the lead raw materials are charged with soda ash or potash together with precious metal raw materials and fed to the smelting process to produce crude lead concentrating precious metals, and slag matte directed to the smelting of antimony raw materials.  3. The method according to p. 1, characterized in that before melting the antimony raw materials are blended with slag matte from the smelting of lead raw materials and fed to the smelting to obtain slag, rough antimony and matte, directed to the smelting of lead raw materials.  4. The method according to p. 3, characterized in that the melting of antimony raw materials is carried out on slag and matte, which is leached, to obtain an antimony sulfide-alkaline solution and cake fed to the melting of lead raw materials.  5. The method according to p. 2, characterized in that the lead raw materials use lead zinc-containing raw materials, which are blended with soda ash and fed to the smelting with obtaining lead and slag matte melt, sent to the ore cycle of lead-zinc flotation.  6. The method according to p. 2, characterized in that the lead raw materials are mixed with potash and fed for smelting to produce crude lead and slag matte melt, directed to the production of sulfate-potash fertilizers.

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