RU2017840C1 - Galvanic production slims processing method - Google Patents

Abstract

FIELD: nonferrous metallurgy. SUBSTANCE: slims, fusing agents and carbon containing reducing agent are charged on surface of oxide molten bath. Oxygen enriched air blast is permanently fed in and over molten bath. Melting process is going under temperatures of 1200 - 1400 C. Blast oxygen amount, fed in molten bath, is 1.0 - 1.8 from theoretically required to oxidize charge carbon to get carbon oxide II. Amount of charge carbon containing reducing agent is 1.0 - 1.2 from theoretically required to reduce zinc, copper, cobalt and nickel of charge to get metals with carbon oxide II formation and to support heat balance of the process. 0.4 - 1.0 amount of oxygen from theoretically required to oxidize charge carbon and hydrogen to get carbon oxide IV and water is fed over molten bath. Feeding of carbon containing fuel in molten bath is possible. In the case oxygen amount in blast, fed in molten bath, is 1.0 - 1.7 from theoretically required to oxidize charge carbon and blast to get oxide II and hydrogen - to get water. EFFECT: method is used in nonferrous metallurgy. 2 cl, 2 tbl

Description

 The invention relates to methods for processing industrial and domestic waste and can be used in non-ferrous metallurgy for processing secondary raw materials.

 A known method of processing sludges containing non-ferrous metals, including the loading of sludge, fluxes and a carbon-containing reducing agent, their reduction melting to produce slag, a metal alloy and gaseous products. In accordance with this prototype method, sludges of electrolytic refining of copper are subjected to reduction smelting. As a reducing agent, carbon-containing agents are used in an amount of 1-4 wt.% Sludge. Fluxing additives are Si-containing compounds and lime.

 The disadvantage of the prototype method is that during processing only non-ferrous metals that have a high vapor pressure of metals or compounds are extracted from it. At the same time, nickel, copper and other valuable components are contained in the slurries of galvanic production. In value terms, they can prevail over zinc, lead, cadmium and indium recoverable into sublimates. In the presence of an organic fraction in the sludge, it is partially decomposed and removed with gases, often with the formation of carcinogens, for example benzopyrene.

 The purpose of the invention is to increase the complexity of the use of raw materials.

The goal is achieved in that the sludge loading, fluxes and a reducing agent is carried on the surface of the oxide melt, the melting is carried out at 1200-1400 ° ^C under an oxygen-containing feed into the melt and the blowing of the melt, the amount of oxygen in the air blast supplied to the melt is maintained at the rate of 1 , 0-1.8 from theoretically necessary for the oxidation of carbon in the charge to carbon monoxide (II), the amount of oxygen in the blast above the melt is maintained at a rate of 0.4-1.0 from theoretically necessary for the oxidation of carbon and hydrogen with organic stavlyayuschey load to carbon oxide (IV) and water, the amount of carbonaceous reductant in the feed rate of 1.0-1.2 is maintained by the theoretically required for recovery of zinc oxide, copper, cobalt and nickel in the feed to metals.

 In addition, carbon-containing fuel is supplied to the melt together with oxygen-containing blast in an amount necessary to maintain heat balance, and the amount of oxygen in the blast is maintained at a rate of 1.0-1.7 from theoretically necessary for the oxidation of carbon in the charge and blast to oxide (IV ) and water.

 The essence of the proposed method consists in the fact that the sludge, reducing agent and fluxes necessary for slag formation are subjected to pyrometallurgical processing in a bubble machine such as the Vanyukov furnace. In this case, due to the selection of process conditions (gas phase composition, temperature, blasting mode), the reduction of oxides to metals and sublimation of volatile metals and compounds is achieved. As a result, zinc, lead, cadmium, bismuth are removed with gases sparging the melt, and nickel, cobalt and copper, being restored, form droplets of metal alloy deposited in the slag formed by sludge components and fluxes. At the bottom of the metallurgical unit, they form an alloy layer, which alone or together with the slag is released from the metallurgical unit. In the latter case, the slag and alloy can be separated in a separate unit, such as an electric furnace. The alloy can be independently processed to produce marketable products, such as cupronickel, and can be sent to the last stage of the conversion of sulfide copper-nickel raw materials. Gases containing vapors of zinc, lead, bismuth, their compounds and other volatile components, as well as the decomposition products of the organic component of sludge and mechanical dust removal are subjected to oxygen-containing blasting with the complete oxidation of all organic compounds to carbon dioxide and water. From the obtained gases, sublimates of non-ferrous metals can be effectively captured by existing gas-cleaning equipment with the subsequent receipt of marketable products. In this case, the main role in the afterburning of organics is played by the process temperature, the value of which, with a sufficient amount of oxygen in the blast on afterburning, ensures the completeness of oxidation of the organic component to carbon monoxide (IV) and water. Slags obtained in the process are non-toxic and can be used in the production of building materials.

 The method is as follows.

Reducing sludge with a reducing agent and fluxes are loaded into a metallurgical unit, for example, Vanyukov’s furnace, on the surface of a slag melt sparged with oxygen-containing blast. Preliminary preparation of raw materials for smelting is possible, including drying and pelletizing or briquetting with a reducing agent and fluxes to reduce dust extraction. By maintaining a certain ratio of oxygen in the blast to the theoretically necessary, incomplete oxidation of the loading carbon occurs with the creation of the necessary oxygen melting potential (CO ₂ / CO ratio) according to the reactions
2C + O ₂ = 2CO (1)
C + O ₂ = CO ₂ (2) and at the same time reduction of non-ferrous metals by reactions
Cu ₂ O + CO = Cu + CO ₂ (3)
NiO + CO = Ni + CO ₂ (4)
ZnO + C = Zn + CO (5), etc.

 Volatile non-ferrous metals and their compounds, as well as products of incomplete decomposition of organics and part of the charged metals are carried away by the process gases and carried away with them. In the immediate vicinity of the melt surface, oxygen-containing blast is supplied through special tuyeres. By supplying a sufficient amount of oxygen and the optimum process temperature, it is possible to completely clean the components of the organic component to carbon monoxide (IV) and water. Compounds of non-ferrous and rare metals: zinc, lead, bismuth, indium, etc. are fairly well captured from gases by existing methods, therefore, gases sent to the atmosphere do not pose an environmental hazard. At the same time, the recovery and bubbling process provides a fairly complete extraction of volatile compounds in gases, i.e. high complexity of the use of raw materials. This is facilitated by the fact that copper, nickel and cobalt, being restored, pass into the alloy. The resulting particles of these metals are cobalized in the oxide melt sparged by the gases and settle, forming this alloy on a copper-nickel basis. Slag is formed due to oxide components, sludge and fluxes, the amount and composition of which is selected so that the slag has a fairly low melting point and viscosity, as well as a composition that ensures minimal loss of non-ferrous metals. From the metallurgical unit, slag is discharged continuously through a siphon or as it accumulates through holes. The metal alloy is produced through a hole or together with slag, followed by separation in an electric sump. It is sent either to self-processing with the extraction of non-ferrous metals, or to processing by other known methods, for example, to the last stage of the conversion of copper-nickel mattes. Captured sublimates of non-ferrous metals can also be processed in a known manner.

PRI me R 1. For smelting in the pilot furnace Vanyukov was fed slurries of galvanic production composition, wt.%: CuO 12,0, NiO 5,46; CoO 0.3; Fe ₂ O ₃ 16.2; S 4.33 (sulfate); Cr ₂ O ₃ 2.4; MgO 5.6; PbO 2.23; CdO 0.15; ZnO 5.74; CaO 24.3; Al ₂ O ₃ 4,2; organic fraction - 12.7% (average composition of C ₆ H ₅ ); the rest is other. The furnace is a coffered unit with a hearth area in the tuyere section of 0.7 m ² . The initial data were burdened with flux-sand containing 95%, poured and loaded into the furnace. The moisture content of the sludge is 8-12%. The charge was loaded onto the surface of the oxide melt, into which blast was fed through tuyeres with an oxygen content of 65-95%. The oxygen content in the blast controlled the process temperature. Above the surface of the slag melt, technical oxygen was supplied through tuyeres to burn off products of incomplete combustion of organics and sublimated sulfides of non-ferrous metals. The temperature of the process (the melt in the zone of oxygen supply into it) was controlled by periodic immersion of thermocouples. Slurry loading capacity in all experiments was 1 t / h. Gases were cleaned of dust in electrostatic precipitators and a wet gas purification system. Slag was discharged through a siphon into an electric sump. The alloy was released through a hole in the bottom of the furnace. Smelting products were analyzed for non-ferrous metals.

 To reduce the oxides of copper, nickel, zinc, lead and cadmium contained in the sludge, it is estimated that 0.04 t / h of carbon in the charge is required. Given the need to maintain the heat balance of the furnace, in addition to the organics contained in the charge, a charge of 50 kg / h of coke containing 80% carbon was required. In the experiments, the amount of coke was varied and it was up to 90 kg / h according to the proposed method, which ensured the stable operation of the process and corresponded to the declared limits. It should be noted that the organic matter contained in the sludge plays the role of a reducing agent of non-ferrous metal compounds.

Slag contained 30-32% SiO ₂ ; 18-23% CaO; 16-18 FeO; 4-5% Al ₂ O ₃ ; 7-9% (MgO + Cr ₂ O ₃ ). When working on the proposed method, it contained 0.2-0.4% nickel; 0.3-0.5% copper; 1-2% zinc; 0.02-0.04% Co; traces of lead and cadmium. The metal alloy contained 50-60% copper; 20-25% nickel; 1-2% cobalt; 0.2-0.3% lead; 10-15% iron; 1-2% sulfur. Sublimates contain 40-50% zinc; 18-20% lead; 1.5-2.6% cadmium.

 The results of the experiments are given in table. 1, which also presents the results of processing sludge of this composition in a Waelz kiln according to the prototype method. Compared with the prototype method, not only an increase in the extraction of lead, zinc, cadmium is achieved, but also copper, nickel and cobalt are additionally extracted. In addition, the proposed method is more environmentally friendly.

 PRI me R 2. Processing were subjected in the same furnace sludge of the specified composition. Instead of coke, natural gas was supplied through special tubes in tuyeres for oxygen supply as a reducing agent and coke (98.5%). Slurry capacity was 1 t / h.

The results are given in table. 2. The amount of natural gas in all experiments was 50 nm ³ / h, which, taking into account the organic component, corresponded to Q _pr ^ang.in / Q _t ^ang.in = 1.1.

The ratio of V _n ^pr / V _n ^t in all experiments was maintained equal to 0.7 and the oxygen supply over the melt was 260 nm ³ / h. The temperature of the process was 1280-1300 ^about C. The results are given in table. 2. The analysis of tabular data shows that in this case, the best indicators are achieved when working on the proposed method within the claimed limits.

 Using the proposed method allows: to ensure the comprehensive use of raw materials, extracting a number of non-ferrous metals: nickel, copper, cobalt into an alloy suitable for further processing; to create an environmentally friendly technology for processing sludge from galvanic production, eliminating the formation of toxic waste; to increase the extraction into sublimates from the raw materials of this type: zinc - by 7.0-12.2%; lead - by 17-20%; cadmium - by 13.7-25.3%.

Claims (2)

1. METHOD FOR PROCESSING Sludge from galvanic production, including loading sludges containing non-ferrous metal compounds and an organic component, fluxes and a carbon-containing reducing agent, their reduction melting to produce slag, a metal alloy and gaseous products, characterized in that, in order to increase the complexity of use of raw materials, sludge, fluxes and reducing agent are loaded onto the surface of the melt, melting is carried out at 1200 - 1400 ^o With the supply of oxygen-containing blast into the melt and over the melt m, and the amount of oxygen in the blast supplied to the melt is maintained at a rate of 1.0 - 1.8 from theoretically necessary for the oxidation of carbon in the charge to carbon monoxide (II), the amount of oxygen in the blast above the melt is maintained at a rate of 0.4 - 1.0 from the organic component of the charge theoretically necessary for the oxidation of carbon and hydrogen to carbon monoxide (IV) and water, the amount of carbon-containing reducing agent in the charge is maintained at a rate of 1.0 - 1.2 from the theoretically necessary for the reduction of zinc, copper, and cobal oxides and that nickel metal is loaded up.  2. The method according to claim 1, characterized in that the carbon-containing fuel is supplied to the melt together with an oxygen-containing blast in an amount necessary to maintain thermal balance, the amount of oxygen in the blast being maintained at a rate of 1.0 - 1.7 from the theoretically necessary for oxidation carbon in loading and blasting to oxide (IV) and water.

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