RU2523034C1 - Refining of black lead refining of copper - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: proposed method comprises coarse copper extraction by liquidation and fine copper extraction at the melt temperature of 335-345°C. Said fine copper extraction is carried out by introduction of sulphur into the melt to obtain the chemical compound, melt mixing and removal of chemical compound as the output. Sulphur is heated to 130-150°C and introduced in the melt bottom part in liquid state.

EFFECT: lower sulphur input, non-polluting process.

1 dwg, 1 ex

Description

The invention relates to ferrous metallurgy and can be used in the refining of rough lead, battery scrap, secondary lead and lead secondary alloys.

A known method of refining lead (SU 901317, publ. 30.01.1982), including the melting of lead, decontamination by treating the melt with iron-containing material, which is used clinker Waelz kiln with 3-4-5-fold consumption of metallic iron in relation to the content of arsenic in lead.

The disadvantage is the need for subsequent refining of lead from impurities contained in the clinker.

A known method of refining crude lead or lead alloys from copper (US Pat. RU No. 2323987, publ. 05/10/2008), including the melting of crude lead or lead alloy, the introduction into the melt of pre-heated to 80-120 ° C metallic zinc, forming with copper compound, at a melt temperature of 410-450 ° C, subsequent mixing of the melt and removal of the resulting chemical compound in the form of a removal.

The disadvantages are the need for subsequent refining of lead from metal and overheating of lead above the melting point of zinc, i.e. additional energy costs.

There is a method of refining crude lead from copper (decimation) (Production of non-ferrous metals. NI Utkin. - M .: Intermet Engineering, 2002 - S.247-248), adopted as a prototype and including coarse de-separation by segregation and thin de-separation at a melt temperature of 335-345 ° C, carried out by introducing into the melt sulfur, forming a chemical compound with copper, mixing the melt and removing the resulting chemical compound in the form of a removal.

The disadvantage is the high consumption of sulfur, the formation of a large amount of sulfur dioxide over the bucket.

The technical result of the invention is to reduce the consumption of sulfur and reduce emissions into the environment of a harmful substance - sulphurous anhydride.

The technical result is achieved in that in a method for refining crude lead from copper, including melting crude lead, coarse demineralization by segregation and fine demineralization at a melt temperature of 335-345 ° C, carried out by introducing sulfur into the melt, forming a chemical compound with copper, mixing the melt and removing the resulting chemical compounds in the form of removal, sulfur is heated to a temperature of 130-150 ° C and introduced in a liquid state into the lower part of the melt.

Heating sulfur to a temperature of 130-150 ° C provides optimal viscosity (fluidity) of molten sulfur. When sulfur is heated below 130 ° C, the viscosity of sulfur is high. Also, when sulfur is overheated above 150 ° C, the viscosity and, accordingly, the energy consumption for its supply to molten rough lead sharply increase.

The introduction of sulfur in a liquid state into the lower part of the melt ensures a uniform dissolution of sulfur in the entire volume of molten crude lead, an effective reaction of the formation of copper sulfide, which is removed in the form of removal, i.e. reducing sulfur consumption, as well as preventing contact of sulfur with the environment, therefore, reducing the formation of significant emissions of sulfur dioxide.

The method of refining rough lead from copper is illustrated by the schematic diagram in figure 1, which shows: 1 - capacity for rough lead; 2 - heater; 3 - removable cover; 4 - mixing device; 5 - thermal insulation pipeline; 6 - dosing pump; 7 - pipeline; 8 - consumable capacity for molten sulfur.

The method is as follows. The container for refining rough lead 1 is installed in the heater 2. The rough lead is heated and the temperature of molten lead is maintained at 335-345 ° C. On top of the tank 1, a removable cover 3 is installed complete with a mixing device 4, a heat-insulated pipe 5 and a metering pump 6, to which a pipe 7 is previously connected to supply molten sulfur from the supply tank 8 at a temperature of 130-150 ° C. In the supply tank 8, sulfur is heated to a temperature of 130-150 ° C due to steam or other heat source. From the supply tank 8, molten sulfur is introduced at a temperature of 130-150 ° C using a metering pump 6 into the lower part of the melt of the tank 1 under a mixing device 4. Liquid sulfur is introduced when the mixing device 4 is operating.

Example 1. In a container made of heat-resistant steel, 10 kg of crude lead containing 0.1% (mass.) Copper was heated to a temperature of 340 ° C, a stirrer (mixer) was installed and solid granular sulfur was fed for 10 minutes into a funnel formed in rough lead by a mixing device. The copper content of debonded lead is 0.005%. The consumption of solid sulfur was 0.01 kg. During decontamination, the formation of sulfur dioxide is noticeable.

Example 2. Under the same conditions, pre-molten sulfur was supplied to the molten lead in the lower part of the vessel under the mixer at a temperature of 140 ° C for 10 minutes. The copper content of debonded lead is 0.005%. The consumption of pre-molten sulfur was 0.008 kg. The formation of sulfur dioxide is minimal.

Thus, the method allows to reduce the consumption of sulfur and reduce the release into the environment of a harmful substance - sulphurous anhydride.

Claims (1)

A method of refining crude lead from copper, including coarse decontamination by segregation and fine deaeration at a melt temperature of 335-345 ° C, comprising introducing sulfur into a vessel with a melt, forming a chemical compound with copper, mixing the melt and removing the sample in the form of the aforementioned chemical compound, characterized in that sulfur is heated to a temperature of 130-150 ° C and introduced in a liquid state into the lower part of the vessel with the melt with melt stirring.

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