RU2705280C1 - Method for flotation separation of sphalerite and copper minerals from iron sulphides - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to concentration of minerals. Method for flotation separation of sphalerite and copper minerals from iron sulphides involves conditioning of ground pulp with a complexing regulator, a collector selective to zinc and copper, and a foaming agent and separation of zinc concentrate into a foam product of flotation. Ammonium rhodanide is used as a complexing regulator. Complexing collector used is dithiopyrilmethane (1-phenyl-2,3-dimethyl-pyrazolone-5-thione). Ratio of collector and complexing agent ranges from 1:0.5 to 1:4.

EFFECT: method ensures selective separation of valuable components into a concentrate with simultaneous reduction of non-return losses of valuable components with common tails.

1 cl, 1 tbl

Description

The invention relates to the field of mineral processing, in particular, to flotation separation of sulfide minerals from concentrates and can be used in flotation concentration of sulfide copper-zinc pyrites, pyrrhotite and arsenopyrite-containing, gold-bearing ores, as well as tin-containing sulfide ores that contain in addition to cassiterite, sulfides of copper, zinc, lead, silver, as well as iron-containing sulfides, the presence of which in concentration concentrates impairs their quality and complicates further metal urgichesky repartition.

A known method of enrichment of sulfide ores, including the introduction of a surface modifier of sphalerite to increase the sorption of xanthate, the introduction of a collector and blowing agent. In this method, copper sulfate is used as a surface modifying agent. Separation of sphalerite from iron minerals is carried out in a highly alkaline calcareous medium. [Bogdanov O.S., Maksimov II, Podnek A.K., Yanis N.A. Theory and technology of ore flotation. - M., Nedra. 1980. - p. 363.].

However, in this method it is necessary to strictly control the consumption of copper sulfate in order to reduce the unproductive consumption of xanthate.

A known method of flotation of polymetallic ores, including the introduction of a surface modifier of sphalerite, xanthate and an additional collector MKOP with foaming ability. As an additional collector, MKOP reagent obtained on the basis of the mother liquor for the production of butyl xanthate and propylene oxide is used. The method allows to exclude a blowing agent from the flotation process and to increase the extraction of copper and zinc. [Ivanova T.A., Zaslavskaya N.N., Turnikova V.I. Obtaining, properties and application of a new flotation reagent. // Metallurgical technology in the processing of ores and concentrates of non-ferrous metals: Scientific. Proceedings of Gintsvetmet - M., 1993.S. 119-123. A.S. No. 1457232 of the USSR and A.S. No. 1640868 USSR].

However, for the production of MKOP reagent, it is necessary to use a xanthate production waste with a stable composition.

A known method of flotation separation of sphalerite and copper minerals from iron sulfides, including conditioning pulverized pulp in the presence of a complexing collector and a complexation regulator. In this patent, diantipyrylmethane (1-phenyl-2,3-dimethyl 4-dimethylaminopyrazolone is a complexing reagent -5), capable of forming a strong compound with these metals, and ammonium thiocyanate is used as a complexation regulator. [Chanturia V.A., Ivanova T.A., Chanturia E.L., Zimbovsky I.G. “The method of flotation separation of sphalerite and copper minerals from iron sulfides”, Russian patent for invention, RU (11) 2504438 (13) C1 application 2012129942 / 03.16.07.2012].

However, this reagent is able to be easily oxidized by iron ions (3+) on the surface of iron-containing sulfides and the input phase of the pulp, which can lead to unproductive consumption of the reagent.

The closest in technical essence, combination of features and the achieved result can be recognized as a method of flotation of copper-zinc sulfide ores in an alkaline calcareous medium, including the introduction of copper sulfate, conditioning pulp with butyl xanthate and a blowing agent.The separation efficiency substantially depends on the presence of impurities in the separated minerals. [L.Ya. Shubov, S.I. Ivankov, N.K. Shcheglova Flotation reagents in the processes of mineral processing. Book 2, p. 165 (prototype)].

The disadvantage of this method is the low extraction of a valuable component in the concentrate, low selectivity index, high consumption of flotation reagents, high metal loss with tailings.

An object of the invention is to increase the efficiency of separation of sulfide minerals of zinc and copper from iron sulfides from copper-zinc or polymetallic ores and concentration products.

The technical result obtained by the implementation of the invention is to provide selective separation of valuable components into a concentrate while reducing the irretrievable losses of valuable components with common tails in the presence of a complexing reagent-collector selective for zinc and copper, a complexation regulator and a blowing agent.

To achieve this goal, it is proposed to use the developed method of flotation separation of sphalerite and copper minerals from iron sulfides, including conditioning pulverized pulp with a complexation regulator, a collector selective for zinc and copper, and a blowing agent, and the allocation of zinc concentrate in the foam flotation product, and, as ammonium thiocyanate or copper sulfate are used to regulate complexation. As a collector, dithiopyrilmethane (1-phenyl-2,3-dimethyl-pyrazolone-5-thion) is used. In a preferred embodiment, a collector to ammonium thiocyanate ratio of 1: 2 is used. It is advisable to use the developed method for pulp with a particle size of (- 0.1 mm). The method is implemented as follows.

As a complexing reagent selective for zinc and copper, dithiopyrilmethane is used, capable of forming a strong compound with these metals, and ammonium thiocyanate is used as a complexation regulator, while the ratio of collector and complexation regulator is from 1: 0.5 to 1: 4.

In addition, copper sulfate is used as a complexation regulator, and xanthogenate (BCS) or any other sulfhydryl collector is used as an additional collector.

When implementing the method can be used:

- dithiopyrilmethane (1-phenyl-2,3-dimethyl-pyrazolone-5-thion), which is a white or yellowish crystalline product, slightly soluble in water, soluble in mineral acids and in acetic acid, acetone, chloroform, dimethylformamide and alcohols, Mv 420.63 mp 236-237 ° C.

- ammonium thiocyanate (NH ₄ CNS) GOST 27067-86 or sodium thiocyanate

- acetic acid (UK) GOST 18270-72

- (sulfhydryl) collector, potassium butyl xanthate (BKS), corresponding to (GOST 7927-75) or other alkyl xanthates or alkyl dithiocarbamates, etc.

- blowing agents: GOST 6792-74 pine oil, or Methylisobutylcarbinol (MIBK) TU 6-02-891-78.

The selectivity of the action of dithioptrylmethane is based on the ability to form a hardly soluble complex compound with zinc Zn (C ₁₃ H ₁₇ ON ₃ ) ₂ (NCS) ₂ or a compound with copper on the surface of sulfide minerals and the simultaneous ability to form a water-soluble compound with iron ions ( 3+) on the surface of pyrite or other iron-containing sulfides. The introduction of complexation regulators of rhodanidione, or copper sulfate leads to the formation of more stable complex compounds of dithiopyrilmtan with zinc and stronger hydrophobization of the surface of sphalerite. The introduction of copper sulfate in front of the collector leads to the simultaneous formation of complexes of 1-phenyl-2,3-dimethyl-pyrazolone-5-thione with zinc and copper on the surface of sphalerite.

To perform flotation separation of sphalerite and pyrite in laboratory conditions, a laboratory mechanical flotation machine was used; in industrial conditions, any type of flotation machine can be used.

To confirm the effectiveness of this method, a comparison was made with the method selected as a prototype.

The experiments were performed on the above laboratory equipment using methyl isobutyl carbinol (MIBK) as a blowing agent; the minerals used were crushed to (-0.1 + 0.044 mm).

The size required for the experiments was obtained by abrasion of minerals in a porcelain mill and dispersion into classes on sieves.

1. By the method of the prototype (experiment 1 in the table).

A portion of the crushed mineral pyrite or sphalerite (1 gram) was placed in a flotation chamber, poured with an aqueous solution of pH10.5 (CaO); CuSO ₄ 200 g / t was introduced, then pulp with a BCS 100 collector (g / t) was conditioned, MIBK blowing agent was fed, mixed for 0.5 minutes, then floated for 3 minutes.

2. By the method of flotation separation of sulfide minerals using dithiopyrilmethane (experiments 2-4 in the table)

A weighed portion of the crushed mineral pyrite or sphalerite (1 gram) was placed in a flotation chamber, filled with water, a collector of DTM 50, 100 or 200 (g / t) was introduced and the pulp with a collector was conditioned for 1 min, MIBK blowing agent was fed, mixed for 0.5 min., then floated for 3 minutes.

3. By the method of flotation separation of sulfide minerals using dithiopyrilmethane (experiment 5 in the table), but before feeding the collector DTM (100 g / t), a CuSO ₄ 200 g / t regulator was introduced.

4. By the method of flotation separation of sulfide minerals using dithiopyrilmethane (experiments 6-8 in the table), but simultaneously with the collector of DTM (100 g / t), a complexation regulator of ammonium thiocyanate NH ₄ SCN was introduced at a weight ratio of DTM: NH ₄ SCN of 1: 1 to 1: 4.

5. By the method of flotation separation of sulfide minerals using dithiopyrilmethane (experiment 9 in the table), but a weighed sample of ground chalcopyrite (1 gram) was placed in a flotation chamber, filled with water, DTM collector, 100 (g / t) was introduced and pulp was collected with collector 1 min, MIBK blowing agent was fed, stirred for 0.5 minutes, then floated for 3 minutes.

6. By the method of flotation separation of sulfide minerals using dithiopyril (experiment 10 in the table), but simultaneously with the collector of DTM (100 g / t), the complexation regulator of ammonium thiocyanate NH ₄ SCN was introduced at a weight ratio of DTM: NH ₄ SCN 1: 2.

6

An analysis of the data in the table shows that the best conditions for the separation of pyrite and sphalerite by the proposed method are the conditions of experiment 7 and experiment 8. In the absence of a complexation regulator (experiment 2-4), the extraction of sphalerite at DTM costs of 50-300 g / t does not exceed 63.5% when recovering pyrite <3%. The developed method allows to provide a difference in the extraction of minerals of pyrite and sphalerite 5.8% higher compared with the method of the prototype.

Claims (1)

The method of flotation separation of sphalerite and copper minerals from iron sulfides, including conditioning pulverized pulp in the presence of a complexing collector and a complexation regulator, introducing a blowing agent and isolating zinc and copper sulfide minerals into the foam flotation product, characterized in that as a complexing collector selective to zinc and copper, use dithiopyrilmethane, capable of forming a strong connection with the mentioned metals, and as a regulator of complex Ammonium thiocyanate is used, and the ratio of the collector to the complexation regulator is from 1: 0.5 to 1: 4.