SU871832A1 - Zinc mineral depressor for polymetallic ore flotation - Google Patents

Description

using sphalerite polyethylenepolyamine phosphoric acid as the depressor of the formula -CH.HCN, - And where AND is the degree of polymerization from 5 DR 16. The essence of the process is as follows. A copper zinc flotation is carried out collectively. The resulting copper-zinc concentrate is fed to a selective copper flotation, which is conducted in a highly alkaline environment using butyl potassium xanthate and butyl aeroflot as collectors. For the separation of copper and zinc sulphides, the flotation of copper-containing minerals is carried out with the simultaneous feeding of polycomnlexone into the pool in the form of an aqueous solution. Polycomplexon suppresses sphalerite flotation, which leads to zinc concentration in the chamber product and copper in the foam. The consumption of lolicomplex depending on the material composition of the ore and the technological mode of its processing varies from 5 to 25 g / t. The lower consumption of polycomplexon fed into the copper flotation cycle increases the loss of cic in the copper concentrate, the larger reduces the extraction of copper to copper concentrate somewhat. Example. Selections are carried out for flotation of sulfide copper-zinc ore from the Lezshnskoye deposit. Collective copper-zinc concentrate is directed to selective copper flotation. The alkalinity of the pulp is created by lime and amounts to 56 g / m free CaO, the consumption of potassium butyl potassium ntogenate is 30 g / t, butyl aerofloat is 20 g / t. Depression sphale; in the copper flotation cycle, polycomplexone is produced, the flow rate of which varies from 5 to 25 g / t. In parallel, experiments were carried out on the selective flotation of the same ore with the addition of sulfur as a depressant as sodium. The supply of pollys complexone in the cycle of copper flotation causes a deeper depression sphalerite compared with sodium sulphide. At the same time, the polycomplex has a less depressing effect on chalcopyrite compared with sodium Sulfur. These data indicate that Polycomplex provides more complete separation of copper and zinc sulphides by the flotation method. A feed rate of 25 g / t of polycomplexon to the copper flotation cycle suppresses sphalerite flotation by 50%. For depression of sphalerite to the same level with sodium sulphide, the consumption of the latter is required to increase to 800 g / t. The lesser depressive effect of polycomplexon on chalcopyrite allows copper recovery to be increased by 3-5% compared with the known method. The depressive effect of polycomplexon and its comparison with the known sodium sulfide depressor has also been studied on pure minerals chalcopyrite and sphalerite in order to eliminate interference from the influence of the mixture of minerals on the flotation of each of them. Cond: Conducting experiments: pulp pH 11, OJ collector - butyl potassium xanthate, consumption 300 g / t; blowing agent - isoamyl alcohol, consumption of 50 g / t; Polycomplexon depressors and sodium sulphide, consumption from 3 to 60 g / t. The depressing effect of polycomplex on chalcopyrite is insignificant, its degree of suppression is from 0.02 to 0.09, with a consumption of polycomplex from 3 to 60 g / t. The degree of suppression of sphalerite at the same costs increases from 0.17 to 0.67, i.e. sphalerite is depressed by polycomplex 5-20 times stronger than chalcopyrite. Sodium sulfide has a depressant effect on sphalerite and chalcopyrite. When this depressor is consumed from 3 to .60 g / t, the degree of suppression of sphalerite flotation ranges from 0.67 to 0.76; chalcopyrite 0.15-0.54, i.e. The selectivity of suppressing the flotation of sulfides with sodium sulphide is significantly lower than with polycomplexon. The use of polycomplexon for flotation of copper-zinc sulfide ores allows to increase the recovery of metals in the same concentrates and to reduce the zinc content in the copper concentrate.

Claims (6)

1. US patent 2664198, cl. 209-167, published. 1952. 2. US patent number 2660307, cl. 209-167, published. 1952. 3. Authors certificate of USSR N 181565, cl. B 03 D 1/02, 1964. 4. The patent of Japan 1 22441, cl. 9c311 publ. 1962. 5. Patent Czechoslovakia No. 103675, cl. 1c, 10/01, publ. 1962. 6.Driker B.N. et al. Teaching the effect of nitrogen-phosphorus-containing polycomplexon on the crystallization kinetics of calcium sulfate. Journal of Applied Chemistry, 1975, 2, p. 277 (prototype).