Study on Comprehensive Recovery Process of Flotation of Cyanide Tailings in a Gold Mine

Study on Comprehensive Recovery Process of Flotation of Cyanide Tailings in a Gold Mine

In recent years, in order to make full use of the country's precious mineral resources, reduce environmental pollution, and also increase the economic benefits of enterprises, many factories and mines have paid attention to the comprehensive recovery of useful minerals in cyanide leach residue, and their beneficiation process has been re-elected. Flotation, magnetic separation, re-floating combined processes, etc. The flotation recovery process for the purpose of sulfide ore accounts for a large proportion, among which there are many factories and mines that have been successfully recovered, but the recovery effect of factories and mines is not satisfactory. This paper analyzes and discusses the theory in this way and finds out the main effects affecting the recycling effect. The reason is to take corresponding contingency measures, aiming at guiding the production and providing a reference for theoretical analysis and process design for decision makers and scientists.

1. Analysis of influencing factors

1.1 Formation and influence of calcium peroxide film Cyanide method is used to extract gold , usually using lime as “protective alkali”. The pH value of the pulp is generally about 11. At the same time, in order to meet the cyanide ratio, it is necessary to press air into the slurry. , oxygen or peroxide is added to increase the leaching rate of gold and silver. Such high alkalinity, oxygen enrichment and long-time immersion will form a hydrophilic calcium peroxide film (CaO2) on the surface of the ore particles, and the formation of this film is non-selective to the ore particles due to the ore particles in the slurry. The difference in surface electrical properties makes metal sulfide ore easier to form than non-metallic gangue minerals. The formation of a calcium peroxide film (CaO2) calcium peroxide film causes the collector to lose its selectivity for various minerals, and the film also hinders the adsorption of the collector and the surface of the ore. Ca2++2OH → Ca(OH)2 Ca2++O2 → CaO2 is the effect of removing CaO2 film. It is often necessary to refine the water and reduce the pH to 8~9, and stir it vigorously or even re-grind.

1.2 Cyanide immersion gold process is a strong oxidation process Cyanide pulp must be strong alkaline pulp, pH=11, and often inflated into the slurry, even pure oxygen, or add strong oxidants, such as H2O2, CaO2, Na2O2 BaO2, etc., in the deoxidation purification process of cyanide tailings, bleaching powder (CaOCl2), bleaching essence [Ca(OCl)2], sodium hypochlorite (NaOCl) are often used to treat cyanide tailings to meet environmental protection requirements. These processes from leaching to sewage treatment are treated under high alkalinity and strong oxidizing conditions for up to two or thirty hours, which is a long process for recoverable sulphide ore in cyanide tailings. The strong oxidation process is sufficient to oxidize the surface, thereby reducing the floatability. Sometimes recovered by flotation pyrite have difficulty, because pyrite surface portion of the sulfur in the highly alkaline pulp into the free oxygen-rich conditions, generating further oxidation basic sulfate, ferric hydroxide generated the final film [Fe (OH ) 3] covered by the surface of the pyrite particles. Therefore, in order to eliminate such effects, it is often necessary to add a corresponding activator or re-grind to expose the fresh surface of the mineral.

1.3 residual cyanide cyanide tailing sulfide flotation effects are known inhibitors, lime is added cyanide sulfide flotation effects inhibitors, used to inhibit the pyrite, copper ore, the amount of a few grams To a few tens of grams, the amount of cyanide immersion gold cyanide is a few hundred grams / ton, more than kilograms, so that it is enough to suppress all sulfide ore. Therefore, when cyanide tailings flotation sulfide ore, the residual cyanide in cyanide tailings should be minimized, such as tailings pressure filtration, etc., and it is best to carry out comprehensive recovery after sewage treatment.

1.4 Cyanide salts in cyanide tailings are inhibitors of sulfide ore flotation. During the cyanidation process, the minerals associated with gold and silver ore also react with cyanide to form metal cyanide salts. These cyanide salts It is a powerful inhibitor in the flotation of sulfide ore. 1.4.1 Iron minerals and sodium cyanide to form sodium ferrocyanate Pyrite: FeS2+NaCN==Fe S+NaCNS

Pyrrhotite: Fe5S6+NaCN==NaCNS+5FeS

Ferrous sulfide: Fe S+2O2==FeSO4 FeSO4+6NaCN==Na4[Fe(CN)6]+Na2SO4

Metal iron filings: Fe+6NaCN+2H2O==Na4[Fe(CN)6]+2NaOH+H2↑ 1.4.2

Copper mineral and sodium cyanide form sodium copper cyanate cholesteric: 2CuSO4+4NaCN==Cu2(CN)2+2Na2SO4+(CN)2↑

Azurite: 2CuCO3+8NaCN==2Na2Cu(CN)3+2Na2CO3+(CN)2↑

Malachite: 2Cu(OH)2+8NaCN==2Na2Cu(CN)3+4NaOH+(CN)2↑

Copper ore: 2Cu2S+4NaCN+2H2O+O2==Cu2(CN)2+Cu2(CNS)2+4NaOH 1.4.3

Zinc mineral reacts with sodium cyanide to form sodium zinc cyanate Sphalerite: ZnS+4NaCN==Na2Zn(CN)4+Na2S

Zinc Oxide: ZnO+4NaCN+H2O==Na2Zn(CN)4+2NaOH

Zinc-zinc ore: ZnCO3+4NaCN==Na2Zn(CN)4+Na2CO3, etc. These metal cyanide salts can form a hydrophilic film on the surface of the mineral and inhibit the adsorption of the xanthate molecule and inhibit it.

1.5 A large amount of metal ions remaining in the cyanide tailings consumes a large amount of metal ions, especially Ca2+, Fe2+, Cu2+, Zn2+, in the cyanide tailings. The xanthate was discovered as early as 1782, but the earliest use of xanthate was chemical analysis. For example, the reaction of xanthate with copper salt to produce precipitation was used to quantitatively analyze copper. The presence of these metal ions has a catalytic effect on the decomposition of xanthate, and a large amount of poorly soluble metal salts of xanthate precipitates, which consumes a large amount of xanthate. 4ROCSSNa+2Me++==Me2(ROCSS)2↓+(ROCSS)2+2Na2SO4 Therefore, the cyanide tailings flotation method is comprehensively recovered, and the amount of collector is usually large, which is why.

1.6 The large amount of salts produced during the cyanidation process deteriorates the flotation process as described above: a large amount of alkalis and salts remain in the cyanide tailings, such as Ca(OH)2, CaO2, Fe(OH)3, Mem ( CN)n, Ca(OCl)2, FeSO4, Na2S, Na2SO4, Na2CO3, etc., the presence of these salts in large quantities makes the chemical reaction process very complicated and difficult to predict. Because they contaminate the surface of the ore particles, the surface of the ore particles is unrecognizable, and the physical and chemical properties of the original surface are lost, which increases the difficulty of flotation separation.

1.7 Mudification caused by fine grinding cyanide consumes a large amount of flotation agent to destroy the selectivity of flotation. In order to improve the leaching rate of gold and silver, the mixing cyanide usually has a grinding fineness of 90%-200 mesh or 90%-325 mesh or more. Therefore, mineral mud is inevitably produced, and these slime will not only adsorb on the surface of the ore, but also lose its original surface properties. At the same time, a large amount of slime will adsorb a large amount of flotation agent due to its large specific surface area and surface energy, resulting in an increase in the amount of flotation agent.

2. Technical measures to improve the flotation effect of cyanide tailings

It can be seen from the above analysis that the technical route to improve the flotation effect of cyanide tailings should be carried out around drug removal and deliming.

2.1 Mechanical de-peking and de-mudging The scrubbing machine is strongly stirred and scrubbed, and the de-slipping bucket is dehydrated and de-sludged. After further dehydration and de-druging with a filter press, the flotation is re-pulled with water.

2.2 Appropriate addition of de-pharmaceutics, such as adding appropriate amount of activated carbon to remove the drug, the residual cyanide in cyanide tailings, copper ion removal effect is better, but must control the amount of de-agent added, otherwise the dosage is too large, which will lead to a large amount of flotation reagent The increase is in the range.

2.3 Appropriate addition of slime dispersant If water glass or carboxymethyl cellulose is added in an appropriate amount, it is very beneficial to improve the separation effect.

2.4 Re-grinding cyanide tailings For cyanide tailings with coarser grain size, if it is economically reasonable, it can be separated by re-grinding flotation for the purpose of comprehensive recovery.

2.5 Use a selective collector. Select Z-200 when separating copper and sulfur. 2.6 Add an appropriate amount of activator To eliminate the influence of surface oxidation of the ore particles, add an appropriate amount of activator, but use a selective activator.

2.6 Pre-selection and post-finishing flotation with re-election For low-grade cyanide tailings, the primary concentrating machine with large processing capacity, low investment and low cost can be used for primary enrichment, and most of the residual gangue sludge can be discarded. Then flotation separation is carried out. Technically more reliable and economically more reasonable.

3. Production and application of lead, copper and sulfur comprehensive recovery in cyanide tailings

The main metal minerals in cyanide tailings of a cyanide plant are pyrite, galena, chalcopyrite, and a small amount of pyrrhotite, magnetite, hematite, gangue minerals are mainly quartz , and A small amount of chlorite, kaolin, etc. Lead content is 19.95%; copper is 4.21%; gold is 5.00g/t; silver is 508.76g/t, sulfur is 37.50%. The cyanide tailings of the plant are washed by three-stage countercurrent, concentrated by a thickener at a concentration of 55-60%, placed in a buffer stirred tank for high concentration for a long time (up to more than 1 hour), and scrubbed to remove the ore. The above various films on the surface are then preferentially selected into the flotation at a high concentration. The process makes full use of the residual C in cyanide tailings, cyanide and the like to inhibit pyrite, limonite and galena. The natural floatability reduces the process of re-slurrying and re-adding pyrite and chalcopyrite inhibitors, reducing production costs and simplifying the process. At the same time, high-concentration flotation is beneficial to the floating of large-scale lead ore, and at the same time enhances the scrubbing effect between the ore particles, which is beneficial to the surface of fresh ore particles and the collector. The chemical conditions were: dispersing agent 3000 g/t, inhibitor 80 g/t, diphtheria yellow drug 300 g/t, and No. 2 oil 120 g/t. pH = 10-11. The floating lead tailings flow into the floating copper stirring tank by self-flow, and the copper flotation concentration is 30%. The process flow is a coarse, three-sweep, three-selection. The chemical conditions are: dispersing agent 1500g/t, Ding Huang Drug 1200g / t No. 2 oil 200g / tpH = 10. From the perspective of production sorting, the mineral processing technical indicators are ideal, the lead recovery rate is greater than 90%, the copper recovery rate is 53.92%, the total gold recovery rate (available) is 86%, and the total silver recovery rate (valuable) is 97.74%. Fully recovered gold, silver and lead, especially to compensate for the low recovery rate of silver cyanide. The sulfur concentrate contains more than 35% sulfur. However, due to the high content of metal ions in the backwater, the amount of collector is large, and there is still a need for further improvement.

4, the conclusion

(1) The technical point of the comprehensive recovery flotation of cyanide tailings is to remove various films on the surface of the ore particles, and also the minerals.

(2) In the flotation process of cyanide tailings, the use of dispersant is indispensable, but the dosage must be strictly controlled.

(3) It adopts lead, copper and sulfur priority flotation process, which is technically feasible and economically reasonable. It is an ideal process for flotation of cyanide tailings.

(4) Because the cyanide leaching slag has a fine particle size and a large slurry ratio, high concentration and fast flotation in the floating lead is beneficial to the recovery of lead.

(5) The comprehensive recovery of cyanide tailings will benefit the country and benefit the environment. The production practice of the plant proves that the comprehensive recovery of cyanide tailings is not only technically feasible, but also can earn more than 3 million yuan per year. It can also resettle more than 60 employees, and the economic and social benefits are very significant.

Gasket

A gasket is a mechanical seal which fills the space between two or more mating surfaces, generally to prevent leakage from or into the joined objects while under compression.

Gaskets allow for "less-than-perfect" mating surfaces on machine parts where they can fill irregularities. Gaskets are commonly produced by cutting from sheet materials.

Gaskets for specific applications, such as high pressure steam systems, may contain asbestos. However, due to health hazards associated with asbestos exposure, non-asbestos gasket materials are used when practical.

It is usually desirable that the gasket be made from a material that is to some degree yielding such that it is able to deform and tightly fill the space it is designed for, including any slight irregularities. A few gaskets require an application of sealant directly to the gasket surface to function properly.

Some (piping) gaskets are made entirely of metal and rely on a seating surface to accomplish the seal; the metal's own spring characteristics are utilized (up to but not passing σy, the material's yield strength). This is typical of some "ring joints" (RTJ) or some other metal gasket systems. These joints are known as R-con and E-con compressive type joint.

PTFE Gasket, Spiral Wound Gasket, Ring Joint Type Gaskets

Shijiazhuang Bang dong Pipeline Technology Co,Ltd. , https://www.bd-pipefitting.com