EP0298392A2 - Method and agents for obtaining minerals from sulphate ores by flotation - Google Patents

Abstract

In ore flotation, collecting agent mixtures are used which contain - unsubstituted primary and secondary C8-C22-alkyl- and/or -alkenyl-amines and/or salts thereof and - xanthates, dithiophosphates, mercaptobenzothiazoles, xanthogen formates (alkylcarbonic/alkylxanthic acid anhydrides) and/or thionocarbamates. <IMAGE>

Description

The invention relates to a flotation process for extracting minerals, in particular sulfidic minerals such as pyrite, chalcopyrite and pentlandite, and gold from ores. The invention further relates to a collector mixture and flotation aids which contain this collector mixture.

According to the invention, a process for the extraction of minerals from ores by flotation is made available, in which ground ore is mixed with water to form an ore suspension (slurry), air is introduced into the suspension in the presence of a collector system and the resulting foam together with the ore content contained therein separates. This method is characterized in that, as a collector, a mixture containing
at least one amine compound A from that of unsubstituted primary and secondary amines of the formulas I and II,
RNH₂ (I)
R¹ R² NH (II)
- in which R, R¹ and R² each represent alkyl or alkenyl radicals having 8 to 22 carbon atoms, and water-soluble salts of the above-mentioned primary and secondary amines and
- At least one thio compound B from the group formed from xanthates, the dithiophosphates, mercaptobenzthiazoles, xantogen formates (alkyl carbonic acid-alkyl xanthogen anhydrides) and thionocarbamates
starts.

The invention further provides a collector mix for use in the extraction of minerals from ores by flotation containing
at least one amine compound A from that of unsubstituted primary and secondary amines of the formulas I and II,
RNH₂ (I)
R¹R² NH (II)
in which R, R¹ and R² each represent alkyl or alkenyl radicals having 8 to 22 carbon atoms, and water-soluble salts of the above-mentioned primary and secondary amines and
- At least one thio compound B from xanthates, dithiophosphates, mercaptobenzthiazoles, xanthogen formates (alkyl carbonic acid alkyl xanthogenic anhydrides) and thionocarbamates formed group.

The unsubstituted primary and secondary amines of the formulas I and II and their water-soluble salts used as amine compounds A are known compounds which can be prepared by known methods of organic synthesis. The alkyl and alkenyl radicals R, R¹ and R² in the formulas I and II are preferably straight-chain, as is the case in the amines which are derived from naturally occurring fatty acids. The radicals R, R¹ and R² are therefore preferably straight-chain octyl, decyl, dodecyl, tetradecyl, hexadecyl, octadecyl, eicosyl, docosyl, hexadecenyl, octadecenyl and docosenyl radicals. The amines of the formulas I and II can be used as defined individual compounds. However, it is preferred to use compound mixtures in which the radicals R, R 1 and R 2 each have different chain lengths within the defined range of the carbon atoms present. Of particular interest here is a primary alkyl / alkenylamine of the formula I with 10 to 18 carbon atoms in the radical R and its water-soluble salts. The alkyl / alkenyl residues of this amine mixture are derived from the uncured fatty acid mixture which is obtained from beef tallow by fat cleavage. This amine mixture is also known as "uncured tallow amine".

If water-soluble salts of the amines of the formulas I and II are used in the process according to the invention, these are in particular sulfates, phosphates, formates, propionates and preferably chlorides and acetates.

In a special embodiment of the invention, which is particularly suitable for the processing of gold-containing ores, the amine compound A used is the acetate of the above-described primary alkyl / alkenylamine with 10 to 18 Carbon atoms. In this specific embodiment, it is preferred to use a xanthate or a dialkyldithiophosphate as thio compound B.

The substances used as thio compounds B can be water-soluble or water-insoluble. The xanthates, dithiophosphates and mercaptobenzothiazoles are water-soluble alkali metal salts. The xanthogen formates and the thionocarbamates are water-insoluble, oily substances. The following groups of substances can be considered as thio compounds B:
Xanthates of formula III,
ROC (S) -S⁻X⁺ (III)
in which R is an alkyl radical having 2 to 8 carbon atoms and X is Na or K,
the thiophosphates of the formula IV,
(RO) ₂P (S) -S⁻ X⁺ (IV)
in which R is an alkyl radical of 2 to 8 carbon atoms and X is Na or K,
Sodium or potassium salts of mercaptobenzothiazole,
Xanthogen formates (alkyl carbonic acid-alkyl xanthogenic acid anhydrides) of the formula V,
R¹-OC (S) -SC (O) -O-R² (V)
in which R¹ and R² each represent an alkyl radical having 1 to 8 carbon atoms and
Thionocarbamates of the formula VI,
R¹-OC (S) -NHR² (VI)
in which R¹ and R² each represent alkyl radicals having 1 to 8 carbon atoms.

The thio compounds B mentioned are known compounds which can be prepared by customary methods of organic synthesis.

The optimal effectiveness of the thio compounds B depends to a certain extent on the pH prevailing in the cloudy. Mercaptobenzothiazoles, xanthogen formates and thionocarbamates can be used in the pH range from 2 to 11, with mercaptobenzthiazoles working best under relatively acidic conditions, while xanthogen formates and thionocarbamates are effective in both alkaline and acidic media. Xanthates and dithiophosphates work best in a relatively alkaline medium in the pH range of 6 to 11.5. If a flotation process is to be carried out at a given pH value, this should be taken into account when selecting the thio compound B. Conversely, for a given thio compound B, when carrying out the flotation, a corresponding pH in the turbidity must be set.

In the collector mixture used in the process according to the invention, the weight ratio of amine compound A to thio compound B is in the range from 1: 9 to 9: 1, weight ratios from 1: 4 to 2: 1 being preferred. The Amine compounds A are added to the ore suspension in amounts of 1 to 500 g per metric ton of ore and the thio compounds B in amounts of 1 to 500 g per metric ton of ore.

In the process according to the invention, a foamer can be added to the slurry in order to stabilize the foam formed during the flotation. Particularly suitable for this purpose are the alcohols, propylene glycols and ethers commonly used in flotation as foaming agents, for example methylisobutylcarbinol (4 methylpentanol-2), which is commercially available in 97% purity under the name MIBC, methylpolypropylene glycol ether, the molecular weight of which is approximately 200 on average and Triethoxybutane, which is commercially available under the name TEB. Methyl isobutyl carbinol is preferred for the purposes of the invention.

To adjust a suitable pH value, which promotes the effectiveness of the amine compounds A and thio compounds B used, the acidic or basic agents customary in flotation can be added, for example sodium silicate, lime (calcium oxide) and inorganic or organic acids. It is important to ensure that the means for adjusting the pH is selected according to the mineral to be extracted and the collector combination used in each case, so that a flotation medium of suitable acidity or alkalinity is obtained.

Furthermore, in the process according to the invention, suitable, conventional pushers, which have the task of preventing the flotation of undesired gangue minerals, can be added to the slurry. The pushers connect to the gangue minerals, usually through adsorption, and prevent them from floating. In this way, the separation of the gangue minerals from the mineral to be extracted is promoted. Suitable pushers guar gums and dextrins are particularly suitable for the process according to the invention. Particularly preferred here is a chemically modified guar gum with a linear chain of beta-D-mannopyranose units, which are 1,4-linked to single-link alpha-D-galactopyranosyl residues which appear as side chains. The chemical modification includes the depolymerization of the guar gum to reduce the molecular weight and the substitution of hydroxyl groups in the guar structure by anionic groups. The degree of substitution in a commercial product sold under the name ACROL® J2P 350 is 0.1.

To activate the sulfidic minerals to be floated, customary activators can be added to the slurry in the process according to the invention. Copper sulfate, in particular, has proven to be suitable as an activator, which additionally has the property of modifying the structure of the foam formed favorably.

The usual flotation aids used in the process according to the invention in addition to the amine compounds A and the thio compounds B, such as foaming agents, pushers and activators, are added in the amounts of the slurry known and customary for such flotation processes. The alkaline or acidic agents mentioned are used in the amounts which are necessary for setting the desired pH.

The collector mixture to be used in the process according to the invention can contain, in addition to the amine compounds A and the thio compounds B, further components which are known for their collector properties. Hydrocarbon oils have proven to be particularly suitable for this purpose, in particular neutral aliphatic and aromatic solvents with boiling points in the range of 160 to 260 ° C. Hydrocarbon oils with a low aromatic content and a boiling range of 190 to 225 ° C. are preferred.

The amine compounds A, the thio compounds B and the other auxiliaries to be used in the process according to the invention can be added individually and in succession to the turbidity to be floated. For the practical implementation of the method, it can be advantageous if premixed combinations of two or more auxiliaries are provided, in which the components are present in a predetermined weight ratio to one another. A mixture of flotation aids with a content of has proven to be particularly advantageous
at least one amine compound A from that of unsubstituted primary and secondary amines of the formulas I and II,
RNH₂ (I)
R¹R²NH (II)
in which R, R¹ and R² each represent alkyl or alkenyl radicals having 8 to 22 carbon atoms, and salts of the group formed above primary and secondary amines,
- a neutral hydrocarbon oil and
- a foamer
in a weight ratio of (4-6): (3-5): 1 and for use in conjunction with at least one thiover bond B is determined from the group formed from xanthates, dithiophosphates, mercaptobenzothiazoles, xanthogen formates (alkylcarbonic acid-alkylxanthogenic acid anhydrides) and thiocarbamates.

The method of the invention is characterized by the use of a specific, defined collector combination. The flotation is carried out under the general conditions known for the methods of the prior art. In this context, reference should be made to the following references on the technological background of ore processing: H. Schubert, Processing of Solid Mineral Substances, Leipzig, 1967; B. Wills, Mineral Processing Technology Plant Design, New York, 1978; D.B. Purchas (ed.), Solid-Liquid Separation Equipment Scale-up, Croydon, 1977; E.S.Perry, C.J. van Oss, E. Grushka (ed.), Separation and Purification Methods, New York, 1973 to 1978.

The method of the invention is particularly suitable for use in sulfidic mineral ores and for the extraction of gold, platinum, uranium, copper, zinc, nickel, cobalt, silver, lead and iron.

In the following examples, percentages are always in percent by weight without further addition.

• Fig. 1 ein Fließbild eines Flotationsverfahrens, das in den Beispielen 1 und 2 eingesetzt wird;
• Fig. 2 ein Fließbild eines Flotationsverfahrens, das in den Beispielen 3 bis 9 eingesetzt wird;
• Fig. 3 eine graphische Darstellung der gemäß den Beispielen 3 bis 7 erhaltenen Ergebnisse;
• Fig. 4 ein Fließbild eines Flotationsverfahrens, das in Beispiel 10 eingesetzt wird, und
• Fig. 5 ein Fließbild eines Flotationsverfahrens, das in Beispiel 11 eingesetzt wird.

The invention is explained below on the basis of preferred exemplary embodiments and with reference to the drawings. Show it:

• 1 is a flow chart of a flotation process used in Examples 1 and 2;
• Fig. 2 is a flow chart of a flotation process used in Examples 3 to 9;
• 3 shows a graphical representation of the results obtained according to Examples 3 to 7;
• Fig. 4 is a flow chart of a flotation process used in Example 10, and
• 5 is a flow chart of a flotation process used in Example 11.

The following Examples 1 to 9 relate to flotation processes with gold ore samples with the following composition or essentially corresponding to this composition:

Composition of the gold ore:

Quartzite 90 - 95%
Chlorite 1 - 2%
Pyrophyllite 3 - 5%
Cerussite 1 - 2%
Pyrite 0.5 - 1.0%
Uraninite traces
Kerogen traces; 0.2%
Carbon traces
other sulfides (pyrrhotite, galena, chalcopyrite) traces
Gold (metal) traces

The gear classification corresponds to that of conglomerates.

In the following examples, a primary alkyl- / alkenylamine of the formula RNH₂ (I) with 10 to 18 carbon atoms (uncured tallow amine) is used as collector, in which the following chain length distribution applies to R:
C₁₀ - 0.5%
C₁₂ - 2.0%
C₁₄ - 3 - 5%
C₁₆ - 28 - 35%
C₁₈ - 58 - 67%

The iodine number is 35 to 55.

Example 1. Flotation of a South African gold ore.

A certain amount of South African gold ore was ground with water to form a slurry with a particle size such that 70% of the particles passed through a sieve with 0.074 mm (200 mesh) openings. The solids content of the slurry was 38% by weight and its density was 1.32.

Preflotation 10 and cleaning flotation 12 were carried out in a conventional manner in a Denver 12 laboratory flotation cell. The flotation steps are shown in the form of a flow diagram in FIG. 1.

The preliminary flotation 10 was carried out in the usual way with a slurry 16 which contained water, ground ore and flotation aids. The flotation aids comprised a xanthate and a primary amine, which together form a collector mixture (a) according to the invention, further a pusher (b) and copper sulfate (c). Details for the reagents are given below.

Added reagents:

• (a) Collecting mixture according to the invention, containing
  - sodium n-propylxanthate (SNPX) in an amount of 50 g per metric ton of solids in the slurry;
  an acetate of the uncured tallow amine described above in an amount of 50 g per metric ton of solid in the slurry; and
  - A foamer consisting of a methylpolypropylene glycol ether of the formula CH- (OC₃H₆) _x - OH4 with an average molecular weight of about 200 (DOWFROTH 200) in an amount of 20 g per metric ton of solid in the slurry;
• (b) a pusher in the form of a chemically modified guar gum (ACROL® J2P 350) in an amount of 10 g per metric ton of solid in the slurry; and
• (c) an activator / foam modifier in the form of 35 g copper sulfate per metric ton of solid in the slurry; and
• (d) Lime to adjust the pH of the slurry to 9.2.

The additives (b), (c) and (d) were added separately to the slurry, as were the xanthate, amine and foaming constituents of the collector mixture (a).

15 minutes after the start of the pre-flotation 10, a concentrate after pre-cleaning 17, the gold and other sulfidic minerals (eg Iron sulfide) and was contaminated with a limited amount of gangue minerals, and besides, exits from pre-flotation 18, which contained the majority of the gangue minerals originally present in the ground ore. The concentrate from pre-flotation 17 was separated from the outflows of pre-flotation 18; Samples of outlets 18 were dried and analyzed in the usual way. The analysis results are summarized in Table 2.

The cleaning flotation 12 was carried out with a slurry after pre-flotation 22, which contained water and the concentrate after pre-cleaning 17 together with further proportions of activator / foam modifier and pusher of the additives (d) and (e) explained below.

• (d) Kupfersulfat in einer Menge von 5 g pro metrischer Tonne Feststoff in der ursprünglich eingesetzten Trübe 16;
• (e) chemisch modifiziertes Guargummi (ACROL® J2P 350) in einer Menge von 10 g pro metrischer Tonne Feststoff in der ursprünglich eingesetzten Trübe 16.

The following reagents were added for cleaning flotation 12:

• (d) copper sulfate in an amount of 5 g per metric ton of solid in the slurry 16 originally used;
• (e) chemically modified guar gum (ACROL® J2P 350) in an amount of 10 g per metric ton of solid in the slurry 16 originally used.

5 min after the start of cleaning flotation 12, the slurry after pre-flotation gave a foam product with a concentrate after cleaning 24, which contained gold and other sulfidic minerals, contaminated with a reduced proportion of gangue minerals, and exits from cleaning flotation 26 with the remaining gangue minerals from the Concentrate after pre-cleaning 17. Samples of concentrate 24 and outlets 26 were dried and analyzed using conventional methods; the results obtained are summarized in Table 2. Unless stated otherwise, the additives summarized in Table 1 were added to the slurry originally used for the pre-flotation. Table 1 Summary of the display properties as well as the composition and amount of additives for pre- and cleaning flotation. Ground ore : Grinding size 70% <0.074 mm (200 mesh) Opacity 38% by weight solid density 1.32 Flotation aids : Collector: Na-n-propyl xanthate 50 g / t and primary amine acetate 50 g / t Foamer: DOWFROTH 200 20 g / t Pusher: ACROL® J2P 350 60 g / t for pre-flotation 10 g / t for cleaning flotation Activator / foam modifier: Copper sulfate 35 g / t for pre-flotation 5 g / t for cleaning flotation pH : 9.2 Flotation time : 15 min for pre-flotation 5 min for cleaning flotation Analysis results for pre- and cleaning flotation gold Total sulfur % By weight Content g / t % Spread Salary% S % Spread Concentrate after cleaning 2.9 7.2 40.8 32.85 81.6 Cleaning flotation exits 2.9 1.98 11.2 3.19 7.9 Departures of the pre-flora 94.2 0.26 48.0 0.13 10.5 Calculated for flotation 100.0 0.511 100.0 1.17 100.0

In a continuous flotation process, the exits after cleaning 26 can be recirculated and added to the slurry before the pre-flotation 16.

Example 2: Flotation of a South African gold ore:

Example 1 was repeated with the additives summarized in Table 3 below. Unless stated otherwise, the additives were added to the slurry originally used; the quantities given relate to g / metric ton of solid in the slurry originally used. Table 3 Summary of the display properties as well as the composition and amounts of the added additives for the pre- and cleaning flotation. Ground ore : Grinding size 70% <0.74 mm (200 mesh) Opacity 38% density 1.32 Flotation aids : Collector: Na-n-propyl xanthate 50 g / t and primary amine acetate 25 g / t and Hydrocarbon oil * 20 g / t and Methyl isobutyl carbinol (MIBC; foamer) 5 g / t Additional foamer: DOWFROTH 200 20 g / t Pusher: ACROL® J2P 350 20 g / t for pre-flotation 10 g / t for cleaning flotation Activator / foam modifier: Copper sulfate 35 g / t for pre-flotation 5 g / t for cleaning flotation pH : 9.2 Flotation time : 15 min for pre-flotation 5 min for cleaning flotation *) Hydrocarbon oil with a boiling range of 190 to 225 ° C; Aromatics content of 0.5% V / V, density at 20 ° C 0.785; Flash point 65 ° C (SHELLSOL® K)

The primary amine acetate was mixed with SHELLSOL K and MIBC before adding to the slurry. A mixture of uncured primary tallow amine acetates, SHELLSOL K and MIBC has a liquid consistency and is therefore easier to handle than the amine itself (as used in Example 1), which has a paste-like consistency. In addition, in this example, a quantity of the amine that was smaller by half was added to the slurry originally used; the results obtained are nevertheless advantageous compared to those of Example 1. It should be noted that the chemical expenditure for the flotation according to Example 2 is considerably lower than that of Example 1. Table 4 Analysis results for pre- and cleaning flotation gold Total sulfur % By weight Content g / t % Spread Salary% S % Spread Concentrate after cleaning 2.8 8.5 44.9 32.25 81.0 Cleaning flotation exits 2.0 1.78 6.7 2.5 4.5 Preflotation departures 95.2 0.27 48.4 0.17 14.5 Calculated for flotation 100.0 0.53 100.0 1.12 100.0

Example 3: Flotation of a South African gold ore.

A certain amount of South African gold ore was ground in water to form a slurry with the following properties:
Ore grinding size 70% <0.833 mm (20 mesh)
Turbid density 24% by weight solids
Density 1.18

A commercially available collector mixture, which is sold under the trade name TROCOL S50, was produced by mixing the following components: Weight ratio uncured primary tallow amine acetate 50% SHELLSOL K (neutral hydrocarbon oil) 40% MIBC 10%

A pre-flotation 30 was carried out in a Denver D12 laboratory flotation chamber in the usual manner and as shown in the flow diagram of FIG. 2. The cloudy 34 consisted of:
the ground ore in water,
150 g of the flotation aid mixture described above per metric ton of solid in the slurry,
50 g copper sulfate as activator / foam modifier per metric ton of solid in the slurry, and
100 g ACROL® J2P 350 as pusher per metric ton of solid in the slurry.

The pH of the slurry was between 10.1 and 10.4.

10 minutes after the start of the flotation, the slurry 34 gave a foam product with a pre-purification concentrate 38 that contained gold and other sulfidic minerals such as iron sulfide and was contaminated with a limited amount of the gangue minerals originally present in the ground ore, and exits from the pre-flotation 36 that contained the bulk of the gangue minerals.

The concentrate 38 was separated from the outlets 36 in a conventional manner. Samples of the exits from pre-flotation 36 and concentrate 38 were dried and analyzed; the results are shown in Table 6.

The flotation process according to Example 3 was not carried out in accordance with the process of the invention. An amine compound A was added to the slurry 32 according to the definition of the collector mixture according to the invention, but no thio compound B was carried out. Example 3 was carried out in order to enable comparisons to be made with the results of Examples 4 to 6 which were carried out according to the method of the invention.

Examples 4 to 7: Further flotations of the ground ore from example 3.

Example 3 was repeated with the following deviations:
In Examples 4 to 6, a collector combination according to the invention was used, which contained a mixture of TROCOL S50 (see Example 3) and sodium methylxanthate in different weight ratios (according to Table 5 below); the flotation process was carried out at a pH of 9.5. Example 7 was performed for comparison purposes only with a collector containing only sodium ethyl xanthate and no primary or secondary amine. Table 5 Additives for the milled ore of Examples 3 to 7 (g / t solids in the original slurry) Example No. Sodium ethyl xanthate TROCOL 350 Copper sulfate ACROL ® J2P 350 3rd - 150 50 100 4th 50 100 50 100 5 75 75 50 100 6 100 50 50 100 7 150 - 50 100 Analysis results of the pre-flotations according to Examples 3-7. gold Total sulfur Example No. product % By weight Content g / t % Spread Salary% S % Spread 3rd concentrate 2.62 260.0 81.39 4.71 13.39 Exits 97.38 1.6 18.61 0.91 100.00 Ber. for task 100.00 8.4 100.00 0.91 100.00 4th concentrate 4.89 166.0 91.43 17.50 0.91 Exits 95.11 0.8 8.57 0.09 9.09 Ber. for task 100.00 8.9 100.00 0.94 100.00 5 concentrate 3.29 266.0 88.50 19.67 66.30 Exits 96.71 1.0 11.50 0.34 33.70 Ber. for task 100.00 8.4 100.00 0.98 100.00 6 concentrate 2.25 229.0 80.20 17.74 43.99 Exits 97.75 1.3 19.80 0.52 56.01 Ber. for task 100.00 6.4 100.00 0.91 100.00 7 concentrate 1.85 447.0 83.97 2.60 5.08 Exits 98.16 1.6 16.03 0.91 94.92 Ber. for task 100.00 9.8 100.00 0.94 100.00

The figures in% for the yield of gold and total sulfur were summarized in a graphic representation, which is shown in FIG. 3 of the drawings. It follows from the illustration that the sulfur output was improved when a collector mixture according to the invention, consisting of a mixture of an amine (in TROCOL S50) with a xanthate instead of the amine without the xanthate (example 3) or the xanthate without the amine (Example 7) was used. The sulfur output decreased according to Examples 4 to 6 when the proportion of TROCOL in the collector mixture decreased. It also follows from the curve that the yield of gold was improved in Examples 4 and 5, while in Example 6 it was slightly less than in Examples 3 and 7. It follows that a preferred proportion of TROCOL is over 50% by weight of the xanthate present.

The results of the above examples suggest that there is an interaction between the amine and the xanthate. It appears to be an association, probably an ionic association between these compounds, although a chemical reaction does not occur. Further signs of an interaction or ionic association were obtained in foaming experiments.

These foaming attempts included foaming a liquid mixture of sodium ethyl xanthate and a surfactant in a container with air bubbles passed through the liquid, foaming the foam over the rim of the container, collecting the foam and determining the concentration of xanthate present therein, determining the Concentration of the xanthate present in the remaining liquid in the container and calculation of the concentration factor of the xanthate in the foam. The results of these tests are shown in Table 7 below.

In a first of these experiments, an anionic surfactant, namely dodecyl sulfate, was used at a pH of 9.2. In a second experiment, cationic dodecylamine was used as a surfactant at pH 9.2. In a further eight experiments (Experiments 3 to 10), acetates of the primary uncured tallow amine were used as cationic surfactants at different pH values and in different surfactant to xanthate ratios according to Table 7 below.

The concentration factor was calculated by dividing the xanthate concentration in the foam by the xanthate concentration in the remaining liquid. Table 7 Surfactant added to the xanthate solution Trial No. pH Ratio of surfactant: xanthate at the initial concentration Concentration factor in the foam Dodecyl sulfate 1 9.2 2: 1 1.02 Dodecylamine 2nd 9.2 2: 1 2.24 uncured tallow amine acetate 3rd 8.5 2: 1 4.20 4th 8.5 1: 1 3.60 uncured tallow amine acetate 5 9.2 2: 1 3.20 6 9.2 1: 1 1.80 7 9.2 0.50: 1 1.80 8th 9.2 0.25: 1 1.20 uncured tallow amine acetate 9 10.5 2: 1 0.60 10th 10.5 1: 1 0.70

As can be seen from Table 7 and as could be expected, the anionic surfactant, dodecyl sulfate, did not interact or not associate with the xanthate; accordingly, there is no increase at all in the relative concentration of the xanthate in the foam. However, there was a significant increase in the xanthate concentration in the foam when the cationic surfactants (i.e., dodecylamine and primary amine acetate) were used at appropriate pH values. At pH values of 10.5, which are above the pKa values of the amine salts used in these experiments, the amine no longer occurs in a cationic form; Therefore, it is not expected to interact or associate with the xanthate anion.

Examples 8 and 9: Flotation of a South African gold ore.

Example 3 was repeated with diisobutyldithiophosphate (dialkyldithiophosphate) instead of xanthate in the amounts given in Table 9, with an ore sample from the underflow of a cyclone from a tertiary grinding circle, which was used instead of the finely ground ores used in the previous examples; the additives explained in Table 8 were also used. Table 8 Summary of the display properties as well as the composition and amount of additives for flotation Ground ore : Grinding size like in the underflow of a cyclone of a tertiary grinding circuit Opacity 68% by weight solid density 1.82 Flotation aids : Collector: Dialkyldithiophosphate TROCOL S50 (see example 3) additional foamer: DOWFROTH 200 Pusher: ACROL J2P 350 pH modifier: Lime (ie CaO) pH value : 11 Flotation time : 2 min

Examples 8 and 9 show "flash flotation", which is used when a highly enriched, small concentrate mass is required. By definition, "flash flotation" comprises a relatively short flotation time. Accordingly, the flotation times for Examples 8 and 9 were only 2 minutes. A longer flotation time would have resulted in a higher yield of gold and sulfur, but in a less enriched concentrate of greater mass. Table 9 Additives for the milled ore of Examples 8 and 9 (g / t solids in the original slurry) Example No. Dialkyl dithiophosphate TROCOL S50 DOWFROTH 200 ACROL® J2P 350 8th 10th 20th 30th - 9 10th 40 30th 10th Analysis results after flotations according to Examples 8 and 9. gold Total sulfur Example No. product % By weight Content g / t % Spread Salary% S % Spread 8th concentrate 2.8 804.00 86.4 1.47 3.5 Exits 97.2 3.65 13.6 1.18 96.5 Ber. for task 100.00 26.10 100.00 1.19 100.00 9 concentrate 3.0 855.00 85.5 9.49 24.4 Exits 97.0 3.45 11.5 0.91 75.6 Ber. for task 100.0 29.00 100.00 1.17 100.00

As can be seen from Table 10, the application of gold from the concentrate after pre-flotation is more favorable when using a collector with a primary amine and a dithiophosphate than the application of gold from a collector that contains a primary amine and a xanthate (see Examples 4 to 6) contains. However, the sulfur output in the concentrate after pre-flotation according to Examples 8 and 9, in which dithiophosphate was used together with the acetate of a primary amine, is significantly lower than in Examples 4 to 6, in which the xanthate together with the acetate one primary amine was used. Accordingly, collectors containing a mixture of a primary or secondary amine and a thiophosphate in the absence of copper sulfate are for such Flotation systems are more suitable, where the application of sulfur is of secondary importance.

Examples 10 and 11 below were carried out with fabrication waste that had been discarded as a gold mining waste a few years ago and in which residual cyanide had decomposed in air.

Example 10: Flotation of manufacturing exits.

A certain amount of fabrication exits from previous gold mining processes were milled with water to form a slurry with a grinding size of 70% <0.074 mm (200 mesh) and a slurry density of 38% by weight solids or a density of 1.32. Sulfuric acid 48 was added to the slurry to adjust the pH to 4.0. The resulting mixture was conditioned in a Pachuca tank 49 for six hours.

First there was a first flotation 50.1 in the usual way with the slurry 52 originally used, which consisted of the ground ore in water and the following flotation aids 54:
Sodium mercaptobenzothiazole (SENKOL® 50) in an amount of 80 g per metric ton of solid in the slurry, as a collector,
ACROL® J2P 350 in a quantity of 60 g per metric ton of solid in the slurry, as a pusher
DOWFROTH 200 in an amount of 20 g per metric ton of solid in the slurry, as a foamer, and
Copper sulfate in an amount of 60 g per metric ton of solid in the slurry, for the activation of sulfidic minerals and foam modification.

5 minutes after the start of flotation 50.1, the slurry 52 gave a foam product with a first concentrate 54.1, which contained gold and other sulfidic minerals and was contaminated with a limited amount of the gangue minerals originally present in the ground ore. The concentrate 54.1 was separated off in the usual way; the flotation was continued with a second flotation 50.2 with the remaining turbidity 52. 10 minutes later, another foam product, which contained a second concentrate 54.2, had accumulated on the surface of the slurry. In addition, the exits 56 were preserved, which contained the majority of the aisle minerals originally present in the manufacturing exits.

The first and second flotation 50.1, 50.2 were carried out in the usual manner and are shown in the flow diagram according to FIG. 4.

Concentrate 54.2, like concentrate 54.1, contained gold and other sulfidic minerals contaminated with gangue minerals. The concentrate 54.2 was separated from the outlets 56.

The concentrate 54.1, the concentrate 54.2 and the outlets 56 were dried and analyzed in the usual way. The results of the analysis are summarized in Table 12. Table 11 Summary of the properties of the fabrication exits as well as the composition and quantity of additives for the first and second flotation. Ground ore : Grinding size 70% <0.074 mm (200 mesh) Opacity 38% by weight solid density 1.32 Flotation aids : Collector: Na mercaptobenzthiazole 80 g / t Foamer: DOWFROTH 200 20 g / t Pusher: ACROL® J2P 350 60 g / t Activator / foam modifier: Copper sulfate 60 g / t Flotation pH : 9.2 Flotation time: 5 min for the first flotation 10 min for the second flotation Analysis results of the flotation products gold Total sulfur % By weight Content g / t % Spread Salary% S % Spread Concentrate 1 1.6 5.2 21.1 28.76 55.0 Concentrate 2 1.7 5.25 22.7 11.92 24.2 Concentrates 1 + 2 3.3 5.22 43.8 20.08 79.2 Exits 96.7 0.23 56.2 0.18 20.8 for task 100.0 0.40 100.0 0.83 100.0

Example 11: Flotation of manufacturing exits.

A certain amount of manufacturing waste from previous gold mining operations was milled with water to create a cloudy solution. Lime 58 was added to the slurry to adjust the pH to 9.2; the resulting mixture was conditioned in a Pachuca tank 59 for 45 minutes.

As described in Example 10, a first flotation 60.1 was carried out, but with flotation aids 62, which included a collector mixture according to the invention and which are explained in more detail in Table 13. A concentrate 64.1 was obtained.

• a) der pH-Wert der restlichen Trübe durch Zugabe von Schwefelsäure 66 auf 4 eingestellt und die Trübe bei diesem pH-Wert etwa 45 min in einem Pachuca-Tank kondi­tioniert; anschließend wurden
• b) die Flotationshilfsmittel 70 gemäß Tabelle 13 zugesetzt.

After the first flotation 60.1, a second flotation 60.2 was carried out in the customary manner as described in Example 10, a second concentrate 64.2 being obtained. Before the second flotation, however, 60.2

• a) the pH of the remaining slurry is adjusted to 4 by adding sulfuric acid 66 and the slurry is conditioned at this pH for about 45 minutes in a Pachuca tank; subsequently
• b) the flotation aids 70 according to Table 13 are added.

As in Example 10, the second flotation was carried out for 10 minutes before the resulting second concentrate 64.2 and the exits 72 were collected. Table 13 Summary of the characteristics and the composition as well as the amount of additives for the first and second flotation. A. For the first flotation. Ground ore : Grinding size 70% <0.074 mm (200 mesh) Opacity 38% by weight solid density 1.32 Flotation aids : Collector: Na-n-propylxanthate 10 g / t and TROCOL S50 (see example 3) 10 g / t Foamer: DOWFROTH 200 12 g / t Pusher: ACROL® J2P 350 40 g / t Activator / foam modifier: Copper sulfate 40 g / t pH regulator: Lime (CaO) pH : 9.2 Flotation time : 5 min B. For the second procedure. Flotation aids : Collector: Na mercaptobenzthiazole 80 g / t Foamer: DOWFROTH 200 4 g / t Pusher: ACROL® J2P 350 60 g / t Activator / foam modifier: Copper sulfate 30 g / t pH regulator: sulfuric acid pH : 4.0 Flotation time : 10 min Analysis results of the flotation products gold Total sulfur % By weight Content g / t % Spread Salary% S % Spread Concentrate 1. 1.0 10.55 26.61 25.3 34.5 Concentrate 2 1.8 6.00 25.9 20.46 47.8 Concentrates 1 + 2 2.8 7.63 51.2 22.65 82.3 Exits 97.2 0.21 48.8 0.14 17.7 for task 100.0 0.42 100.0 0.77 100.0

As can be seen from Tables 12 and 14, the combined application of gold in the combined concentrates using a collector mixture of the invention was more favorable than application of gold using a conventional collector. It is noteworthy that in the first 5 minutes of flotation with that with the collector mixture of the invention in alkaline medium (ie pH 9.2), the yield of gold was higher than in the first 5 minutes of flotation with a conventional collector in acid medium. The sulfur output was higher when the collector mixture according to the invention was used. Furthermore, the gold and sulfur contents were in the combined Concentrates higher when using the collector mixture according to the invention.

The effectiveness and ease of handling of the flotation aids, in particular when using the TROCOL reagent mixture, and the improved yield of minerals to be obtained are further advantages of the invention.

In the flotation of ores and stored manufacturing processes, in which the usual flotation using xanthates or other sulfhydryl collectors under alkaline conditions does not give satisfactory results, it is common to add acid and to float gold and sulfidic minerals with collectors such as sodium mercaptobenzothiazole. However, this involves additional costs, since acid is used and the exits have to be neutralized with lime. However, the method and the flotation aids of the invention also enable satisfactory flotation under alkaline conditions so that less acidification is required and the resulting neutralization costs are reduced.

Claims (28)

1. A process for the extraction of minerals from ores by flotation, in which ground ore is mixed with water to form an ore suspension, air is introduced into the suspension in the presence of a collector system and the resulting foam is separated off together with the ore content therein, characterized in that as a collector a mixture containing
at least one amine compound A from that of unsubstituted primary and secondary amines of the formulas I and II,
RNH₂ (I)
R¹R²NH (II)
in which R, R¹ and R² each represent alkyl or alkenyl radicals having 8 to 22 carbon atoms, and salts of the group consisting of primary and secondary amines and
- At least one thio compound B from the group formed from xanthates, dithiophosphates, mercaptobenzthiazoles, xanthogen formates (alkyl carbonic acid-alkyl xanthogen anhydrides) and thionocarbamates
starts. 2. The method according to claim 1, characterized in that amines of the formulas I and II are used, in which R, R¹ and R² each represent straight-chain alkyl or alkenyl radicals. 3. The method according to at least one of claims 1 and 2, characterized in that the amine compound A is an acetate salt of a primary or secondary amine. 4. The method according to at least one of claims 1 and 2, characterized in that the amine compound A is a chloride salt of a primary or secondary amine. 5. The method according to at least one of claims 1 to 4, characterized in that the thio compound B is a xanthate of the formula III,
ROC (S) -S⁻ X⁺ (III)
in which R is an alkyl radical having 2 to 8 carbon atoms and X is Na or K. 6. The method according to at least one of claims 1 to 4, characterized in that the thio compound B is a dithiophosphate of the formula IV,
(RO) ₂P (S) -S⁻ X⁺ (IV)
in which R is an alkyl radical having 2 to 8 carbon atoms and X is Na or K. 7. The method according to at least one of claims 1 to 4, characterized in that the thio compound B is a dialkyl xanthogen formate (alkyl carbonic acid-alkyl xanthogen anhydride) of the formula V,
R¹-OC (S) -SC (O) -O-R² (V)
in which R¹ and R² each represent an alkyl radical having 1 to 8 carbon atoms. 8. The method according to at least one of claims 1 to 4, characterized in that the thio compound B is a dialkylthionocarbamate of the formula VI,
R¹-OC (S) -NHR² (VI)
in which R¹ and R² each represent an alkyl radical having 1 to 8 carbon atoms. 9. The method according to at least one of claims 1 to 4, characterized in that the thio compound B is a sodium or potassium salt of a mercaptobenzothiazole. 10. The method according to at least one of claims 1 to 9, characterized in that the mass ratio of amine compound A to thio compound B is in the range from 1: 9 to 9: 1, preferably in the range from 1: 4 to 2: 1. 11. The method according to at least one of claims 1 to 10, characterized in that the amine compound A is added to the ore suspension as part of a mixture comprising the amine compound A, a neutral hydrocarbon oil and a foamer in a mass ratio of (4-6): ( 3 - 5): 1 contains. 12. The method according to at least one of claims 1 to 11, characterized in that the ore suspension, the amine compound A in an amount of 1 to 500 g per metric ton of ore and the thio compound B in an amount of 1 to 500 g per metric ton of ore. 13. The method according to at least one of claims 1 to 12, characterized in that the mineral is a sulfidic mineral. 14. The method according to at least one of claims 1 to 12, characterized in that minerals are obtained from the foam, the at least one of the elements made of gold, platinum, uranium, copper, zinc, nickel, cobalt, silver, lead and iron formed group included. 15. The method according to at least one of claims 1 to 14, characterized in that the amine compound A is an acetate of a primary alkyl / alkenylamine having 10 to 18 carbon atoms. 16. Collector mix for use in the extraction of minerals from ores by flotation containing
at least one amine compound A from that of unsubstituted primary and secondary amines of the formulas I and II,
RNH₂ (I)
R¹R²NH (II)
in which R, R¹ and R² each represent alkyl or alkenyl radicals having 8 to 22 carbon atoms and salts of the group consisting of primary and secondary amines and
- At least one thio compound B from the group formed from xanthates, dithiophosphates, mercaptobenzthiazoles, xanthogen formates (alkylcarbonic acid-alkylxanthogenic acid I anhydrides) and thiocarbamates. 17. A collector mixture according to claim 16, characterized in that the amine compound A is an acetate salt of a primary or secondary amine. 18. A collector mixture according to claim 16, characterized in that the amine compound A is a chloride salt of a primary or secondary amine. 19. collector mixture according to at least one of claims 16 to 18, characterized in that the thio compound B is a xanthate of the formula III,
ROC (S) -S⁻ X⁺ (III)
in which R is an alkyl radical having 2 to 8 carbon atoms and X is Na or K. 20. collector mixture according to at least one of claims 16 to 18, characterized in that the thio compound B is a thiophosphate of the formula (IV),
(RO) ₂P (S) -S⁻ X⁺ (IV)
in which R is an alkyl radical having 2 to 8 carbon atoms and X is Na or K. 21. A collector mixture according to at least one of claims 16 to 18, characterized in that the thio compound B is a dialkyl xanthogen formate of the formula (V),
R¹-OC (S) -SC (O) -O-R² (V)
in which R¹ and R² each represent alkyl radicals having 1 to 8 carbon atoms. 22. collector mixture according to at least one of claims 16 to 18, characterized in that the thio compound B is a dialkylthionocarbamate of the formula (VI),
R¹-OC (S) -NHR² (VI)
in which R¹ and R² each represent alkyl radicals having 1 to 8 carbon atoms. 23. collector mix according to at least one of claims 16 to 18, characterized in that the thio compound B is a sodium or potassium salt of a mercaptobenzothiazole. 24. Collector mixture according to at least one of claims 16 to 23, characterized in that the mass ratio of amine compound A to thio compound B is in the range from 1: 9 to 9: 1, preferably in the range from 1: 4 to 2: 1. 25. Collector mixture according to at least one of claims 16 to 24, characterized in that the amine compound A is an acetate of a primary alkyl / alkenylamine having 10 to 18 carbon atoms. 26. A collector mixture according to claim 25, characterized in that the thio compound B is a xanthate. 27. A collector mixture according to claim 25, characterized in that the thio compound B is a dialkyldithiophosphate. 28. Flotation aid mixture for use in connection with at least one thio compound B from the group formed from xanthates, dithiophosphates, mercaptobenzthiazoles, xanthogen formates (alkylcarbonic acid-alkylxanthogenic acid anhydrides) and thiocarbamates, characterized by a content of
at least one amine compound A from that of unsubstituted primary and secondary amines of the formulas I and II,
RNH₂ (I)
R¹R²NH (II)
in which R, R¹ and R² each represent alkyl or alkenyl radicals having 8 to 22 carbon atoms, and salts of the group formed above primary and secondary amines,
- a neutral hydrocarbon oil and
- a foamer,
in a mass ratio of (4 - 6): (3 - 5): 1.

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