EA032176B1 - Collector for froth flotation of clay minerals from potash ores - Google Patents

Abstract

The invention relates to a flotation process for removal of slimes from potash ores wherein a collector is used which is a propoxylated ethoxylated fatty amine having the formula (I) wherein R1 is a hydrocarbyl group having 8-24 C-atoms, the sum of all m is on average 2-6, and the sum of all n is on average at least 15 and at most 100.

Description

The invention relates to a flotation method for removing sludge from potassium ores, in which a collector is used, which is a propoxylated ethoxylated fatty amine of the formula (I), where K1 is an alkyl group of 8-24 carbon atoms, the sum of all w is on average 2 -6 and the sum of all n averages at least 15, at most 100.

032176 Β1, SCr - CH — O) _t (CH3CHNgO → H

sn.

(I)

Technical field

The invention relates to a method for removing clay sludge from potassium ores by flotation of at least a portion of said sludge using one or more specific propoxylated ethoxylated primary fatty amines as a collector.

State of the art

Foam flotation of potassium ore is a common way to extract sylvin (KC1) from ore pulp. Examples of potassium ores are sylvinite, carnallite, langbainite and cainite.

Common barren minerals, in addition to halite (IaC1), are various types of water-insoluble fine-grained minerals, such as clay minerals, silicate-carbonate minerals, anhydrites, iron oxides, etc., often collectively referred to as sludge. Siliceous waste rock (clay) consists of very small particles and has a large surface area, which negatively affects the extraction of sylvin (KC1) from potassium ore by the method of foam flotation. The collector used during flotation is usually adsorbed on clay, which leads to a large consumption of the collector and a small yield of metal. Clay also complicates other sylvin enrichment processes, such as dissolution.

Some technical developments were aimed at solving problems caused by the presence of sludge. Mechanical methods, such as the use of hydrocyclones, centrifuges, hydroseparators, etc., are non-selective and lead to the loss of fine particles of sylvin. Some patents are devoted to a method in which clay-containing sylvinite ores are cleaned of sludge by selective flocculation of sludge (clay) and subsequent foam flotation of the sludge. Polyacrylamides are mainly used as flocculants; some compounds are proposed as collectors. Examples of collectors described in the literature are ethoxylated primary amines (I8 3805951 and KI 2278739), mixtures of nonionic and anionic collectors (I8 4192737), ethoxylated fatty acids (I8 1304893) and ethoxylated alkyl phenol (KI 2237521).

I8 3805951 describes a method for purification of sylvinite ores from sludge by selective flocculation and subsequent foam flotation of sludge. This method involves treating ore pulp with a high molecular weight acrylamide polymer to flocculate the sludge and then a cationic collector, which is, for example, the condensation product of 1 to 10 moles of ethylene oxide with 1 mole of primary or secondary aliphatic amine C12-C18.

No. 1,068,191 discloses a method for flotation of potassium ores using ethoxylated fatty amines.

KI 2278739 describes a method for beneficiating potassium ores, which involves grinding ore, removing water-insoluble clay-carbonate impurities by forming a flotation suspension and subsequent flotation of potassium chloride. The compounds used to form the flotation suspension are ethoxylated primary amines with 15-50 ethoxy groups per mole of amine.

However, there is still a need for more effective potassium sludge purification agents that would not adversely affect potassium recovery.

Description of the invention

It was unexpectedly discovered that compounds of the formula

K1 ----- Ν '

CH ₂ CH — O—

H (I) sn ₃ where K1 is a hydrocarbon group consisting of 8-24, preferably 12-22, most preferably 16-22 carbon atoms, the sum of all m is on average 2-6, preferably 2-5, the sum of all η is on average, at least 15, preferably at least 20, at most 100, preferably at most 80, more preferably at most 60, even more preferably at most 50, even more preferably at most 40, most preferably at most 35, are very effective collectors to remove slurry of potassium ores. It should be noted that the compounds of formula (I) of the present invention contain two oxyalkylene chains, however, these two chains do not have to be the same.

In addition, it should be noted that since these compounds are prepared by sequentially propoxylating the fatty amine with equivalents of a propoxylating reagent and ethoxylating with η equivalents of an ethoxylating reagent, the hydroxypropyl groups are closer to the nitrogen atom than the hydroxyethyl groups. In addition, due to the fact that propoxylated ethoxylated fatty amines can be obtained in this way, they do not have to be pure products,

- 1,032,176 consisting of only one compound, on the contrary, they can also be compositions containing various propoxylated ethoxylated fatty amines that satisfy the above average values for t and n.

Few documents of the prior art describe similar compounds corresponding to the formula (I). For example, CB 1112390 discloses propoxylated ethoxylated amines, which are an intermediate that reacts with hydroxyethanesulfonic acid or hydroxypropanesulfonic acid to thereby produce sulfonic acid-functional surface-active compounds that are said to be suitable for ore flotation. EP 2444527 A2 discloses the use of the propoxylated ethoxylated amine surfactant (SAS) EShortorotepep ™ C18 / 18 in the electrodeposition of tin. None of these documents of the prior art describes or proposes the use of propoxylated ethoxylated amines of formula (I) to remove sludge from potassium ores, not to mention its advantages.

Thus, the invention relates to a method for flotation of sludge from potassium ores by using propoxylated ethoxylated fatty amines of the formula (I) as collectors. In this method, collectors are added to ore pulp subjected to flotation treatment.

Thus, in a first embodiment, the present invention relates to a method in which the compounds of formula (I) are used as collectors.

One of the preferred embodiments of the invention is a method in which the compounds of formula (I), wherein K1 is a hydrocarbon group consisting of 16-22 carbon atoms, the sum of all m is 2-5, the sum of all n is 15-50, as collectors. The hydrocarbon group K1 in a preferred embodiment of the invention is an aliphatic group, which may be a saturated alkyl or unsaturated alkenyl group and a linear or branched group.

When using new collectors, it is possible to improve the separation of water-insoluble components (sludge), and preferably there is no negative effect on the extraction of sylvin. More preferably, sylvin recovery is enhanced when the method of the present invention is used, compared to a method that uses a prior art manifold.

The method of the present invention typically includes the steps of:

a) the formation of pulp of ground potassium ore containing a potassium mineral and a clay component in an aqueous medium, which is typically a saturated saline solution, preferably a saline solution, saturated with dissolved potassium ore from a real ore deposit;

b) conditioning the ore pulp with a flocculant and a collector of formula (I) as defined above;

c) introducing air into the conditioned ore pulp;

b) removal of the resulting foam.

The collector of the present invention is added to an aqueous suspension containing ore in an amount effective to achieve flotation of sludge from the ore. An effective amount is usually from 5 to 500 g of collector per 1000 kg of solid ore. It is preferable to use from 15 to 50 g of collector per 1000 kg of solid ore. During flotation, the clay component accumulates in the foam, due to which the product of the flotation chamber is depleted in the clay component.

Flocculants suitable for the method described above are those compounds known to those skilled in the art that are capable of flocculating clay mineral particles in a mineral pulp, for example, among others, polyacrylamides and copolymers of acrylamide with other ethylenically unsaturated monomers such as acrylic acid.

In the conditioning step, the flocculant is preferably added to the ore pulp prior to the addition of a collector of formula (I).

The resulting sylvin-rich flotation chamber product is then, as a rule, further purified in the second flotation stage, while the sylvin is floated.

Thus, another embodiment of the present invention also relates to a method in which the first treatment of the invention is followed by an additional step, which involves flotation of sylvin using another collector. This other collector is preferably a fatty amine.

The present invention is further illustrated by the following examples with reference to the accompanying drawing.

Brief Description of the Drawing

The drawing graphically shows the results obtained in the example described below. The extraction of water-insoluble components (^ T.) in the foam product (%) is presented as a function of the number of units of propylene oxide (PO) in the collectors.

Examples.

Description of the experiment.

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Flotation procedure.

The way.

When practicing the invention, potassium ore was ground to a particle size suitable for flotation and washed in water saturated with dissolved potassium ore from a real ore deposit. Then the pulp was loaded into a flotation machine and diluted to an appropriate concentration. The machine was turned on and the appropriate amount of flocculating polymer was added in the form of a 0.1-0.5% aqueous solution. In the examples used 20 g of polyacrylamide per 1000 kg of ore. Then a collector diluted in water was added, the pulp was conditioned for several minutes. The air supply was turned on, the resulting foam containing sludge (water-insoluble components) was removed as flotation tails.

The flotation chamber product (non-flotation), also known as the bottom product, contains concentrated potassium ore, ready for further processing.

Samples of the foam fraction containing mainly the slurry product and the lower product were dried and analyzed for the content of KCl and water-insoluble components (W.1.) In both fractions. To assess the results, a material balance was calculated, i.e. extracting KS1 and Sh.1. The content of KC1 and W.1. in flotation feedstock (ore sample subjected to flotation treatment) was calculated as the sum of the recorded content in the foam product and the bottom product for each test. When comparing with the general analysis, there are some differences that can be explained as small variations in the ore sample and variations between different analyzes. The test results are shown in the following tables.

In the foam product, the content and extraction of KC1 should be low, and the content and extraction of Ш.1. should be high. If this condition is fulfilled, this means that flotation is efficient and selective, and the loss of valuable mineral KC1 is small. The bottom product must contain W.1. only to a small extent. The selectivity index (KC1 extraction / extraction Sh.1.) Is calculated to illustrate the selectivity, this value should be low. All percentages are given in weight percent.

Example.

In this example, the sludge was floated from potassium ore, containing, on average, 30.5 wt.% (% Wt./weight.) KC1 and 5.0-5.5% wt./weight. water-insoluble components (W.1.). Polyacrylamide (Aeeoy A110, molecular weight 1.9x10 ⁶ Ό) was present as a flocculant in an amount of 20 g / 1000 kg of ore.

Used collectors are listed in table. one.

Table 1

Collectors Compound A (for comparison) tall alkylamine - 30 EO Compound B tall alkylamine - 2 PO - 30 EO Compound C tall alkylamine - 4 PO - 30 EO Connection ϋ tall alkylamine - 4 PO - 35 EO Compound E tall alkylamine - 4 PO - 40 EO Compound E tall alkylamine - 5.2 PO - 30 EO Compound C tall alkylamine - 5.2 PO - 35 EO Compound H tall alkylamine - 5.2 PO - 40 EO

In all trials, the dosage of the collector (AH) was 35 g / 1000 kg of ore.

The content of KC1 and W.1 was determined. in the foam product and the bottom product. Based on these values and the specific recovery of the foam product and the lower product, the total content of KC1 and W.1 was calculated. in the ore sample used for flotation (see table. 2B). Then, determining the selectivity index for the foam product, we calculated the extraction value of KC1 and W.1. in the foam product for all flotation tests. The results are presented in table. 2A.

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Table 2A

Test No. RO ¹¹ EO ¹¹ Foam sludge flotation product Kselect will Lower product fl. Specific extraction,% Content,% Recovery% Content,% KC1 I. I. KC1 I. I. KC1 I. I. 1 Comparison A 0 thirty 10.8 23.1 28.8 9.1 61.5 0.148 31.5 2.20 2 Compound B 2 thirty 11.8 24.7 27,2 9.5 62.9 0.151 31.7 2.15 3 Compound C four thirty 11,4 23.6 29.0 8.8 63.5 0.138 31,4 2.15 4 Connection ϋ four 35 12.8 25.5 26, 8 10.7 64.9 0.165 31.1 2.10 5 Connection E four 40 12.7 25.1 26, 6 10.5 64,2 0.163 31.3 2.15 6 Connection E 5.2 thirty 10.6 23.9 30,4 8.2 62.0 0.133 31,4 2.20 7 Compound C 5.2 35 11.8 24.4 28,2 9.5 62.5 0.151 31.3 2.25 8 Connection N 5.2 40 11.2 24.1 29.2 8.9 62.1 0.144 31,0 2.25

¹⁾ Moles of PO per mole of tall alkylamine.

²⁾ Moles of EO per mole of tall alkylamine or propoxylated tall alkylamine.

Table 2B

Ore sample, calculated grade (%) KC1 I. I. 1 (Comparison) 30, 9 5.1 2 30, 9 5.1 3 30.5 5.2 four 30,4 5.3 five 30.5 5.3 6 30, 6 5.2 7 30.5 5.3 eight 30,2 5.2

When using the same dosage, extract No. 1. was higher for a flotation experiment carried out with a propoxylated and ethoxylated primary (tall alkyl) amine in accordance with the invention than with an ethoxylated primary amine (30 EO), which was used as an example of the prior art.

The selectivity index indicates that in all tests, and for comparison, and examples of the invention, the selectivity was similar. This means that the product corresponding to the invention is more effective than the reference substance during the flotation of the slurry product from potassium ore and does not increase the loss of KCl.

An increase in recovery is also shown in the drawing, where the results obtained for the extraction of water-insoluble components (No. 1.) In the foam product (%) are plotted as a function of the number of propylene oxide (PO) units in the collectors.

Obviously, these results demonstrate an improvement over the product containing 0 PO and 30 moles of EO per mole of amine. It was unexpectedly found that the introduction of PO in accordance with the invention increases the recovery of water-insoluble components at a given dosage of the collector.

Claims (10)

CLAIM 1. The use of a propoxylated ethoxylated fatty amine of the formula where K1 is a hydrocarbon group of 8-24 carbon atoms, the sum of all m averages 2-6 and the sum of all η averages at least 15 and at most 100, as a collector in the process of foam flotation to remove sludge from potassium ores. - 4 032176 2. The use according to claim 1, in which K1 means a hydrocarbon group consisting of 12-22 carbon atoms. 3. The use of claim 1 or 2, wherein the sum of all η averages at least 20. 4. The use according to any one of claims 1 to 3, in which the sum of all m is on average 2-5. 5. The use according to any one of claims 1 to 4, in which the sum of all η is at most 80. 6. The use according to any one of claims 1 to 5, in which the propoxylated ethoxylated fatty amine has the formula (I) in which K1 is a hydrocarbon group consisting of 12-22 carbon atoms, the sum of all m is 2-5, the sum of all η is 15-50. 7. The use according to claim 6, in which the propoxylated ethoxylated fatty amine has the formula (I), in which K1 and the sum of all m are as described in claim 6, and the sum of all η is 20-40. 8. The use according to claim 7, in which the propoxylated ethoxylated fatty amine has the formula (I) in which K1 means a hydrocarbon group consisting of 16-22 carbon atoms. 9. A foam flotation method for removing sludge from potassium ores using a collector having the formula (I) described in any one of claims 1 to 8. 10. The method according to claim 9, which includes the steps of: a) pulp formation of ground potassium ore containing potassium mineral and clay component in an aqueous medium; b) conditioning the ore pulp with a flocculant and a collector having the formula (I) described in any one of claims 1 to 8; c) introducing air into the conditioned ore pulp; ά) removal of the resulting foam. 66,0 _Ί --tallovy alkylamine-XPO-ZOEO -a-tallow alkylamine-XPO-35EO ^|! tall alkylamine-xRO-40EO Collector dosage 35 g / t 65.0 ή f Wed o '' About t f