DE1155072B - Process for the flotation of very fine-grained minerals - Google Patents

Description

Process for the flotation of very fine-grained minerals The invention relates is based on a process for the flotation of very fine-grained minerals with the exception of sulphidic and silicate minerals.

It is known that saturated and unsaturated fatty acids act as collectors be used for the flotation of oxidic ores in alkaline or acidic pulp. The aim is for the collector molecules to be distributed as evenly as possible in the pulp the fatty acids are often added in the form of their soluble salts which also have a better possibility of attachment via the free valence to the COO group is given. The fatty acid flotation must be acidic in the case of oxidic ores Range in order to achieve sufficient selectivity. However, since the relatively weak free fatty acid precipitates in the acidic range, the collector, apart from the slight dissociation of the acid, only adsorptively on the mineral are accumulated.

The often considerable difficulties also caused great difficulties Shares of the finest grains that were contained in the goods to be floated, so that until today the desludging of the minerals before the flotation is necessary was deemed. The adverse effect of the finest grains of the goods from under about 60 μ is mainly due to the fact that they blur the differences in selectivity and increase the collector consumption so much that processing by means of flotation is no longer economical. However, this will be achieved through prior desludging Overall yield decreased. In addition, are with the sludge produced by the Due to extensive sludge management, very high investment costs and operating costs tied together.

The object of the invention is to create a flotation process which enables the flotation of minerals that contain considerable proportions of very fine material. This object is achieved by using fatty acid condensation products with aminocarboxylic acids, with taurine, alkyl taurine, aryl taurine and / or salts of these products as collectors during flotation, specifically in the case of minerals with an upper grain size in the range of 100 t, in which at least one large part of the goods has grain sizes of less than 60 #t.

While there is already the use of sodium lauryl sarcosinate as a Flotation agents have been proposed, however, this proposal will convey this to those skilled in the art not the doctrine that it is possible to use this agent as a collector and in particular using the collector group according to the invention with minerals to float a considerable amount of very fine-grained material. As stated above was, one has rather so far the desludging of minerals, which is a very fine-grained Well contained, deemed necessary before flotation.

When using the collector according to the invention it is now possible even minerals containing very fine-grained components without prior desludging to float, so that a much simpler treatment process than so far and the very extensive, associated with a desludging of the ore Sludge economy is avoided. So there are significant costs in the processing saved.

The collectors according to the invention also offer the advantage that both In the acidic as well as in the basic area there are good attachment possibilities are. This significantly improves the collector effect.

In the case of minerals, which consist only of elements, and in the case of coal, can the attachment of the collector molecule via coordinated bonds with the molecules of the mineral.

The collectors according to the invention also offer the advantage that their collector effect on different minerals in contrast to the fatty acids depends very much on the pH of the flotation pulp and the amount of collector added. It also depends on the accessibility of the mineral cations on the cleavage surfaces the minerals and the solubility of that formed by the mineral cations and the collector Off the salt.

As a result of these dependencies arise in a further embodiment the following possibilities of the method according to the invention, the swimming behavior the to influence individual minerals differently.

Minerals, whose ability to chemically attach the collector, varies is large, can be selective in that way, possibly with saving oppressive Means to be floated that with a small amount of collector, which only for Floating the most easily floatable mineral is sufficient, this mineral is swum and that, if further minerals are to be floated, the flotation of these minerals each with higher collector concentrations in the flotation pulp he follows.

Minerals whose floatability changes with changing pu values of the Turbidity changes to different degrees, can be selectively floated in such a way that at a certain pH value the mineral is swum first, which The easiest floatable at this pH value is that the pH value of the pulp is thereafter is set to a value at which the other mineral is easily floatable, and that the other mineral is then floated up.

The options listed here for training the process according to the invention can also be used for minerals, which consist of individual Elements exist, and with coal.

Physical factors must also be taken into account during flotation, such as turbidity temperature, grain size, etc.

In a further embodiment of the invention, the amount and the properties of the foam produced during flotation by adding silicone oil and / or a soap solution. The amount added depends on the Character of the ore and the collector. By adding silicone oil or a Soap solution can with a collector who is at the same time a foamer and a large amount of foam developed, the purity of the product produced can be greatly improved. aside from that the destruction of the foam is facilitated.

As the effectiveness of the collector according to the invention, as from the above It can be seen very much from the reactivity of the cations Minerals with the collector and the structure of the crystal lattice of the minerals as well as the resulting position of the cations on the cleavage surfaces, is The grid structure is given here as an example for some minerals.

1. Quartz (SiO2) forms SiO # tetrahedra, in which the small Si cation is surrounded by four oxygen ions, which are relative to the Si cation have a large ionic radius, so that the Si cation is completely packed. the Bonds in the SiO # tetrahedron are so strong that they cannot be damaged by mechanical forces can be destroyed. The bonding forces between the oxygen atoms are different SiO # tetrahedra are relatively small, so that the cleavage surfaces after these Zones of weakness run. This results in the shell-like break. This stands for the addition of an anion-active collector with quartz no cation is available. To It is evident from these explanations that quartz can be used with the collectors according to FIG Invention can not be swum.

2. Wolframite, (Fe, Mn) WO4, crystallizes in a monoclinic prismatic manner. being Lattice type is sufficiently marked with the Schoenfliesschen symbol C, #,. on Because of this type of lattice and the binding forces in the lattice, wolframite cleaves preferentially after the area (010). Two Fe and Mn ions are exposed on this surface which the collector anion can attach via a chemical compound.

3. Tin stone (SnO2) crystallizes ditetragonal-dipyramidal. Because of of the lattice type D '4 (rutile lattice) 4h splits tin stone imperfectly according to the surface (100), on which four Sn ions are exposed at the edges of the elementary lattice, see above that the collector and the tin stone are deposited here via a chemical compound can be made buoyant.

4. Lead luster (PbS) has an ion lattice of the NaCl type. It divides preferably after the area (110) on which five Pb cations per elementary lattice are free to which the collector can attach itself via a chemical compound.

5. Cerussite (PbCO3) crystallizes rhombic-dipyramidal and splits imperfect after the surface (110). No Pb ions are exposed on this surface. To the requirement of an accumulation via a chemical connection of collector ions To create the Pb cation, the CO3 complexes have to be removed from the cerussite lattice can be dissolved out by acidifying the flotation pulp. Then the Pb cations lie free, and the collector can accumulate via a chemical compound. One can So cerussite float in the acidic area with collectors according to the invention and needs no longer to sulfide.

6. Scheelite (CaWO4) crystallizes tetragonal-pyramidal and possesses a body centered tetragonal grid. Because of this type of lattice and the binding forces Scheelite can split in the lattice according to the surface (101), so that on the split surfaces two Ca ions each are exposed. Collector anions can transfer to these Ca ions add a chemical compound. The solubility of the salt from Ca ion and collector ion is very small, so that scheelite can be floated relatively easily.

7. Magnetite (Fe3O4) crystallizes cubic-hexakisoctahedral and splits according to the surface (111). Due to the lattice structure and the splittability, an Fe ion is exposed on each of the six edges of the octahedron, on which a chemical attachment of the collector can take place.

8. Chromite (FeCr "04) has a spinel lattice that corresponds to that of magnetite. An Fe ion is exposed on each of the six edges of the octahedron, to which the collector can attach itself via a chemical compound.

9. Olivine, (Mg, Fe) Si041 splits after the surface (010) on which there are four Mg ions and four Fe ions. However, here the binding forces in the olivine lattice are so strong because of the high formation temperature of the olivine that no valences can be exposed for the accumulation of a collector according to the finding. So olivine cannot be swum with the collector according to the invention.

10. Pyrite (FeS,) crystallizes cubic-disdodecahedral and has a lattice of rock salt type. It splits according to the surface (100) on which five Fe ions are exposed in the elementary lattice. The collector can be deposited via these ions. 11. Calcite (CaCO3) crystallizes ditrigonal-scalenohedral and splits completely according to the rhombohedral surface (1011), on which five Ca ions are exposed. The Ca ions and the collector form salts of very low solubility, so that calcite can be floated very well.

12. Hematite (Fe2O3) crystallizes ditrigonal-scalenohedral and possesses no cleavage, d. That is, there are no cleavage surfaces with residual valences are free. It shows a layer lattice in which the valences are within each layer are completely set. There is only van der Waals between the individual layers Binding forces, so that there is a detachment after the area (0001). On this However, no valences are free on the surface, so that there is no possibility of attachment a collector according to the invention. By acidifying the flotation pulp However, the hematite is attacked on the surface and there are possibilities of accumulation created for the collector of the Fe cation. Hematite can therefore float in acidic turbidity will.

From these statements it can be seen that in the flotation process according to the invention, the flotation behavior of the individual minerals due to the Knowledge of their crystal lattice structure can be predicted.

The invention is explained in more detail below with reference to a few exemplary embodiments. "Medilan KA" was used as a collector in exemplary embodiments I to VI. The word »Medialan« is protected as a trademark. This collector is the sodium salt of the condensation product of a coconut fatty acid with sarcosine. The chemical structural formula of the collector is as follows: In this formula, R represents a hydrocarbon group. Medialan KA also has foaming properties, so that special foaming agents need not be used in the exemplary embodiments. Example I In this experiment a heavily weathered 0.7 to 8% WO tungsten ore was floated. The gangue of the ore was quartz. The main disruptive components were magnetite and brown iron. The quartz that was present in large quantities was partly so finely fused with the brown iron that even when grinding to grain sizes below 60 p, as in the present case, quartz and brown iron could not be separated from one another. For this reason, a high output of wolframite could be achieved in the experiment, but only a relatively low enrichment, since brown iron is also collected with Medialan KA.

Up to now, tungsten ore in grain sizes below about 60 µt was not at all floatable. Flotation conditions Grain ......... 100%, below 60 µ Cloud density ....... pre-cleaning 400 g solids 11 turbidity each Post-purification 100 g of solid 11 turbidity each Control agent .. 5 kg of water glass per 1 t of feed material in the Exposure time of Glass of water .... 10 minutes pH value .......... 2 to 3, adjusted by H2SO4 Collector quantity .... 0.5 kg Medialan KA per 1 t good Exposure time of Collector ....... 3 minutes The pre-concentrates were cleaned three times. The outflows of the post-cleaning become one second concentrate further processed. Test result C. Weight where, percent off ,)% ) bring Magnetite pre-concentrate 1.35 0.0 - Concentrate I ......... 1.10 33.82 46.5 Concentrate II ........ 0.60 35.38 26.5 Concentrate III ........ 0.35 30.25 13.25 I to III ............ 2.05 33.67 86.25 Departure of the cleaning ........... 6.20 1.63 12.62 Mountains ............... 90.40 0.01 1.13 Task ............. 100.00 0.80 100.00 EXAMPLE II In this experiment, scheelite-containing residues which, in addition to quartz, contained various silicates and sulfides as gangue, were floated. A tungsten concentrate with the highest possible output should be obtained from this good.

Even finest-grained scheelite ore (grain sizes below about 60 µt) was previously not floatable. In coarser grain classes, the flotation of scheelite with the aid of fatty acids or their salts also made it more difficult that the flotation result was very much dependent on the respective water hardness. In flotation according to the method according to the invention, the flotation result is almost independent of the water hardness. Flotation conditions Grain ...... 100%, below 60 µt Cloud density .... 300 g of solid per 1 l of cloud in the Pre-cleaning 1st sulfide stage: pH value .......... 7 Control agent ... 3 kg of water glass per 1 t of good, 10 minutes of exposure Time Collector ......... 0.3 kg of potassium ethylxanthate each 1 t of feed material Foamer ......... 1 drop of foamer F (as Substitute for pine oil) 2. Scheelite stage: pH value .......... 2 (HCI) Collector ......... 1 kg Medialan KA per 1 t up good 3 minutes exposure time The Scheelite pre-concentrates were each cleaned three times. The waste from the first concentrate was processed together with the mountains to make the second concentrate; the same applies to the third concentrate. Test result Weight WO3 percent off bring Pre-concentrate ....... 13.7 8.31 7.4 Concentrate I ......... 5.87 40.25 15.6 Concentrate II ........ 12.94 44.85 38.1 Concentrate III ....... 2, 28 52.70 7.8 Concentrate IV ........ 2.60 34.97 6.0 Concentrate V ........ 1.15 47.35 3.56 Concentrate VI ........ 2.76 36.18 6.54 I to VI .............. 27.60 42.70 77.60 Departure of the cleaning ........... 16.70 8.98 10.0 Mountains ............... 42.00 1.81 5.0 Task ............. 100.00 15.21 100.00 EXAMPLE III A scheelite-tinstone mixed ore which had accumulated through pre-enrichment and which had quartz as gangue and from which a high-quality scheelite concentrate and a high-quality tin concentrate was to be obtained was floated.

Seems to split better than pewter stone. As a result, more with Scheelite Cations are exposed, so there are more possibilities for attachment to the scheelite given for the collector anion. This is already supported by the grid structure preferred accumulation possibility of the collector on the scheelite due to the different Solubility of the tin and calcium salts of the collector. That stemming from the Scheelite The calcium salt of the collector is less soluble in the basic range than the corresponding one Tin salt. In this way, the scheelite can be separated from the tin stone in the basic area. If necessary, the tin stone can then be swum in the acidic area, because the tin salt of the collector is sparingly soluble in the acidic range.

Up to now, tin stone could only be separated electrostatically from scheelite with grain sizes down to 100 µt. For grain sizes below 100 µt, as in the present case 100)% below 90V, there has not yet been a processing method. For this reason, concentrates of this type, obtained by pre-enrichment, have hitherto been further processed metallurgically. Flotation conditions Grain ......... 100%, below 90 p Cloud density ....... 200 g solids per 1 l cloud Control agent 15 kg per 1 t of water glass, 10 mi utes exposure time pE value .......... 8.5 to 9.5 Collector quantity .... 0.6 kg Medialan KA per 1 t good 3 minutes exposure time The first pre-concentrate was cleaned once. The waste from the post-cleaning process with the mountains from the pre-cleaning process was floated onto a second pre-concentrate.

This second pre-concentrate was cleaned once and gave that second concentrate.

The waste from the second concentrate is referred to as concentrate III because of its high content. Test result Weight where, Sn % yield% yield Concentrate I ................. 3.8 79.7 8.0 1.21 0.21 Concentrate II ................ 16.5 80.0 34.9 1.98 1.56 Concentrate III ............... 20.2 69.65 37.3 1.59 1.54 I to III ..................... 40.5 74.9 80.2 1.7 33.1 Departure of post-cleaning .... 59.5 12.58 19.8 33.63 96.70 Task ..................... 100.0 37.91 100.0 20.69 100.00 As the result of the table shows, tungsten contents of approximately 75%, WO, with about 80% yield and only about 1.7%, tin content, can be achieved in the scheelite concentrate. The material referred to as waste can be reworked on tin stone, with at least 35% enrichment being possible with almost 85% yield.

Example IV A chromite ore from Turkey was prepared which contained serpentine and olivine as gangue. As stated above, the collector according to the invention cannot be attached to olivine, but can be attached to chromite, so that the chromite can be selectively separated from the olivine. The serpentine contained in the ore did not need to be taken into account, since it is a pure magnesium hydrosilicate on which none of the collectors according to the invention can attach itself. Flotation conditions Grain ......... 100%, below 100 Cloud density ....... 200 g solids per 11 pulp pu value .......... 2 to 3 Regulating agent .. 4200 g water glass per 1 t good Collector .......... 1500 g Medialan KA per 1 t of good The concentrate was cleaned three times; the waste from the post-cleaning process was referred to as intermediate material and would have to be further opened up and returned to the task in practical operation. Test result Weight Cr2O3 percent off % bring Chromite concentrate ... 29.7 50.01 55.4 Intermediate goods ......... 31.4 24.39 31.9 Disposals ............ 38.9 8.87 12.7 100.0 26.97 100.0 Example V In this experiment a hematite-pyrite ore was floated from Sergans, which had lime and quartz as gangue. The larger part of this ore is processed in practice by sink-float processing. The sludge was not yet usable. A hematite concentrate and, if possible, a silica disulfide concentrate should be obtained from this sludge.

As described above, the calcite can be floated very easily because of the low solubility of the salt that arises from the Ca cation and the collector. That is why he was swum first. Only after the lime has been removed, after further addition of the collector, the iron salt of the collector is formed with the exposed Fe cations of the pyrite due to the somewhat greater solubility of this salt, so that the second mineral, the pyrite, was floated out. The pulp was then acidified in order to allow the collector to accumulate on the hematite, so that this iron ore could be floated (iron concentrate) and thus separated from the quartz. Flotation conditions Grain ......... 100%, below 100 µ with a Share of 57%, below 60 µt Cloud density ....... 200 g solids per 1 l cloud Regulating agent .. 1800 g water glass per 1 t Feed Lime level ......... pn value 7 Collector: 500 g Medialan KA 1 t of feed material each The concentrate was used twice post-cleaned; all off courses were continued together processed in the pyrite stage. Pyrite level ......... pH value 7 Collector: 800 g Medialan KA 1 t of feed material each The concentrate was used twice post-cleaned; the departures were processed together on an intermediate Pyritz estate. Intermediate material (pyrite) pH value 7 Collector: 200 g Medialan KA 1 t of feed material each The concentrate was used twice post-cleaned; the incurred Disposals were made in the iron level processed. Iron level (hematite) With HCl the pi 4 was acidifies Collector: 2000 g Medialan KA 1 t of feed material each The concentrate was used twice post-cleaned; the departures the- of this level are the mountains. Test result Good weight Fe - tot. s percent% output% output Lime concentrate ............... 25.90 10.80 7.08 3.40 15.20 Pyrite concentrate .............. 10.00 27.20 6.90 23.50 40.80 Pyrite-iron intermediate ....... 17.50 43.00 19.20 11.40 34.70 Fe concentrate ............... 40.20 60.20 61.20 1.30 9.00 Mountains ...................... 6.40 34.90 5.62 0.29 0.30 Task ..................... 100.00 39.47 100.00 5.77 100.00 The table shows that in the third flotation stage, the iron stage, an iron concentrate with a content of 600 % Fe could be obtained. The pyrite pre-concentrate and the intermediate pyrite material must be re-ground in order to enrich the pyrite and at the same time to be able to extract some of the oxidic iron contained in them. The high iron content in the mountains is of little importance as the iron output in the mountains is only 5,620 / 0 . EXAMPLE VI Diagram 1 shows the results of a series of tests in which a wolframite-quartz mixture was floated with the addition of various amounts of soap. The soap reduces the amount of foam formed and thereby the purity of the product, i. H. the content of tungsten, increased. From the test series shown in Diagram 1, two smoke samples, namely one without the addition of soap and one test with an addition of 0.1 kg of soap per 1 t of feed material, are listed numerically. The pre-concentrates were not cleaned up in these experiments, since the success is already visible in the pre-flotation. Flotation conditions Grain ......... 100% below 60 µt Cloud density ....... 200 g solids per 1 l cloud pH value .......... 2 Collector amount .... 1 kg Medialan KA per 1 t Feed 3 minutes exposure time Test results 1. Without adding soap Weight where, Sio2 percent% output% output Pre-concentrate ............... 17.5 34.98 92.3 47.5 9.22 Disposals ..................... 82.5 0.62 7.7 99.0 90.78 Task ...................... 100.0 6.63 100.0 90.0 100.0 2. Addition of 0.1 kg of soap per 1 t of feed material (0.1% soap emulsion) Weight where, Sio2 percent% output% ö output Pre-concentrate ................. 11.4 52.18 92.5 18.8 2.38 Disposals ............... 88.6 0.56 7.5 99.13 97.62 Task ...................... 100.0 6.43 100.0 90.0 100.00 Already 0.1 kg of soap per 1 t of feed, corresponding to 10em3 of a 0.1% soap solution, result in a very good value.

It is also noteworthy that by improving the foam simultaneous application of the WO3 content has risen from 35 to 52%.

It should also be noted that the silica content in the pre-concentrate without soap 47.5% SiO2, with soap ifar 18.8% SiO2.

Example VII In this experiment, a taconite ore of the Mesabi range, Minnesota, with an iron content of 36.13% floated. It was one Ore sludge that resulted from the wet mechanical processing of this ore. The grain size was below about 60 µ.

The sodium salt of the condensation product of alsic acid and methyltaurine with the chemical constitutional formula was used as a collector: Flotation conditions Grain ......... 100% below 6Ö µ Cloud density ....... 250 to 300 g solids each 1 l cloudiness pn value .......... 3 to 4, set by sulfuric acid Collector quantity .... 0.22 kg per 1 t of feed material Other means ..... 0.2 kg sodium oleate per 1 t Feed The addition of the sodium oleate as soap turned out to be necessary because the use of the above-mentioned collector was associated with a very large amount of foam. Foam development was slowed down by adding sodium oleate. Also owns. the sodium oleate had a certain collector effect of its own, which was beneficial.

The preconcentrate was cleaned four times, with the middle products 1 to 4 being wasted. Test results Weight Fe percent off % bring Fe concentrate ....... 46.64 61.50 79.40 Fe average product 4 ... 0.90 31.10 0.78 Fe average product 3 ... 2.84 22.40 1.76 Fe middle product 2 ... 5.32 18.00 2.65 Fe average product 1 ... 11.35 11.15 3.50 Mountains ............... 32.95 13.06 11.91 Task ............. 100.00 36.13 100.00

Claims (4)

CLAIMS: 1. A process for flotation of fine-grain materials, with the exception of sulfidic and silicate minerals, characterized in that as a collector fatty acid condensation products with aminocarboxylic acids, taurine, Alkyltaurin or Aryltaurin and / or - Ver salts of these products - are applies, namely at minerals with an upper grain size in the range of about 100 V., in which at least a large part of the material has grain sizes of less than 60 #t. 2. The method according to claim 1, characterized in that minerals whose ability to chemically accumulate the collector, is of different sizes, are selectively floated in such a way, optionally saving oppressive means, that with a smaller amount of collector, which is only used to float the the most easily floatable mineral is sufficient, this mineral is floated, and that, if further minerals are to be floated, the flotation of these minerals takes place in each case with higher collector concentrations in the flotation rods. 3. The method according to claim 1, characterized in that minerals, their Floatability varies with changing pH values of the pulp changes to be selectively floated in such a way that at a given pH first the mineral is swum, which is easiest at this pH value it can be floated that afterwards the pn value of the pulp is adjusted to a value in which the other mineral is easily floatable, and then the other mineral is floated up. 4. The method according to any one of the preceding claims, characterized in that the flotation rods silicone oil and / or soap solution are added. Documents considered: German Auslegeschrift No. 1 021 302; Neunhoeffer, "Basics of Swimming Preparation" 1948, p. 39/40; "Mining Sciences", 1956, p. 100; Römpp, "Chemie-Lexikon", 1958, 4th edition, Vol. II, p. 3847.