CA1304943C - Metal production process by reduction of metallic salts - Google Patents

Abstract

E 6616 A jl Ma 87 PATENT OF INVENTION PROCESS FOR THE PRODUCTION OF METALS BY REDUCTION OF METAL SALTS Abstract description The process for the production of a metal by reduction of a salt of this metal is characterized in that a exchange between a reducing metal and a reducible metal within a bath of molten metal salts, under conditions where the reducible metal in the state of reduced metal is immiscible in this bath in the presence of the reducing metal in the previously state dissolved in said bath. Single figure

Description

F ~, 1f, 'jl i3 (~ 4,943 May 87 - 1 -PROCESS FOR THE PRODUCTION OF METAL ~
P ~ R ~ EDU ~ TION OF METAL SALTS
The present invention relates to the preparation of metals by reduction of their salts, according to a process which involves a chemical exchange reaction with a reducing metal for the reducible metal to be produced, in a reaction medium ensuring contact between metals and the corresponding salts. It makes it possible to obtain metals reduced to liquid or solid state, easily separable from reaction environment, but its industrial interest is above all sensitive for the production of refractory metals in powder.
10Titanium is an example of such a refractory metal to hush up.
Currently, the most common processes used to make titanium are the Kroll process, and the Hunter process, which involves using as an agent reducing magnesium or sodium respectively, which one acts at high temperature and in a neutral atmosphere, titanium chloride vapors.
These processes lead to titanium in a form porous, which is frequently referred to for this reason sponge. These sponges are generally not usable in this form directly. They require subsequent purification treatments which are very energy-consuming. And if they are transformed into ingots, we must deplore, during the machining of the ingots, the losses of important matters, which can vary from 30% to 90% of the weight according to the shape of the products concerned.
However, US Patent 2,839,385 has proposed reduce titanium by magnesium in a magnesium chloride bath. But the reaction takes place in this case from TiCl2 dichloride, that it is necessary to prepare beforehand by reducing the t, ~ l 1304943 May 87 tetrachloride by titanium metal. Control of the intermediate production of dichloride makes this process bad convenient and not very suitable for scaling up industrial.
The present invention provides a solution to these difficulties, thanks to a process making it possible to manufacture titanium powder which can be used directly by powder metallurgy techniques. His interest, particularly evident for titanium, also exists in with regard to other metals, particularly with regard to tantalum, which is used in powder for the manufacture of capacitors, and with regard to niobium. In addition, the same process can also prove to be very useful in producing other metals obtained in the liquid state, such as magnesium.
The invention provides a method for producing a metal by reduction of a salt of this metal, characterized in that there is an exchange between a reducing metal and a reducible metal in a metal halide bath melted, under conditions where the reducible metal in the state of reduced metal is immiscible in this bath in the presence of reducing metal, this being previously dissolved in said bath.
It should be understood that each of the metals inter-coming into the reaction can be a pure metal as well than a mixture of metals or an alloy, as well as the salts corresponding metals can be mixtures of salts. One can in particular find interest in operating the reaction on mixtures of molten salts forming between them eutectics melting at a lower temperature than the individual salts, this is for the reducible metal, either preferably for the reducing metal, or again for each of them. Therefore, all the salts involved in the process are usually halides.
In implementing the process, it is advantageous geux to choose as a reducing metal the calciu ~ and in a first step, to completely dissolve this calcium F- ~, 61 ~ ~ 304943 , ~ d1 May 87 the molten salt bath constituting the reaction medium.
This condition allows in the second stage to start from very diverse products to be reduced, in the form of finely solids divided, liquids or gases, which then will not be necessarily dissolved but only dispersed in the bath. However, preferential conditions for placing of the process involve the dissolution of the metal reducing, usually due to its transformation into a compound soluble in the bath, while the metal to be produced is initially in the form of an equally soluble compound and that it is obtained in the form of an insoluble reduced metal, and more particularly solid powder.
According to a secondary characteristic of the process object of the invention, the reducing metal is produced in the same bath from its salt and a metallic compound more reducing than it, consisting of calcium chloride C2Ca. This prior reduction step produces the metal reducer in situ in the bath, which appeared highly favorable for obtaining a final powder of good quality. Carbon is easy to collect in the solid state and to separate from the bath, before introducing the metal to reduce, usually as a halide.
This procedure procedure regenerates the reaction bath by producing the reducing metal in situ.
It is then applicable not only to calcium or sodium, but especially magnesium. It makes it possible to magnesium effective in the process of the invention, despite its poor solubility.
The bath temperature is naturally chosen at a temperature equal to or higher than the temperature of fusion of its essential constituents, and ~ especially especially that of calcium chloride or its eutectics which can thus constitute said molten salt dissolving reducing calcium. For example, in a vertical reactor, calcium can be introduced to the upper part of the reactor, in the form of a finely solid . .'jl 1304943 May 87 divided, for example with a particle size of the order of 0.5 to 2 millimeters. ~ let's call it can also be produced in situ in the bath from calcium carbide, in particular by ~ changes with magnesium present as chloride dissolved in the bath. In case the reduced metal is obtained in the solid state, the bath temperature acts generally on the particle size of the metal which forms, a higher temperature leading to particles larger metal and vice versa.
As for the halide of the metal to be reduced, it can be introduced into the reactor, for example at the bottom a vertical reactor, in the state of a halide in phase liquid or gas phase. If it is in the liquid phase, the temperature of the molten salt bath, which is generally high (above 500 ~ C in most cases), may cause sufficient vaporization of the halide to cause its dispersion, and possibly its dissolution in the bath. It is also possible to find similar conditions, to proceed directly to a injection of halide in molten salt in gaseous form.
Metal halide injections to reduce on the one hand ~ and reducing metal on the other hand, can be performed simultaneously if however the distance of the points injection is such that the halide to be reduced on the one hand, and the reducing metal on the other hand, are dissolved in the salt before they can interact with each other.
The reduced metal to be produced can be chosen in particular among those of the group made up of: Al, Si, Cr, Co, Fe, Ni, Ti, Zr, V, Nb, Ta, Mo and W.
3 ~ For reasons which will be explained in the following this description, the invention, without being there limited, is more particularly suitable for so-called refractory metals, i.e. those with extremely high melting points which are obtained at the state of powdery solids. Among these metals, mention will be made especially titanium, niobium and tantalum.
F 6616 1 ~ 04943 May 87 Daris the most frequent case, the halide of these metal which is used in the process according to the invention is a chloride.
As the reducing metal, it is possible to use non only calcium, but also in particular lithium (Li), sodium (Na), potassium (K), berylium (Be) or strontium (Sr), or in some cases the Mg / Ca mixture, which has allowed to obtain particularly interesting results in the case of titanium production. In this case, the bath molten salt advantageously consists of a mixture MgC12 / CaC12 -Among the eutectics usable to constitute the reaction medium, we can therefore cite the mixtures MgCl2 / CaCl2, but also the MgCl2 / NaCl and CaCl2 / NaCl which, in the appropriate proportions, form relatively low melting point eutectics.
Another advantage of the invention lies in the possibility of forming alloys within the framework of reduced metal production. To do this, simply not a Mehn metal halide, but a mixture of several halides of different metals. In appropriately choosing halides, plus particularly the chlorides of the metals in question, and introducing them in selected proportions, we can lead to alloys whose constitution will reflect the proportions of metals introduced. When production direct powder alloys does not appear possible, we can however make the alloy later, by sintering from the metallic mixture by techniques powder metallurgy classics.
For purposes of illustration, the invention will now be nant described with reference to the accompanying drawing which represents a embodiment of a device for the implementation of the process according to the invention.
This device comprises a reactor 1, the ~ 6616 1304 ~ 43 ~ i ~ i 87 - 6 -height is ~ large compared to the width for the reasons which will be explained below. Heating means

2.2 ', of a type known per se, are arranged around the reactor 1, in order to per ~ ettre it to reach and get maintain at the required temperature.
The halide of the metal to be produced, which can by example being TiCl4, is introduced by a tube 3 which leads to the lower part of reactor 1, in a diffuser 4 which ensures the dispersion of the metal halide within the liquid contained in the reactor 1 ~
This liquid 5 consists of a mixture of halo-molten metal, in which occurs the redox exchange between the metal to be reduced and the reducing metal.
The reducing metal, assumed to consist of calcium at solid state, is introduced at 6 into reactor 1, at the part furthest from the diffuser 4. In the case of the figure, the diffuser 4 is located at the bottom of the reactor, the reducing metal feed hopper 6 being at the top of said reactor.
The process carried out in the molten bath 5 involves the dissolution of the reducing metal in its halide in this bath on the one hand, the dispersion or dissolution of the halide to be reduced on the other hand.
In order to ensure this dispersion in the environment reaction, stirring means 7 are provided in the reactor 1.
In the upper part of reactor 1, the metal or the metals introduced in 6 are first entrained mechanically, then dissolved; they migrate by diffusion or by convection in the reaction medium. In the homogeneous solution of calcium in molten salt obtained, we operate then the reduction of the halides introduced at the bottom of the reactor. The reaction gives rise, for example in the E 66l6 May ~
in the case of titanium, to a powder which settles easily.
To recover this powder, you can various ways after emptying the reactor 1 by a thermal valve 8, equipped with heating means allowing to liquefy the solidified metal salts. We can in particular send the part of bath concerned on a filter 9 where we collect a "cake" that we can take back after grinding with alcohol, water, or even water acidulated to extract the powdery metal. It is also possible to separate the metal from its salt by distillation of the latter.
In the physical state in which it is, the metal can be easily worked by means known in itself given its high degree of purity. he can be used in powder metallurgy, for example easily implemented techniques, as opposed to hard to grind sponges that were obtained by techniques previously applied to metals, such as titanium.
In order to regenerate the salt bath, we can put this in contact with a more reducing compound, by example of calcium carbide. Assuming that the regeneration takes place in a separate reactor rather than directly in the halide bath, we can predict that the residual salt containing the carbon and the impurities of the carbide is reprocessed by blowing air for the purify and generate heat.
The examples below are given as further illustration of the process according to the invention.

3 ~ Example 1 In this example 9 the metal halide to be reduced was titanium tetrachloride TiC14, and the metal reducing was calcium.
The reactor used was cylindrical and had an 8 cm diameter. 3 kg were poured into this reactor of CaCl2, the molten salt bath having a height of the order about 30 cm. We operated at the chloride temperature molten calcium, namely 830 ~ C.
We first sent calcium to the top of the reactor after starting the agitation of the bath. The calcium was injected in the form of beads whose diameter average was of the order of 1 mm. They easily dissolved in the molten CaCl2 bath.
Titanium tetrachloride was then sent to the liquid state using an injector at the bottom of a reactor tubular which was placed vertically. Tetrachloride titanium volatilized and the gas bubbles escaped the base of the injector where they were finely dispersed by agitation.
In order to avoid corrosion of the reactor walls, a slight excess of calcium has been forecasted compared to stoichiometric proportions corresponding to the reaction of reduction of TiC14 by Ca.
After the reaction the agitation was allowed to continue for about 15 minutes and then it was stopped so as to allow the titanium powder to settle. This decantation lasted about 10 minutes.
We then drained the lower half of the bath by through a thermal valve and this half was sent on a filter of a type known per se.
The powder was analyzed from a chemical point of view titanium thus obtained; this analysis gave the following results, in which the percentages, such as moreover throughout this text, are indicated in weight.
Ti: 99.80%
O: 0.05% (500 ppm) Fe: 0.05% (500 ppm) Ni: 0.004% (40 ppm) Cr: 0.007% (70 ppm) E 5616 13049 ~ 3 , 'jl May 87 N: 0.005% (50 ppm) H: 0.015% (150 ppm) S: 0.025 ~ (250 ppm) The particle size of the titanium powder was 5 between 1 and 10 microns.
For an amount of 1.08 kg of Ca injected and 2.55 kg of TiC14, between 600 and 640 g of powdered powder were recovered titanium, which corresponded to a yield of between 92.5% and 99%.
Example 2 In order to lower the temperature of the reaction medium, energy consumption and consequently tick, we operated in a eutectic mixture CaCl2 ~ NaCl including the melting point is around 500 ~ C, for a weight composition corresponding to approximately 34.5% in weight of NaCl.
In order to maintain the eutectic composition, we have planned the simultaneous addition of sodium chloride spray rulent, along with calcium, at 146.3 g NaCl per 100 g of Ca.
The other operating conditions were identified than those of Example 1.
In the reactor initially containing 3 kg of CaCl2 / NaCl eutectic mixture, 0.5 kg of Ca was added, 0.73 kg of NaC1, then 1.18 kg of TiCl4 at a temperature approximately equal to 580 ~ C.
After decantation and filtration, 292 were recovered g of titanium powder, with a particle size between 0.3 and 5 microns, which corresponded to a yield of around 97% by weight.
The purity of the titanium powder, after analysis, was around 99.85%.
The levels of impurities detected were significantly lower than in the previous example, at ~ 6616 130 ~ 9 ~ 3 jl .ai 87 - 10 _ know :
Fe 300 ppm 0 250 ppm H 100 ppm Example 3 In the same way as for titanium, we can produce tantalum from TaCl5 pentachloride which ~ ond at 220 ~ C and boils at 234 ~ C.
In 2 kg of a salt bath consisting of the CaCl2 / NaCl eutectic containing approximately 34.5% by weight of NaCl, metallic calcium was injected in 0.5 to 1 mm in diameter at the same time as sodium chloride in top of the reactor. Then we introduced the TaCl5 vapor to the base of the reactor, tantalum pentachloride being worn before boiling in a separate cell.
1692 g of TaCl5, 472 g of Ca and 690 g were injected NaCl.
The bath level has practically doubled in the cell and after filtration of the molten salt bath and washing with water and alcohol, 830 g of powder were collected having a particle size between 0.5 and 3 microns.
The working temperature was 600 ~ C. The measured yield was 97%.
Example 4 To get more tantalum particles larger than in the previous example, we operated more high temperature (850 ~ C) in 2 kg of bath con ~
Pure CaCl2. 505 g of calcium and 1800 g of TaCl5 were added.
898 g of tantalum powder having a particle size between 5 and 10 microns.
The yield was practically equal to the unit (around 99%).
Example 5 We proceeded as in Example 4 but with F 6 ~ 16 Evil 87 13049 ~ 3 NbCl5, preheated to 370 ~ C in an annex cell for inject it so ~ s vapor form.
400 g of Ca and 1080 g of NbCl5 were injected.
370 g of niobium powder, granular, were obtained.
lometry from 1 to 6 microns, a practically unitary yield.
Example 6 Zirconium powder was produced in placing in conditions identical to those prevailing for the production of titanium, namely:
- salt bath consisting of pure CaCl2 (3 kg) at 850 ~ C
- ZrCl4 carried above its sublimation point in an annex cell (350 ~ C).
The injection of 400 g of Ca and 1166 g of ZrCl4 has allowed to recover 446 g of granular zirconium powder metrics between 0.3 and 10 microns, a yield 98%.
Example 7 The process used for the preparation of titanium in powder according to examples 1 and 2, was applied in conditions analogous to the production of magnesium metal by reduction of MgCl2 chloride.
In this case, the metal produced is liquid at the temperature of the molten salt bath, but while the chlorides and the reducing metal ~ Ca or Ca and Na) dissolves wind in this bath at the concentrations used, magnesium liquid is poorly soluble in the bath. It settles at the upper surface, where it is easy to collect in the state practically pure.
Example 8 The salt bath being based on chloride calcium CaCl2, added magnesium chloride 13049 ~ 3 May 87 - 12 -MgCl2, then calcium carbide C2Ca in small pieces.
In this case, little use is made of sodium chloride, calcium carbide already poorly soluble in chloride magnesium.
The reaction is carried out at 800 ~ C. We obtain then magnesium in the liquid state, carbon in the state solid and base salt (CaCl2). Carbon separation provides a magnesium-based reducing bath produced in situ in the molten salt bath.
Titanium tetrachloride was added to a reactor containing such a calcium chloride bath, added with magnesium. The reaction was then carried out according to the procedure of Example 1.
This reaction leads to the formation of titanium metal and magnesium chloride. Titanium was then separated from the salt mixture Cl2Mg / Cl2Ca.
This mixture of metal salts was regenerated by reduction with calcium carbide according to the procedure below carbon top and separation by filtration or burning, to then be reused in the previous reactor, ensuring the reduction of titanium by magnesium.
The same bath regeneration procedure by the calcium carbide can be applied when the metal reducing is calcium.
It goes without saying that the invention cannot be limited to the specific modes of implementation which have been described in the previous examples. Indeed, the man of art can in each case adapt the conditions the particular problem submitted to it.

Claims (11)

F 516 A. / jl May 87 - 13 - 1. Method of producing a metal by reduction of a salt of this metal, characterized in that in a first step, a reducing metal is dissolved in a molten metal salts and in a second step we add the salt to be reduced, under conditions where the reducible metal in the reduced metal state is immiscible in the bath presence of the reducing metal in the state of dissolved salt in said bath. 2. Method according to claim 1, characterized in what reduction is ensured by calcium put in solution in said bath. 3. Method according to claim 2, characterized in that the reduction takes place from said metal salt dissolved in said bath. 4. Method according to claim 2, characterized in what the salt to be reduced is a titanium halide, tantalum or niobium and in that the reduced metal is obtained in powder form. 5. Method according to claim 1, characterized in that said molten salt is at least partly a halide of said reducing metal. 6. Method according to claim 5, characterized in that the reducing metal is introduced into said bath in mixture with a halide of another metal forming with the halide of said reducing metal a eutectic constituting said bath. 7. Method according to claim 4, characterized in that said metal salt to be reduced is a chloride. 8. Method according to claim 2, characterized in what we introduce the reducing calcium in the divided state in said bath, with stirring 9. Method according to claim 1, characterized in what the reducing metal is magnesium which is formed in Y / d May 87 located in the molten salt bath by reduction of a halide magnesium in solution with calcium carbide and in this that we remove the carbon formed before the injection of the salt of the metal to be reduced. 10. Method according to claim 9, characterized in that said salt to be reduced is tetrachloride of titanium. 11. Method according to claim 1, characterized in that the reducing metal is regenerated by the action of calcium carbide on the halide of said reducing metal.