TECHNICAL FIELD

[0001] The present description relates to a process for producing magnesium metal from dihydrate magnesium chloride wherein anhydrous HCI is released and recycled.

BACKGROUND ART

[0002] Magnesium can be produced commercially by electrolysis of anhydrous magnesium chloride melts. It is well known that the drying process is the most complex and difficult stage in the electrolysis process in the production of magnesium. In fact, most of the R&D in magnesium production over the last decades focused on the drying process for production of anhydrous magnesium chloride with low content of magnesium oxide. The reason for this is to avoid three negative characteristics of the magnesium chloride hydrate hydrolysis reaction:

1 . The creation of magnesium oxide, which will cause sludging in the electrolysis cells, which reacts with the graphite anodes and negatively impacts the energy efficiency of the electrolytic cell.

2. Losses of magnesium chloride during the process.

3. Some oxycompounds can participate in parasitic electrochemical reactions on the carbon anode consuming it in the process .

[0003] Therefore, complete dehydration of MgCI ₂ must be conducted under conditions which minimize magnesium oxidation. Temperature and gaseous environment influence the formation of magnesium oxide compounds. To avoid that magnesium comes into contact with the air and so minimize the risk of oxidation, electrolysis cells operate under an inert atmosphere.

[0004] The dehydration of magnesium chloride hexahydrate is commonly carried out in a one or two stages drying process with hot air followed by one- stage of HCI drying. The first allow to remove between four and five hydrate content. Final dehydration of the MgCI ₂ ^» 2H ₂ 0 must take place with large amount of dry HCI gas to prevent hydroxychloride formation (MgOHCI). This gas has to be dehydrated before recirculation.

[0005] By conventional electrolysis processes of magnesium metal production, dichlore gas (Cl ₂ ) is released then combined with hydrogen gas (H ₂ ) to form hydrogen chloride gas (HCI), which is used for drying magnesium chloride as indicated above. Presently, magnesium chloride feed preparation involves important costs, decreasing profits margins due mainly to the energy consumption to heat the gas at elevated temperature.

[0006] U.S. patent 3,760,050 describes a process for the preparation of substantially anhydrous magnesium chloride suitable for fusion electrolysis. The authors have put emphasis on size, mechanical strength and resistance to abrasion of magnesium chloride pellets. Accordingly, the manufacture of pellets involves balling together dehydrate prills and tetrahydrate molten in a rotating disk. The agglomerates are thereafter dehydrated in a shaft kiln by HCI gas at 330°C for about 900 minutes. The disadvantage of this treatment is that it consumes a lot of energy to reach this temperature and maintain the heat condition for a long time. Furthermore, U.S. patent 3,760,050 does not disclose a mean to dehydrate hydrous HCI gas released in the described process for recycling in a continuous process of magnesium metal production.

[0007] Accordingly, there is thus still a need to be provided with a cost- effective process for producing magnesium metal from MgCI ₂ ^» 2H ₂ 0 and recycling the HCI used during the dehydration process under an inert environment.

SUMMARY

[0008] In accordance with the present description there is now provided a process for producing magnesium metal from dihydrate magnesium chloride comprising the steps of dehydrating MgCI ₂ ^» 2H ₂ 0 with anhydrous hydrochloric acid (HCI) to obtain anhydrous magnesium chloride, releasing hydrous HCI gas; and electrolyzing the anhydrous magnesium chloride in an electrolytic cell fed using an inert gas under an inert atmosphere, wherein magnesium metal and hot anhydrous hydrogen chloride are produced, wherein a first fraction of the hydrous HCI gas is dehydrated by contact with a desiccant agent in a drying unit to produce anhydrous HCI and water, and wherein said hot anhydrous HCI produced by at least one of the electrolytic cell and the drying unit is reused to dehydrate the MgCI ₂ ^» 2H ₂ 0.

[0009] In an embodiment, the process described herein further comprises the step of feeding a second fraction of the hydrous HCI gas through a scrubbing unit to obtain a hydrochloric acid solution.

[0010] In an embodiment, the hydrochloric acid solution contains 30-34% of HCI.

[0011] In another embodiment, the hydrochloric acid solution is continuously cooled by heat exchanger.

[0012] In an embodiment, the hydrochloric acid solution is at a temperature between -10 to 0 ^° C.

[0013] In another embodiment, the process described herein further comprises the step of feeding the first fraction of the hydrous HCI gas into a condenser for desiccation to produce hydrogen chloride gas and a hydrochloric acid solution of 22-28% before being dehydrated in the drying unit.

[0014] In an embodiment, a dehydrating agent is further fed into the condenser.

[0015] In another embodiment, the dehydrating agent is a hydrochloric acid solution.

[0016] In another embodiment, the process described herein further comprises the step of feeding the first fraction of the hydrous HCI gas and a dehydrating agent into a condenser for desiccation to produce hydrogen chloride gas and a hydrochloric acid solution of 22-28%, before the hydrogen chloride gas being dehydrated in the drying unit, wherein the dehydrating agent is the hydrochloric acid solution of 30-34% obtained from the scrubbing unit.

[0017] In another embodiment, one or more chloride is concurrently fed into the condenser.

[0018] In an embodiment, the one or more chloride is a chloride solid.

[0019] In another embodiment, the one or more solid chloride is added to the hydrochloric acid solution before being fed into the condenser.

[0020] In another embodiment, the one or more chloride is at least one of a hydrochloric solution, a HCI-LiCI solution, a HCI-CaCI ₂ solution, a HCI-MgCI ₂ solution and a HCI-ZnCI ₂ solution.

[0021] In another embodiment, the hydrochloric acid solution of 22-28% is recycled to a leaching step of a process of extracting magnesium from magnesium bearing ores producing MgCI ₂ ^» 2H ₂ 0.

[0022] In another embodiment, the desiccating agent is at least one of CaCI ₂ , CaS0 , and H ₂ S0 .

[0023] In an embodiment, the condenser is a plate column.

[0024] In a further embodiment, the drying unit is a drying tower.

[0025] In a supplemental embodiment, the anhydrous HCI is at 400°C.

[0026] In another embodiment, the MgCI ₂ ^» 2H ₂ 0 is dehydrated in a fluidized bed dryer.

[0027] In another embodiment, the anhydrous HCI is reintroduced in the fluidized bed dryer.

BRIEF DESCRIPTION OF THE DRAWINGS

[0028] Reference will now be made to the accompanying drawings, showing by way of illustration, a preferred embodiment thereof, and in which: [0029] Fig. 1 illustrates a bloc diagram of a process according to one embodiment for producing magnesium metal from dihydrate magnesium chloride and recycling the anhydrous HCI produced.

[0030] Fig. 2 illustrates a bloc diagram of a process according to another embodiment for producing magnesium metal from dihydrate magnesium chloride and recycling the anhydrous HCI produced.

DETAILED DESCRIPTION

[0031] It is provided a process for producing magnesium metal from dihydrate magnesium chloride wherein anhydrous HCI is produced in-situ and recycled back in the process in a free oxygen atmosphere.

[0032] The present disclosure concerns the dehydration of dihydrate magnesium chloride in anhydrous magnesium chloride which is used to produce magnesium metal by electrolysis. It is specifically described a process to dehydrate magnesium chloride by the use of anhydrous HCI gas which is dried for recirculation.

[0033] The process described herein concerns the dehydration of MgCI ₂ *2H ₂ 0 by HCI gas from an electrolysis cell and a dehydration unit(s) of hydrous HCI. As can be seen in Figs. 1 and 2, essentially the dehydration unit(s) encompasses a condenser, a dry unit, and a scrubbing unit under an inert atmosphere.

[0034] Dihydrate salt are dried to anhydrous MgCI ₂ in a fluidized bed with HCI at elevated temperature, approximately 400 to 450 °C (step a in Fig. 1 ). Under these conditions the chloride is convert to the anhydrous form in a rapid rate than at lower temperatures. For examples, at 300°C, 16.5 hours were necessary to dry magnesium chloride partially hydrated compared to 5 minutes at 400°C.

[0035] The hot HCI gas leave the electrolysis cell at 600-700°C while HCI gas leaving the dehydration units could be at less than 100°C. Depending on the desiccant agent used in the drying unit, the temperature will vary according to operational conditions, which differ on solid or liquid state. The dehydration is conducted under a free oxygen atmosphere by the presence of protection gas from an electrolysis cell. To obtain the targeted temperature, the HCI from the cell passes through a heat exchanger where the thermic energy of the fluid is transferred to the HCI from the dry unit. Alternatively, the hot and cold HCI gases can be mixed to reach the targeted temperature.

[0036] It is important to note that as disclosed herein, one advantage of the process described herein is the use of latent heat from the electrochemical cell instead of using a furnace to provide a high temperature (hot ) dehydration gas. The heat of the cell is principally generated by the ohmic drop between the anode and cathode transmiting some energy to the molten salt under continuous operation. It is generally admitted in the industry that the cathode connecting bar or busbar should be cooled down to avoid over heating of the cell.

[0037] The use of gaseous HCI will fundamentally reduce the hydrolysis reactions, thus reducing magnesium oxide formation. Opposite reactions to hydrolysis take place with HCI. The excess of hot HCI gas prevents or reverses the formation of hydroxychloride and favors the third reaction.

MgO + HCI(g)→ MgOHCI (1 )

MgOHCI + HCI(g) → MgCI ₂ + Η ₂ 0 ₍₉₎ (2)

MgCI ₂ '2H ₂ 0→ MgCI ₂ + 2 Η ₂ 0 ₍₉₎ (3)

[0038] The MgCI ₂ is then electrolyzed in an electrolysis cell equipped with a diffusion gas anode that generates anhydrous HCI gas. The electrolytic process operate in molten salt media at 700°C and is maintained in free oxygen content for obvious security reasons. Molten magnesium generated into the cell burns in contact with air and can explode in contact with humid air. The use of a protective gas (inert gas) prevents this reaction. Numerous commercial gases are used to protect this reaction to occur like F134A, HFE7100, HFE7200, Novec-612 or others. The mixture of gas released by the electrolytic cell is used to dehydrate MgCI ₂ ^» 2H ₂ 0 together with the HCI gas from the dehydration units.

[0039] When a porous carbon anode for distribution of hydrogen is used in an electrolytic production of magnesium, as described for example in PCT/CA 2014/050102, wherein hydrogen gas is fed into the electrolysis cell, the content of which is incorporated herein by reference in its entirety, dry HCI gas is released as per the equation herein below:

MgCI ₂₍ s ₎ + H ₂₍ g ₎ → Mg _(s) + 2 HCI _(g).

[0040] As illustrated in Figs 1 and 2, the integrated process described herein consists in HCI dehydration, which is recycled back and reintroduced to the base part of the fluidized bed to dehydrate of MgCI ₂ ^» 2H ₂ 0. Also, the paired protection gas is returned to the electrolysis step (b). The introduction of protection gas in the circuit limits the level of oxygen thus reducing the magnesium oxide formation.

[0041] In an embodiment, as illustrated in Fig. 1 , the gas containing water vapor and hydrogen chloride is dehydrated in one step. Typically, a gaseous fraction of the hydrous HCI at 300 to 400°C passes through a scrubbing unit (step i) to obtain a hydrochloric acid solution at about 22 to 28%. This HCI 22- 28% solution can be used for leaching magnesium silicate ores as described for example in the process disclosed in International application no. PCT/CA2015/050670, the content of which is incorporated herein by reference in its entirety.

[0042] The other part or fraction of the gaseous hydrous HCI is dehydrated by contact with a desiccant agent in a dry unit (step 2). The desiccating agent can be in a solid or liquid form, such as CaCI ₂ , CaS0 , H ₂ S0 . These compounds are hygroscopic. Hydrogen chloride gas is dehydrated by chemisorption of water. When the agent is saturated, it is necessary to drive off the water for reusing it by heating. Solid agents are calcined and the temperature required to dry them vary according to the used agent. The sulphuric acid is concentrated by evaporation. [0043] The protection gas is released from the scrubbing unit (step i) and dry unit (step 2). The gas is recycled in the electrolysis step in major part by their low solubility in aqueous media and their non-reactivity with the drying compound.

[0044] The dry unit can be for example a drying tower packed with the desiccant agent. When the agent is saturated in water, it is necessary to drive off the water in order to reuse it. The agents in a solid form are dried in an oven or in a fluidized bed to produce granules. The sulphuric acid for example is concentrated by evaporation in an appropriate vessel.

[0045] At the end of the process, anhydrous hydrogen chloride at 400-450°C is produced and reintroduced to the base part of the fluidized bed dryer to dehydrate MgCI ₂ ^» 2H ₂ 0 and a new cycle is restarted.

[0046] This way of dehydration allows to obtain a hydrogen chloride gas with low moisture content where the desiccant agent is dried on regular basis according to the mass or volume used.

[0047] In another embodiment, two dehydration steps of wet hydrogen chloride are proposed. A fraction of hydrogen chloride at 300 to 400 °C passes first through a scrubbing unit (step i) to obtain a hydrochloric acid solution at about 30 to 34 percent. In contact with water, the HCI is strongly ionized and absorption is favored. The reaction is also exothermic. To reach this level of concentration, the solution is continuously cooled to increase the solubility of the gas.

[0048] The concentrated HCI solution and the other part of hydrous hydrogen chloride are fed into a condenser (step 1 in Fig. 2). Hydrochloric solution at 30-34% produced from the scrubbing unit at about -10 to 0°C can serve as a dehydrating agent. At these temperatures, the vapor pressure of water in a 30-34% HCI solution is low and hydrous HCI gas is efficiently desiccated by contact. Optionally, chloride salts can be added directly to the 30- 34% HCI solution in the condenser, which reduces the solubility of HCI gas in aqueous solution and increases the volatility of HCI. For example, one or more chloride used can be at least one of a hydrochloric solution, a HCI-LiCI solution, a HCI-CaC solution, a HCI-MgCI ₂ solution and a HCI-ZnCI ₂ solution. A residual hydrochloric acid solution at about 22 to 28% is obtained. This HCI 22-28% solution can be recuperated and used for leaching magnesium silicate ores as described hereinabove.

[0049] Particularly, regarding the use of the condenser in step 1 , the concentrated HCI solution is fed to the upper part of the condenser and the hydrous HCI gas at bottom part. A plate column can be used as a condenser which is maintained cold by a thermal heat exchanger where a coolant liquid is circulated.

[0050] Alternatively, the HCI solution is supplemented to the condenser and not coming from a scrubbing unit in order for the hydrous HCI gas to be efficiently desiccated by contact as described previously.

[0051] The HCI gas released from the condenser is then passed through the drying unit (step 2) as described hereinabove, mainly dehydrating the HCI gas by contact with the desiccant agent in the dry unit to produce anhydrous HCI. Anhydrous hydrogen chloride is produced and reintroduced to the base part of the fluidized bed dryer to dehydrate MgCI ₂ ^» 2H ₂ 0 in order for a new cycle to be restarted.

[0052] The process described above generates an HCI gas with very low moisture content where the water absorbed by the desiccating agent is dried off less frequently than the previous method described. By limiting the drying process, energy is saved.

[0053] While the invention has been described in connection with specific embodiments thereof, it will be understood that it is capable of further modifications and this application is intended to cover any variations, uses, or adaptations of the invention, including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains and as may be applied to the essential features hereinbefore set forth, and as follows in the scope of the appended claims.