This invention relates generally to processes for recovering titanium and, more particularly, to a process for producing titanium metal sponge employing an exothermic reaction in a single reaction shell (vessel) between titanium tetrachloride vapor and molten magnesium vapor or sodium vapor producing, respectively, magnesium chloride, sodium chloride, and titanium metal sponge.
The two processes most widely used for producing titanium are the Kroll process and the Hunter process.
The Kroll process reacts titanium tetrachloride, TiCl4 with molten magnesium, Mg, to produce titanium metal in an inert atmosphere, usually argon, by the reaction:
2Mg+TiCl4→Ti+2MgCl2
The Hunter process reacts titanium tetrachloride with molten sodium, Na, to produce titanium metal in an inert atmosphere, usually argon, by the reaction:
4Na+TiCl4→Ti+4NaCl
Considering the atomic masses of magnesium, sodium, and titanium, the reaction equations indicate that one pound (lb.) of magnesium or 1.9 pounds (lbs.) of sodium will produce one pound of titanium. Experience has shown, however, that required magnesium and sodium quantities are 10-to-15% greater than the reaction equations suggest.
Current commercial production facilities produce titanium sponge by either the Kroll or the Hunter process. The two processes are not simultaneously or sequentially used in the same reaction vessel to produce titanium.
The reaction vessels used do not contain electrolysis cells enabling reclamation and reuse of either magnesium chloride or sodium chloride. The magnesium chloride MgCl2 and sodium chloride NaCl byproducts produced by the two processes are pumped out of the reaction vessel and transported to another site to reclaim magnesium and sodium, usually by electrolysis. The handling of molten magnesium chloride and molten sodium chloride and transportation to a remote site present technical problems which have associated costs.
U.S. Pat. Nos. 4,487,677 and 4,516,426 describe a process and equipment for production of titanium sponge which separates the magnesium chloride from the titanium immediately following the Kroll process reaction and returns the magnesium chloride to the electrolyte in an electrolysis cell inside the same reaction vessel to enable magnesium production for a succeeding Kroll process reaction.
The process described in U.S. Pat. No. 4,516,426 eliminates the need to transport magnesium chloride or sodium chloride byproducts of the Kroll and Hunter process reactions to a remote facility for reclamation of magnesium or sodium, providing potential for considerable economic benefit. Other process characteristics, however, reduce the efficiency of the process and equipment described in U.S. Pat. Nos. 4,487,677 and 4,516,426.
The electrolyte used for magnesium production is magnesium chloride; no other salts are added. This compound has a relatively high melting point of approximately 1317° F. making it necessary to operate the electrolysis cell at high temperature with concomitant short refractory life. Molten magnesium chloride has relatively low electrical conductivity, causing generation of much waste heat during electrolysis, increasing the cost of magnesium recovery.
In the process disclosed in the aforementioned patents, a fixed amount of liquid titanium tetrachloride periodically is injected into a container holding molten magnesium. This procedure did not adequately control the Kroll process reaction. Contact of liquid titanium tetrachloride which has a boiling point of 278° F. (136.4° C.) with liquid magnesium at temperatures of 1300-to-1400° F. (704-to-760° C.) followed by a highly exothermic reaction could generate high gas turbulence in the product container, blowing the magnesium pool out of the open lower end of the product container submerged in the electrolyte, preventing further titanium tetrachloride-magnesium reaction.
Very small amounts of chlorine containing more than 200 ppm water may contact steel surfaces during salt electrolysis, producing iron chloride, FeCl2. Since the compound has a melting point of approximately 1240° F., liquid iron chloride could drop into the electrolyte. Iron chloride has a lower negative free energy than magnesium chloride. Consequently, the electrolysis cell would produce iron instead of magnesium until the iron chloride had been consumed.
The container holding the titanium product produced by the Kroll process is made of graphite. Titanium carbide forms during the exothermic reaction, bonding the titanium to the product container and making titanium separation without breaking the container difficult, thus adding to the cost and difficulty of producing titanium.
U.S. Pat. No. 6,942,715 describes stirring methods to increase the efficiency of the reaction of titanium tetrachloride and magnesium in producing titanium by the Kroll process. Stirring is not used to enable this reaction in the process herein described.
Unlike current commercial processes for producing titanium sponge, the present invention does not pump out magnesium chloride or sodium chloride from the reaction vessel or transport either compound to a remote facility for reclamation of magnesium and sodium. Magnesium chloride and sodium chloride byproducts of the Kroll and Hunter processes are immediately separated from the titanium produced and electrolyzed by an electrolysis cell in the reaction vessel to reclaim magnesium and sodium for reuse.
In contrast with U.S. Pat. No. 6,942,715, stirring is not used to enable this reaction in the process herein described.
The accompanying drawings, which are incorporated in and form a part of the specification, illustrate the embodiments of the present invention and, together with the following description, serve to explain the principles of the invention. For the purpose of illustrating the invention, there are shown in the drawings embodiments which are presently preferred, it being understood, however, that the invention is not limited to the specific instrumentality or the precise arrangement of elements or process steps disclosed.
In the drawings:
In describing a preferred embodiment of the invention, specific terminology will be selected for the sake of clarity. However, the invention is not intended to be limited to the specific terms so selected, and it is to be understood that each specific term includes all technical equivalents that operate in a similar manner to accomplish a similar purpose.
Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings. The process, in accordance with present invention, and its associated use is disclosed below.
U.S. Pat. Nos. 4,487,677; 4,516,426; and 6,942,715 are incorporated by reference as if fully set forth herein.
Electrolyte Description
The reactor shell contains an electrolysis cell in its base and a molten salt mixture of three or more salts. One of the salts is magnesium chloride (MgCl2). The Gibbs free energy (negative free energy) of the MgCl2 is lower than that of the other salt mix components. Consequently, MgCl2 will electrolyze before the other salts electrolyze.
The salt mix chosen has the following physical properties:
A preferred embodiment of a salt mix is 20%-to-40% magnesium chloride (concentration 0.2 to 0.4) containing a maximum water content of 2%, 30%-to-50% sodium chloride, and 10%-to-20% barium chloride. Minimization of water content inhibits formation of magnesium oxide, which increases the viscosity of the electrolyte and may form an insulating film on the cathode.
During electrolysis, magnesium chloride concentration is allowed to drop from 0.40 to 0.10 if titanium sponge is to be produced by use of the Kroll process, only.
Magnesium chloride concentration is allowed to drop below 0.10 if titanium sponge is to be produced by sequential use of the Kroll and Hunter processes. In such event, sodium chloride electrolysis will begin when magnesium chloride concentration drops to 0.07-to-0.08. Since the density of sodium is less than that of magnesium, a sodium pool will form on top of the magnesium pool and titanium will be produced by the Hunter process before the metal is produced by the Kroll process. The publication titled Electrolytic Production of Magnesium—Kh. L. Strelets, U.S. Dept. of Commerce Report No. TT 76-50003, pps. 226-227, describes the co-production of magnesium and sodium when magnesium chloride concentration is in the 0.07-to-0.08 range.
Commercial magnesium producers do not use salt mixes containing a high concentration of magnesium chloride which then is allowed to drop to 0.07-to-0.08 during electrolysis because salt mixes containing high concentrations of magnesium chloride have relatively low electrical conductivity increasing energy cost per unit of magnesium produced. The allowable upper magnesium chloride concentration limit ranges from 0.15 to 0.18.
Once a determination has been made of optimum magnesium chloride concentration during electrolysis, magnesium chloride is added to the electrolyte to maintain this concentration as magnesium is harvested.
The increased energy cost in electrolyzing a salt mix containing a high concentration of magnesium chloride is more than offset by the savings attained by in situ electrolysis of the magnesium chloride byproduct generated during use of the Kroll process.
Precipitation of Salt Particles from the Chlorine Gas Stream during Electrolysis
The liquid salt mixes used have a high vapor pressure. Consequently, the chlorine gas stream generated during salt electrolysis contains a significant amount of salt vapor. This vapor solidifies and agglomerates when it passes into valves and orifices which are near ambient temperature, forcing a shutdown of the electrolysis cell.
This problem is overcome by insertion of a heat exchanger and condenser between the electrolysis cell and the first control valve. Cooling the gas stream causes precipitation of salt vapor from the chlorine stream. The precipitate is collected in a trap which is periodically cleaned.
Titanium Tetrachloride Flow Control and Gassification—Delivery System
Kroll and Hunter process reaction turbulence is minimized by control of titanium tetrachloride droplet size, discharge rate, and gasification of the liquid before it enters the reaction zone.
Droplet size and discharge rate are controlled by use of a titanium tetrachloride pumping system which maintains a 10 psig pressure against a solenoid valve, an “On-Off” interval timer, and a cycle timer. Valve opening and closing time and repeat rate can be adjusted to 10 millisecond accuracy.
Gasification is accomplished by discharge of liquid titanium tetrachloride onto a heated cone before the compound contacts the magnesium or sodium vapor above the magnesium or sodium pool, enabling a vapor-to-vapor reaction between titanium tetrachloride gas and magnesium gas above the liquid magnesium pool.
Use of a Titanium Container for Sponge Production
Commercial reaction vessels, which contain the titanium sponge produced by either Kroll or Hunter process reactions, are made of steel. The sponge reacts with the steel to produce a layer of ferrotitanium between the sponge and the steel.
Since iron content in commercial grade titanium cannot exceed 0.10%, care must be taken in separating the sponge that is produced from the ferrotitanium.
Use of a titanium product container prevents ferrotitanium formation and need for use of separation procedures.
Wet Chlorine Control Components
Technical grade anhydrous magnesium chloride may contain up to 2% water. Consequently, chlorine produced during electrolysis will contain more than 200 ppm water. This “wet” chlorine will react with iron at elevated temperatures to form iron chloride. Since presence of this compound pollutes the electrolyte and prevents either magnesium or sodium production by electrolysis, it is mandatory that wet chlorine produced during electrolysis not contact any steel surfaces.
Hot chlorine also will react with the titanium product container to form titanium tetrachloride, dissolving the container.
Chlorine reaction with steel reaction vessel components is prevented by plasma spraying all such components with nickel-base alloys which are compatible with wet chlorine.
Chlorine reaction with the titanium product container is prevented by placement of the product container inside a graphite tube whose Darcy coefficient of permeability has been reduced by graphite manufacturer's use of a proprietary impregnation process.
Preparation for Salt Heating
Referring now to
Heating Frame 1 supports the Electrical Resistance Furnace 2, Reactor Shell 3, and the Superstructure 4 which houses all other components of the titanium production system.
Vacuum Valve 5 is opened to connect a vacuum pumping system to the Reactor Shell Plenum 6. Vacuum Valve 7 is opened to equalize pressure on inside and outside of Bellows 8 during pumpdown. The plenum is pumped down to 150-to-500 millitorr in a preferred embodiment of the invention.
Vacuum Valve 5 is closed. Argon Valve 9 is opened to connect the plenum to an argon source. The plenum is backfilled with argon and pressurized to 2-to-3 psig. Argon Valve 9 is closed. Chlorine Control Valve 10 is opened to connect Reactor Shell Plenum 6 to Check Valve 11 which has a 5 psig cracking pressure.
Salt Heating
Electric Resistance Furnace 2 heats Reactor Shell 3 and Salt Mix 12 to 1450-1600° F. As the temperature increases, any water of hydration held by the magnesium chloride component of the salt mix ultimately enters into the reaction
MgCl2.H2O→MgO+2HCl
When the pressure reaches 5 psig, Check Valve 11 opens allowing discharge of argon and hydrochloric acid gas into Tank 13 containing a 15% Sodium Hydroxide Solution, NaOH 14. The argon component bubbles through the sodium hydroxide to atmosphere. The hydrochloric acid gas component enters into the reaction
HCl+NaOH→NaCl+H2O
neutralizing the hydrochloric acid.
Salt Electrolysis
Referring now to
A DC power supply is connected to Anode 23 and Cathode 24 whose electrical isolation is maintained by Mica Insulator 25, and started to electrolyze the magnesium chloride component of the salt mix between the electrodes. The DC power supply is preferably rated at 3000 amperes, 6-to-18 VDC.
Magnesium ions move to the cathode; chlorine ions move to the anode.
Liquid magnesium rises from the cathode into the Product Container to form Magnesium Pool 26. Salt vapor in the chlorine is precipitated by Heat Exchanger 27. The chlorine either may be stored and sold as electrolytic grade chlorine or pass through Chlorine Control Valve 10 and Check Valve 11 into the Sodium Hydroxide Solution 14 to be neutralized. Reaction of sodium hydroxide and chlorine produces hypochlorite (NaOCl—bleach).
Continuation of electrolysis after magnesium chloride concentration in the electrolyte has dropped below 0.08 produces sodium, floating on top of the magnesium since density of sodium is less than that of magnesium.
The amount of metal produced by electrolysis is determined by a probe sensing salt mix height and also by integration of chlorine mass flow rate readings. When the desired amount of reactant metal has been produced, the electrolysis power supply is shut down.
Production of Titanium Metal
The Titanium Tetrachloride Pumping System is actuated to apply a constant 10-to-15 psig pressure on Solenoid Valve 28. One Interval Timer and one Cycle Timer are adjusted to control operation of Solenoid Valve 28 to optimize droplet size and number of droplets discharged per minute. Liquid titanium tetrachloride passes through Tickle Feed Tube 29 and falls onto heated Gasifier Cone 30 vaporizing the liquid. (It should be noted that a flat Gasifier plate or disk may be used instead of Gasifier Cone 30. However, in the preferred embodiment, it was found that a Gasifier Cone 30 was more efficient since it has a greater surface area than a disk of the same diameter.)
Graphite Seal 31 constrains titanium tetrachloride gas to fill the plenum in Titanium Product Container 19, reacting with the sodium or magnesium vapor above the metal pool and the pool surface. Titanium sponge deposits on the inside surface of the Titanium Product Container 19. Liquid sodium chloride and/or magnesium chloride reaction byproducts sink into the electrolyte enabling electrolysis recycling.
Retrieval of Titanium Sponge from the Titanium Product Container
Continuing to refer to
Referring again to
Argon pressure is set at 3 psig. Argon Valve 9 is opened. Argon flows through the Reactor Shell Plenum 6 but is not discharged because Check Valve 11 cracking pressure is 5 psig. Argon pressure is maintained until internal temperatures are below 130° F. to prevent a vacuum from developing during cooling.
Close Argon Valve 9. Open Oxygen Metering Valve 32. Set flow rate at 1 standard cubic foot per hour. Oxygen will passivate the surface of the titanium sponge produced, preventing an exothermic reaction when the reaction vessel is opened to air.
Referring again to
Referring now to
Although this invention has been described and illustrated by reference to specific embodiments, it will be apparent to those skilled in the art that various changes and modifications may be made which clearly fall within the scope of this invention. The present invention is intended to be protected broadly within the spirit and scope of the appended claims.
Number | Name | Date | Kind |
---|---|---|---|
1800589 | Barstow et al. | Apr 1931 | A |
2205854 | Kroll | Jun 1940 | A |
2783195 | Raynes et. al. | Feb 1957 | A |
2890112 | Winter, Jr. | Jun 1959 | A |
2891857 | Eaton | Jun 1959 | A |
2908619 | Barnett | Oct 1959 | A |
3021268 | Egami | Feb 1962 | A |
4487677 | Murphy | Dec 1984 | A |
4518426 | Murphy | May 1985 | A |
4783326 | Srednicki | Nov 1988 | A |
6942715 | Ito et al. | Sep 2005 | B2 |
20030145682 | Anderson et al. | Aug 2003 | A1 |
Number | Date | Country | |
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20080087139 A1 | Apr 2008 | US |