WO2001045906A2 - Production de metaux et de leurs alliages - Google Patents

Production de metaux et de leurs alliages Download PDF

Info

Publication number
WO2001045906A2
WO2001045906A2 PCT/US2000/042699 US0042699W WO0145906A2 WO 2001045906 A2 WO2001045906 A2 WO 2001045906A2 US 0042699 W US0042699 W US 0042699W WO 0145906 A2 WO0145906 A2 WO 0145906A2
Authority
WO
WIPO (PCT)
Prior art keywords
aluminum
titanium
vapor
zirconium
chloride
Prior art date
Application number
PCT/US2000/042699
Other languages
English (en)
Other versions
WO2001045906A3 (fr
Inventor
James J. Myrick
Original Assignee
Myrick James J
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Myrick James J filed Critical Myrick James J
Priority to AU47151/01A priority Critical patent/AU4715101A/en
Priority to US09/936,525 priority patent/US6699305B2/en
Publication of WO2001045906A2 publication Critical patent/WO2001045906A2/fr
Publication of WO2001045906A3 publication Critical patent/WO2001045906A3/fr

Links

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B22CASTING; POWDER METALLURGY
    • B22FWORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
    • B22F9/00Making metallic powder or suspensions thereof
    • B22F9/16Making metallic powder or suspensions thereof using chemical processes
    • B22F9/18Making metallic powder or suspensions thereof using chemical processes with reduction of metal compounds
    • B22F9/28Making metallic powder or suspensions thereof using chemical processes with reduction of metal compounds starting from gaseous metal compounds
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B22CASTING; POWDER METALLURGY
    • B22FWORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
    • B22F9/00Making metallic powder or suspensions thereof
    • B22F9/002Making metallic powder or suspensions thereof amorphous or microcrystalline
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22BPRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
    • C22B34/00Obtaining refractory metals
    • C22B34/10Obtaining titanium, zirconium or hafnium
    • C22B34/12Obtaining titanium or titanium compounds from ores or scrap by metallurgical processing; preparation of titanium compounds from other titanium compounds see C01G23/00 - C01G23/08
    • C22B34/1263Obtaining titanium or titanium compounds from ores or scrap by metallurgical processing; preparation of titanium compounds from other titanium compounds see C01G23/00 - C01G23/08 obtaining metallic titanium from titanium compounds, e.g. by reduction

Definitions

  • the present invention is directed to the production of metals and their alloys, particularly including refractory metallic alloys such as titanium and zirconium aluminides and amorphous metals.
  • titanium is relatively abundant in nature (e.g., as rutile-TiO 2 and ilmenite-FeTiO 3 , and has highly useful properties.
  • this refractory metal is unfortunately relatively expensive to extract and reduce from its ores, and difficult to fabricate into useful products in view of its high melting point, sometimes requiring use of film or powder metallurgy techniques such as hot isostatic processing of a powdered or thin film form. It is difficult to purify, and even more expensive to prepare in powder form suitable for advanced powder metallurgical manufacturing processes.
  • Titanium is conventionally produced by reduction of titanium tetrachloride with magnesium metal in a steel batch retort (the "Kroll process").
  • Kroll process A significant part of the high cost of titanium as a result of the inefficiency and batch nature of the Kroll process which is currently used for its manufacture. This process produces crude titanium
  • Relatively lightweight gamma-TiAl based intermetallic alloys have desirable strength to weight and other properties, particularly in comparison with the heavier titanium and nickel-base alloys currently used in combustion and compressor sections of engines.
  • a two-phase (TiAl + Ti 3 Al), structure distributed as fine or coarse lamellar microstructures including the ⁇ 2 (Ti3Al), orthorhombic (Ti 2 AINb) and ⁇ (TiAl) classes of alloys may be particularly optimal for some applications.
  • More sophisticated titanium and TiAl reinforced composite aerospace components such as advanced SiC-fiber-reinforced titanium alloy aeroengine and structural components, are under development in many countries (including the U.S., France, the U.K and China).
  • Such advanced composites utilize expensive Ti or TiAl powders and/or foils in their manufacture, [see, e.g., Z.X. Guo, "Towards Cost Effective Manufacturing Of Ti/SiC Fibre Composites And Components", Materials Science and Technology, Vol. 14, pp. 864-872 (1998)].
  • Zirconium and its alloys are of particular use to the nuclear power industry, and chemical and materials industries, and for amorphous metal compositions.
  • Zirconium-based alloys important materials for containing or alloying with uranium fuel, and for the construction of critical components of nuclear reactors.
  • Zirconium also has a wide variety of other uses, as a getter in vacuum tubes, as an alloying agent in steel, in surgical appliances, photoflash bulbs, explosives, fiber spinnerets, and lamp filaments, and as a superconductor (with niobium) to make superconductive magnets.
  • a refractory metal Zirconium can be difficult to shape and work.
  • a variety of Zirconium-aluminum and similar alloys may be quenched to an amorphous, ductile state.
  • amorphous Zr-Al alloys which have significant malleability in their amorphous form.
  • Such amorphous Zirconium alloys typically include aluminum, together with metals such as Fe, Co, Ni or Cu which promote amorphous phase formation.
  • Bulk glass-forming metals based on Ti, Al, Zir and/or Fe which can retain their amorphous state without extremely fast cooling rates typically have three to five or more metallic components with a large atomic-size mismatch to facilitate a high packing density without crystallization..
  • the difference in Gibbs free energy between an undercooled metal alloy glass and the corresponding crystallized alloy is the driving force for crystallization.
  • glass- forming ability is high as has been done for alloys such as Zr-Ti-Cu-Ni-Be, and Cu-Ti- Zr-Ni.
  • the Gibbs free energy difference for such "stable" glass-forming alloys may be only 2-4 Kilojoules per mole, normalized to the melting temperature of the respective alloy, even when cooled to temperatures as low as 1/3 the crystalline melting temperature of the alloy.
  • the metal glass formers with the lowest critical cooling rates have smaller (e.g., less than 2 kJ/mole) Gibbs Free Energy differences than do the glass formers with higher critical cooling rates.
  • the small driving force for crystallization of such bulk metal glass mixtures results from their small free volume, and their short-range order in the supercooled liquid, because the variety of atoms with different sizes in the mixture permits effective packing in the glassy state.
  • Amorphous alloys containing zirconium and titanium have excellent intrinsic corrosion resistance and mechanical properties, but unfortunately have been very- expensive. Powder preparation for powder metallurgy manufacturing is also very expensive.
  • Zirconium is not scarce in nature, but is expensive to extract and reduce from its ores, because of its very high reactivity and high melting point. It is also difficult to purify magnesium chloride byproduct, and even more expensive to prepare in powder or alloy form suitable for advanced powder metallurgical manufacturing processes. Uniform alloy formation can also be an expensive processing step.
  • Zirconium occurs chiefly as a silicate in the mineral zircon (ZrSiO 4 ), and as an oxide in the mineral baddeleyite.
  • Zirconium is produced commercially by reduction of chloride with magnesium (the Kroll Process), as well as other methods. Hafnium is invariably found in Zirconium ores, and the separation of Hf from Zr is difficult. Commercial-grade Zirconium accordingly contains from 1 to 3% Hafnium.
  • Efforts have been made to directly produce titanium powders by reduction of titanium halides in molten salts, and by ultrahigh temperature plasma treatment of TiCl 4 , but such approaches have not yet found commercial success.
  • Sodium fluorotitanate, Na TiF 6 dissolved in molten cryolite, can be reduced by metallic aluminum to produce a powder of metallic Ti, but requires addition of NaF in stoichiometric amount during the reaction to preserve the liquid cryolite medium, and produces large quantities of sodium fluoroaluminate byproduct.
  • FIGURE 1 is a graph of the Gibbs free energy of an aluminum monochloride formation from aluminum and aluminum trichloride as a function of temperature
  • FIGURE 2 is a plot of the molar functions, at equilibrium, as a function of temperature, of various aluminum and titanium chloride species;
  • FIGURE 3 is a graph of the Gibbs free energy of a chloroalummothermic reduction of titanium chlorides
  • FIGURE 4 is a plot of the molar functions, at equilibrium, as a function of temperature at atmospheric pressure, of various aluminum and titanium chloride species
  • FIGURE 5 is a process and equipment flow diagram of the chloroalummothermic reduction of titanium chlorides to produce titanium aluminides
  • FIGURE 6 is a plot of the molar fractions of various aluminum and iron chloride and oxide species in the chloroalummothermic reduction of ferrous oxide, which may be applied to produce iron aluminide and alumina in powder form for powder metallurgy use;
  • FIGURE 7 is a process and equipment flow diagram of the chloraluminothermic reduction of zirconium chloride to produce zirconium aluminides, together with the refining of titanium as titanium chlorides from its ore.
  • the present invention is directed to vapor-phase processes for producing titanium and zirconium metals such as titanium and zirconium aluminides (e.g., TiAl, Ti 3 Al, ZrAl) high-performance alloys (e.g., Ti-Al-N) and glass-forming metal alloys such as Zr-Ti- Cu- ⁇ i-Al-based alloys.
  • Preferred aspects of the methods may comprise the steps of generating a stream of aluminum subchloride at a temperature greater than about 1000° C.
  • aluminum trichloride vapor by contacting aluminum trichloride vapor with an aluminum metal-containing source preferably at a pressure in the range of from about 0.1 to about 1.5 atmosphere, mixing a titanium and/or zirconium chloride reactant with the aluminum subchloride gas to reduce the titanium and/or zirconium chloride reactant(s) to metallic titanium, or titanium or zirconium alloys and to form aluminum trichloride gas, and removing the aluminum trichloride gas from the metallic reaction product.
  • aluminum subchloride gas preferably aluminum monochloride, AlCl(g), although some aluminum dichloride may also be present, is used as a vapor-phase reducing agent for titanium chloride (e.g., titanium or zirconium trichloride, or titanium or zirconium tetrachloride) vapor, to produce a metallic titanium and/or zirconium based metal, such as titanium aluminide, zirconium aluminide or titanium powder, and aluminum trichloride vapor, AlCl 3 (g) .
  • the aluminum subchloride gas e.g., AlCl
  • the aluminum subchloride gas may be subsequently regenerated for reuse.
  • the aluminum trichloride to aluminum subchloride conversion cycle is relatively inexpensive, and may utilize a relatively impure aluminum source, such as scrap aluminum or an inexpensive aluminum-silicon-iron alloy formed by carbothermic reduction of bauxite.
  • the aluminum source is reacted with AlCl 3 (g), for example, at about 1200° C. at a pressure of 0.2 atmospheres, to form aluminum monochloride gas AlCl(g).
  • a selected reaction material such as titanium or zirconium tetrachloride or trichloride or mixtures thereof may be introduced into, or otherwise mixed with the aluminum monochloride gas to form a reaction mixture.
  • the aluminum monochloride is less stable and is more able to serve as a reducing agent for the zirconium and/or titanium chloride, together with any other alloying metal chlorides.
  • the temperatures at which the "oxidation" of AlCl to A1C1 3 , and the "reduction" of titanium chloride (and any other alloying agent and reactant) occurs to a commercially significant extent, depend upon the overall thermodynamics of the particular reaction.
  • the reduced titanium or zirconium or titanium alloy reaction product may be produced in powder form. Coatings and solid deposits may also be provided. Unlike the standard Kroll batch process for titanium manufacture, the manufacturing process can be continuous, and can be scaled for efficient, large-scale production.
  • the process can be utilized to produce intimately uniform, "molecularly mixed" titanium and/or zirconium aluminide powders (e.g., TiAl, TiAl 3 , ZrAl. ZrAl 3 , etc.) or pure titanium powder without the need for the expensive and energy-intensive arc refining required by the current Kroll process.
  • the process can also be adapted to incorporate other alloying agents such as niobium, to produce important titanium alloys such as Ti-Al-Nb powders, and can also be applied to include TiB and other refractory materials of importance to powder metallurgical and thermal spray metallurgical manufacture.
  • the AlCl vapor produced may be reacted directly with zirconium chloride introduced as a vapor, spray or powder (ZrCl , ZrCl 3 , etc.) to produce zirconium aluminides.
  • the zirconium manufacturing process is continuous, and can be scaled for efficient, large- scale production.
  • the process is also able to produce intimately uniform, "molecularly mixed" titanium and zirconium alloys (e.g., ZrAl, ZrAl 3 , etc.) without the need for the expensive and energy-intensive arc refining required by the current Kroll process.
  • the process can also be extended by subsequent treatment with hydrogen and zirconium chloride to produce "pure" Zr metal powders from the alloys.
  • the process is technically robust and can be adapted to incorporate a wide variety of alloying agents such as uranium, niobium, tin, iron, chromium and nickel, to produce a correspondingly wide variety of Zirconium alloys.
  • the process can also be extended to process Zirconium ores in energy and material-efficient recycle operation. It may also be used, if desired, to preferentially separate Hafnium under efficient energy conditions.
  • the invention is also directed to reaction apparatus for manufacturing zirconium alloy powder, and to the powder so produced.
  • the present methods may be used to produce a wide variety of intermetallic compounds such as intermetallic zirconium aluminides and titanides.
  • Intermetallic alloys or compounds have an ordered periodic arrangement of the constituent elements, which provides a chemically bonded crystal structure rather than the solid solutions found in many conventional alloys.
  • the methods may also be used to produce amorphous alloys.
  • the present disclosure is generally directed to continuous, vapor- phase process for direct manufacture of Ti, and titanium and/or zirconium alloy powders.
  • the methods are very robust, and in addition to titanium itself, are particularly desirable for production of intermetallic TiAl, Ti 3 Al, TiAl 3) FeAl, NiAl 3 , NiAl, ZrAl, ZrAl 3 , Ni 3 Al, glass-forming Ti and Zr alloys, and other alloys as powders suitable for powder metallurgy fabrication.
  • the process has inherent economies suitable for making such titanium alloys as inexpensive, commodity metals for general use, rather than as exotic materials to only be used only when their high performance is required despite their presently high cost.
  • the present processes use an aluminum subchloride transport reaction.
  • aluminum subchloride vapor is used to reduce titanium tetrachloride vapor, to directly and efficiently produce
  • TiAl, Ti 3 Al, TiAl 3 or Ti powder A variety of different Ti and Ti and/or Zr alloy products may be produced merely by varying the reaction stoichiometry:
  • the Gibbs Free Energy of the formation of aluminum monochloride from aluminum and aluminum trichloride is exothermic over about 1200° C, so that AlCl vapor can be readily formed above this temperature.
  • FIGURE 1 illustrates the Gibbs free energy of the aluminum transport reaction of Eq. (5).
  • FIGURE 1 two temperature ranges are illustrated in the reaction example described here: • Subchloride generation TI at about 500-600° C, at which aluminum metal is generated and condensed from the vapor phase to reduce TiCl 4 gas, and • Reduction temperature T2 at about 1200-1300° C, at which AlCl is generated
  • FIGURE 2 represents an equilibrium calculation (by Outukumpu HSC thermodynamic calculation software) of the molar concentration of aluminum subchloride and aluminum trichloride species from the reaction of Eq. (5), at thermodynamic equilibrium, over a temperature range from the sublimation point of A1C1 3 at about 300° C, to about 2000° C.
  • AICI 3 vapor (which will remove the chlorine components from the reactions of Eq. (1) - (3), is also a favored species at equilibrium conditions.
  • T2 aluminum monochloride vapor is the predominant species at equilibrium, and A1C1 3 vapor is at relatively low concentration.
  • the present methods can use AlCl vapor as a vapor phase reducing agent for titanium and/or zirconium chlorides, alone or mixed with other alloying or other materials.
  • the reduction of TiCl 3 or TiCl by AlCl is thermodynamically highly favored at temperatures in the TI range of about 500-700° C, as shown by the graph of FIGURE 3 for the reaction of TiCl 4 with AlCl, to produce TiAl powder.
  • reaction product species concentration for the function of TiAl from TiCl 4 and AlCl according to Equation 5 at thermodynamic equilibrium similarly shows a very favorable exothermic reaction at the TI temperature of 500-700° C. to form TiAl by the process without substantial formation of titanium subchlorides, which are more stable at higher temperatures.
  • FIGURE 4 shows the molar proportions of the reactants and reaction products at the TI reaction temperature of 500-700° C. As indicated, the reaction will be further driven to completion by the reaction of Ti and Al to form TiAl, and by the separation of the metal particles from the AICI 3 reaction vapor, as will be more fully discussed in connection with FIGURE 5. Even at elevated temperatures, for example, between 700° C. and 1100° C. where titanium subchlorides are relatively more stable, these subchloride vapors can still be separated from metallic solids.
  • Aluminum subchloride vapor can also be used to reduce Zirconium tetrachloride vapor, to directly and efficiently produce ZrAl, Zr 2 Al 3 , ZrAl 3, Zr 3 Al or similar alloy powders.
  • the different Zr alloy products may be produced merely by varying the reaction stoichiometry:
  • FIGURE 3 is a graph of the Gibbs free energies calculated by F*A*C*T software of the ZrCl 4 , HfCl 4 and UC1 4 reduction reactions with AlCl, and the reaction of Al with ZrCl 4 .
  • AlCl vapor has sufficient "reducing power" to reduce highly reactive ZrCl 4 , as well as HfCl 4 , and UC1 which are even somewhat more difficult to reduce.
  • ZrA shows a very favorable reaction at the TI temperature of 500-700° C. to form ZrAl and related Zr-Al alloys/ compounds.
  • the following FIGURE 4 shows the molar proportions of the reaction products of 7 AlCl + 2 ZrCl 4 , (Eq. 1, above) with emphasis by red line for the proportions of the various species at the TI reaction temperature of 500- 800° C.
  • the desired products, ZrAl powder, and AICI 3 gas are by far the predominant products of the reaction at 700° C.
  • the reaction can be further driven to completion by phase factors, which permit the separation of the Zirconium- aluminum alloy particles from the AICI 3 reaction vapor, and any small amounts of subchloride produced.
  • the stoichiometric ratio of the TiCl 4 and AlCl reactants can be readily changed to produce other alloys, such as Ti 3 Al or TiAl intermetallics, or Ti metal, in accordance with the previous reaction equations, Eq. 1-4.
  • Reactants such as boron, niobium, iron, nickel, and/or chromium chlorides may also be included with the TiCl , to make high- performance alloys such as Ti-48Al-2Nb-2Cr, and Ti AlNb, which are inexpensive and highly uniform because their precursor chlorides are mixed in the vapor phase.
  • Such chlorides may at least partially dissolve in titanium tetrachloride, so that even if they are not volatilized at the reduction reaction temperature range T2, they will be intimately dispensed when sprayed with the TiCl 4 into the reaction zone. To the extent such chlorides so not dissolve in the TiCl 4 to provide dispersed levels in the final metallic titanium-based product, they may also be finely ground and dispersed in a TiCl 4 liquid which is sprayed into the reduction reaction zone. Oxides of these alloying materials may also be used, and the resulting reaction product will contain alumina powder, which may be separated using density classification techniques, or my be retained as a ceramic reinforcing agent.
  • Titanium and titanium alloys are used as structural components in many aircraft, space satellites and missiles. Typical applications include Ti fan disks, turbine blades, and vanes in aircraft turbine engines, and cast and forged structures. Unalloyed titanium is used in jet engine shrouds, cases, airframe skins, firewalls, and other hot-area equipment for aircraft and missiles; and is also used in heat-exchangers, while alloys such as Ti-6Al-2Sn-4Zr-2Mo (Ti-6242, or UNS 54620) are used in gas turbine engine and air- frame applications where high strength and toughness, creep resistance, and high temperature stability at temperatures up to 450° C. (840° F.) are required. Such alloys can be made in powder form by incorporating SrCl 2 , ZrCl 2 , and MoCl 2 in the TiCl 4 .
  • the present glassy alloy production process is highly energy efficient and robust, and has low energy consumption and capital investment.
  • aluminum subchloride vapor is used to reduce mixed metal chloride vapor, to directly and efficiently produce amorphous metal alloy powders.
  • a wide variety of different metal glass alloy products may be produced, merely by varying the reaction stoichiometry.
  • the reaction stoichiometry For example, to make crystalline or bulk glass alloys such as Zr 52.5 Cu ⁇ 7 . 5 Nii 4.5 Al ⁇ oTi 5 (lOK sec critical cooling rate) or Zr 57 Cu ⁇ 5 . 4 Nii 2 . 6 Al ⁇ oNb 5 (lOK/sec critical cooling rate), the following chloride vapor in appropriate stoichiometry would be blended for reaction with AlCl(g) to form the desired glass composition.
  • the present methods will reduce other metal chloride mixtures with titanium and.or zirconium chlorides.
  • Chlorides such as NiCl 2 , NbCls and FeCl 3 can be directly reduced by AlCl vapor, because the Gibbs Free Energy for their direct reduction (particularly to form alloys) is negative.
  • Substantially all transition and rare earth metal chlorides can similarly be reduced by aluminum to form intimately mixed metal powders.
  • Fe, Nb, Ni, Co, Cu and similar metals are easily reduced by aluminum, so crystalline and amorphous alloys containing mixtures of all of those materials can be made.
  • AlCl(g) can even reduce refractory ZrCl 4 .
  • AlCl vapor cannot be used to directly produce pure Zr metal from ZrCl 4 , because the Gibbs Free Energy for this reaction is positive in the 500- 1000° C. range. Fortunately, however, zirconium is strongly exothermic in forming alloys with aluminum, and a variety of glass-forming metals. This has important implications for the manufacture of inexpensive Zr-containing bulk amorphous metal powders. Because the Gibbs Free Energy of properly formulated zirconium-aluminum bulk metal glasses only differs from that of the precipitated crystalline alloys by about 2 kJ/g-atom, which is a very small amount, the reduction by AlCl(g) of the glass alloys including zirconium metal is still thermodynamically favorable.
  • glassy zirconium alloy formation by AlCl(g) reduction is thermodynamically favorable at reduction temperatures of less than 900° C. (e.g., 500-700°C.) because of the high heat of formation of zirconium-containing glassy alloys.
  • ZrAl powder, and AICI 3 gas are by far the predominant products of the reaction at 700° C.
  • the reaction is further driven to completion by phase factors, which easily permit the physical separation of the amorphous metal alloy particles from the AICI 3 reaction vapor and any small amounts of subchloride produced.
  • a preferred example of the overall process manufacturing TiAl is illustrated in the flow diagram of FIGURE 5.
  • scrap or crude aluminum 50 and aluminum trichloride 52 are reacted in a retort tower 54at the reaction zone T2 temperature of 1200-1300° C, to produce AlCl gas 56, which is conducted to a separate reaction reactor 58 for reduction of TiCl 4 at the TI reaction reactor temperature of 700° C. and 1500° C.
  • Aluminum trichloride may be introduced as a vapor into an aluminum melt, and the aluminum melt may be "splashed" or circulated through the tower in order to increase reaction kinetics.
  • the interior surfaces of the tower 54 should be constructed of materials such as carbon, spinels, alumina, tungsten, or even titanium or zirconium (which may be conveniently thermlaly sprayed on interior surfaces of the reaction vessels and conduits) or other such refractory materials which are relatively inert to reaction with aluminum and aluminum chlorides at elevated temperatures. Titanium tetrachloride 60 is mixed with the AlCl gas 56 in the TI reaction zone 58, and the reaction mixture is cooled to a temperature of about 500-700° C.
  • Relatively cool liquid TiCl (molecular weight 189.7) may be sprayed into the hot AlCl gas (molecular weight 62.4) to both partially cool it and vaporize the TiCl (note that the reaction is exothermic, in any event). Heat may be recovered for power generation heating of aluminum and/or aluminum trichloride from the reactor 58.
  • the vapor-phase AlCl is a reducing agent for the TiCl 4 blended therewith, as previously discussed, to produce TiAl powder 62, and vapor-phase A1C1 3 gas 64.
  • the solid TiAl powder 62 produced by the reaction may be easily separated from the aluminum trichloride vapor by a cyclone 66 or other separation system operating above the vapor point of A1C1 3 .
  • the powder 62 may be flushed with an inert gas such as argon, or a reversibly removable gas such as hydrogen (which can alloy with the zirconium and/or titanium metal powder at lower temperatures), to assist flushing and removal of any residual AICI 3 .
  • Vacuum treatment of the collected TiAl product even at moderate temperatures may also be used to further remove any residual chloride components.
  • a chloride source such as TiCl 4 or ZrCl 4 may be used with hydrogen at these low temperatures to remove aluminum from aluminum containing alloys, leaving pure titanium or zirconium. The hydrogen respectively forms Ti or Zr hydrides, which release the aluminum for removal as AlCl vapors.
  • TiAl powder may be at least partially recycled to the reactor 58 to serve as a nucleating source for metal deposition, if it is desired to increase the particle size of the TiAl or other metal powder produced by such reaction processes.
  • the process equipment is relatively simple and inexpensive, consistent with commodity production, as compared to conventional titanium batch production equipment (closed steel retorts, vacuum arc equipment, etc.). and can be easily scaled for large capacity.
  • Conventional metal chloride tower, piping, and powder separation cyclone equipment, none of which are particularly expensive, may constitute the principal components.
  • the present process utilizes close coupling of distillation separation, and chemical vapor reaction systems, to improve the yields of the reaction, the production of desired alloys, and to lower energy consumption and capital investment.
  • Energy savings can be realized, for example, when a crude carbothermic molten aluminum such as a mixture of aluminum and aluminum carbide or Al-Fe-Si alloy, and heated aluminum trichloride from specific reaction steps are separated and used as reactants in a zirconium or titanium reduction, and TiCl or ZrCl generation steps.
  • the energy from the latent heat and exothermic reactions may be used to drive other reactions.
  • the process is very robust, and produces alloys as powders suitable for powder metallurgy fabrication, and for preparation of titanium and/or zirconium-aluminum alloys.
  • the process has inherent economies suitable for making such titanium and/or zirconium alloys as inexpensive, commodity metals for general use, rather than as exotic materials to be used only when their high performance is required despite their presently high cost. It may also be used to prepare Zr metal powder from the Zr-Al alloy by treatment with hydrogen and a chloride source such as ZrCl 4 .
  • the aluminum trichloride byproduct can also be used to directly recover titanium, zirconium, and other metals directly from their ores.
  • An example of the overall process is further illustrated in the flow diagram of FIGURE 7.
  • scrap aluminum or even less-expensive carbothermic aluminum e.g., a mixture of molden aluminum with aluminum chloride
  • crude coke-furnace reduced Al-Fe-Si are reacted with aluminum trichloride in a reaction tower at the reaction zone T2 temperature of 1300-1500° C, to produce AlCl vapor.
  • the furnaced crude aluminum can be introduced into the tower at high temperature (e.g., 1500-2200° C), and this heat can be used directly in the formation of AlCl.
  • the aluminum subchloride gas is conducted to a separate reaction zone for reduction of a glassy metal chloride mixture at the TI temperature.
  • Glassy metal-forming components such as FeCl 3 , TiCl 4 , NbCls, NiCl 2 and/or ZrCl 4 , as well as WC1 5 , may be mixed with the AlCl gas in the TI reaction zone, and the reaction mixture cooled to a temperature of about 500-800° C.
  • TiCl 4 and ZrCl 4 , and powdered non-volatilized chlorides such as CuCl 2 may be used to cool the hot AlCl gas and vaporize the chlorides.
  • Expansion through a nozzle into a partial vacuum zone can also be used to very rapidly cool the reacting chloride vapor.
  • a partial vacuum to produce a sub atmospheric pressure in the AlCl generator e.g., 0.1 to 0.9 atmospheres
  • a partial vacuum is relatively easy to implement for the methods described herein, because the aluminum chloride byproduct condenses to a solid at temperatures below about 200° C.
  • the reactant vapors may be initially mixed at a temperature above the crystallization/solidification temperature of the metal alloy (which is typically a deep eutectic with a relatively low melting point), and rapidly cooled to a temperature below the glass transition temperature of the alloy.
  • the metal alloy which is typically a deep eutectic with a relatively low melting point
  • the aluminum subchloride vapor, AlCl(g) vapor becomes a reducing agent for the Ti or Zr alloy, or glassy metal chloride mixture as previously discussed, to produce crystalline or glassy alloy powder as described by reactant formulation selection, and AICI 3 vapor.
  • the solid alloy powder produced by the reaction may be easily separated from the aluminum trichloride vapor by a cyclone or other separation system operating above the vapor point of AICI 3 .
  • the separated crystalline or amorphous alloy powder may be flushed with an inert gas such as argon or hydrogen to assist removal of any residual AICI 3 .
  • Small amounts of subchlorides which may be produced are also relatively volatile at the recovery temperature, and can be removed with the AICI 3 .
  • Hydrogen can be used to further remove residual chlorides as aluminum trichloride vapor at 100-300° C, preferably at subatmospheric pressure.
  • the ordering of these glass alloy metals of different atomic size into crystalline structures has low driving force and takes significant time, particularly if the composition has a low (1-3 kJ/mole) difference in Gibbs Free Energy between the glass and alloy states.
  • the reduction of the mixed metal chloride vapor by aluminum can be sufficiently rapid that the glassy alloys do not have time to crystallize. If an adiabatic or other expansion nozzle is used to cool the reactants, cooling can occur at extremely high rates, of up to 10 6 degrees K per second.
  • FIGURE 5 An example of the overall process and a reaction system for carrying it out is further illustrated in the flow diagram of FIGURE 5.
  • scrap aluminum or even less-expensive carbothermic aluminum or crude coke-furnace reduced Al-Fe-Si are reacted with aluminum trichloride in a distillation reaction tower at the reaction zone T2 temperature of 1200-2000° C, to produce AlCl vapor.
  • T2 temperature 1200-2000° C
  • carbothermic aluminum the heat of the latest molten metal is used efficiently in the aluminum subchloride manufacture.
  • This reactive distillation also retains most other metals or metal chlorides in the reactive distillation tower, because of their lack of volatility. These metals and/or chlorides are in solid, non-aqueous form which permits ready reuse.
  • the pure aluminum subchloride gas is conducted to a separate reaction zone for reduction of ZrCl at the TI temperature.
  • ZrCl 4 is mixed with the AlCl gas in the TI reaction zone, and the reaction mixture is cooled to a temperature of about 500-700° C.
  • ZrCl 4 (molecular weight about 233) may be used to cool the hot AlCl gas (molecular weight about 62.4), and vaporize the ZrCl 4 .
  • the aluminum subchloride vapor, AlCl(g) becomes a reducing agent for the ZrCl as previously discussed, to produce ZrAl or other Zr-aluminide alloy powder by stoichiometry control, and A1C1 3 gas.
  • the solid ZrAl alloy powder produced by the reaction may be easily separated from the aluminum trichloride vapor by a cyclone or other separation system operating above the vapor point of AICI 3 .
  • the separated alloy powder may be flushed with an inert gas such as argon or hydrogen (which can alloy with the powder at lower temperatures) to assist flushing of any residual AICI 3 .
  • Small amounts of subchlorides, which may be produced are also volatile at the recovery temperature, and can be removed with the AICI 3 . It is also important that a zirconium alloy coating can be deposited on substrates placed in the reduction zone.
  • the substrates may be refractory substrates such as ceramic fibers or monofilaments such as silicon carbide fibers or tow, glass fibers, other metals such as uranium or uranium oxide cylinders or spherical particles steel or stainless steel fibers or reinforcing bars, conduits or other structural members at a suitable temperature in the range of, for example, 300-1500° C.
  • the substrates may be coated in the reaction chamber in any suitable manner, such as by placing them in the reduction chamber, moving them through the zone (e.g., filaments) or utilizing a vibrating or fluidized bed with the reacting vapors. Continuous processes are particularly efficient, and benefit from the present invention. Any zirconium alloy powder may continue to be collected which does not deposit on the substrates.
  • hot AICI 3 vapor produced by the reduction of the metal chloride mixture can be recycled to regenerate the AlCl vapor.
  • the hot AICI 3 vapor can be used directly in a countercurrent distillation reactor to generate the metal chloride vapors directly from ores such as Ilmenite (FeTiOs) and Zircon (ZrSiO 4 ).
  • Direct distillation and purification of ZrCl , TiCl , CoCl 2 , NiCl 2 , MnCl 2 and other volatile metal chlorides can be carried out from their ores using AICI 3 vapor byproduct . This can eliminate the costly chemical refining steps which make Ti and Zr so expensive.
  • chloride reaction potential which exploits the difference between the Gibbs Free Energy for metal oxides and metal chlorides, is used conventionally in metal chloride production towers to separate different volatile chlorides, such as SiCl 4 , TiCl 4 and FeCl 3 .
  • the ore can be reacted with AICI 3 at elevated temperature to separate or remove different constituents of their ores, as shown at the right-hand side of FIGURE 7. Because the AICI 3 vapor is already heated, this is a very energy efficient process. As shown in FIGURE 5, the hot AICI 3 vapor produced by the reduction of ZrCl 4 can be recycled to the first reactive distillation tower to regenerate the AlCl vapor.
  • the hot AICI 3 vapor can be used in a countercurrent or other distillation reactor to generate ZrCl 4 from ores such as ZrSiO (see, for example, Othmer, et al., "Halogen Affinities - A New Ordering of Metals to Accomplish Difficult Separation"), AICKE Journal (Vol. 18, No. 1) Jan. 1972, pp.217- 220) to separate the different constituents of the ore, as shown at the right-hand side of FIGURE 7, above.
  • the HfCl 4 impurity can also preferentially be separated from the desired ZrCl 4 product, if such separation is desired.
  • a suitable zirconium ore may be processed in a counter-current manner to efficiently recycle the hot AICI 3 vapor in ore processing and component extraction.
  • a suitable zirconium ore such as Zircon (ZrSi0 4 ) or zirconium oxide ore such as baddeleyite (ZrO 2 ) is introduced into a counter current reactor. While the reaction is shown as a chloride reaction tower, through which the ore passes downward, in practice a series of interconnected metal chloride reactors may be used, in which the vapor flows may be controlled among them to simulate counter current processing, may also be used.
  • the reactive AICI 3 vapor is introduced at the "bottom" of the column (or to the rector with the last-processed ore components), which contains the "lowest chloride potential" of the potentially volatile chloride cations (e.g., SiCl 4 ) and the previously reacted nonvolatile chloride component of the ore (e.g., CaCL NaCl), the other volatile component having been conducted upwards as chloride vapors, as shown in FIGURE 7.
  • S1CI 4 and enriched HfCl 4 may be removed, distilled and processed.
  • ZrCl may similarly be recovered and distilled, if desired, while iron chlorides and other chloride reactive metals with a high chloride potential may also be recovered at appropriate temperatures along the reactor. The same result can be achieved with titanium ores such as ilmenite and rutile.
  • the stoichiometric ratio of the ZrCl 4 and AlCl reactants can be changed to produce other alloys, ranging from Zr 3 Al to ZrA ⁇ .
  • other reactants such as Boron, Niobium, Iron, Nickel, Tin and/or Chromium chlorides may also be included with the ZrCl 4 , to make high- performance alloys, which are inexpensive and may be highly uniform if their precursor chlorides are mixed in the vapor phase.
  • Uranium alloys with aluminum can be produced in the same way, as well as Zr-U alloys.
  • Fibers or surfaces of carbon organopolymers such as polyvinyl chloride or polyvinylidine chloride may be "coated" with zirconium carbide in the reduction reaction zone, when in contact with the reacting aluminum subhalide and zirconium halide vapors.
  • Aluminum may also be at least partially removed from the Zr-Al alloy powders, by reactively distilling them with AICI 3 at a T2 temperature of 1600-1800°C. or more where AlCl and A1CL vapor have a very negative Gibbs Free Energy:
  • the process uses very simple, scalable and inexpensive equipment and unit operations.
  • the process is very efficient in thermal energy utilization and material reuse and can be easily scaled for large capacity.
  • Conventional metal chloride manufacturing towers, piping, and powder separation cyclone, none of which are particularly expensive, constitute the principal components.
  • Aluminum raw material can be very inexpensively produced in molten form using a conventional stack-type or similar carbothermic reduction furnace (see, for example, Alcoa's expired U.S. Patents 4,299,619 and 3,971,653 to Alcoa, entitled, "Energy Efficient Production Of Aluminum By Carbothermic Reduction of Alumina") .
  • the apparatus and process can have relatively low operating costs.
  • the aluminum used in the process may be inexpensive scrap, aluminum carbide or crude raw aluminum such as Al or Al-Fe-Si produced at very low cost by carbothermic reduction of bauxite, which can be delivered "hot" in molten form at 1300-1800° C for reactive distillation with AICI 3 to produce AlCl.
  • Carbothermic production of molten Aluminum directly uses the latent heat energy of the molten aluminum for the AlCl vapor production. If aluminum scrap is used, the valuable alloy components of the scrap can generally be separated and recovered by the reactive distillation in the formation of volatile AlCl, as another ecological and economic benefit of the process.
  • Zirconium aluminides such as ZrAl 3 and ZrAl scrap or product for rework
  • ZrAl 3 and ZrAl scrap or product for rework can be used as an aluminum source for AlCl vapor production (albeit at relatively high temperatures), with the added benefit of producing a higher Zirconium content, as discussed above, for "pure" unalloyed Zr production.
  • An aluminum-wire or aluminum powder plasma gun to process A1C1 3 for AlCl production or for introducing low-valatility metal chloride reactants may also be used.
  • Such methods for producing powdered metallic products can comprise the steps of forming a stream of aluminum subchloride vapor at a temperature of at least about 1000° C , and preferably at least about 1100° C.
  • a suitable oxide or halide reactant is mixed with the aluminum subchloride vapor stream.
  • the aluminum subchloride is then reacted with the metallic oxide or halide reactant, to reduce the reactant to form a solid powdered metallic product and to form aluminum trichloride vapor.
  • the aluminum trichloride vapor can then be separated from the powdered solid metallic product.
  • Simple cyclone or gravity separation are effective separation techniques, but filters, etc. may also be used.
  • intermetallic iron aluminides and iron titanides may be produced by reacting iron chlorides with aluminum subchloride in a manufacturing system like that of FIGURE 5.
  • FIGURE 6 illustrates an outukumpu thermodynamic equilibrium calculation for the initial reactants 6FeO + 16A1C1, calculated in terms of Fe and Al production. A slight excess of aluminum was included in the calculation to show Fe and Al as separate curves. As shown in FIGURE 6, the reduction reaction of FeO and AlCl proceeds readily at temperatures below about 1200° C. In addition, the exothermic reaction of Fe and Al to form FeAl intermetallic compounds further drives the reaction to completion, to form FeAl powders.
  • the iron or other metal chloride When the iron or other metal chloride does not readily vaporize at the reaction temperatures, it may be finely ground (e.g., to a particle size of less than 44 microns, preferably less than 10 microns in maximum dimension) and introduced into the aluminum subchloride as a powder, or with a carrier such as TiCl 4 .
  • metal oxides such as FeO, NiO, or CoO may be finely ground and utilized as a reactant feed stream into the aluminum subchloride vapor in the reactor system of FIGURE 5 , either alone or with a carrier reactant such as TiCl 4 :
  • 6FeO + 12 AlCl + 6TiCl 4 6FeTi + 2Al 2 O 3 + 12AlCl 3 f ⁇

Abstract

L'invention concerne des procédés permettant de produire des alliages de titane et de zirconium, en particulier des alliages en poudre formés par réduction chloroaluminothermique en phase vapeur continue.
PCT/US2000/042699 1999-12-08 2000-12-08 Production de metaux et de leurs alliages WO2001045906A2 (fr)

Priority Applications (2)

Application Number Priority Date Filing Date Title
AU47151/01A AU4715101A (en) 1999-12-08 2000-12-08 Production of metals and their alloys
US09/936,525 US6699305B2 (en) 2000-03-21 2000-12-08 Production of metals and their alloys

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
US16958099P 1999-12-08 1999-12-08
US60/169,580 1999-12-08
US19098100P 2000-03-21 2000-03-21
US60/190,981 2000-03-21

Publications (2)

Publication Number Publication Date
WO2001045906A2 true WO2001045906A2 (fr) 2001-06-28
WO2001045906A3 WO2001045906A3 (fr) 2002-01-24

Family

ID=26865199

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/US2000/042699 WO2001045906A2 (fr) 1999-12-08 2000-12-08 Production de metaux et de leurs alliages

Country Status (2)

Country Link
AU (1) AU4715101A (fr)
WO (1) WO2001045906A2 (fr)

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2004060594A1 (fr) * 2002-12-26 2004-07-22 Millenium Inorganic Chemicals, Inc. Procede de production de materiau elementaire et d'alliages
EP1441039A2 (fr) * 2003-01-22 2004-07-28 General Electric Company Procédé de préparation d'un article avec matrice renforcée par dispersion
US6902601B2 (en) * 2002-09-12 2005-06-07 Millennium Inorganic Chemicals, Inc. Method of making elemental materials and alloys
EP1618976A3 (fr) * 2004-07-22 2006-08-16 General Electric Company Procédé permettant de fabriquer un article métallique à gradient de composition, sans fusion
CN106745217A (zh) * 2017-03-14 2017-05-31 江苏展钛科技有限公司 一种用于铝粉还原四氯化钛制取三氯化钛的方法及反应器
US10100386B2 (en) 2002-06-14 2018-10-16 General Electric Company Method for preparing a metallic article having an other additive constituent, without any melting
CN108723389A (zh) * 2017-04-18 2018-11-02 台湾积体电路制造股份有限公司 形成导电粉末的方法
US10604452B2 (en) 2004-11-12 2020-03-31 General Electric Company Article having a dispersion of ultrafine titanium boride particles in a titanium-base matrix

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2766111A (en) * 1951-10-18 1956-10-09 Nat Res Corp Method of producing refractory metals
US2770541A (en) * 1952-08-14 1956-11-13 Nat Res Corp Method of producing titanium

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2766111A (en) * 1951-10-18 1956-10-09 Nat Res Corp Method of producing refractory metals
US2770541A (en) * 1952-08-14 1956-11-13 Nat Res Corp Method of producing titanium

Cited By (13)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US10100386B2 (en) 2002-06-14 2018-10-16 General Electric Company Method for preparing a metallic article having an other additive constituent, without any melting
US6902601B2 (en) * 2002-09-12 2005-06-07 Millennium Inorganic Chemicals, Inc. Method of making elemental materials and alloys
US6955703B2 (en) * 2002-12-26 2005-10-18 Millennium Inorganic Chemicals, Inc. Process for the production of elemental material and alloys
WO2004060594A1 (fr) * 2002-12-26 2004-07-22 Millenium Inorganic Chemicals, Inc. Procede de production de materiau elementaire et d'alliages
EP1441039A3 (fr) * 2003-01-22 2006-05-17 General Electric Company Procédé de préparation d'un article avec matrice renforcée par dispersion
EP1441039A2 (fr) * 2003-01-22 2004-07-28 General Electric Company Procédé de préparation d'un article avec matrice renforcée par dispersion
EP1618976A3 (fr) * 2004-07-22 2006-08-16 General Electric Company Procédé permettant de fabriquer un article métallique à gradient de composition, sans fusion
US7384596B2 (en) 2004-07-22 2008-06-10 General Electric Company Method for producing a metallic article having a graded composition, without melting
US10604452B2 (en) 2004-11-12 2020-03-31 General Electric Company Article having a dispersion of ultrafine titanium boride particles in a titanium-base matrix
CN106745217A (zh) * 2017-03-14 2017-05-31 江苏展钛科技有限公司 一种用于铝粉还原四氯化钛制取三氯化钛的方法及反应器
CN106745217B (zh) * 2017-03-14 2018-02-06 江苏展钛科技有限公司 一种用于铝粉还原四氯化钛制取三氯化钛的方法及反应器
CN108723389A (zh) * 2017-04-18 2018-11-02 台湾积体电路制造股份有限公司 形成导电粉末的方法
US11819923B2 (en) 2017-04-18 2023-11-21 Taiwan Semiconductor Manufacturing Company, Ltd. Conductive powder formation method and device for forming conductive powder

Also Published As

Publication number Publication date
WO2001045906A3 (fr) 2002-01-24
AU4715101A (en) 2001-07-03

Similar Documents

Publication Publication Date Title
US6699305B2 (en) Production of metals and their alloys
Froes Titanium: physical metallurgy, processing, and applications
US4356029A (en) Titanium product collection in a plasma reactor
EP3512655B1 (fr) Production de matériaux d'alliage de titane par réduction de tétrahalogénure de titane
US7559969B2 (en) Methods and apparatuses for producing metallic compositions via reduction of metal halides
Khatri et al. Formation of TiC in in situ processed composites via solid-gas, solid-liquid and liquid-gas reaction in molten Al Ti
EP1641581B1 (fr) Procedes permettant la production de composes metalliques
AU2017345719B2 (en) Producing titanium alloy materials through reduction of titanium tetrachloride
US11247270B2 (en) Method for preparing vanadium and vanadium alloy powder from vanadium-containing materials through shortened process
WO1995025824A1 (fr) Procede de reduction d'halogenures de metaux au moyen d'aerosols
Yuan et al. A critical review on extraction and refining of vanadium metal
AU2017345609B2 (en) Producing titanium alloy materials through reduction of titanium tetrachloride
Reddy Processing of nanoscale materials
Hayes et al. Advances in titanium extraction metallurgy
WO2001045906A2 (fr) Production de metaux et de leurs alliages
Gambogi et al. Titanium metal: extraction to application
Parfenov et al. Subchloride aluminothermic extraction of titanium from chlorides
CN109022827B (zh) 从钛矿石直接制备TiAl合金的方法
JP3598580B2 (ja) 遷移金属ホウ化物粉末の製造方法
Khoshhal Formation of Two Types of Alumina/Intermetallic Composites based on the Reaction of Ilmenite and Aluminum
Andreev et al. FORMATION OF Mo/Nb/Si/B CAST COMPOSITE BY SHS IN CONDITIONS OF ARTIFICIAL GRAVITY
Hardman Oxide Processing Routes for Aluminium Master Alloys
Sale Refractory Metal Alloyed Powders by Volatile Halide-Liquid Metal Reaction

Legal Events

Date Code Title Description
AK Designated states

Kind code of ref document: A2

Designated state(s): AE AG AL AM AT AU AZ BA BB BG BR BY BZ CA CH CN CR CU CZ DE DK DM DZ EE ES FI GB GD GE GH GM HR HU ID IL IN IS JP KE KG KP KR KZ LC LK LR LS LT LU LV MA MD MG MK MN MW MX MZ NO NZ PL PT RO RU SD SE SG SI SK SL TJ TM TR TT TZ UA UG US UZ VN YU ZA ZW

AL Designated countries for regional patents

Kind code of ref document: A2

Designated state(s): GH GM KE LS MW MZ SD SL SZ TZ UG ZW AM AZ BY KG KZ MD RU TJ TM AT BE CH CY DE DK ES FI FR GB GR IE IT LU MC NL PT SE TR BF BJ CF CG CI CM GA GN GW ML MR NE SN TD TG

121 Ep: the epo has been informed by wipo that ep was designated in this application
WWE Wipo information: entry into national phase

Ref document number: 09936525

Country of ref document: US

AK Designated states

Kind code of ref document: A3

Designated state(s): AE AG AL AM AT AU AZ BA BB BG BR BY BZ CA CH CN CR CU CZ DE DK DM DZ EE ES FI GB GD GE GH GM HR HU ID IL IN IS JP KE KG KP KR KZ LC LK LR LS LT LU LV MA MD MG MK MN MW MX MZ NO NZ PL PT RO RU SD SE SG SI SK SL TJ TM TR TT TZ UA UG US UZ VN YU ZA ZW

AL Designated countries for regional patents

Kind code of ref document: A3

Designated state(s): GH GM KE LS MW MZ SD SL SZ TZ UG ZW AM AZ BY KG KZ MD RU TJ TM AT BE CH CY DE DK ES FI FR GB GR IE IT LU MC NL PT SE TR BF BJ CF CG CI CM GA GN GW ML MR NE SN TD TG

REG Reference to national code

Ref country code: DE

Ref legal event code: 8642

122 Ep: pct application non-entry in european phase
NENP Non-entry into the national phase in:

Ref country code: JP