WO2000039514A9 - Procede et appareil permettant de fondre des dechets magnetiques a base de terres rares et alliage primaire fondu de dechets magnetiques a base de terres rares - Google Patents

Procede et appareil permettant de fondre des dechets magnetiques a base de terres rares et alliage primaire fondu de dechets magnetiques a base de terres rares

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Publication number
WO2000039514A9
WO2000039514A9 PCT/JP1999/007264 JP9907264W WO0039514A9 WO 2000039514 A9 WO2000039514 A9 WO 2000039514A9 JP 9907264 W JP9907264 W JP 9907264W WO 0039514 A9 WO0039514 A9 WO 0039514A9
Authority
WO
WIPO (PCT)
Prior art keywords
earth magnet
rare earth
scrap
melting
crucible
Prior art date
Application number
PCT/JP1999/007264
Other languages
English (en)
Japanese (ja)
Other versions
WO2000039514A1 (fr
Inventor
Yoichi Hirose
Tatsuo Go
Miki Renda
Nobuhiko Kawamura
Atsushi Otaki
Original Assignee
Showa Denko Kk
Yoichi Hirose
Tatsuo Go
Miki Renda
Nobuhiko Kawamura
Atsushi Otaki
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 Showa Denko Kk, Yoichi Hirose, Tatsuo Go, Miki Renda, Nobuhiko Kawamura, Atsushi Otaki filed Critical Showa Denko Kk
Priority to JP2000591371A priority Critical patent/JP4263366B2/ja
Publication of WO2000039514A1 publication Critical patent/WO2000039514A1/fr
Publication of WO2000039514A9 publication Critical patent/WO2000039514A9/fr

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Classifications

    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22BPRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
    • C22B59/00Obtaining rare earth metals
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22BPRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
    • C22B7/00Working up raw materials other than ores, e.g. scrap, to produce non-ferrous metals and compounds thereof; Methods of a general interest or applied to the winning of more than two metals
    • C22B7/001Dry processes
    • C22B7/003Dry processes only remelting, e.g. of chips, borings, turnings; apparatus used therefor
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22BPRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
    • C22B9/00General processes of refining or remelting of metals; Apparatus for electroslag or arc remelting of metals
    • C22B9/16Remelting metals
    • C22B9/22Remelting metals with heating by wave energy or particle radiation
    • C22B9/226Remelting metals with heating by wave energy or particle radiation by electric discharge, e.g. plasma
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27BFURNACES, KILNS, OVENS, OR RETORTS IN GENERAL; OPEN SINTERING OR LIKE APPARATUS
    • F27B3/00Hearth-type furnaces, e.g. of reverberatory type; Tank furnaces
    • F27B3/08Hearth-type furnaces, e.g. of reverberatory type; Tank furnaces heated electrically, with or without any other source of heat
    • F27B3/085Arc furnaces
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27BFURNACES, KILNS, OVENS, OR RETORTS IN GENERAL; OPEN SINTERING OR LIKE APPARATUS
    • F27B3/00Hearth-type furnaces, e.g. of reverberatory type; Tank furnaces
    • F27B3/10Details, accessories, or equipment peculiar to hearth-type furnaces
    • F27B3/24Cooling arrangements
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P10/00Technologies related to metal processing
    • Y02P10/20Recycling

Definitions

  • the present invention relates to a method of reusing an alloy having a high oxygen concentration such as scrap generated in a process of manufacturing a rare-earth magnet by a melting technique, a melting apparatus used in a recycling method, and a secondary melting method.
  • Rare-earth magnet primary molten alloy prepared in such a way that it can be used to produce magnetic alloy materials hereinafter referred to as “magnet alloys”. Background art
  • scraps include defective sintering products that occur during the sintering process, defective shapes that occur due to chipping during cutting, and defects that occur due to pinholes and the like during the plating process. Scraps such as defective products are included.
  • the alloy for rare earth magnets is melted in a high-frequency induction furnace in a vacuum or inert gas atmosphere, the residue with high oxygen concentration adheres to the refractory lining and remains in the crucible. This is a molten slag, but it is included in scrap in a broad sense.
  • powdery scrap is generated during the process of cutting and polishing the sintered body. This is a state in which water used for cutting and powder of abrasives are mixed, and as a general method, a method of dissolving and extracting with an acid is used to recover useful metals such as rare earth elements. Already done.
  • rare-earth metals that are extremely active in high frequency melting, arc melting, and plasma melting are disclosed. Because it is difficult to convert slag into slag and separate rare earth metals from slag, a method has been proposed in which the amount of scrap added to virgin raw materials is limited and redissolved.
  • the problem with the melting method is that the surface of the molten metal is covered with the slag due to the large amount of slag generated, making it difficult to observe the state of the molten metal and measure the temperature; this slag adheres firmly to the inner wall of the crucible and grows As a result, the internal volume of the crucible is reduced, which causes a fence of the input material to be hung; the work of periodically removing the slag from the inner wall of the crucible becomes difficult, and the life of the crucible is shortened. And so on.
  • the present inventors have analyzed the cause of the low yield when the rare-earth magnet scrap is melted using a normal high-frequency induction melting furnace, and as a result, the rare-earth metal originally contained in the scrap was analyzed.
  • the oxide is separated from the scrap melt, the molten metal is also entrained in the slag and the metal is suspended in the oxide, resulting in poor yield.
  • high oxygen concentration Slag was present in the form of slag, and the apparent amount of slag increased, resulting in a decrease in yield.
  • the method described in the above-mentioned Japanese Patent Application Laid-Open No. 8-31616 is a method in which a metal (alloy) containing a rare earth magnet constituent element as a main component, a so-called virgin raw material, is first dissolved to prepare a seed water, and then the scrap is produced.
  • This method belongs to the re-melting method rather than the scouring method in which oxides are positively removed by melting.
  • the method of Japanese Patent Application Laid-Open No. Hei 7-126109 proposes a method of melting quartz glass in which impurities are not mixed from a container, and that the plasma has a high energy density and a granular silica is added to the container prior to melting. He states that laying down mosquitoes is important in achieving the desired effect.
  • Japanese Patent Application Laid-Open No. 3-25247 states that the twin torch plasma method is excellent in that it is easy to restart when melting waste such as incineration ash. As described above, it has been known that the conventional twin torch plasma dissolution method provides excellent results in dissolving oxide materials and wastes. Disclosure of the invention
  • the present invention provides a method for separating metal from any rare-earth magnet scrap, such as scrap generated in the process of manufacturing the rare-earth magnet and residues in the crucible generated when the raw material for the rare-earth magnet is melted.
  • ⁇ Dissolution that actively promotes separation By providing a melting and refining method, oxides are partially separated and removed, and extremely good yields can be achieved when the raw materials for rare earth magnets are secondarily melted in the next vacuum high frequency induction melting furnace. This is the purpose.
  • the method according to the first aspect of the present invention is the method for obtaining a raw material for producing a rare earth magnet by first melting a scrap of a rare earth magnet, wherein a water-cooled crucible or a refractory crucible in which a part or all of a molten metal holding part is insulated.
  • a rare earth magnet scrap is charged into the crucible, and the rare earth magnet scrap is provided by a plasma torch comprising at least one pair of an anode and a cathode provided above the crucible.
  • the present invention relates to a method of melting a scrap of a rare earth magnet, which is characterized by melting.
  • the apparatus for melting the rare earth scrap for carrying out the first method of the present invention is provided in a plasma arc melting furnace having a plasma torch comprising at least one pair of an anode and a cathode. It is characterized in that a water-cooled crucible or a refractory crucible whose part or whole is insulated is arranged.
  • a method according to a second aspect of the present invention is the method for obtaining a raw material for producing a rare earth magnet by first melting a scrap of the rare earth magnet, wherein the molten metal holding part has a heat insulating part and a water cooling part.
  • the present invention relates to a method of melting a scrap of a rare earth magnet, which comprises charging a scrap and melting the scrap of the rare earth magnet by a tungsten stain or a transition type plasma arc.
  • the apparatus for melting a rare earth scrap for carrying out the second method of the present invention is a crucible in which a molten metal holding section includes a heat insulating part and a water cooling part in a tungsten arc or transition type plasma arc furnace. It is characterized by the arrangement of
  • the method according to a third aspect of the present invention is the method for obtaining a raw material for producing a rare-earth magnet by first melting a scrap of a rare-earth magnet, wherein the molten-metal holding part is placed in a crucible having a heat insulating structure. And a tungsten arc or a transition type plasma arc is generated between a first electrode for locally covering the heat insulating surface of the crucible and a second electrode disposed above the crucible.
  • the present invention relates to a method of melting scraps of rare earth magnets, which is characterized by melting scraps of rare earth magnets.
  • the melting device of the rare earth scrap for carrying out the third method of the present invention includes: a crucible having a heat retaining structure with a molten metal holding portion in a tungsten arc or transition type plasma arc furnace;
  • the second step is to locally cover the heat insulating surface of the crucible.
  • It comprises a first electrode and a second electrode disposed above the crucible.
  • the alloy obtained by primary melting the rare earth magnet scrap according to the present invention is:
  • the sum of Sm and Ce is 10 to 40 wt%, Nd is 5 wt% or less, Fe force; 25 wt% or less, Cu force; 4 to 10 wt%, Zr
  • oxygen is 0.1 wt% or less, and the balance is mainly Co, and unavoidable impurities caused by the rare earth magnet manufacturing process excluding oxygen, and
  • the present invention relates to a primary molten alloy of a rare earth magnet scrap characterized by being an invading element caused by primary melting except Fe.
  • Nd, Pr, and Dy are 20
  • Co force S is 5 wt% or less
  • Cu force S is 0.5 wt% or less
  • Nb is 1 wt% or less
  • oxygen is 0.1 wt% or less
  • the balance is mainly Fe.
  • the present invention relates to a primary molten alloy of a rare earth magnet scrap characterized by being an unavoidable impurity due to a rare earth magnet manufacturing process excluding oxygen and an invading element due to primary melting excluding Fe.
  • the obtained primary molten alloy has advanced agglomeration and separation of oxides, it can be melted using the next vacuum high-frequency induction melting furnace, and the yield when reused can be extremely high.
  • melting by a tungsten arc melting furnace or a transition type plasma arc melting furnace is usually performed by a skull melting method using a copper water-cooled crucible in order to make a melting raw material a direct counter electrode to an arc torch.
  • a shell (skull) of a solidified layer is formed on the inner surface of the water-cooled crucible by the raw material itself.
  • the NdFeB-based magnet melts the scrap of the SmCo-based magnet using an ordinary arc melting furnace or plasma melting furnace. If so, it becomes difficult to sufficiently raise the temperature of the molten metal above the melting point of the alloy. Therefore, if the melting is performed while keeping the temperature of the molten metal low, the deoxidizing scouring effect becomes insufficient. As a result, the yield when the obtained primary ingot is secondarily melted is extremely low at 70% or less.
  • the viscosity difference of the alloy from the melting point is 200 ° C or more, and the viscosity of the alloy becomes extremely high. To decline. Therefore, it is considered that the separation of oxides by agglomeration and flotation progresses rapidly together with the stirring effect of plasma heating.
  • insulation generally assumes that a water-cooled crucible is made of a metal that is a good conductor of heat, and indicates that a contradictory poor conductor of heat is used. As a result, there is no skull in this heat insulating part. Specifically, a heat-insulated conductor is fixed to a part of a water-cooled crucible made of copper or the like in the molten metal holding part of the crucible to form an adiabatic part, or the crucible is made of a water-cooled metal part and a heat-insulated conductor part. Or the entire crucible is made of a poor conductor of heat.
  • Examples of poor conductors of heat include refractory materials such as alumina, zirconium, yttria, calcium, magnesia, etc., and fired products of their composite oxides. .
  • alumina refractories are the most economical and durable. The mixing of aluminum from the refractory into the metal is controlled to less than a problematic level by controlling the heat input from the plasma arc etc. so that the temperature of the molten pool does not become too high. be able to.
  • the molten metal holding part of the crucible is insulated to such an extent that a phenomenon such as the expansion of the molten pool occurs.
  • the heat insulation region is preferably at least 20%, more preferably at least 30%, and even more preferably at least 50% of the inner area of the crucible.
  • the entire inner area of the crucible may be insulated, or the whole may be a refractory crucible.
  • a refractory crucible it may be lined with a refractory inside the metal container (shell). S Regardless of whether the refractory used for this lining is a fixed type refractory or an irregular type refractory.
  • the shell can be jacket-cooled.
  • this method has the advantage of dissolving rare earth magnet scraps with a high oxygen concentration, so it is not advisable to add virgin metal to the material to be dissolved.
  • some virgin metal preferably 30% by weight or less, may be charged into the molten raw material. Good.
  • the virgin metal industrial pure iron, electrolytic iron, rare earth metals such as neodymium, rare earth mother alloys such as ferroneodymium, and ferroboron can be used.
  • the coagulation separation of oxides proceeds even if the molten metal holding time is prolonged, but its contribution is small compared to the temperature, which is not desirable from the viewpoint of productivity.
  • the skull remains, but the skull is thinner than in the case of a normal water-cooled crucible, and no skull is generated at the bottom or other portion where the refractory layer is arranged. You can do much.
  • the next raw material can be charged into the remaining skull to continue melting.
  • the skull shrinks by the time the next raw material is charged, and a gap may be formed between the skull and the crucible. If the conductivity of the skull and crucible is poor, an arc is generated during this time, and the crucible may be locally melted.Therefore, a pure iron plate must be used to ensure conduction between the crucible on the anode side and the scalp. It is better to have a metal energizing part such as.
  • the raw materials are additionally charged as appropriate, and the molten metal is provided at the edge of the crucible and overflows from the tap hole, thereby preventing the crucible from tilting. It is also possible to continue refining continuously.
  • the method of the present invention when the power supply is stopped at the time of tapping, the surface of the molten metal is covered with the oxide slag. However, if the raw material is charged before the molten metal is completely solidified, the slag layer is broken, and a current-carrying part is formed by the raw material, so that current can be continuously supplied.
  • the twin torch plasma is composed of at least a pair of electrodes of an anode and a cathode, so that the crucible does not need to be conductive.
  • Each torch is inserted from the top of the melting furnace chamber into the melting crucible with the tip of the torch inserted into the melting crucible, without changing the melting atmosphere, the insertion angle is variable, and the vertical position can be adjusted. It is installed as follows.
  • the selection range of the voltage, current and input of the plasma torch needs to be changed according to the melting amount and melting time per batch. Generally, it is necessary to increase the plasma current and output as the melting time increases and the melting time decreases. For example, when dissolving 50 kg of scrap per batch, 150 to 300 kW is appropriate. When dissolving 200 kg of scrap, 400 to 600 kW is appropriate.
  • melting by a tungsten arc melting furnace or a transition type plasma arc melting furnace is performed by a skull melting method using a copper water-cooled crucible in order to use a melting raw material as a direct counter electrode to an arc torch.
  • a shell (skull) of a solidified layer by the raw material itself is formed on the inner surface of the water-cooled crucible, and the corrected paper (Rule 91) The raw material charged on the side is dissolved.
  • the molten pool will be wide and deep. For this reason, the molten metal temperature can be easily raised. Therefore, convection in the molten metal of the rare-earth magnet scrap or in the crucible residue having a high oxygen concentration is promoted, and the oxides are easily floated. It can be significantly accelerated.
  • This method employs a different crucible structure from the second method.
  • a structure in which the molten metal holding portion of the crucible is covered with a refractory material to form a heat insulating structure, and a structure in which the refractory material is locally covered with a metal electrode (first electrode) is selected.
  • the refractory surface is locally covered with a metal electrode in order to secure the power supply.
  • a plate electrode for this coating.
  • a plate-shaped metal electrode if one or more holes are provided at the bottom of the crucible, the temperature of the molten metal rises, and after sufficient separation of oxygen, the metal electrodes on and around the holes become By utilizing the melting and disappearing, it becomes possible to extract the molten metal, that is, to discharge the molten metal.
  • the timing of tapping can be controlled by controlling the heat input from the tungsten arc or transitional plasma arc during melting, or by selecting the material and thickness of the metal electrode described later. Can also be adjusted.
  • an iron electrode can be used as the material of the metal electrode.
  • steel with a low content of carbon and other harmful impurities as raw materials for rare-earth magnets Corrected paper (Rule 91) The use of a material makes it possible to prevent the contamination of these elements, so it is desirable to use an electrode made of industrial pure iron.
  • an electrode made of a high melting point metal such as niobium, molybdenum, tantalum, or an alloy thereof can be used.
  • the heat input from the tungsten arc or the transitional plasma arc is controlled in the same way as preventing the contamination of aluminum when using alumina refractories, so that the temperature of the molten pool does not become too high. By doing so, the incorporation of the metal elements constituting these electrodes into the substance to be dissolved can be suppressed to a level that is not problematic.
  • the primary molten alloy according to the present invention Since this is melted as an ingot of 1 to 50 kg that can be directly charged into the secondary melting furnace, it will be referred to as “primary ingot” below.
  • the primary ingot of the present invention has a significantly lower oxygen concentration than the scrap state, and is significantly lower than the conventional vacuum-melted primary ingot.
  • the composition of this primary ingot is analyzed, combined with the virgin raw material, and the composition is determined so that the desired composition is obtained. Secondary melting by a method, forging, and alloying for magnets.
  • the amount of oxygen in the metal is reduced by the primary melting, when the secondary melting is performed using a vacuum high-frequency melting furnace, the slag-like metal content due to the unseparated oxide remaining in the metal decreases and the yield increases. The rate can be improved.
  • the amount of primary ingot obtained from the rare earth magnet scrap must be determined in consideration of the following points. This is because the scrap has a high carbon concentration due to the lubricant used during the magnetic field press molding in the magnet manufacturing process, and decarburization is almost expected during the primary melting. Therefore, the carbon content in the primary ingot is typically as high as 0.04% or more. Incidentally, the carbon content of the magnet alloy melted only from the virgin raw material is usually less than 0.04%, typically about 0.02%. If the amount of the primary ingot is excessively increased, the secondary dissolution ingot may be excessively increased. The carbon content of the magnet also increases, which adversely affects the properties of the magnet obtained from it. Considering this limitation by the amount of carbon, the primary ingot obtained by this method can be secondary-dissolved as 50% by weight or less, and the balance can be secondary virgin material.
  • the secondary ingot obtained by mixing and melting the primary ingot and the virgin raw material is used as the alloy for the magnet.
  • the primary ingot alone may be used as an alloy for magnets, and the ratio of this alloy may be limited in the pulverization and mixing process in the later manufacture of magnets.
  • composition of the primary ingot of the present invention 15 to 40% of the rare earth element and Fe as the main component of the balance represent the component range obtained by dissolving the most common grade scrap. It is specified.
  • Oxygen is mixed in as impurities in the manufacturing process of the rare earth magnet, particularly in the pulverizing process or the sintering process. However, since this reduction is an important achievement of the present invention, it is limited to 1% or less.
  • the components of the alloy for the magnet include Sm—Fe, Cu, Zr, and Nd (which may be partially replaced by Pr, Dy) of the Co-based magnet, and one Fe—
  • B-based magnets such as B, A 1, Co, Cu, and Nb, and these are used as components of magnet alloys regardless of the quantity.
  • a metal such as Fe is mixed from the metal electrode used in the third method, in addition to the trace elements from the various refractories described above, for example, A1 and the like.
  • This Fe is a necessary component of the magnet alloy.
  • a 1 is S m — Co-based magnets are harmful to magnetic properties, while Nd—Fe-B magnets allow small amounts of alloying elements, but too much are harmful to magnetic properties. Therefore, the amount is preferably 1% or less.
  • FIG. 1 is a cross-sectional view showing one embodiment of a water-cooled copper crucible for carrying out the first and second methods of the present invention.
  • FIG. 2 is a sectional view showing one embodiment of a refractory crucible for carrying out the first method of the present invention.
  • FIG. 3 is a diagram showing an embodiment of the first melting apparatus of the present invention using a twin torch plasma arc melting furnace.
  • FIG. 4 is a view showing one embodiment of the melting apparatus according to the second and third aspects of the present invention using a transfer type plasma arc melting furnace.
  • FIG. 5 is a perspective view showing one embodiment of a water-cooled copper crucible provided with a current-carrying part for carrying out the second method of the present invention.
  • FIG. 6 is a drawing showing one embodiment of a refractory crucible for carrying out the third method of the present invention.
  • FIG. 7 is a drawing showing another embodiment of a refractory crucible for carrying out the third method of the present invention.
  • FIG. 8 is a drawing showing still another embodiment of the refractory crucible for carrying out the third method of the present invention. Description of embodiments of the invention
  • FIG. 1 shows a crucible having a water-cooled structure made entirely of copper for carrying out the method of the present invention.
  • 1 is a copper crucible
  • 2 is a refractory plate
  • 3 is a raw material
  • 4 is a cooling water inlet
  • 5 is a cooling water passage
  • 6 is a cooling water outlet.
  • the refractory plate 2 is used only at the bottom of the crucible 1 and the side wall remains a water-cooled copper crucible, so that the heat input by the plasma and the insulation by the refractory plate 2 are balanced.
  • the molten pool can be deepened.
  • the shape of the refractory is simple, the durability is excellent, and the cost is excellent because it is inexpensive. Dissolution method.
  • FIG. 2 shows a refractory crucible for carrying out the method of the present invention.
  • a refractory crucible is placed in a metal container.
  • 7 is an alumina crucible and 9 is an iron container.
  • the gap between the crucible and the container is filled with alumina powder 8.
  • FIG. 3 shows an embodiment of a twin torch plasma melting furnace.
  • reference numeral 10 denotes a plasma torch, which generates plasma 11 between an anode torch 10a and a cathode torch 10b.
  • Fig. 4 shows the transfer type plasma arc melting furnace.
  • reference numeral 15 denotes a plasma torch, which generates a plasma arc between the torch and the raw material charged in the copper crucible 1.
  • the tungsten arc melting furnace has a structure in which a tungsten electrode is provided in place of the plasma contact 15 and an arc is generated between the electrode and the raw material.
  • 16 is a raw material charging pipe.
  • FIG. 5 shows a crucible provided with a current-carrying part 17.
  • the current-carrying part 17 is formed by bending an iron plate or the like in accordance with the inner shape of the crucible so as to be in contact with the inner wall of the water-cooled copper crucible. Melting by this method ⁇ The following rare earth magnet scrap can be charged and melted inside the skull left after tapping.
  • a gap is formed between the crucibles due to the shrinkage of the remaining skull, which causes the conductivity to deteriorate and the crucible to be melted.
  • a current-carrying part 17 for ensuring conduction between the crucible and the skull.
  • FIG. 5 three plasma towers A crucible for use in a plasma arc furnace with two conductors is shown, and three conducting parts are provided so that a conducting part is arranged between two torches.
  • the metal electrode 20 is, for example, a plate-like electrode covering the bottom of the crucible, and the crucible is vertically separated into a bottom 21 and a side wall 22.
  • the electrode 20 is sandwiched between the bottom 21 and the side wall 22 so as to ensure that power is supplied from the outer periphery of the electrode 20 to the power supply.
  • the crucible after melting the rare earth magnet scrap, the crucible is tilted and heated.
  • a crucible structure in which a tap hole 25 is provided at the bottom 21 of the crucible may be used.
  • Example 1 (Example of the first invention)
  • NdFeB magnet (Analytical value: Nd + Pr—29.0 wt%, Dy-2.5 wt%, A1-0.32 wt%, B— 1.03 wt%, O-0.66 wt%, C-0.04 wt%, Fe remaining) as raw materials, and a water-cooled copper crucible (No. 1) whose bottom is insulated with a sintered alumina plate.
  • a 5 O kW twin torch plasma arc melting furnace (Fig. 2), argon gas was converted to plasma and melted to obtain a primary ingot.
  • the melting amount of each knuckle is 1.5 kg, and the melting point of this alloy is 1200 to 125 ° C, so the melting temperature is higher than this by more than 300 ° C. 550 was decided.
  • the crucible 1 had an inner diameter of 170 mm and a depth of 70 mm, and an alumina sintered plate 2 having a thickness of 20 mm was arranged at the bottom thereof.
  • the primary dissolution yield was calculated by dividing the product weight by the charged raw material weight.
  • the melting time in this twin torch plasma arc melting furnace was 13 minutes, and the melting power of the primary ingot was 2. SkWhZkg. Since the bottom of the crucible is insulated, the melting time is short and the melting power is small.
  • the obtained alloy was used as a raw material and melted in an argon gas atmosphere using a vacuum high-frequency induction melting furnace.
  • the primary ingot is usually added to the virgin material to make the composition of the magnet alloy, but in order to investigate the yield, the entire amount was melted with the primary ingot alone.
  • Table 1 shows the dissolution yield of the primary ingot, the dissolution yield of the secondary dissolution, and the average oxygen analysis value of the primary ingot.
  • Example 2 (Example of the second invention)
  • Example 2 A scrap of the NdFeB magnet used in Example 1 was used as a raw material, and an endless crucible (FIG. 2) was arranged. A 50 kW twin torch was used as in Example 1. Melting was performed in a plasma arc furnace to obtain a primary ingot. Analytical value of primary ingot: Nd + Pr—25.0 wt%, Dy-2.2 wt%, A1-0.38 wt%, B-0.99 wt%, ⁇ _ 0.019 wt%, C-0.04 wt%, Fe remaining. The dissolution amount of the batch was 1.5 kg, and the melting temperature was 1550 ° C.
  • the alumina crucible 7 has an inner diameter of 170 mm, a depth of 70 mm, and a thickness of 30 mm.
  • This solution The solution time was 12 minutes, and the melting power of the primary ingot was 2.6 kWhkg. As in Example 1, the dissolution time was short and the dissolution power was small.
  • the dissolution yield and average oxygen concentration at this time are shown in Table 1. These values were also the same as in Example 1, and an ingot with a high yield and a remarkably reduced oxygen concentration could be obtained.
  • Example 1 The NdFeB-based magnet scrap and virgin raw material used in Example 1 were melted using a 15 kW vacuum high-frequency induction melting furnace. The amount of dissolution was 5 kg, and the amount of scrap added to the virgin material was 50%. Table 1 shows the dissolution yield and average oxygen analysis value of the obtained primary ingot. The dissolution yield is assumed to be 95%, which is the average yield when the virgin raw material is dissolved using only the virgin raw material, and only the scrap is dissolved to match the overall yield. The yield was calculated and the value was given.
  • Example 2 Using the scrap of the NdFeB-based magnet used in Example 1 as a raw material, 5 kg was melted using a 15 kW vacuum high-frequency induction melting furnace to obtain a primary ingot. Analytical value of primary ingot: Nd + Pr—25.0 wt%, Dy-2.3 wt%, A1-0.335 wt%, B—1.01 wt%, ⁇ — 0.020 wt%, C-0.04 wt%, Fe remaining.
  • Example 1 As in Example 1, this primary ingot was melted again using a vacuum high-frequency induction melting furnace. As in Example 1, the dissolution yield and the average oxygen analysis value were determined and are shown in Tables 1 and 2. Comparative Example 3
  • Example 1 As a scrap material for the NdFeB magnet used in Example 1, a 50 kW thin torch plasm mark melting furnace using a water-cooled copper crucible without any heat insulation was used. 1.5 kg was dissolved to obtain a primary ingot. Analytical value of primary ingot: Nd + Pr-28. 0 wt%, Dy-2.4 wt%, A1-0.322 wt%, B-1.02 wt%, O — 0.42 wt%, C— 0.44 wt%, Fe remaining. This device can melt scrap with a melting point of 1200 to 125 ° C, but the melting temperature cannot be raised sufficiently because the crucible is not insulated. It stopped at 0 ° C.
  • the skull was also thick, and about half of the charged raw material remained in the crucible as a skull.
  • the melting time in this plasma arc melting furnace was 22 minutes, and the melting power for the primary ingot was 13 kWh / kg.
  • this primary ingot was melted using a vacuum high-frequency induction melting furnace.
  • the dissolution yield and the average oxygen analysis value were determined and the results are shown in Table 1, as in the example.
  • the oxygen analysis value in the primary ingot is very high, and the deoxidizing effect is insufficient.
  • the scrap is melted in a plasma arc furnace equipped with a normal water-cooled crucible crucible, it is not insulated, and is not kept at a high temperature even if it is melted. It is clear that the oxygen concentration in remains high. For this reason, the yield in secondary melting in a high-frequency induction furnace was low, and was almost the same as when scrap was melted as it was. Ingot dissolution yield, oxygen analysis
  • the melting amount per batch is 1.5 kg, and the melting point of this alloy is 1300 ° C Based on the above, the melting temperature was set at 300 ° C. higher and 160 ° C. higher than this.
  • the crucible 1 had an inner volume of 110 mm in diameter and a depth of 70 mm, and an alumina sintered plate 2 having a thickness of 20 mm was arranged at the bottom thereof.
  • the melting time in this arc melting furnace was 11 minutes, and the melting power of the primary ingot was 1.5 kWhZkg. Because the bottom is insulated, the melting time is short and the melting power is small.
  • the obtained alloy was used as a raw material and melted in an argon gas atmosphere using a vacuum high-frequency induction melting furnace.
  • the primary ingot is usually added to the virgin raw material to obtain a magnet alloy composition, but in order to examine the yield, the entire amount was melted only with the primary ingot.
  • Table 2 shows the dissolution yield of the obtained primary ingot, the dissolution yield of the secondary dissolution, and the average oxygen analysis value of the primary ingot.
  • Example 3 a conducting part made of a pure iron plate (thickness I mm x width 15 mm, three pieces) was provided in contact with the inner wall of the water-cooled copper crucible shown in Fig. 5
  • a primary ingot of the following analysis value was obtained.
  • the melting temperature was 16 ° C, which was the same as in the example.
  • the analysis value of the primary ingot was Nd + Pr-24.8 wt%, Dy-2.1 wt%, A1-0.35 wt%, B-0.98 wt%, O -0.018 wt%, C-0.04 wt%, Fe remaining.
  • Example 3 a magnetic alloy was melt-formed using this primary ingot.
  • the dissolution yield was determined in the same manner as in Example 1, and the average oxygen analysis value of the primary ingot was measured. The results are shown in Table 2.
  • Table 2 also in the plasma arc melting furnace, remarkably reducing the oxygen concentration and a high secondary melting yield were obtained as in Example 3 by melting the scrap at a high temperature.
  • the residue remaining in the crucible (Sm—31.6 wt%, Fe-4.6 wt%, Zr -2.0 wt%, O-2.8 wt%, Co remaining) and a 30 kW tungsten arc melting furnace with a water-cooled copper crucible ( Figure 1) insulated with a sintered aluminum plate at the bottom.
  • Metals could be recovered by melting in an argon gas atmosphere using a furnace.
  • the dissolution amount is 1.5 kg
  • the dissolution yield of the obtained primary ingot is 75%
  • the composition analysis value is Sm-15.0 wt%, Fe-28.0 wt%.
  • Example 3 To the scrap of the NdFeB magnet used in Example 3, 10% of a virgin material containing Nd metal, which is highly oxidized, was added, and the primary ingot was formed in the same manner as in Example 3. Obtained. The oxygen analysis value of this ingot was sufficiently reduced to no significant difference from Example 1.
  • Example 8 (Example of the first invention)
  • Example 2 Using the scrap of 45 kg of the NdFeB magnet used in Example 1 as a raw material, the side was insulated with a sintered alumina cylinder 23, and the bottom was only a water-cooled copper plate 24. Using a 300 kW plasma arc melting furnace in which the crucibles shown in the figure were arranged, melting was performed in an argon gas atmosphere to obtain a primary ingot. Analytical values of the primary ingot were Nd + Pr-25 28 wt%, Dy-2.3 wt%, A1-0.34 wt%, B-l. 0 0 wt%, O — 0.018 wt%, C-0.04 wt%, Fe remaining.
  • the dissolution temperature was set at 160 ° C., the same as in Example 3.
  • the crucible 1 was a sintered alumina cylinder 23 having an inner diameter of 32 O mm, a depth of 15 O mm, and a thickness of 30 mm, and a water-cooled copper plate 24 was disposed at the bottom thereof.
  • Example 3 a magnetic alloy was melt-formed using this primary ingot. As shown in Table 2, also in this method, the oxygen concentration was significantly reduced and a high secondary dissolution yield was obtained by dissolving the scrap at a high temperature.
  • Example 6 the raw material of the NdFeB-based magnet scrap was melted, and after tapping, before the melt was completely solidified, additional raw materials were added without breaking the argon gas atmosphere. Then, electricity was supplied again to dissolve. When the molten metal in the crucible became full, a part of the molten metal was poured out by tilting the crucible, and the raw material was added, so that it could be melted continuously. In addition, the metal solidified in the tap at the top of the crucible, and an abnormal arc flew in this part at the beginning of energization, so the solidified metal in this part was cut out slightly to make the tap.
  • Example 10 (Example of the third invention)
  • Scrap of NdFeB-based magnet used in Example 3 45 kg As a raw material, the sides were insulated with a sintered alumina cylinder, and the bottom was also insulated with a sintered alumina plate.
  • a 300 kW plasma arc melting furnace with a crucible as shown in Fig. 6 in which a circular plate made of pure iron was installed as a current-carrying part melting was performed in an argon gas atmosphere, and the primary ingot was cooled. Obtained.
  • the dissolution temperature was set at 160 ° C., the same as in Example 1.
  • the crucible 1 is a sintered alumina cylinder 10 having an inner diameter of 32 O mm, a depth of 150 mm and a thickness of 3 O mm, and an outer diameter of 32 O mm and a thickness of 3 O mm at the bottom thereof. Was placed, and a 0.5 mm pure iron circular plate was placed inside.
  • Example 1 1 (Example of the third invention)
  • Example 3 Using the scrap of the NdFeB magnet used in Example 3 as a raw material, the sides were insulated with a sintered alumina cylinder 22 and a tap hole 25 was opened at the center of the bottom.
  • a crucible as shown in FIG. 8 was provided, in which heat was insulated by a single-nut-shaped sintered alumina plate 21 and a circular plate 20 made of pure iron was installed as a conducting part inside the pure iron part. Melting was performed in an argon gas atmosphere using a 0 kw plasma arc melting furnace. When melted, the center of the steel plate was broken, and the molten metal flowed to the bottom, and a primary ingot was obtained in the mold installed below.
  • Analytical values of the primary ingot were Nd + Pr-25.5 wt%, Dy-2.2 wt%, A1-0.35 wt%, B-1.01 wt%, O -0.018 wt%, C-0.04 wt%, Fe remaining.
  • the sintered aluminum plate at the bottom was a doughnut having an inner diameter of 10 O mm, an outer diameter of 320 mm, and a thickness of 30 mm under the same conditions as in Example 10. Dissolved. In this method, slag and some metal remained in the crucible, so that a 40 kg ingot with little slag entrainment was obtained.
  • Example 1 2 Example of the third invention
  • Example 10 After melting and tapping under the same conditions as in Example 10, the slag on the upper part of the solidified metal remaining in the crucible was partially scraped, and the lower metal layer was exposed to secure a current-carrying part. After that, the method of adding additional raw materials, re-energizing and melting was repeated. At this time, there was also a charge with a hole in the center of the remaining solidified metal. In this case, iron foil or an iron plate was placed to close the hole and the raw material was charged. With this method, the same ingot as in Example 10 was obtained. Industrial applicability

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Abstract

L'invention concerne un procédé permettant d'augmenter le rendement obtenu dans un processus, qui consiste à séparer des métaux de déchets produits par un processus de production d'un aimant à base de terres rares. Les matériaux d'alliage pour aimant à base de terres rares sont raffinés par fusion, de façon à séparer positivement les oxydes, puis soumis à une seconde fusion au moyen d'un four de fusion à induction haute fréquence sous vide. Une partie ou la totalité des déchets (3) sont chargés dans un creuset (1) isolé (2) à refroidissement par eau, ou dans un creuset réfractaire (7, 21, 22), et soumis à une fusion au moyen de deux jets de plasma (10A, 10b) et à une fusion à l'électrode de tungstène ou à l'arc à migration.
PCT/JP1999/007264 1998-12-25 1999-12-24 Procede et appareil permettant de fondre des dechets magnetiques a base de terres rares et alliage primaire fondu de dechets magnetiques a base de terres rares WO2000039514A1 (fr)

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CN102492848B (zh) * 2011-12-22 2014-10-08 张森 一种用冷坩埚感应熔炼技术回收NdFeB废料的方法
CN104651612B (zh) * 2013-11-19 2017-06-20 荆门市格林美新材料有限公司 熔融稀土废料回收稀土的方法
DE102014206223A1 (de) 2014-04-01 2015-10-01 Fme Freiberger Metallrecycling Und Entwicklungsdienstleistungen Gmbh Verfahren zur Rückgewinnung Seltener Erden aus Seltene Erden-haltigen Zusammensetzungen
DE102014224015B4 (de) 2014-11-25 2019-07-04 Fme Freiberger Metallrecycling Und Entwicklungsdienstleistungen Gmbh Verfahren zur Rückgewinnung Seltener Erden aus Seltene Erden-haltigen Leuchtstoffen
CN108977674A (zh) * 2018-07-31 2018-12-11 邳州市尕星医药技术服务有限公司 一种从稀土电解废料中提取稀土氧化物的方法
CN108754163A (zh) * 2018-07-31 2018-11-06 邳州市尕星医药技术服务有限公司 一种从稀土废料中提取稀土金属的方法
KR102122428B1 (ko) * 2019-07-12 2020-06-19 주식회사 알인텍 주조 알니코 자석의 원재료 재생 방법 및 주조 알니코 자석의 제작 방법

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JP2980481B2 (ja) * 1992-10-19 1999-11-22 新日本製鐵株式会社 複式アーク炉設備の操業方法
JPH085247A (ja) * 1994-06-15 1996-01-12 Tsukishima Kikai Co Ltd プラズマ式溶融炉
JP3450447B2 (ja) * 1994-07-15 2003-09-22 住金モリコープ株式会社 希土類磁石スクラップの溶解方法
JPH0924326A (ja) * 1995-07-10 1997-01-28 Konica Corp 円筒状基材の塗布方法及び該装置
JPH0942850A (ja) * 1995-07-28 1997-02-14 Ishikawajima Harima Heavy Ind Co Ltd 直流アーク炉
JP3377906B2 (ja) * 1996-03-11 2003-02-17 株式会社タクマ プラズマ溶融炉における溶融スラグの流動性低下防止方法
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