CN1064510A - The preparation method of neodymium and Nd-Pr base heavy rare-earth alloy - Google Patents
The preparation method of neodymium and Nd-Pr base heavy rare-earth alloy Download PDFInfo
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- CN1064510A CN1064510A CN 92101707 CN92101707A CN1064510A CN 1064510 A CN1064510 A CN 1064510A CN 92101707 CN92101707 CN 92101707 CN 92101707 A CN92101707 A CN 92101707A CN 1064510 A CN1064510 A CN 1064510A
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Abstract
The present invention relates to the preparation method of a kind of neodymium or praseodymium neodymium based heavy rare earths alloy, be that to select fluorochemical for use be fused electrolyte, wherein composition (wt%) is: neodymium or praseodymium neodymium fluorochemical 40~89, heavy rare earth fluoride 1~40, Calcium Fluoride (Fluorspan) 0~15, when preparation also need add 10~50 lithium fluoride, cathode current density 6~20A/cm during meodymium-base alloy
2, anodic current density 0.1~1.5A/cm
2, under 980~1100 ℃ of electrolysis temperatures, add oxide compound continuously, wherein heavy rare-earth oxide is 10~35%, substrate metal oxide is 65~90%, adopts the present invention can make the heavy rare earth alloy of heavy rare earths content height, alloy carbon content low (<0.05%).
Description
The present invention relates to the method that a kind of electrolytic process prepares rare earth alloy, be used in particular for preparing neodymium or Nd-Pr base heavy rare-earth alloy.
At present, the preparation method of heavy rare earth metal has two kinds of metallothermic reduction and reduction-distillation, but complex process, the cost height can not continuous production.In order to obtain cheap Nb-Fe-B magnet raw material, some production methods about preparation Dy-Fe, Dy-Nd alloy have appearred in succession, and as European patent EP 0229516A, but its alloy ingredient is uncontrollable.Chinese patent application CN1040399A has proposed a kind of preparation method and device thereof of the Dy-Nd of production alloy, is at NdF
3, DyF
3, LiF and BaF
2In the fluoride molten salt of forming, under 1050~1150 ℃ electrolysis temperature, the nearly 10A/cm of cathode current density
2, be feedstock production with rare earth oxide Dy content 3~10%, the Dy-Nd alloy of carbon content 0.11%.This alloy is with regard to its dysprosium content, can be used for directly joining Dy content and be not more than 3.3% Nd-Dy-Fe-B permanent magnet, for being higher than 3.3% permanent magnet because magnetic property requires to add Dy content, can not satisfy the requirement of direct preparation permanent magnet alloy, need to add in addition the higher metal Dy of price, so just lost the meaning of preparation Dy-Nd alloy, with regard to alloy mass, because raw material Nd and contain in the Nd alloy non-rare earth impurity especially carbon is to the influence of Nd-Fe-B magnet coercive force greatly, for this reason, magneticsubstance producer requires to be lower than 0.05% as the Nd alloy carbon content of magnet raw material, the Dy-Nd alloy of the carbon content 0.11% that obtains of prior art just can not satisfy the raw materials quality requirement of preparation Nd-Dy-Fe-B permanent magnet like this, will have a strong impact on the performance of magnet.
The objective of the invention is to obtain a kind of carbon content is low, the heavy rare earth alloy amount the is high Nd or method of PrNd based heavy rare earths alloy of preparing.
For achieving the above object, the present invention is achieved in that
Fused electrolyte is made up of fluorochemical, and wherein the matrix metal fluorochemical is 40~89wt%, and heavy rare earth fluoride is 1~40wt%, and the cathode current density during electrolysis is 6~20A/cm
2, anodic current density is 0.1~1.5A/cm
2, electrolysis temperature is 980~1100 ℃, adds oxide compound continuously, and heavy rare-earth oxide is 10~35wt% in this oxide compound, and substrate metal oxide is 65~90wt%
When above-mentioned heavy rare earth alloy was neodymium based heavy rare earths alloy, fused electrolyte was (wt%): neodymium fluoride 40~89, and heavy rare earth fluoride 1~40, lithium fluoride 10~15, Calcium Fluoride (Fluorspan) 0~15, electrolysis temperature are 1030~1100 ℃.
When described heavy rare earth alloy is praseodymium neodymium based heavy rare earths alloy, fused electrolyte is (wt%): didymium fluorochemical 40~89, heavy rare earth fluoride 1~40, Calcium Fluoride (Fluorspan) 0~15, electrolysis temperature is 980~1100 ℃, add oxide compound in the electrolytic process, wherein heavy rare-earth oxide is 10~35, and the didymium oxide compound accounts for 65~90%.
Above-mentioned heavy rare earth metal refers to a kind of among Dy, Ho, Tb, the Er.
Below the present invention is further described.
The present invention has selected electrolysis of fluorides plastid matter, and lithium fluoride is 10~50wt% in the ionogen, and neodymium fluoride (or didymium fluorochemical) is 40~89wt%, and heavy rare earth fluoride 1~40wt% also can increase by the Calcium Fluoride (Fluorspan) of 0~15wt%.
Wherein, lithium fluoride can reduce electrolytical liquidus temperature, increases electrolytical electricity and leads, when content during less than 10wt%, liquidus temperature raises, and viscosity increases the preparation that is unfavorable for alloy, then the alloy yield is low to surpass 50wt%, and obtain that the content of impure physics also increases to some extent in the alloy.
The Calcium Fluoride (Fluorspan) that adds 0~15Wt% can reduce the fusing point of electrolysis of fluorides matter.
Compared with prior art, do not contain barium fluoride BaF in the fusion electrolysis plastome of the present invention
2, can make like this that carbon content reduces greatly in the product alloy, this be because: under comparatively high temps, be added with BaF
2Electrolysis mass-energy and the anodic gas reaction that produces of electrolytic process generate barium carbide, barium carbide passes to alloy with carbon again, makes that carbon content increases in the alloy.
In ionogen, the addition of heavy rare earth fluoride is relevant with heavy rare-earth oxide ratio in the electrolysis raw material, heavy rare-earth oxide is higher than in the ionogen corresponding fluorochemical proportion more for a long time in the electrolysis raw material, can not be reduced, this not only can not prepare the heavy rare earth alloy of predetermined content, the dissolved oxygen thing is sneaked into generate in the alloy.
Electrolytic process depends primarily on electrolysis temperature smoothly among the present invention, electrolysis temperature is low excessively, electrolytic process can't normally carry out, the too high then prepared alloy of electrolysis temperature easy and electrolyzer lining material, anode and the effect of alloy receptor, make alloy seriously polluted, cause alloy preparation process alloy yield low, therefore, adopt lower electrolysis temperature in the electrolytic process as far as possible, to guarantee quality product and technico-economical comparison.According to mentioned above principle, when preparation neodymium based heavy rare earths alloy, adopt 1030-1100 ℃ electrolysis temperature, electricity density is 6-20A/cm when the preparation Nd-Pr base heavy rare-earth alloy
2, anodic current density is 0.1-1.5A/cm
2Satisfying under the aforesaid operations condition situation, the lower alloy of preparation heavy rare earths content adopts lower cathode current density electrolysis effectiveness good; The higher alloy of preparation heavy rare earths content, adopt the high cathode current density more satisfactory, at this moment the cathode surface local temperature will be higher than electrolytical temperature in the groove, and this not only helps the alloy preparation, also can reduce electrolytical temperature effectively and promptly reduce electrolysis temperature.
Because cathode current density is higher, anodic current density is also higher in identical electrolyzer, and anodic current density can reach 1-1.5A/cm among the present invention
2, and it is generally acknowledged that anodic current density must be less than 1A/cm in the existing technology
2, otherwise will produce tangible anode effect, and anodic current density of the present invention is greater than 1A/cm
2Do not produce anode effect, in same electrolyzer, can under higher current density, operate like this, make electric current can pass to greatest limit and reach same electrolyzer, strengthened production process owing to the energising flow increases.
Specifically, when the heavy rare earth alloy of the present invention's preparation was dy-nd alloys, ionogen was neodymium fluoride, dysprosium fluoride and lithium fluoride, and cathode current density is 11-20A/cm
2, optimum value is 13-15A/cm
2, electrolysed substance is dysprosium oxide 11-19%, the oxide compound of Neodymium trioxide 89-91%, compared with prior art, the present invention raises the negative electrode local temperature owing to adopted the high cathode current density, could prepare the higher neodymium-dysprosium alloy of dysprosium content under the temperature close with prior art.If adopt the current density close then can not prepare the neodymium-dysprosium alloy of dysprosium content of the present invention with prior art, this is because dysprosium content height causes due to the alloy melting point rising, anode the solid deposited neodymium-dysprosium alloy will occur and grow up, and finally causing anode and cathode to connect electrolytic process can not go on.
Compared with prior art, in the fused electrolyte of the present invention owing to do not contain BaF
2, can make that like this carbon content reduces greatly in the product heavy rare earth alloy, drop to below 0.05% by 0.11% as carbon content in the Dy-Nd alloy, the present invention simultaneously adopts the 10A/cm of high cathode current density by prior art
2Below bring up to 11-20A/cm
2, the negative electrode local temperature is improved, under close electrolysis temperature, prepare the much higher alloy of heavy rare earths content like this, in the Dy-Nd alloy, Dy content is brought up to 11-15% by 2-10%.Like this, in the scope of the invention described above, can prepare by any change ionogen composition, cathode and anode current density, electrolysis temperature and reinforced ratio that content is low, heavy rare earths content reaches as high as 35% neodymium or Nd-Pr base heavy rare-earth alloy.
Introduce embodiments of the invention below:
Embodiment 1
Plumbago crucible is for containing electrolyte container and make anode, and the dark 15cm of its internal diameter 10cm, ionogen be neodymium fluoride 70%, fluoridize terbium 16%, lithium fluoride 14%, cathode current density 7-12A/cm
2, 1040 ℃ of electrolysis temperatures, electrolytic process add Neodymium trioxide 228 grams, terbium sesquioxide 44 grams, and 160 amperes in electric current, anode are φ 0.8cm tungsten bar, 7 volts of voltages, electrolysis time 2 hours makes Nd-Tb alloy 221 grams, and Tb content is 14.7%, and carbon content 0.036% in the alloy.
Embodiment 2
The above-mentioned plumbago crucible of same employing is the Sheng electrolyte container, and makes anode, ionogen NdF
365%, DyF
318%, LiF18%, anodic current density 11-17A/cm
2, 1050 ℃ of electrolysis temperatures, negative electrode are φ 0.8cm molybdenum bar, electrolytic process adds Nd
2O
3262 grams, Dy
2O
358 grams, 7.3 volts of voltages, electrolysis time 1.5 hours makes that to contain dysprosium be that 17.9% Nd-Dy alloy 257 restrains, and the alloy carbon content is 0.03%.
Embodiment 3
Electrolyzer is the same, and ionogen is a didymium fluorochemical 60%, dysprosium fluoride 20%, lithium fluoride 20%, 100 amperes of Faradaic currents, 6.5 volts of voltages, 990 ℃ of electrolysis temperatures, cathode current density 7A/cm
2, negative electrode molybdenum bar φ 0.8cm, electrolytic process add 300 gram didymium oxide compounds, 40 gram dysprosium oxides, and electrolysis time 2.5 hours makes that to contain dysprosium be 11.2% didymium alloy 271.5 grams, alloy content carbon amount 0.026%.
Embodiment 4
Electrolyzer is the same, and ionogen is fluoridized erbium 15%, neodymium fluoride 67%, and lithium fluoride 18%, 100 amperes of Faradaic currents, negative electrode φ 0.8cm molybdenum bar, cathode current density is 13A/cm
2, 1040 ℃ of electrolysis temperatures, 6.9 volts of voltages, electrolysis time 1 hour, electrolytic process add Neodymium trioxide 156 grams, and Erbium trioxide 28 grams make neodymium erbium alloy 136.4 grams, and alloy contains erbium 12.3%, alloy carbon containing 0.034%.
Embodiment 5
Electrolyzer is the same, ionogen holmium fluoride 10%, and neodymium fluoride 70%, lithium fluoride 20%, 100 amperes of Faradaic currents, negative electrode are φ 0.8cm molybdenum bar, cathode current density 12A/cm
2, 1040 ℃ of electrolysis temperatures, 6.7 volts of voltages, electrolysis time 1 hour, electrolytic process add Neodymium trioxide 150 grams, and Holmium trioxide 20 grams make neodymium holmium alloy 125 grams, contain holmium 8.25%, alloy carbon containing 0.043%.
Embodiment 6
Electrolyzer is the same, and ionogen is a didymium fluorochemical 70%, holmium erbium fluorochemical 15%, and lithium fluoride 15%, 120 amperes of Faradaic currents, negative electrode are φ 10cm molybdenum bar, cathode current density 12A/cm
2, 1040 ℃ of electrolysis temperatures, voltage 6.5-6.9 volt, electrolytic process add 302 gram didymium oxide compounds, holmium erbium oxide compound 35 grams, and electrolysis time 2 hours makes and contains holmium erbium 9.1% didymium-holmium erbium alloy 254.1 grams, alloy carbon containing 0.029%.
Claims (7)
1, a kind of method for preparing rare earth alloy, it is characterized in that: fused electrolyte is formed (wt%) by fluorochemical: wherein the matrix metal fluorochemical is 40~89, heavy rare earth fluoride is 1~40, cathode current density 6~20A/cm
2, anodic current density 0.1~1.5A/cm
2, under 980~1100 ℃ of electrolysis temperatures, add oxide compound continuously, wherein heavy rare-earth oxide is 10~35%, substrate metal oxide is 65-90%.
2, method according to claim 1, it is characterized in that: when described heavy rare earth alloy was the neodymium base, fused electrolyte is (wt%): neodymium fluoride accounted for 40~89, and heavy rare earth fluoride is 1-40, also add the Lithium Oxide 98min of 10-50 in addition, electrolysis temperature is 1030~1100 ℃.
3, method according to claim 2 is characterized in that: the Calcium Fluoride (Fluorspan) that also can add 0~15wt% in the described fused electrolyte.
4, method according to claim 1, it is characterized in that: when described heavy rare earth alloy is praseodymium neodymium base, fused electrolyte is (wt%): praseodymium neodymium fluorochemical 40~89, heavy rare earth fluoride 1~40, electrolysis temperature is 980~1100 ℃, heavy rare-earth oxide is 10~35wt% in the adding oxide compound, and the didymium oxide compound accounts for 65~90%.
5, method according to claim 4 is characterized in that: the Calcium Fluoride (Fluorspan) that also can add 0~15wt% in the described electrolysis of fluorides matter.
6, according to the described method of claim 1~5, it is characterized in that: described heavy rare earth metal is a kind of among Dy, Ho, Tb, the Er.
7, according to claim 1,2,3,6 described methods, it is characterized in that: when described heavy rare earth alloy was neodymium-dysprosium alloy, cathode current density was 11~20A/cm
2, electrolysed substance is that Neodymium trioxide accounts for 82~89%, dysprosium oxide accounts for 11~19%.
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CN 92101707 CN1025228C (en) | 1992-03-18 | 1992-03-18 | Process for preparation of Nd and Nd-Pr base heavy rare-earth alloy |
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CN 92101707 CN1025228C (en) | 1992-03-18 | 1992-03-18 | Process for preparation of Nd and Nd-Pr base heavy rare-earth alloy |
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CN1064510A true CN1064510A (en) | 1992-09-16 |
CN1025228C CN1025228C (en) | 1994-06-29 |
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CN1078268C (en) * | 1999-10-12 | 2002-01-23 | 冶金工业部钢铁研究总院 | Process for preparing mixed rare-earth metals |
WO2008095448A1 (en) * | 2007-02-07 | 2008-08-14 | Grirem Advanced Materials Co., Ltd. | A rare earth alloy, the preparing method and use thereof |
CN101240394B (en) * | 2007-02-07 | 2010-06-30 | 有研稀土新材料股份有限公司 | Rare earth alloy, preparation technique and application thereof |
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1992
- 1992-03-18 CN CN 92101707 patent/CN1025228C/en not_active Expired - Fee Related
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