RU2257421C1 - Refractory metal alloy production process - Google Patents

Abstract

FIELD: metallurgy, namely production of refractory metal alloys by out-of-furnace aluminothermic reduction.

SUBSTANCE: process comprises steps of preparing charge of compound of refractory metal, aluminum and oxides of alkali-earth metals; placing charge in metallic crucible on surface of ignition mixture of alkali-earth metal peroxide and aluminum; reducing it and melting; adding to charge in addition waste material of previous melting and chlorate while providing relation of aluminum powder to peroxide of alkali-earth metal in ignition mixture 4 : 1.

EFFECT: enhanced degree of metal transition to alloy, lowered impurity content such as carbon, reduced explosion hazard of process.

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Description

The invention relates to metallurgy, and in particular to methods for producing alloys of refractory metals.

A known method (1) for producing a niobium-containing material by aluminothermic reduction in the presence of a metal from the group of iron, chromium, nickel or their oxides when using niobium oxyfluoride as a starting material. Alkaline earth metal or lithium oxide is also added to the charge.

The disadvantage of this process is the low yield of niobium in the alloy 86.3-90.7%, which is not enough for an expensive metal. In addition, the cost of using lithium compounds is greatly increased. it in the form of fluoride is irretrievably lost with dump slag.

Known (2, pp. 389-391) is a method for producing niobium-tantalum-containing alloys by aluminothermic reduction of niobium-tantalum-containing materials (columbite, tantalite, pyrochlore or mixtures thereof) in the presence of potassium chlorate.

The disadvantage of this method is that, despite the addition of magnesium in some cases to the charge, the process is unstable, which is characterized by a spread in the degree of extraction of niobium and a constantly low yield of tantalum in the alloy (60-70%). Alloys are contaminated with undesirable impurities (tin, silicon) and, most importantly, carbon.

Known (2, pp. 458-460) is a method for producing tungsten-containing alloys by aluminothermic reduction of tungsten-containing materials in the presence of lime.

The disadvantage of this method is the low overall metal yield, because part of it disappears during the smelting process in the form of trioxide, and part (up to 10%) - due to insufficiently complete interaction of the ingot with slag - must be removed from the surface of the ingot due to its high contamination with impurities.

Known (2, pp. 316-319) is a method for producing molybdenum-containing alloys by aluminothermic reduction of molybdenum-containing materials in the presence of lime and fluorspar.

The disadvantage of this method is the low extraction of metal from the alloy, because part of the material flies in the form of oxides during the smelting process, and part (8-9%) is sorted out during the cleaning of the ingot, in which the carbon content still exceeds 0.1%. In addition, trying to restore molybdenum as much as possible, an ingot with an overestimated (more than 1%) aluminum content is obtained.

The prototype of our invention is a method (3) for obtaining ligatures of refractory metals by the secondary isothermal reduction of their oxides (MO ₃ , ZrO ₂ , Nb ₂ O ₅ ) in the presence of alkali metal peroxides (CaO ₂ , MgO ₂ ).

The disadvantage of this method is the loss of metals and a high content of impurities in them, in particular carbon, the source of which is alkaline earth metal peroxides (due to the technology of their production, they contain carbon dioxide groups).

The problem to which this invention is directed is to increase the degree of transition of metals to alloy, reduce the content of impurities, in particular carbon, in the final alloy and reduce the explosiveness of the process.

The problem is solved by a method for producing refractory metal alloys by out-of-furnace aluminothermic reduction, including mixing a raw material containing refractory metal oxides with alkaline earth metal oxides, aluminum powder and perchloric acid salt, placing a charge in a metal crucible, placing an ignition mixture on its surface and melting to obtain an alloy ingot, at the same time, waste from the previous melting is introduced into the charge, and an ignition mixture consisting of alkaline earth metal peroxides is placed on the charge surface and aluminum powder, taken in a ratio of 4: 1.

The transience of the occurring redox reactions (melting time 1.0-1.5 min), provided by the ratio of the components involved in them, makes the process explosive. Participation as a component of the waste from the previous smelting, without changing the necessary ratios and increasing the degree of metal extraction into the alloy, at the same time will cause a part of the heat generated from exothermic reactions to be spent on its melting, which prevents overheating of the charge. The use of peroxides only in the ignition part will prevent: firstly, overheating of the charge, because reactions with their participation are the most exothermic, and secondly, it will reduce the degree of transition of impurities (most importantly, carbon) into the alloy. After the mixture is quenched with an ignition mixture containing alkaline earth metal peroxides in a ratio of 4: 1 with aluminum (but in amounts in which the carbon contained in them is removed into the gas phase at the initial moment and does not enter the alloy), the reaction proceeds from the surface to the bottom of the crucible. This prevents the threat of gas concentration inside the charge mass with further explosion or discharge of the charge. The energy is sufficient to form an ingot with a maximum yield of reduced metal of a sufficient degree of purity.

Examples of implementation.

Raw materials containing refractory metal oxides were thoroughly mixed with alkaline earth metal oxides, powdered aluminum, potassium chlorate and waste from the previous smelting. If necessary, liquefied slag was introduced into the process fluorspar. The mixture was placed in a metal crucible. An ignition mixture of carefully mixed alkaline earth metal peroxides and aluminum powder, taken in a ratio of 4: 1, was placed on its surface. The mixture through this mixture was ignited using a hot nichrome spiral. At the end of the active phase and cooling, the alloy was separated from the slag.

Example 1. The oxides of molybdenum (MoO ₂ ), zirconium (ZrO ₂ ) and silicon (SiO ₂ ) were mixed with aluminum powder, potassium chlorate (KClO ₃ ) and calcium oxide (CaO) in the presence of calcium fluoride (CaF ₂ ) and waste from the previous swimming trunks taken at a ratio of:

Molybdenum oxide (MoO ₂ ) 0.253

Zirconia (ZrO ₂ ) 0.166

Silica (SiO ₂ ) 0.036

Aluminum Powder 0.33

Calcium Oxide (CaO) 0.020

Calcium Fluoride (CaF ₂ ) 0.004

Waste from the previous heat 0.125

Potassium Chlorate (KClO ₃ ) 0.065

The ignition part of the charge consisted of calcium peroxide (CaO ₂ ) and Al powder of grade PA-4, taken in a ratio of 4: 1. As a result of melting, an alloy of the ACMK brand was obtained, containing, wt.%: Mo - 39.0; Zr - 19.5; Si - 4.0; Al - 37.5, C- <0.01. The degree of transition of molybdenum to the alloy was 96.5%.

Example 2. The oxides of molybdenum (MoO ₂ ), tungsten (WO ₃ ) and titanium sponge were mixed with aluminum powder, potassium chlorate (KClO ₃ ) and calcium oxide (CaO) in the presence of calcium fluoride (CaF ₂ ) and waste from the previous heat taken with the ratio:

Molybdenum oxide (MoO ₂ ) 0.26

Tungsten Oxide (WO ₃ ) 0.09

Titanium Sponge 0.04

0.35 aluminum powder

Calcium Oxide (CaO) 0.056

Calcium Fluoride (CaF ₂ ) 0.007

Waste from previous heat 0.15

Potassium Chlorate (KClO ₃ ) 0.058

The ignition part of the charge consisted of magnesium peroxide (MgO ₂ ) and Al powder of grade PA-4, taken in a ratio of 4: 1. As a result of melting, an MPTA grade alloy was obtained, containing, wt.%: Mo - 36.0; W - 17.5; Ti - 8.0; Al is the rest, C is <0.01. The degrees of transition of molybdenum and tungsten to the alloy were 96.2 and 95.7%, respectively.

Example 3. The oxides of molybdenum (MoO ₂ ), zirconium (ZrO ₂ ) were mixed with aluminum powder, potassium chlorate (KClO ₃ ) and calcium oxide (CaO) in the presence of calcium fluoride (CaF ₂ ) and waste from the previous smelting, taken at a ratio of:

Molybdenum oxide (MoO ₂ ) 0.279

Zirconia (ZrO ₂ ) 0.208

Aluminum powder 0.299

Calcium Oxide (CaO) 0.03

Calcium Fluoride (CaF ₂ ) 0.004

Waste from the previous heat 0.125

Potassium Chlorate (KClO ₃ ) 0.05

The ignition part of the charge consisted of barium peroxide (BaO ₂ ) and PA-4 grade Al powder, taken in a ratio of 3.7: 1. As a result of melting, an alloy of the ACMK brand was obtained, containing, wt.%: Mo - 43.0; Zr - 24.5; Al - 32.5, C - <0.01. The degree of transition of molybdenum to the alloy was 96.5%.

Example 4. The oxides of molybdenum (MoO ₂ ), chromium (Cr ₂ O ₃ ) and silicon (SiO ₂ ) were mixed with aluminum powder, potassium chlorate (KClO ₃ ), iron and calcium oxide (CaO) in the presence of calcium fluoride (CaF ₂ ) and waste from the previous heat taken at a ratio of:

Molybdenum oxide (MoO ₂ ) 0.224

Chromium oxide (Cr ₂ O ₃ ) 0.146

Silica (SiO ₂ ) 0.034

Iron oxide (Fe ₂ O ₃ ) 0.027

Aluminum powder 0.335

Calcium Oxide (CaO) 0.027

Calcium Fluoride (CaF ₂ ) 0.015

Waste from the previous heat 0.170

Potassium Chlorate (KClO ₃ ) 0.021

The ignition part of the charge consisted of calcium peroxide (CaO ₂ ) and Al powder of grade PA-4, taken in a ratio of 4: 1. As a result of melting, an alloy of the AHMK brand was obtained, containing, wt.%: Mo - 33.5; Cr 24.3; Si - 4.2; Al - 33.5; Fe - 5.2; C is <0.01. The degrees of transition of molybdenum and chromium to the alloy were 95.5 and 95.0%, respectively.

Example 5. The oxides of niobium (Nb ₂ O ₅ ) and silicon (SiO ₂ ) and the waste from the previous smelting were mixed with aluminum powder, potassium chlorate (KClO ₃ ) and calcium oxide (CaO) in the presence of calcium fluoride (CaF ₂ ) taken in ratio:

Niobium oxide (Nb ₂ O ₅ ) 0.410

Silica (SiO ₂ ) 0.001

Waste from previous heat 0.144

Aluminum powder 0.364

Calcium Oxide (CaO) 0.042

Calcium Fluoride (CaF ₂ ) 0.005

Potassium Chlorate (KClO ₃ ) 0.032

The ignition part of the charge consisted of calcium peroxide (CaO ₂ ) and Al powder of grade PA-4, taken in a ratio of 4: 1. As a result of melting, an alloy was obtained containing, wt.%: Nb - 69.6; Si - 0.08; Al - 29.4, C - <0.01. The degree of transition of niobium to the alloy was 95.8%.

Thus, embodiments of the invention demonstrate the positive effect of the process in the presence of salts of perchloric acid: the degree of conversion of niobium, tungsten, molybdenum, chromium to alloy was 95.0-96.8%, and tantalum increased from 60-70 to 90.5 %, carbon content in the alloy did not exceed 0.01%. The process is technological, fleeting, cost-effective.

List of references

1. US patent No. 10410378, C 22 B 34/24, “Method for producing niobium alloys,” applicant Robert A. Gustison, Kaweki Berilko Industries, publ. 27.04.79, application No. 272764201, s. 04/28/78, bull. No 33 on 09/07/83.

2. R. Durrer, G. Volkert, "Metallurgy of Ferroalloys", M., Metallurgy, 1976

3. Copyright certificate No. 498345 "Method for the production of refractory metal alloys by out-furnace aluminothermic reduction", class C 22 D 7/06, authors, N. Dubrovsky et al., Pz Pyshminsky experimental plant "Giredmet", claimed 12.01.73. Application No. 1871175 / 22-1, publ. 21.03.75.

Claims (1)

A method of producing refractory metal alloys by out-of-furnace aluminothermic reduction, comprising mixing a raw material containing refractory metal oxides with alkaline earth metal oxides, aluminum powder and chloric acid salt, placing a charge in a metal crucible, placing an ignition mixture on its surface and melting to obtain an alloy ingot, characterized the fact that waste from the previous melting is introduced into the charge, and an ignition mixture consisting of alkaline earth metal peroxides and Rosca aluminum in the ratio 4: 1.