阅读说明：本技术 一种Mg-Zn-Zr中间合金及其制备方法 (Mg-Zn-Zr intermediate alloy and preparation method thereof ) 是由 张财淦 许瑞高 朱福生 廖志金 杨清 于 2019-11-22 设计创作，主要内容包括：本发明公开的Mg-Zn-Zr中间合金及其制备方法,其中Mg-Zn-Zr中间合金,包括如下组成,wt％,Mg 20％～50％；Zr 3％～5％；Zn为余量及不可避免的杂质。本发明方案公开的中间合金及其制备方法,电流效率高,生产成本低,生产的产品没有夹渣,氧含量低,成分均匀、偏析少,长期连续生产中具有较高的质量稳定性。(The invention discloses a Mg-Zn-Zr intermediate alloy and a preparation method thereof, wherein the Mg-Zn-Zr intermediate alloy comprises the following components, by weight, 20-50% of Mg; 3 to 5 percent of Zr; the balance of Zn and inevitable impurities. The intermediate alloy and the preparation method thereof disclosed by the scheme of the invention have the advantages of high current efficiency, low production cost, no slag inclusion of the produced product, low oxygen content, uniform components, less segregation and higher quality stability in long-term continuous production.)

1. An Mg-Zn-Zr intermediate alloy comprises the following components in percentage by weight,

Mg 20％～50％；

Zr 3％～5％；

the balance of Zn and inevitable impurities.

2. The Mg-Zn-Zr master alloy according to claim 1, wherein said master alloy comprises the composition, in wt%, Mg 35%, Zr4.5%, Zn for the rest, and unavoidable impurities.

3. A preparation method of Mg-Zn-Zr intermediate alloy comprises the following steps:

a tungsten cathode and a graphite anode are arranged in the graphite electrolytic cell;

mixing fluoride in a graphite electrolytic cell to form a molten salt mixture system to form an electrolytic system;

the raw material oxides including magnesium oxide, zinc oxide and zirconium oxide are used as raw materials to carry out electrolysis, and magnesium ions, zinc ions and zirconium ions are reduced and alloyed at a tungsten cathode.

4. The method of producing a Mg-Zn-Zr master alloy according to claim 3, characterized in that said mixed fluorides are a mixture of lithium fluoride, potassium fluorozirconate, zinc fluoride and magnesium fluoride.

5. The method of producing a Mg-Zn-Zr intermediate alloy, according to claim 4, characterized in that said mixed fluorides comprise, in wt%,

6. the method of producing a Mg-Zn-Zr master alloy according to claim 3, characterized in that said raw material oxides comprise, in wt%,

19.5 to 53.7 percent of magnesium oxide;

27.8-69.9% of zinc oxide;

10.4-19.2% of zirconium oxide.

7. The method of claim 3, wherein the molten salt mixture system forms an electrolysis system having an electrolysis temperature of 800 ℃ to 920 ℃.

8. The method for producing Mg-Zn-Zr intermediate alloy according to claim 3, wherein said electrolysis has a cathodic current density of 4.8 to 6A/cm²。

9. The method for producing a Mg-Zn-Zr intermediate alloy according to claim 3, wherein an anodic current density at the time of electrolysis is 0.8 to 1.2A/cm²。

Technical Field

The invention relates to an alloy metal additive material, in particular to a Mg-Zn-Zr intermediate alloy and a preparation method thereof.

Background

There are two methods for producing master alloys, one is metal-melting and matching and the other is electrolysis. The melting and matching method has the defects that the product has a lot of slag inclusion, uneven components, gas protection is needed, pure metal is adopted as a raw material, and the production cost is high; on the contrary, the molten salt electrolysis is carried out under the protection of molten salt liquid, so the oxidation slag inclusion is less, the components are uniform and controllable, the production efficiency is high, and the production cost is lower. In the existing molten salt method production, the problems of uneven distribution of all constituent elements and unstable material quality easily occur in the preparation of alloy materials, and the application of the intermediate alloy material in the subsequent production and processing of metal alloys is influenced.

Disclosure of Invention

In order to solve the problems, the intermediate alloy and the preparation method thereof disclosed by the invention have the advantages of high current efficiency, low production cost, no slag inclusion in the produced product, low oxygen content, uniform components, less segregation and higher quality stability in long-term continuous production.

The invention discloses a Mg-Zn-Zr intermediate alloy, which comprises the following components in percentage by weight,

Mg 20％～50％；

Zr 3％～5％；

the balance of Zn and inevitable impurities.

The invention discloses an improvement of an Mg-Zn-Zr intermediate alloy, which comprises the following components in percentage by weight, Mg 35%, Zr4.5%, Zn and inevitable impurities for the rest.

The invention discloses a preparation method of Mg-Zn-Zr intermediate alloy, which comprises the following steps:

a tungsten cathode and a graphite anode are arranged in the graphite electrolytic cell;

mixing fluoride in a graphite electrolytic cell to form a molten salt mixture system to form an electrolytic system;

the raw material oxides including magnesium oxide, zinc oxide and zirconium oxide are used as raw materials to carry out electrolysis, and magnesium ions, zinc ions and zirconium ions are reduced and alloyed at a tungsten cathode.

The invention discloses an improvement of a preparation method of Mg-Zn-Zr intermediate alloy, wherein mixed fluoride is a mixture of lithium fluoride, potassium fluorozirconate, zinc fluoride and magnesium fluoride.

The invention discloses an improvement of a preparation method of Mg-Zn-Zr intermediate alloy, mixed fluoride comprises, by weight percent,

the invention discloses an improvement of a preparation method of Mg-Zn-Zr intermediate alloy, which comprises raw material oxides of wt percent,

19.5 to 53.7 percent of magnesium oxide;

27.8-69.9% of zinc oxide;

10.4-19.2% of zirconium oxide.

The invention discloses an improvement of a preparation method of Mg-Zn-Zr intermediate alloy, wherein in an electrolytic system formed by a molten salt mixture system, the electrolytic temperature is 800-920 ℃.

The invention discloses an improvement of a preparation method of Mg-Zn-Zr intermediate alloy, and during electrolysis, the cathode current density is 4.8-6A/cm²。

The invention discloses an improvement of a preparation method of Mg-Zn-Zr intermediate alloy, and during electrolysis, the current density of an anode is 0.8-1.2A/cm²。

Specifically, the method can be adopted for preparing the alloy electrolyte by taking a tungsten rod as a cathode, an arc graphite sheet as an anode and a molybdenum crucible as a receiving container of alloy educt and taking LiF-MgF as₂-ZnF₂-K₂(ZrF₆) The mixed fluoride is molten salt, and MgO, ZnO and ZrO are used₂Is prepared by electrolyzing raw materials.

From the theory of electrolysis, it is known that the most basic condition is that the ionic precipitation potentials of the alloy components are equal if several components of the alloy are to be electrolytically co-precipitated at the cathode, and that if two ions are to be simultaneously precipitated at the cathode:

M₁ ⁿ¹++n₁e＝M₁

M₂ ⁿ²⁺+n₂e＝M₂

must satisfy E_M1 ⁿ¹⁺/M₁＝E_M2 ⁿ²⁺/M₂In practice, the deposition of the alloy is an unbalanced process, the precipitation potential being equal to the algebraic sum of the equilibrium potential, the polarization potential and the depolarization potential, taking into account the polarization and depolarization effects, and having the following relationship:

when in use

And

if the difference is large, two kinds of metal M₁And M₂No interaction occurs on the cathode, and the ion activity a needs to be changed for co-separating out the two metals_M1 ⁿ¹⁺And a_M2 ⁿ²⁺Namely, the activity of the potential-positive ions is reduced, so that the precipitation potential moves towards the negative direction; the addition of appropriate additives (such as potassium fluorozirconate, etc.) makes the metal ions with higher potential form more stable complexes, and reduces the activity of the metal, so that the precipitation potential can be changed to negative.

Mg²⁺+2e＝Mg

Zr⁴⁺+2e＝Zr²⁺

Zr²⁺+2e＝Zr

Zn²⁺+2e＝Zn

The separated Mg-Zn-Zr alloy liquid sinks into the molybdenum crucible along the tungsten rod, then the molybdenum crucible is taken out, and the alloy liquid in the molybdenum crucible is poured into a mould to form an alloy ingot

The principle is as follows: in a molten salt system with the temperature of 800-920 ℃ and the direct current voltage of 12-15V, MgO, ZnO and ZrO2 are dissolved in molten salt and ionized, ionized Mg2+, Zn2+ and Zr4+ are adsorbed on a tungsten cathode bar and are subjected to electron precipitation, so that Mg-Zn-Zr intermediate alloy liquid is alloyed on the cathode bar, the intermediate alloy liquid is higher than the molten salt, the formed Mg-Zn-Zr intermediate alloy liquid flows downwards along the tungsten cathode bar into a molybdenum crucible right below the tungsten cathode bar, the molten salt in the original molybdenum crucible is extruded to occupy space, after a certain amount of intermediate alloy liquid is gathered, the molybdenum crucible is taken out, and the alloy liquid in the molybdenum crucible is poured into a die to form an alloy ingot.

The process has the advantages that: the current efficiency is high, and the production cost is low; the whole reaction process is carried out in the molten salt solution, air is isolated, and the molten salt plays a role in protection, so that the produced product has low oxygen content, less slag inclusion, uniform product yield and less segregation.

Drawings

FIG. 1 is a gold phase diagram of a Mg-Zn binary alloy;

FIG. 2 is a gold phase diagram of a Zn-Zr binary alloy;

FIG. 3 is a gold phase diagram of a product without the use of the master alloy of the present invention in the preparation of a certain type of magnesium alloy;

FIG. 4 is a gold phase diagram of a product when the master alloy of the present invention is used in the preparation of the magnesium alloy of the type shown in FIG. 3;

FIG. 5, tensile curve for high temperature (150 ℃ C.).

Curve 1 in FIG. 5 shows the high temperature tensile curve of the magnesium alloy without the product, and the tensile strength is 166 MPa;

in FIG. 5, curve 2 shows the high temperature tensile curve after the product with 0.5% of Mg 35% -Zr4.5% -Zn 59% is added, and the tensile strength is 169 MPa;

curve 3 in FIG. 5 shows the high temperature tensile curve after the product with 1.5% of Mg 35% -Zr4.5% -Zn 59% is added, and the tensile strength is 180MPa

Curve 4 in FIG. 5 represents the high temperature tensile curve after addition of the product with 4% of Mg 35% -Zr4.5% -Zn 59% and the tensile strength of 197MPa

Curve 5 in FIG. 5 represents the high temperature tensile curve after the addition of the product with 5% of Mg 35% -Zr4.5% -Zn 59% and the tensile strength of 187MPa

Detailed Description

The present invention is further illustrated by the following specific embodiments, which are to be construed as merely illustrative, and not limitative of the remainder of the disclosure in any way whatsoever.

Materials example 1

In this example, the Mg-Zn-Zr master alloy obtained by electrolysis included the following components in wt%,

Mg 44％；

Zr 4％；

the balance of Zn and inevitable impurities

Material example 2

In this example, the Mg-Zn-Zr master alloy obtained by electrolysis included the following components in wt%,

Mg 28％；

Zr 3.5％；

the balance of Zn and inevitable impurities

Material example 3

In this example, the Mg-Zn-Zr master alloy obtained by electrolysis included the following components in wt%,

Mg 20％；

Zr 5％；

the balance of Zn and inevitable impurities

Material example 4

In this example, the Mg-Zn-Zr master alloy obtained by electrolysis included the following components in wt%,

Mg 50％；

Zr 3％；

the balance of Zn and inevitable impurities

Material example 5

In this example, the Mg-Zn-Zr master alloy obtained by electrolysis included the following components in wt%,

Mg 35％；

Zr 4.5％；

the balance of Zn and inevitable impurities.

The feasible scheme of the composition of the material needs to design the feeding of the electrolysis scheme, and the material can be obtained.

The following are specific embodiments for illustrating the feasibility and superiority of the inventive arrangements.

Preparation of example 1

A 6000A, 15V high-frequency switching power supply is used as an output power supply, a phi 400 x h460mm circular graphite electrolytic cell is adopted, the electrolytic cell is placed in a phi 1200 x h800mm circular iron shell, the center of the electrolytic cell is aligned with the center of the shell, and heat-insulating bricks and heat-insulating cotton are filled between the electrolytic cell and the iron shell; 4 arc graphite sheets with phi 350mm multiplied by h430mm are used as anodes; a tungsten rod with phi of 50mm multiplied by 600mm is used as a cathode; a molybdenum crucible with the diameter of 50mm is used as a receiving container of the alloy liquid.

LiF 9% and K are mixed according to the following proportion₂(ZrO₂)10％、ZnF₂65％、MgF₂Adding 16% of fluoride fused salt which is uniformly mixed into an electrolytic cell, and heating and melting the fused salt by using an alternating current arc starting machine. Putting a molybdenum crucible at the bottom of electrolysis, inserting a tungsten cathode bar into the molten salt electrolyte to a depth of about 320mm, uniformly adding mixed oxides (the mixture comprises 47.2% of MgO, 12.5% of ZrO and 40.4% of ZnOinto an electrolytic cell, and then electrifying direct current for electrolysis, keeping the temperature of the electrolyte at 800-920 ℃ and the direct current voltage at 12.3V, and keeping the cathode current density at 5.6-6A/cm²The current density of the anode is 0.8-1.0A/cm²After electrolysis for about 1 hour, lifting the cathode bar from the electrolytic bath, clamping the molybdenum crucible by an iron clamp, pouring molten metal in the molybdenum crucible into a mould, cooling, knocking off the molten salt coated on the surface to obtain 2.85kg of Mg-Zn-Zr alloy ingot, and analyzing and detecting the components of the Mg-Zn-Zr alloy ingot to be as follows: mg 44%, Zr 4%, O0.03%, Zn in balance, and other inevitable impurities

Preparation of example 2

A 6000A, 15V high-frequency switching power supply is used as an output power supply, a phi 400 x h460mm circular graphite electrolytic cell is adopted, the electrolytic cell is placed in a phi 1200 x h800mm circular iron shell, the center of the electrolytic cell is aligned with the center of the shell, and heat-insulating bricks and heat-insulating cotton are filled between the electrolytic cell and the iron shell; 4 arc graphite sheets with phi 350mm multiplied by h430mm are used as anodes; a tungsten rod with phi of 50mm multiplied by 600mm is used as a cathode; a molybdenum crucible with the diameter of 50mm is used as a receiving container of the alloy liquid.

The following proportions are adopted: 9% of LiF and K₂(ZrO₂)10％、ZnF₂65％、MgF₂Adding 16% of fluoride fused salt which is uniformly mixed into an electrolytic cell, and heating and melting the fused salt by using an alternating current arc starting machine. Putting a molybdenum crucible at the bottom of electrolysis, inserting a tungsten cathode bar into the molten salt electrolyte to a depth of about 320mm, uniformly adding mixed oxides (the mixture comprises 31.6% of MgO, 11.4% of ZrO and 57% of ZnO) into an electrolytic cell, and then electrifying direct current to electrolyze, keeping the direct current voltage at 12.2V, the temperature of the electrolyte at 900-920 ℃, and the cathode current density at 4.8-5.2A/cm²The current density of the anode is 0.9-1.10A/cm²After electrolysis for about 1 hour, lifting the cathode bar from the electrolytic bath, clamping the molybdenum crucible by an iron clamp, pouring molten metal in the molybdenum crucible into a mould, cooling, knocking off the molten salt coated on the surface to obtain 2.90kg of Mg-Zn-Zr alloy ingot, and analyzing and detecting the components of the Mg-Zn-Zr alloy ingot to be as follows: 28% of Mg, 3.5% of Zr, 0.03% of O, the balance of Zn and other inevitable impurities.

Preparation of example 3

A 6000A, 15V high-frequency switching power supply is used as an output power supply, a phi 400 x h460mm circular graphite electrolytic cell is adopted, the electrolytic cell is placed in a phi 1200 x h800mm circular iron shell, the center of the electrolytic cell is aligned with the center of the shell, and heat-insulating bricks and heat-insulating cotton are filled between the electrolytic cell and the iron shell; 4 arc graphite sheets with phi 350mm multiplied by h430mm are used as anodes; a tungsten rod with phi of 50mm multiplied by 600mm is used as a cathode; a molybdenum crucible with the diameter of 50mm is used as a receiving container of the alloy liquid.

The following proportions are adopted: 9% of LiF and K₂(ZrO₂)10％、ZnF₂65％、MgF₂The balance being mixedAdding the uniform fluoride fused salt into an electrolytic cell, and heating and melting the fused salt by using an alternating current arc starter. Putting a molybdenum crucible at the bottom of electrolysis, inserting a tungsten cathode bar into the molten salt electrolyte to a depth of about 320mm, uniformly adding mixed oxides (the mixture comprises 22.5% of MgO, 16.2% of ZrO and 61.2% of ZnO61%) into an electrolytic cell, and then electrifying direct current to electrolyze, keeping the direct current voltage at 12.0V, the temperature of the electrolyte at 840-860 ℃, and the cathode current density at 5.0-5.4A/cm²The current density of the anode is 0.8-0.9A/cm²After 3 hours of electrolysis, lifting the cathode bar from the electrolytic bath, clamping the molybdenum crucible by an iron clamp, pouring molten metal in the molybdenum crucible into a mould, cooling, knocking off the molten salt coated on the surface to obtain 3kg of Mg-Zn-Zr alloy ingot, and analyzing and detecting the components of the Mg-Zn-Zr alloy ingot to be as follows: 20% of Mg, 5% of Zr, 0.03% of O, the balance of Zn and other inevitable impurities

Preparation of example 4

A 6000A, 15V high-frequency switching power supply is used as an output power supply, a phi 400 x h460mm circular graphite electrolytic cell is adopted, the electrolytic cell is placed in a phi 1200 x h800mm circular iron shell, the center of the electrolytic cell is aligned with the center of the shell, and heat-insulating bricks and heat-insulating cotton are filled between the electrolytic cell and the iron shell; 4 arc graphite sheets with phi 350mm multiplied by h430mm are used as anodes; a tungsten rod with phi of 50mm multiplied by 600mm is used as a cathode; a molybdenum crucible with the diameter of 50mm is used as a receiving container of the alloy liquid.

The following proportions are adopted: LiF 10% and K₂(ZrO₂)8％、ZnF₂75％、MgF₂And adding the balance of the uniformly mixed fluoride fused salt into an electrolytic cell, and heating and melting the fused salt by using an alternating current arc starter. Putting a molybdenum crucible at the bottom of electrolysis, inserting a tungsten cathode bar into the molten salt electrolyte to a depth of about 320mm, uniformly adding mixed oxides (the mixture comprises 40.7% of MgO, 19.2% of ZrO and the balance of ZnO) into an electrolytic cell, and then electrifying direct current to electrolyze, keeping the direct current voltage at 12.5V, maintaining the temperature of the electrolyte at 860-880 ℃ and the cathode current density at 5.3-5.6A/cm²The current density of the anode is 0.9-1.0A/cm²After about 1 hour of electrolysis, the cathode bar is lifted from the electrolytic bath, the molybdenum crucible is clamped by an iron clamp, and the molten metal in the molybdenum crucible is poured into the electrolytic bathIn the die, after cooling, knocking off the molten salt coated on the surface to obtain 2.7kg of Mg-Zn-Zr alloy ingot, and analyzing and detecting the components of the Mg-Zn-Zr alloy ingot to be as follows: mg 50%, Zr 5%, O0.03%, Zn in balance, and other inevitable impurities

Preparation of example 5

A 6000A, 15V high-frequency switching power supply is used as an output power supply, a phi 400 x h460mm circular graphite electrolytic cell is adopted, the electrolytic cell is placed in a phi 1200 x h800mm circular iron shell, the center of the electrolytic cell is aligned with the center of the shell, and heat-insulating bricks and heat-insulating cotton are filled between the electrolytic cell and the iron shell; 4 arc graphite sheets with phi 350mm multiplied by h430mm are used as anodes; a tungsten rod with phi of 50mm multiplied by 600mm is used as a cathode; a molybdenum crucible with the diameter of 50mm is used as a receiving container of the alloy liquid.

The following proportions are adopted: LiF 8% and K₂(ZrO₂)5％、ZnF₂60％、MgF₂And adding the balance of the uniformly mixed fluoride fused salt into an electrolytic cell, and heating and melting the fused salt by using an alternating current arc starter. Putting a molybdenum crucible at the bottom of electrolysis, inserting a tungsten cathode bar into the molten salt electrolyte to a depth of about 320mm, uniformly adding mixed oxides (the mixture comprises 53.7% of MgO, 16.1% of ZrO and the balance of ZnO) into an electrolytic cell, and then electrifying direct current to electrolyze, keeping the direct current voltage at 12.4V, maintaining the temperature of the electrolyte at 820-840 ℃ and the cathode current density at 5.2-5.5A/cm²The current density of the anode is 1.0-1.20A/cm²After electrolysis for about 1 hour, lifting the cathode bar from the electrolytic bath, clamping the molybdenum crucible by an iron clamp, pouring molten metal in the molybdenum crucible into a mould, cooling, knocking off the molten salt coated on the surface to obtain 2.95kg of Mg-Zn-Zr alloy ingot, and analyzing and detecting the components of the Mg-Zn-Zr alloy ingot to be as follows: 35% of Mg, 4.5% of Zr, 0.03% of O, the balance of Zn and other inevitable impurities.

Preparation of example 6

A 6000A, 15V high-frequency switching power supply is used as an output power supply, a phi 400 x h460mm circular graphite electrolytic cell is adopted, the electrolytic cell is placed in a phi 1200 x h800mm circular iron shell, the center of the electrolytic cell is aligned with the center of the shell, and heat-insulating bricks and heat-insulating cotton are filled between the electrolytic cell and the iron shell; 4 arc graphite sheets with phi 350mm multiplied by h430mm are used as anodes; a tungsten rod with phi of 50mm multiplied by 600mm is used as a cathode; a molybdenum crucible with the diameter of 50mm is used as a receiving container of the alloy liquid.

The following proportions are adopted: LiF 5% and K₂(ZrO₂)7％、ZnF₂80％、MgF₂And adding the balance of the uniformly mixed fluoride fused salt into an electrolytic cell, and heating and melting the fused salt by using an alternating current arc starter. Putting a molybdenum crucible at the bottom of electrolysis, inserting a tungsten cathode bar into the molten salt electrolyte to a depth of about 320mm, uniformly adding mixed oxides (the mixture comprises 19.5% of MgO, 10.4% of ZrO and the balance of ZnO) into an electrolytic cell, and then electrifying direct current to electrolyze, keeping the direct current voltage at 12.3-12.5V, maintaining the temperature of the electrolyte at 880-900 ℃ and the cathode current density at 5.5-5.8A/cm²The current density of the anode is 1.0-1.10A/cm²After about 1 hour of electrolysis, lifting the cathode bar from the electrolytic bath, clamping the molybdenum crucible by an iron clamp, pouring molten metal in the molybdenum crucible into a mold, cooling, knocking off the molten salt coated on the surface to obtain 2.8-3kg of Mg-Zn-Zr alloy ingot, and analyzing and detecting the components of the Mg-Zn-Zr alloy ingot to be as follows: 35% of Mg, 4.5% of Zr, 0.03% of O, the balance of Zn and other inevitable impurities.

The prepared alloy is added into magnesium alloy, zinc and zirconium are distributed at a crystal boundary, because the crystal structure of the zirconium and the magnesium are in a close-packed hexagonal crystal form, the lattice constant is close, and the Mg is 0.320nm for a and 0.520nm for c; the crystal core of a (Mg) is formed by Zr, a is 0.323nm, c is 0.514nm, and Zr meets the principle of heterogeneous nucleation 'size structure matching' of a magnesium matrix, so that the Zr becomes the crystal core of a (Mg), and the Mg-Zr system is a peritectic reaction, inhibits the grain growth, and obviously plays the roles of refining the grains and increasing the alloy strength. The grain size of the magnesium alloy is thinned to 10-50 μm (as shown in FIG. 3 and FIG. 4) from 100-200 μm; under the casting and natural aging state, the high-temperature strength is improved from 166MPa to 197 MPa. As shown in the phase diagrams of Zn-Zr alloys in FIGS. 1 and 2, Zn and Zr can form a Zn-Zr alloy having a zirconium content of about 10% at 850 ℃. The electrolytic ions are alloyed and separated to generate depolarization, so that the potential difference of the ions is reduced, and the elements are favorably separated out.

As can be seen from the comparison in FIG. 5, after the master alloy is added, the high-temperature tensile strength is obviously improved by about 18%. This shows that at least in the range of 1-4%, with the increase of the adding amount of the product of the scheme of the invention, the alloying effect with the magnesium alloy is good, so that the high-temperature strength of the magnesium alloy is gradually increased. Therefore, the scheme provided by the invention is used as an excellent intermediate alloy providing scheme, and is necessarily beneficial to improving the performance of alloy products.

The Mg-Zn-Zr intermediate alloying slag prepared by the method has the advantages of less slag inclusion, low oxygen content, low impurity content, uniform and stable chemical components and lower production cost, is suitable for being used as an additive for smelting high-performance magnesium alloys such as ZW62, VW64, VW75, VW84, WE43, WE54 and the like, and has wide market prospect.

The technical scope of the invention claimed by the embodiments of the present application is not exhaustive, and new technical solutions formed by equivalent replacement of single or multiple technical features in the technical solutions of the embodiments are also within the scope of the invention claimed by the present application; in all the embodiments of the present invention, which are listed or not listed, each parameter in the same embodiment only represents an example (i.e., a feasible embodiment) of the technical solution, and there is no strict matching and limiting relationship between the parameters, wherein the parameters may be replaced with each other without departing from the axiom and the requirements of the present invention, unless otherwise specified.

The technical means disclosed by the scheme of the invention are not limited to the technical means disclosed by the technical means, and the technical scheme also comprises the technical scheme formed by any combination of the technical characteristics. While the foregoing is directed to embodiments of the present invention, it will be appreciated by those skilled in the art that various changes may be made in the embodiments without departing from the principles of the invention, and that such changes and modifications are intended to be included within the scope of the invention.