CN215713259U

CN215713259U - System for preparing 4N-grade high-purity iron

Info

Publication number: CN215713259U
Application number: CN202023224545.0U
Authority: CN
Inventors: 白佳鑫; 董瀚; 韦习成; 余建波; 白鹏十翰; 李建民; 郝建锋; 于华财; 王俊鹏
Original assignee: SHANGHAI UNIVERSITY; Hebei Longfeng Shan Casting Industry Co ltd
Current assignee: SHANGHAI UNIVERSITY; Hebei Longfeng Shan Casting Industry Co ltd
Priority date: 2020-12-28
Filing date: 2020-12-28
Publication date: 2022-02-01
Anticipated expiration: 2030-12-28

Abstract

A system for preparing 4N-grade high-purity iron is characterized in that the purity of 4N is 99.99-99.999 wt%, a cold wall vacuum induction refining furnace and a hydrogen plasma drop melting refining furnace are respectively connected to the same vacuum system, 2N or 3N electrolytic pure iron raw materials can be heated and melted and then are generated into a vacuum refining iron rod in a directional drawing solidification mode, then the vacuum refining iron rod is gradually melted into a drop through hydrogen plasma arcs and then is generated into the 4N-grade high-purity iron rod in a directional drawing solidification mode, other refining agents do not need to be added into a melt, a ceramic crucible is omitted, no ceramic waste residue is generated in the production process, and the system has the characteristics of simple process, simplicity in operation, energy conservation, environmental protection, low cost and the like.

Description

System for preparing 4N-grade high-purity iron

Technical Field

The invention relates to a high-purity iron technology, in particular to a method and a system for preparing 4N-grade high-purity iron, wherein the 4N means that the purity is 99.99-99.999 wt%, a cold wall vacuum induction refining furnace and a hydrogen plasma drop melting refining furnace are respectively connected to the same vacuum system, 2N or 3N electrolytic pure iron raw materials can be heated and melted to generate a vacuum refining iron rod in a directional pull solidification mode, then the vacuum refining iron rod is gradually melted into molten drops through hydrogen plasma arcs to generate the 4N-grade high-purity iron rod in a directional pull solidification mode, other refining agents do not need to be added into a melt, a ceramic crucible is omitted, no waste residue is generated in the production process, and the method and the system have the characteristics of simple process, simple operation, energy conservation, environmental protection, low cost and the like.

Background

When the content of other impurity elements in the iron is extremely low, the iron is pure iron. The pure iron can be divided into 2N industrial pure iron (purity 99.5-99.9%), 3N pure iron (purity 99.9-99.99%), 4N high-purity iron (purity 99.99-99.999%) and 5N ultra-pure iron (purity 99.999-99.9999%) according to purity. Pure iron not only has certain strength, but also has higher toughness and good soft magnetic property, and the electrical conductivity of the pure iron is much better than that of common iron and steel. In addition, the high-purity iron also has a plurality of unique properties, such as higher melting point than common iron, lower recrystallization temperature, difficult rusting in humid air, insoluble sulfuric acid and hydrochloric acid but soluble in nitric acid, difficult cutting by common saw blades and the like. The development and application of pure iron has been rapidly progressing in recent years due to the characteristics of pure iron which are different from ordinary iron. At present, pure iron is widely applied to a plurality of fields such as electric power, machinery, traffic and the like, becomes a material basis of high and new technology industries such as modern society electronics, electricity, computers, communication and the like, and plays an increasingly important role in the fields such as meteorology, medical treatment, military and the like.

Commercially pure iron is a raw material for producing pure iron of higher purity. The production techniques of industrial pure iron can be mainly divided into pyrometallurgy and electrochemical metallurgy according to the difference of refining and purifying processes. The production by adopting a long flow of pyrometallurgy, such as traditional iron ore-sintering (or pellet ore) -blast furnace ironmaking-steelmaking, can meet the control requirement of industrial pure iron on the carbon content, but still needs to further improve the purity by secondary refining to achieve the target component. The large-scale production of industrial pure iron has not been realized due to various reasons such as the complicated refining process. Another commonly used method for producing industrial pure iron is the electrolytic refining method, which belongs to electrochemical metallurgy. The iron to be purified is used as an anode, a salt solution of the iron is used as electrolyte, another pure metal is used as a cathode for electrolysis, and the industrial pure iron with high purity, namely the electrolytic iron, can be obtained on the cathode, wherein the purity is generally not lower than 99.9%. At present, the two methods do not realize the scale production of 4N-grade high-purity iron.

The present inventors have found that the hydrogen plasma arc melting method can obtain a refining and purifying effect equivalent to that of high vacuum melting by purifying at normal pressure. However, it is difficult to reduce metal impurities having physical properties similar to those of the main metal and impurities having a low vapor pressure by the hydrogen plasma arc melting method, and the removal of these impurities requires a suitable chemical purification process. The inventor believes that if the cold wall vacuum induction refining furnace and the hydrogen plasma drop melting refining furnace are combined under the vacuum environment, granular electrolytic iron (namely 2N-3N pure iron or electrolytic industrial pure iron) can be subjected to two vacuum directional solidification purification processes, and the hydrogen reduction refining reaction area can be enlarged by utilizing drop melting under the vacuum environment, so that the production of 4N-grade high-purity iron is favorably realized. In view of the above, the present inventors have completed the present invention.

Disclosure of Invention

Aiming at the defects or shortcomings in the prior art, the invention provides a method and a system for preparing 4N-grade high-purity iron, wherein the 4N-grade high-purity iron has the purity of 99.99-99.999 wt%, a cold wall vacuum induction refining furnace and a hydrogen plasma drop melting refining furnace are respectively connected to the same vacuum system, 2N or 3N electrolytic pure iron raw materials can be heated and melted to generate a vacuum refining iron rod in a directional drawing solidification mode, then the vacuum refining iron rod is gradually melted into molten drops through hydrogen plasma arcs to generate the 4N-grade high-purity iron rod in a directional drawing solidification mode, other refining agents are not required to be added into a melt, a ceramic crucible is omitted, no waste slag is generated in the production process, and the method and the system have the characteristics of simple process, simple operation, energy conservation, environmental protection, low cost and the like.

The technical solution of the invention is as follows:

a system for preparing 4N-grade high-purity iron is characterized by comprising a cold wall vacuum induction refining furnace and a hydrogen plasma drop melting refining furnace which are respectively connected with the same vacuum system.

The cold wall vacuum induction refining furnace is used for heating and melting 2N or 3N electrolytic pure iron raw materials and then generating a vacuum refining iron rod in a directional drawing solidification mode, and the hydrogen plasma drop melting refining furnace is used for gradually melting the vacuum refining iron rod into molten drops through hydrogen plasma arcs and then generating a 4N-level high-purity iron rod in a directional drawing solidification mode.

The vacuum system comprises a mechanical vacuum pump, a Roots vacuum pump and a diffusion vacuum pump which are sequentially started, and the cold wall vacuum induction refining furnace and the hydrogen plasma drop melting refining furnace are respectively connected with the vacuum system through respective control valves.

Cold wall vacuum induction refining furnace is including being located the inside first cold crucible of first real empty room, first half of the outer peripheral face of first cold crucible is provided with induction coil in order to form the first liquid district of melting 2N or 3N electrolysis pure iron raw materials, first orientation solidification district under the first liquid district, first orientation pull system is connected to the bottom of first cold crucible, first real empty room top is provided with the feeder, the discharge gate of feeder passes through the feed deflector and connects the top pan feeding mouth of first cold crucible.

The 2N or 3N electrolytic pure iron raw material is a granular raw material.

The first cold crucible is a water-cooling copper crucible, and the feeder comprises an electromagnetic vibration feeding mechanism.

Hydrogen plasma drips melting refining furnace is including being located the inside cold crucible of second in the real empty room, the top pan feeding mouth top of the cold crucible of second is provided with iron bar rotary device, iron bar rotary device's below is provided with the plasma gun, iron bar rotary device is used for making and passes through the vacuum refining iron bar that cold wall vacuum induction refining furnace obtained is rotatory by the hydrogen plasma arc of plasma gun progressively melts into the molten droplet, the molten droplet drips into through an iron bar molten droplet district in the cold crucible of second forms the second liquid region, the directional solidification zone of second is connected to second liquid region down, the directional pull system of second is connected to the bottom of the cold crucible of second.

The plasma gas adopted by the hydrogen plasma drop melting refining furnace comprises a mixed gas of hydrogen and argon for deoxidation and/or denitrification, and/or oxygen or carbon dioxide for decarburization, and/or chlorine or fluorine for removing tungsten or molybdenum.

A method for preparing 4N-grade high-purity iron is characterized by comprising the steps of using the system for preparing 4N-grade high-purity iron, taking electrolytic iron as a raw material, obtaining a vacuum refining iron rod by adopting a vacuum melting technology of synchronous feeding, heating melting and directional drawing, then gradually melting the vacuum refining iron rod into molten drops through hydrogen plasma arc to enlarge a refining reaction area and accelerate refining speed, and generating the 4N-grade high-purity iron rod in a directional drawing solidification mode.

A method for preparing 4N-grade high-purity iron is characterized by comprising the steps of utilizing the system for preparing 4N-grade high-purity iron, taking electrolytic iron as a raw material, continuously and quantitatively feeding the electrolytic iron in a cold wall vacuum induction refining furnace through a feeder, heating and melting solid electrolytic iron in a first cold crucible, then pulling down and directionally solidifying the molten electrolytic iron to form a vacuum refining iron rod, and performing metal purification through high vacuum and directional solidification in the process; the method is characterized in that the vacuum refining iron rod is adopted as a raw material, the vacuum refining iron rod is rotated and gradually melted in a hydrogen plasma drop melting refining furnace to form molten drops, refining reaction is promoted, the purification effect is controlled by adjusting the rotating speed and the feeding speed, a 4N-grade high-purity iron rod is generated in a directional drawing solidification mode, and the metal is purified through hydrogen reduction and directional solidification in the process.

The invention has the following technical effects: according to the method and the system for preparing the 4N-grade high-purity iron, the cold wall vacuum induction refining furnace and the hydrogen plasma drop melting refining furnace are combined under the vacuum environment, so that granular electrolytic iron (namely 2N-3N pure iron or electrolytic industrial pure iron) can be subjected to two vacuum directional solidification purification processes, the hydrogen reduction refining reaction area can be enlarged by utilizing drop melting under the vacuum environment, and the production of the 4N-grade high-purity iron is facilitated.

The invention relates to a method for preparing 4N-grade high-purity iron, which takes granular electrolytic iron as a raw material and obtains a high-purity iron rod in one step by synchronous feeding, heating and melting and directional drawing in a vacuum cold wall induction furnace; and (3) carrying out rotary drop melting refining on the obtained high-purity iron rod in a hydrogen plasma furnace, and carrying out directional drawing to obtain the 4N-grade high-purity iron rod. The method adopts refining means such as vacuum refining, hydrogen reduction and the like, enlarges the refining reaction area by utilizing drop melting, and accelerates the refining speed. The invention does not need to add other refining agents into the melt, cancels the ceramic crucible, does not generate waste slag in the production process, and has the characteristics of simple process, simple operation, energy saving, environmental protection, low cost and the like.

The hydrogen plasma arc melting method uses hydrogen gas as a plasma generating gas to generate plasma arcs to melt metals, and rapidly removes oxygen, nitrogen, and metal impurities having a high vapor pressure. The method has the advantage of high heating temperature (the arc core temperature can reach 24000-26000K), can melt any metal and nonmetal, can carry out slag melting in the atmosphere and can also carry out slag-free melting in the protective atmosphere, and can generally obtain high-purity iron blocks with the purity of 4N. If a vacuum melting method is adopted to prepare high-purity metal materials such as high-purity iron and the like with low oxide vapor pressure, the rapid purification and deoxidation are difficult, and long melting time is generally required to establish new gas-liquid balance between oxygen and iron. The hydrogen plasma arc melting method mainly removes gaseous impurities such as oxygen, nitrogen and the like, is particularly suitable for rapidly deoxidizing iron, and has the deoxidation rate in direct proportion to the half power of the hydrogen content in plasma gas. The hydrogen plasma arc melting method can also conveniently remove metal impurities with higher vapor pressure than the melting metal, and the metal impurities with high vapor pressure splashed from the surface of the melting metal can be combined with active hydrogen in a plasma state and then enter a gas phase, thereby achieving the purification effect.

Drawings

FIG. 1 is a schematic structural diagram of a system for preparing high-purity iron grade 4N according to the present invention.

The reference numbers are listed below: 1-a feeder; 2-a first cold crucible; 3-an induction coil; 4-a first directional pull system; 5-a vacuum system; 6-plasma gun; 7-iron rod molten drop zone; 8-iron rod rotating device; 9-a mechanical vacuum pump; 10-roots vacuum pump; 11-diffusion vacuum pump; 12-cold wall vacuum induction refining furnace; 13-hydrogen plasma drop smelting refining furnace; 14-a feed guide plate; 15-granular electrolytic iron; 16-vacuum refining iron rods; 17-a second cold crucible; 18-a second liquid region; 19-a second directional solidification zone; 20-a first liquid zone; 21-a first directional solidification zone; 22-second directional drawing system.

Detailed Description

The invention is described below with reference to the accompanying drawings (fig. 1) and examples.

FIG. 1 is a schematic structural diagram of a system for preparing high-purity iron grade 4N according to the present invention. Referring to fig. 1, a system for preparing 4N grade high purity iron comprises a cold wall vacuum induction refining furnace 12 and a hydrogen plasma drop refining furnace 13 which are respectively connected with the same vacuum system 5. The cold wall vacuum induction refining furnace 12 is used for heating and melting 2N or 3N electrolytic pure iron raw materials (such as granular electrolytic iron 15) and then generating a vacuum refining iron rod 16 in a directional drawing solidification mode, and the hydrogen plasma drop melting refining furnace 13 is used for gradually melting the vacuum refining iron rod 16 into molten drops through hydrogen plasma arcs and then generating a 4N-grade high-purity iron rod in a directional drawing solidification mode.

The vacuum system 5 comprises a mechanical vacuum pump 9, a roots vacuum pump 10 and a diffusion vacuum pump 11 which are sequentially started, and the cold wall vacuum induction refining furnace 12 and the hydrogen plasma trickle refining furnace 13 are respectively connected with the vacuum system 5 through respective control valves. Cold wall vacuum induction refining furnace 12 is including being located the inside first cold crucible 2 of first vacuum chamber, first liquid district 20 that first cold crucible 2's the first half on the outer peripheral face is provided with induction coil 3 in order to form the pure iron raw materials of melting 2N or 3N electrolysis, first liquid district 20 down first orientation solidifies district 21, first orientation pull system 4 is connected to the bottom of first cold crucible 2, first vacuum chamber top is provided with feeder 1, feeder 1's discharge gate passes through feed deflector 14 and connects the top pan feeding mouth of first cold crucible 2. The 2N or 3N electrolytically purified iron feedstock is a granular feedstock (e.g., granular electrolytic iron 15). The first cold crucible 2 is a water-cooling copper crucible, and the feeder 1 comprises an electromagnetic vibration feeding mechanism.

Hydrogen plasma drips refining furnace 13 is including being located the inside second cold crucible 17 of the real empty room of second, the top pan feeding mouth top of the cold crucible 17 of second is provided with iron bar rotary device 8, the below of iron bar rotary device 8 is provided with plasma gun 6, iron bar rotary device 8 is used for making to pass through vacuum refining iron bar 16 that cold wall vacuum induction refining furnace 12 obtained is quilt in rotatory the hydrogen plasma arc of plasma gun 6 progressively melts into the molten droplet, the molten droplet drips into through an iron bar molten droplet district 7 form second liquid region 18 in the cold crucible 17 of second, second liquid region 18 is connected down second directional solidification district 19, second directional pull system 22 is connected to the bottom of second cold crucible 17. The plasma gas adopted by the hydrogen plasma drop melting refining furnace 13 comprises a mixed gas of hydrogen and argon for deoxidation and/or denitrification, and/or oxygen or carbon dioxide for decarburization, and/or chlorine or fluorine for removing tungsten or molybdenum.

A method for preparing 4N-grade high-purity iron comprises the steps of utilizing the system for preparing 4N-grade high-purity iron, taking electrolytic iron as a raw material, obtaining a vacuum refining iron rod by adopting a vacuum melting technology of synchronous feeding, heating melting and directional drawing, then gradually melting the vacuum refining iron rod into molten drops through hydrogen plasma arc to enlarge a refining reaction area and accelerate refining speed, and generating the 4N-grade high-purity iron rod in a directional drawing solidification mode.

A method for preparing 4N-grade high-purity iron comprises the steps that by utilizing the system for preparing 4N-grade high-purity iron, electrolytic iron is used as a raw material and is continuously and quantitatively fed in a cold-wall vacuum induction refining furnace through a feeder, solid electrolytic iron is heated and melted in a first cold crucible and then is directionally solidified into a vacuum refining iron rod through pulling down, and metal purification is carried out through high vacuum and directional solidification in the process; the method is characterized in that the vacuum refining iron rod is adopted as a raw material, the vacuum refining iron rod is rotated and gradually melted in a hydrogen plasma drop melting refining furnace to form molten drops, refining reaction is promoted, the purification effect is controlled by adjusting the rotating speed and the feeding speed, a 4N-grade high-purity iron rod is generated in a directional drawing solidification mode, and the metal is purified through hydrogen reduction and directional solidification in the process.

The feeder 1 in fig. 1 comprises an electromagnetic vibratory feeder; the number of splits of the first cold crucible 2 and the second cold crucible 17 is 2-48; the frequency of the induction coil 3 is 1000-100000 Hz; the drawing speed of the first directional drawing system 4 and the second directional drawing system 22 is 0.01-1000 mm/s; the vacuum degree of the vacuum system 5 is 10^-8Pa～10^-7Pa; the power of the plasma gun 6 is 10-500 KW.

A production method of 4N high-purity iron comprises the following steps:

[1] the refining method comprises cold wall vacuum induction refining and hydrogen plasma refining, and the used equipment also comprises two furnace bodies which are respectively a cold wall vacuum induction furnace and a hydrogen plasma drop melting refining furnace, and the two refining furnaces share one set of vacuum system;

[2] taking electrolytic iron as a raw material, continuously and quantitatively feeding the raw material in a cold wall vacuum induction furnace through a vibrating feeder, heating and melting solid electrolytic iron in a cold crucible, and then directionally solidifying and solidifying the molten electrolytic iron into a high-purity iron rod through pulling down, wherein the process is used for metal purification through high vacuum and directional solidification;

[3] adopting an iron rod obtained by a cold wall vacuum induction furnace as a raw material, rotating and gradually melting in a hydrogen plasma furnace to form liquid drops, promoting a refining reaction and realizing purification, wherein the process carries out metal purification through hydrogen reduction and directional solidification;

[4]the plasma gas used by the hydrogen plasma refining furnace is Ar + H₂Mixing gas, wherein the proportion of hydrogen is 0-100%, and the purities of argon and hydrogen are both more than 4N;

[5]the plasma gas used by the hydrogen plasma refining furnace is Ar + H₂Mixing gas, wherein the proportion of hydrogen is 0-100%, and the purities of argon and hydrogen are both more than 4N;

[6]the plasma gas used by the hydrogen plasma refining furnace can be introduced with O₂、CO₂Plasma gas for decarburization, Cl₂、F₂The protective gas is used for removing W, Mo and other high-melting-point impurities in the pure iron;

[7] and cutting and surface treating the pure iron rod refined by the hydrogen plasma to obtain the 4N high-purity iron.

The invention aims to provide a method for preparing 4N high-purity iron by plasma refining or a method for preparing 4N high-purity iron or a production method of 4N high-purity iron, wherein electrolytic iron is used as a raw material, refining means such as vacuum refining and hydrogen plasma refining are combined, and synchronous feeding, heating and melting and directional drawing are adopted to obtain a high-purity iron rod; the refining reaction area is enlarged by utilizing the drop melting, and the refining speed is accelerated. The invention does not need to add other refining agents into the melt, cancels the ceramic crucible, does not generate waste slag in the production process, and has the characteristics of simple process, simple operation, energy saving, environmental protection, low cost and the like.

Example (b): [1]Preparing electrolytic iron samples, wherein each sample weighs about 10kg and is placed in a left chamber of a high-purity iron refining furnace; [2]Connecting circulating cooling water, and checking the smoothness of each cooling pipeline; [3]Starting the mechanical pump, starting the Roots pump when the vacuum degree in the furnace is less than 500Pa, continuously reducing the vacuum degree to 1Pa, and starting the diffusion pump until the vacuum degree in the furnace reaches 3 multiplied by 10^-3Pa；[4]Starting a feeder, simultaneously turning on an induction power switch, melting electrolytic iron in a water-cooled copper crucible, observing the melting condition and the liquid level of the liquid level through an observation hole on the furnace, starting a drawing system when the liquid level rises to the position 2cm above the upper edge of the crucible, and starting directional solidification; [5]The pure iron rod is obtained by adjusting the feeding amount, the power of the induction power supply and the drawing speed to match with each other;

[6]loading the pure iron rod obtained from the refining left chamber into the ion beam drop smelting refining furnace of the right chamber, closing the furnace door, opening the mechanical pump, starting the Roots pump when the vacuum degree in the furnace is less than 500Pa, continuing to reduce the vacuum degree to 1Pa, and then starting the diffusion pump until the vacuum degree in the furnace reaches 3 x 10^-3Pa；[7]Opening the valve, rapidly filling high-purity argon to 0.05MPa, and continuously vacuumizing to 3X 10^-3Pa, for washing the furnace. Closing the valve and the vacuum pump, and quickly filling high-purity argon to the preset experimental pressure; [8]Introducing stable plasma gas argon gas,the flow is 50L/min, and simultaneously, an exhaust pump is opened and an angle valve is adjusted to maintain the pressure in the furnace within a required pressure range;

[9] turning on a non-transferred arc power supply to generate a non-transferred arc between the cathode and the auxiliary anode nozzle, then turning on the transferred arc power supply, transferring the arc between the cathode and the pure iron rod, turning off the non-transferred arc power supply after the transferred arc is stable, starting the pure iron rod to rotate to feed the motor, and performing a plasma drop melting experiment; [10] introducing hydrogen in a required proportion into the plasma gas according to different experimental requirements to promote purification, and controlling the purification effect by adjusting rotation and feeding speed; [11] and after the smelting is finished, sequentially closing the plasma power supply, the plasma gas and the valve. And opening a valve of the vacuum system, starting the vacuum pump, and discharging residual gas in the furnace out of the furnace. When the vacuum degree reaches 1Pa, the vacuum pump and the valve are closed, protective argon is flushed to 1atm, and the furnace door is opened to break the air and take samples.

Those not described in detail in this specification are within the skill of the art. It is pointed out here that the above description is helpful for the person skilled in the art to understand the invention, but does not limit the scope of protection of the invention. Any such equivalents, modifications and/or omissions as may be made without departing from the spirit and scope of the invention may be resorted to.

Claims

1. A system for preparing 4N-grade high-purity iron is characterized by comprising a cold wall vacuum induction refining furnace and a hydrogen plasma drop melting refining furnace which are respectively connected with the same vacuum system;

the vacuum system comprises a mechanical vacuum pump, a Roots vacuum pump and a diffusion vacuum pump which are sequentially started, and the cold wall vacuum induction refining furnace and the hydrogen plasma drop melting refining furnace are respectively connected with the vacuum system through respective control valves;

the cold wall vacuum induction refining furnace comprises a first cold crucible positioned in a first vacuum chamber, the upper half part of the outer peripheral surface of the first cold crucible is provided with an induction coil to form a first liquid state area for melting 2N or 3N electrolytic pure iron raw materials, the first liquid state area is connected with a first directional solidification area, the bottom of the first cold crucible is connected with a first directional drawing system, the top of the first vacuum chamber is provided with a feeder, and a discharge hole of the feeder is connected with a top end feeding hole of the first cold crucible through a feeding guide plate;

2. The system for preparing 4N-grade high-purity iron according to claim 1, wherein the cold wall vacuum induction refining furnace is used for heating and melting 2N or 3N electrolytic pure iron raw materials and then generating a vacuum refining iron rod in a directional drawing solidification mode, and the hydrogen plasma droplet refining furnace is used for gradually melting the vacuum refining iron rod into molten droplets through hydrogen plasma arcs and then generating 4N-grade high-purity iron rods in a directional drawing solidification mode.

3. The system for producing high-purity iron grade 4N according to claim 1, wherein the 2N or 3N raw material for electrolytic pure iron is a granular raw material.

4. The system for producing grade 4N high purity iron of claim 1, wherein the first cold crucible is a water cooled copper crucible and the feeder comprises an electromagnetic vibratory feeding mechanism.

5. The system for preparing high-purity iron grade 4N according to claim 1, wherein the plasma gas used in the hydrogen plasma molten refining furnace comprises a mixed gas of hydrogen and argon for deoxidation and/or denitrification, and/or oxygen or carbon dioxide for decarburization, and/or chlorine or fluorine for removing tungsten or molybdenum.