CN105714016B - Low-carbon, low-sulfur and low nitrogen steel are manufactured at low cost using traditional steelmaking equipment - Google Patents

Abstract

Manufacture the method with the steel lower than 0.035 weight % low-carbon, it includes the following steps: to prepare the furnace melting steel compositions that temperature reaches tapping temperature in converter, the tapping temperature is temperature needed for carrying out desulfurization in VTD, opening tapping oxygen level is the melting steel compositions of 600~1120ppm to ladle, ladle is supplied to slag making compound to form clinker to cover the melting steel compositions in ladle, melting steel compositions in ladle are transported to VTD, it is lower than 650 millibars by being evacuated in VTD come to melting steel compositions progress decarburization, after decarburization, one or more deoxidiers are added into melting steel compositions and deoxidation is carried out to melting steel compositions, after deoxidation, one or more flux compounds are added to carry out desulfurization to melting steel compositions, and Casting melting steel compositions are to form the steel having lower than 0.035 weight % low-carbon.

Description

Low-carbon, low-sulfur and low nitrogen steel are manufactured at low cost using traditional steelmaking equipment

The application is that international filing date is August in 2009 3, application No. is 200980138838.4, entitled " benefits Manufacture low-carbon, low-sulfur and low nitrogen steel at low cost with traditional steelmaking equipment " application for a patent for invention divisional application.

Background and summary of the invention

Certain shaped steel combination objects need relatively low content of carbon (being lower than 0.035%), nitrogen (being lower than 50ppm) and sulphur (low In 30ppm).In the past, the method for preparing these low-carbons and low-sulfur steel is needed using in converter and degasification furnace (degasser) In process combination.Existing method is related to reducing the carbon level of steel compositions in converter (such as electric arc furnaces (EAF)), Alloy addition (alloy addition) is prepared in tapping process (tapping process) to carry out desulfurization and the alloy of steel Change, and steel is then shipped for degasification furnace, such as vacuum tank degasification furnace (vacuum tank degasser) (VTD).In this way Processing route it is simple and quite directly.

In the past, in order to obtain the steel compositions for meeting above-mentioned industrial level, (it is, for example, less than with low-down carbon level 0.025%) steel is tapped in converter.Before tapping, dissolved oxygen levels relevant to these low carbon contents exist in stove 1200ppm~1400ppm order of magnitude.When degasification furnace and stove have a distance, steel has needed since about 1700 DEG C of tappings The temperature loss during degasification furnace is transported in compensation.In tapping process, steel is by aluminium and ferrosilicon (FeSi) deoxidation.It is also added into Lime and aluminium dross are to generate liquid, deoxidation, desulfurization clinker.Using these additives, in being transported to degasification furnace In the process, desulphurization reaction occurs in ladle (ladle).Aluminium, lime, calcium aluminate and white clouds are further added in degasification furnace Stone lime, so that it is guaranteed that removing required sulphur in degassing circulation.Although using aluminium as main deoxidier, these steel groups Closing object is industrially considered as silicon killed steel.

Existing method has the disadvantage that the deterioration including the refractory material to converter is high.Needed for before converter tapping Raised tapping temperature and elevated oxygen level can have a negative impact for the production capacity in furnace.High temperature and hyperoxic conditions make The FeO amount obtained in clinker at high temperature is more, causes excessive furnace wall refractory deterioration.Although using whitewashing to oven refractory It is repaired, this off-time that can still result in stove increases.In clinker high FeO content also result in steel-making efficiency it is lower, This is because losing more iron units in clinker.

Existing method is also needed using low-carbon alloy and additive in the subsequent processing of entire converter, to keep low Carbon level is lower than 0.035 weight %.Low-carbon alloy ingredient (such as low-carbon FeMn) is needed to provide required ingredient, thus will not Damage the final carbon content in steel.Recently, the price of low carbon ferroalloy (carbon ferro-alloy) obviously increases, to lead Cause this method that can not economically produce such mild steel.In addition, the carbon amounts reduced in steel compositions in converter needs volume Outer decarburization time, this can also negatively affect the production capacity in converter.Due to more elevated oxygen level, it is therefore desirable to more silicon Come to carry out deoxidation to steel compositions with aluminium, be further increased so as to cause cost.There is still a need for reduce low-carbon, low nitrogen and low-sulfur steel Production cost.

Applicants have found that manufacture mild steel alternative approach, this method avoid using low carbon ferroalloy and produce Steel has the low-carbon lower than 0.035 weight %, and the method reduce the deteriorations to refractory material, and increase steel-making efficiency.

Disclosed herein is the methods that manufacture has the steel lower than 0.035 weight % low-carbon, and this method comprises the following steps:

(a) prepare furnace melting steel compositions (a heat of molten that temperature reaches tapping temperature in converter Steel composition), which is temperature needed for carrying out desulfurization in vacuum tank degasification furnace,

(b) the melting steel compositions that tapping oxygen level is 600~1120ppm are opened to ladle,

(c) ladle is provided with slag making compound (slag forming compound) to form clinker to cover and contain Melting steel compositions in steel drum,

(d) the melting steel compositions in ladle are transported to vacuum tank degasification furnace,

(e) decarburization is carried out to melting steel compositions by being evacuated to lower than 650 millibars in vacuum tank degasification furnace,

(f) after decarburization, one or more deoxidiers are added into melting steel compositions and melting steel compositions are carried out Deoxidation,

(g) after deoxidation, add one or more flux compounds (flux compound) with to melting steel compositions into Row desulfurization, and

(i) casting melting steel compositions are to form the steel having lower than 0.035 weight % low-carbon.

It, can be by adding free oxygen into melting steel compositions come to the molten steel through decarburization and deoxidation before casting Composition is reoxidized, so that horizontal is that 20~70ppm and total oxygen content are at least 70ppm, and then connect in double roller Casting melting steel compositions are in casting machine (twin roll caster) to form the steel having lower than 0.035 weight % low-carbon Band.

In tapping step, the sulfur content in steel compositions can be 0.02 weight of weight %~0.06 %.In tapping step In, the carbon amounts in steel compositions can be lower than for the nitrogen quantity in 0.02 weight of weight %~0.05 % and steel compositions 0.005 weight %.In addition, the step of preparing furnace melting steel compositions can carry out in electric arc furnaces.

It can be in 1600 DEG C~1650 DEG C of temperature, or in 1650 DEG C~1700 DEG C of temperature, or 1700 DEG C~1750 DEG C temperature open tapping step.

It can be taken off at 1~650 millibar or 350~550 millibars, or under vacuum level equal to or less than 530 millibars Carbon step.

Before decarbonation process, the method for preparing the steel for having low-carbon lower than 0.035 weight % can also include following step It is rapid:

(i) melting steel compositions of the stirring in the ladle of vacuum tank degasification furnace,

(ii) temperature of the carbon amounts in steel compositions, the oxygen amount in steel compositions and steel compositions is measured and recorded,

(iii) provide process model (process model), the process model be associated with steel compositions in oxygen and carbon amounts with Steel compositions reach the decarburization time of the carbon amounts of needs；And

(iv) amount based on the oxygen and carbon that detect in steel compositions, determines decarburization time using process model.

Alternatively or additionally, before decarbonation process, preparing has the method for the steel lower than 0.035 weight % low-carbon can be with Further comprise following steps:

(i) steel compositions of the stirring in the ladle of vacuum tank degasification furnace

(ii) temperature of the carbon amounts in steel compositions, the oxygen amount in steel compositions and steel compositions is measured and recorded,

(iii) provide process model, the process model be associated with steel compositions in oxygen and carbon amount with to steel compositions into The amount of deoxidation additive needed for row deoxidation, and

(iv) amount based on the oxygen and carbon that detect in steel compositions, deoxidation in steel compositions is determined using process model The amount of additive.

The step of one or more flux compounds are added can be related to being added selected from lime, aluminium, calcium aluminate, dolomite stone One or more compounds of ash and fero-manganesesilicon.

Further, alternatively or additionally, before decarbonation process, preparing has the steel lower than 0.035 weight % low-carbon Method may further include following steps:

(i) steel compositions of the stirring in the ladle of vacuum tank degasification furnace

(ii) temperature of the carbon amounts in steel compositions, the oxygen amount in steel compositions and steel compositions is measured and recorded,

(iii) process model is provided, the oxygen and carbon amounts which is associated in steel compositions are carried out with to steel compositions The amount of flux component needed for desulfurization and price based on flux component can select one or more flux components；And

(iv) amount based on the oxygen and carbon that detect in steel compositions, the selection of flux component is determined using process model With their amount.

The invention also includes:

1. manufacturing the method with the steel lower than 0.035 weight % low-carbon comprising following steps:

(a) in converter, prepare the furnace melting steel compositions that temperature reaches tapping temperature, which is vacuum tank Temperature needed for carrying out desulfurization in degasification furnace,

(b) the melting steel compositions that tapping oxygen level is 600~1120ppm are opened to ladle,

(c) it is supplied to ladle and the melting steel compositions in ladle is covered to form clinker with slag making compound,

(d) the melting steel compositions in ladle are transported to vacuum tank degasification furnace,

(e) decarburization is carried out to melting steel compositions by being evacuated to lower than 650 millibars in vacuum tank degasification furnace,

(f) after decarburization, one or more deoxidiers are added into melting steel compositions and melting steel compositions are carried out Deoxidation,

(g) after deoxidation, one or more flux compounds are added to carry out desulfurization to melting steel compositions, and

(i) casting melting steel compositions are to form the steel having lower than 0.035 weight % low-carbon.

2. manufacture described in 1 has the method for the steel lower than 0.035 weight % low-carbon, wherein the steel in tapping step Carbon amounts in composition is 0.02%~0.05 weight %.

3. manufacture described in 1 or 2 has the method for the steel lower than 0.035 weight % low-carbon, wherein prepare furnace molten steel The step of composition, carries out in electric arc furnaces.

4. manufacture described in any one of above-mentioned item has the method for the steel lower than 0.035 weight % low-carbon, wherein decarburization Step is in 1~650 millibar of vacuum level.

5. manufacture described in 4 has the method for the steel lower than 0.035 weight % low-carbon, wherein decarbonation process is in 350 ~550 millibars of vacuum level.

6. manufacture described in any one of above-mentioned item has the method for the steel lower than 0.035 weight % low-carbon, wherein be added The aluminium of requirement is added in the vacuum level that the step of one or more deoxidiers is included in 530~1000 millibars.

7. manufacture described in any one of above-mentioned item has the method for the steel lower than 0.035 weight % low-carbon, further include Following steps: after desulfurization, 1~2.5 millibar is evacuated to except denitrification.

8. manufacture described in any one of above-mentioned item has the method for the steel lower than 0.035 weight % low-carbon, wherein be added The step of one or more flux compounds includes that one kind selected from lime, aluminium, calcium aluminate, dolomite lime and fero-manganesesilicon is added Or multiple compounds.

9. manufacture described in any one of above-mentioned item has the method for the steel lower than 0.035 weight % low-carbon, wherein going out In steel step, the sulfur content in steel compositions is 0.02%~0.06 weight %.

10. manufacture described in any one of above-mentioned item has the method for the steel lower than 0.035 weight % low-carbon, further include Following step before decarbonation process:

(i) melting steel compositions of the stirring in the ladle of vacuum tank degasification furnace,

(ii) temperature of the carbon amounts in steel compositions, the oxygen amount in steel compositions and steel compositions is measured and recorded,

(iii) process model is provided, the oxygen and carbon amounts and steel compositions in process model association steel compositions, which reach, to be needed Decarburization time needed for the carbon amounts wanted；And

(iv) amount based on the oxygen and carbon that detect in steel compositions, determines decarburization time using process model.

11. manufacture described in any one of 1~9 has the method for the steel lower than 0.035 weight % low-carbon, further include Following step before decarbonation process:

(i) steel compositions of the stirring in the ladle of vacuum tank degasification furnace

(ii) temperature of the carbon amounts in steel compositions, the oxygen amount in steel compositions and steel compositions is measured and recorded,

(iii) provide process model, the process model be associated with steel compositions in oxygen and carbon amount with to steel compositions into The amount of deoxidation additive needed for row deoxidation, and

(iv) amount based on the oxygen and carbon that detect determines deoxidation additive in steel compositions using process model Amount.

12. manufacture described in any one of 1~9 has the method for the steel lower than 0.035 weight % low-carbon, further include Following step before decarbonation process:

(i) steel compositions of the stirring in the ladle of vacuum tank degasification furnace

(ii) temperature of the carbon amounts in steel compositions, the oxygen amount in steel compositions and steel compositions is measured and recorded；

(iii) process model is provided, the oxygen and carbon amounts which is associated in steel compositions are carried out with to steel compositions The amount of flux component needed for desulfurization and price based on flux component can select one or more flux components；And

(iv) amount based on the oxygen and carbon that detect, determined using process model flux component selection and they Amount.

13. manufacture described in any one of above-mentioned item has the method for the steel lower than 0.035 weight % low-carbon, wherein 1600 DEG C~1650 DEG C of temperature opens tapping step.

14. manufacture described in any one of 1~12 has the method for the steel lower than 0.035 weight % low-carbon, wherein 1650 DEG C~1700 DEG C of temperature opens tapping step.

15. manufacture described in any one of 1~12 has the method for the steel lower than 0.035 weight % low-carbon, wherein 1700 DEG C~1750 DEG C of temperature opens tapping step.

16. manufacturing the method with the steel lower than 0.035 weight % low-carbon comprising following steps:

(a) prepare the furnace melting steel compositions that temperature reaches tapping temperature in converter, which is vacuum tank Temperature needed for carrying out desulfurization in degasification furnace,

(b) the melting steel compositions that tapping oxygen level is 600~1120ppm are opened to ladle,

(c) it is supplied to ladle and the melting steel compositions in ladle is covered to form clinker with slag making compound,

(d) the melting steel compositions in ladle are transported to vacuum tank degasification furnace,

(e) decarburization is carried out to melting steel compositions by being evacuated to lower than 650 millibars in vacuum tank degasification furnace,

(f) after decarburization, one or more deoxidiers are added into melting steel compositions and melting steel compositions are carried out Deoxidation,

(g) after deoxidation, add one or more flux compounds with to melting steel compositions carry out desulfurization,

(i) free oxygen is added into melting steel compositions until level is that 20~70ppm and total oxygen content are at least 70ppm, and

(j) then casting melting steel compositions are low lower than 0.035 weight % to which formation has in double-roller continuous casting machine The steel band of carbon.

17. manufacture described in 16 has the method for the steel lower than 0.035 weight % low-carbon, wherein in tapping step Carbon amounts in steel compositions is 0.02%~0.05 weight %.

18. manufacture described in 16 or 17 has the method for the steel lower than 0.035 weight % low-carbon, wherein it is molten to prepare furnace The step of melting steel compositions carries out in electric arc furnaces.

19. manufacture described in any one of 16~18 has the method for the steel lower than 0.035 weight % low-carbon, wherein Decarbonation process is in 1~650 millibar of vacuum level.

20. manufacture described in any one of 16~19 has the method for the steel lower than 0.035 weight % low-carbon, wherein Decarbonation process is in 350~550 millibars of vacuum level.

21. manufacture described in any one of 16~20 has the method for the steel lower than 0.035 weight % low-carbon, wherein The aluminium of requirement is added in the vacuum level that the step of one or more deoxidiers are added is included in 530~1000 millibars.

22. manufacture described in any one of 16~21 has the method for the steel lower than 0.035 weight % low-carbon, also wrap It includes following steps: after desulfurization, being evacuated to 1~2.5 millibar except denitrification.

23. manufacture described in any one of 16~22 has the method for the steel lower than 0.035 weight % low-carbon, wherein The step of one or more flux compounds are added includes being added selected from lime, aluminium, calcium aluminate, dolomite lime and fero-manganesesilicon One or more compounds.

24. manufacture described in any one of 16~23 has the method for the steel lower than 0.035 weight % low-carbon, wherein In tapping step, the sulfur content in steel compositions is 0.02%~0.06 weight %.

25. manufacture described in any one of 16~24 has the method for the steel lower than 0.035 weight % low-carbon, also wrap Include the following step before decarbonation process:

(i) melting steel compositions of the stirring in the ladle of vacuum tank degasification furnace,

(ii) temperature of the carbon amounts in steel compositions, the oxygen amount in steel compositions and steel compositions is measured and recorded,

(iii) process model is provided, the oxygen and carbon amounts and steel compositions in process model association steel compositions, which reach, to be needed Decarburization time needed for the carbon amounts wanted；And

(iv) amount based on the oxygen and carbon that detect in steel compositions, determines decarburization time using process model.

26. manufacture described in any one of 16~24 has the method for the steel lower than 0.035 weight % low-carbon, also wrap Include the following step before decarbonation process:

(i) steel compositions of the stirring in the ladle of vacuum tank degasification furnace

(ii) temperature of the carbon amounts in steel compositions, the oxygen amount in steel compositions and steel compositions is measured and recorded,

(iii) provide process model, the process model be associated with steel compositions in oxygen and carbon amount with to steel compositions into The amount of deoxidation additive needed for row deoxidation, and

(iv) amount based on the oxygen and carbon that detect determines deoxidation additive in steel compositions using process model Amount.

27. manufacture described in any one of 16~24 has the method for the steel lower than 0.035 weight % low-carbon, also wrap Include the following step before decarbonation process:

(i) steel compositions of the stirring in the ladle of vacuum tank degasification furnace

(ii) temperature of the carbon amounts in steel compositions, the oxygen amount in steel compositions and steel compositions is measured and recorded；

(iii) process model is provided, the oxygen and carbon amounts which is associated in steel compositions are carried out with to steel compositions The amount of flux component needed for desulfurization and price based on flux component can select one or more flux components；And

(iv) amount based on the oxygen and carbon that detect, determined using process model flux component selection and they Amount.

28. manufacture described in any one of 16~27 has the method for the steel lower than 0.035 weight % low-carbon, wherein Tapping step is opened in 1600 DEG C~1650 DEG C of temperature.

29. manufacture described in any one of 16~27 has the method for the steel lower than 0.035 weight % low-carbon, wherein Tapping step is opened in 1650 DEG C~1700 DEG C of temperature.

30. manufacture described in any one of 16~27 has the method for the steel lower than 0.035 weight % low-carbon, wherein Tapping step is opened in 1700 DEG C~1750 DEG C of temperature.

Detailed description of the invention

Fig. 1 is the general flowchart for producing the method for low-carbon, low nitrogen and low-sulfur steel；

Fig. 2 is the figure for showing the sulfur content of the one heat steel (heats) into vacuum tank degasification furnace using existing method；

Fig. 3 is to show one but not the only one reality compared using existing method and published method of the present invention The figure of the oxygen distribution during arc furnace tapping when applying mode；

Fig. 4 is that the FeO in the electric arc furnaces clinker shown when comparing using existing method and published method of the present invention is distributed Figure；

Fig. 5 is arc furnace tapping mistake when showing the embodiment compared using existing method and published method of the present invention The figure of steel Temperature Distribution in journey；

It is when Fig. 6 is the embodiment using existing method and published method of the present invention, will be before arc furnace tapping process The figure that is compared with the carbon amounts after tapping of oxygen amount；

Fig. 7 is that the vacuum tank that enters when showing the embodiment compared using existing method and published method of the present invention takes off The figure of the sulfur content of the one heat steel of steam stove；

Fig. 8 is when showing the embodiment compared using existing method and published method of the present invention in degassing circulation The figure of carbon distribution in steel afterwards；And

Fig. 9 is when showing the embodiment compared using existing method and published method of the present invention in degassing circulation The figure of sulphur content cloth in steel afterwards.

Detailed description of the invention

Fig. 1 schematically depicts the method for producing low-carbon, low nitrogen and low-sulphur steel (steel grade).In standard During the steel for being ready for use on casting, usually, steel passes through from electric arc furnaces (EAF) to vacuum tank degasification furnace (VTD) to ladle Metallurgical furnace (ladle metallurgical furnace) (LMF) arrives the process of casting machine (not shown).It is disclosed using the present invention Method production steel grade have below about 0.035 weight % low-carbon.The steel grade, which also usually has, is below about 0.005 weight % Low nitrogen and low-sulfur below about 0.003 weight % or below about 0.0015 weight %.

Steel melting factory usually has one or more electric arc furnaces, such as is equipped with 110,000,000 volt-amperes (MVA) transformer 120 tons of (metric ton) EAF.Such electric arc furnaces can have about 30~400 tons of capacity, but be typically used for the place of continuously casting Reason amount is 60~120 tons.Each stove can contain gas injection spray gun, such as the trade mark from Praxair is Co-Jet^TM Three spray gun gas injection systems, combination of oxygen and natural gas can be blown into stove by it, and also have carbon Injection pipe.The system can be used for spraying carbon and oxygen in different proportions during entirely heating steel to manufacture foam-like EAF clinker.In the paper Foamy Slag Fundamentals and Their of Pretorius, E.B. and R.C.Carlisle Practical Application to Electric Furnace Steelmaking, ISS-AIME, EF Conference Proceedings describes the preparation of foam-like clinker in 1998, pp.275-291.Top can also be installed to supply on the EAF To flux system, lime, dolomite and carbon can be supplied by the system to control the basicity and viscosity of clinker, thus in melting In preferably form clinker.Other converters, such as basic oxygen converter can be used in the method for the present invention.

It is in the embodiment of the method for the present invention of this description, when the oxygen content and temperature of steel compositions enter expectation Parameter area within when, open EAF one heat steel in molten steel tapping process.Due to EAF can be separated by with VTD one section away from From, therefore the tapping temperature of steel compositions is selected so that the temperature reduction during being transported to VTD by EAF can be VTD In decarburization and nitrogen and sulphur decrement provide needed for temperature.It can be from stove by eccentric bottom tapping hole (EBT) system Start to tap steel compositions into ladle, is commonly designed the system and to be brought into ladle in tapping process from EAF Clinker minimize.For example, in the EAF of 120 tons of capacity, from stove tapping to about 105 tons of ladle of steel.

Ladle as needed is commonly installed there are two porous plug, which can be used to introduce into steel compositions Argon.Porous plug hook (hook-up) can use to be connected automatically by corresponding ladle trunnion.The tapping work station can also To be equipped with measuring system, the temperature of steel directly can be measured and recorded after tapping, and can measure and record and is additional Information, such as the oxygen level in steel compositions.Once tapping process is completed, g of slag sample use can be taken out from EAF at once To detect the FeO amount in EAF clinker.

Different from past method in the embodiment of the method for the present invention, decarburization is not completed in EAF.Instead, In the embodiment of the method for the present invention, EAF tapping oxygen reduces in the case where corresponding higher tapping carbon level.This is improved Method be included in the opening tapping step of converter, and in the subsequent decarbonation process of VTD.Open tapping (open Tapping) (or (tapping open) is opened in tapping) means to tap in the case where no deliberately addition deoxidier.At this In the embodiment of inventive method, the tapping oxygen content of steel is reduced to about 600~1120ppm, and more desirably, until about 600 ~900ppm.

When VTD and converter have a distance, tapping temperature can be about 1700 DEG C~1750 DEG C, which allows temperature Degree reduces during transporting from stove to VTD.Alternatively, when shortening the time for transporting VTD, tapping temperature can be about 1600 DEG C~1650 DEG C, or alternatively can be about 1650 DEG C~1700 DEG C.In tapping step of the invention, close argon plug from And steel compositions can not be stirred.Once completing the tapping from stove to ladle, so that it may steel sample is taken out, and And slag making compound, such as lime are added to cover steel in ladle, to reduce the heat loss during transporting VTD And oxidation.Bell can preferably be placed on it before ladle transports VTD.

Compared with the conventional method, existing method is added in tapping process into steel compositions tapping step of the invention Lime, calcium aluminate, aluminium, slag deoxidizer and ferrosilicon, and the steel compositions in ladle are carried out in entire tapping process Stirring, so that additive be made to mix with steel compositions.In the embodiment of this method, not to steel group preferably in tapping process Object is closed to be stirred.In addition, other than lime being added in ladle to cover steel, it can be in tapping step of the invention It is added without flux.

Past method requires the carbon level from the EAF steel compositions tapped very low, such as less than 0.025% carbon, out After steel, after having carried out partial desulfurization in ladle, desulfurization is subsequently completed in VTD and removes hydrogen and nitrogen.Existing In method, average tapping temperature is 1708 DEG C.In addition, the average dissolution oxygen content (tapping oxygen) before tapping in EAF is 1398ppm, leading to the mean carbon content in ladle is 0.022%.In the conventional method, the average FeO content in clinker It is 38.6%.In existing tapping process, FeSi, aluminium and lime joined into ladle.

In addition, in past method, aluminium dross is added in ladle to reduce reducible oxide, bring into The concentration of the FeO and MnO of EAP clinker.Traditional EAF clinker brought into is usually less than 500kg.

In contrast, in the embodiment of the method for the present invention, in the case where being added without deoxidation additive, in a furnace Open tapping steel compositions.As described below, tapping opening steps reduce the desulphurizing ability in the ladle before VTD. Existing method is related to that deoxidier is added into ladle and stirs metal and clinker to provide some degree before VTD Desulfurization.In the conventional method, before VTD step, the sulfur content of the steel compositions in ladle is usually from about 0.035 weight % It is reduced to 0.016 weight %.

In the embodiment of the method for the present invention, after tapping step, the steel compositions in ladle are transported To be further processed to reduce the content of hydrogen and nitrogen in VTD, and carry out the desulfurization of steel compositions.Can by delivery vehicle or Overhead crane transports ladle.After transporting above VTD, by the mobile ladle of overhead crane and it can be placed into In VTD tank.Once can establish the connection of VTD porous plug, just plug is opened and passes through porous plug argon is introduced into Sheng steel In steel compositions in bucket, the flow of the argon gas used is usually less than 1m³/min.The flowing of argon causes initially to stir to broken With liquefaction clinker, and keep the steel temperature in entire ladle more uniform.When clinker starts liquefaction, porous plug is closed, and remember Record the measured value of temperature and oxygen amount.These measured values recorded in VTD, and in remembering in furnace before or after tapping The measured value of record may be used to determine the alloy and flux added into steel compositions, and be used to determine the decarbonation process in VTD Length of time.

In the embodiment of the method for the present invention, decarbonation process carries out in VTD, and deoxidation step is then carried out in VTD Suddenly, clinker forming step, desulfurized step and nitrogen remove step.Total time ratio since there are decarburizations, in VTD work station Existing method is about 10 minutes.But in VTD it is increased processing the time will not significantly affect steel compositions preparation it is total when Between.

Decarbonizing process can start after closing argon stirring, and the temperature and oxygen that are recorded in the steel compositions of VTD Amount.Bell is placed on ladle, and starts to carry out the pumping of tank.With being evacuated on ladle, gas will be from Sheng It is removed in steel compositions in steel drum, which includes carbon monoxide (CO), hydrogen and nitrogen.Above steel compositions CO steam drops, carbon and oxygen reaction in addition will form CO, and extract out from steel compositions.Applicants have discovered that carbon and oxygen Reaction provides sufficient stirring action, and can not need the stirring of argon.The vacuum level used in decarbonizing process is low In 650 millibars.In decarbonizing process, vacuum level can be about 1 millibar~650 millibars, and can be 350~550 millibars Or it is lower than 530 millibars.

After decarburization in VTD, in the embodiment of the method for the present invention, aluminium is added into steel compositions and is used to be taken off Oxygen.It is preferred that lime, aluminium, calcium aluminate, dolomite lime, fero-manganesesilicon (FeSiMn) to be added together, and can also be added other Flux forms desulfurization clinker.By the uniform loading hopper of pressure, it is added and adds into steel compositions at the time of this method needs Add agent.The aluminium added under vacuum is reactive.Before aluminium is added, vacuum level can be adjusted to about 530~1000 Millibar.

It can use process model and form required addition come the deoxidation for determining decarburization time and steel compositions and clinker Agent.Process model can be used to control the chemical action of the clinker in VTD, this is because decarburization and deoxygenation step in VTD It will affect the chemical action of clinker.

It can be by the composition of the clinker in the measured value and VTD of the steel compositions recorded after tapping and steel compositions Measured value be supplied to process model (process model), or addition model (Addition Model).Adding model is one It can be used to analyze the data of measured value or input for kind of algorithm, and compare the data and desired value or predetermined value of input. Difference between desired or predetermined value according to the input data, addition model algorithm can determination will be into steel compositions Which kind alloy and flux and their amount are added can promote to remove denitrification and sulphur to desired level.

The concept that addition model can use optical basicity generates better slag composition according to the capacity of sulfide. In Sosinsky, D.J. and Sommerville, the paper The Composition and Temperature of I.D. Dependence of the Sulfide Capacity of Metallurgical Slags, Met.Trans.B, Vol.17B is described optical basicity concept in 1986, pp.331-337.In addition, addition model is utilized alloy and melts The low cost combination of agent addition agent is to prepare desired composition.Addition model may be used to provide with desired steel-furnace The fluid of slag mixed nature, caustic slag and the steel compositions through deoxidation.

In the embodiment of the method for the present invention, addition model can use algorithm to determine decarburization time, which is In VTD after initial stirring, the algorithm of oxygen and carbon amounts in decarburization time and steel compositions is associated with based on empirical data.Addition Model can use, and oxygen amount in VTD in the steel compositions after initial stirring determines the aluminium added after decarburization Amount.The amount of amount and oxygen based on aluminium, since the projection (projection) of the addition model determines the fusing agent additive needed Form desulfurization clinker.

Fixed amount can be provided to controller by adding model algorithm, which can be automatically into steel compositions Addition determines the selected alloy and flux of amount.It is used to provide alloy to steel compositions for example, VTD can have four settings With the hopper (bin) of flux.According to required steel compositions and slag composition, four hoppers can contain lime, aluminium, aluminium One of sour calcium and dolomite lime or fero-manganesesilicon (FeSiMn).Controller can make by oneself each hopper activity from And the selected alloy or fusing agent additive of measured quantity is provided into the steel compositions of the correspondingly amount of having determined that.To required After the alloy and fusing agent additive wanted are weighed, at the time of this method needs, by the uniform loading hopper of pressure by it Be added in the steel compositions in ladle.

In the embodiment of the method for the present invention, since from additive needed for loading hopper charging, cover is placed on its behaviour Make in position.It closes porous plug and starts the pumping of tank.Total cycle time in VTD can be about 35 minutes.

After decarburization and deoxidation, 1~2.5 millibar of vacuum level can achieve except denitrification.

Alternatively or additionally, after desulfurization, it can achieve 1~2.5 millibar of vacuum level except denitrification.Under pumping is inhaled Being down to 1~2.5 millibar of time is typically less than 7 minutes, and this depend partly on the thermal process of tank.Complete the removal of desulfurization and nitrogen Time be about 20 minutes.

In the conventional method, design addition model is mainly for generation of the condition that can only remove desulfuration and nitrogen.In existing side In method, steel compositions by part deoxidation, are deoxidized in some one heat steels to about 6.6ppm, and with about 1645 DEG C compared with The high temperature into ladle.Since some sweetening processes occur after tapping, and during transporting VTD, Therefore the sulfur content distribution in the steel compositions for entering VTD is irregular.Fig. 2 shows enter in the conventional method The distribution of sulphur in vacuum tank degasification furnace.The concentration for entering the average carbon of VTD, nitrogen and sulphur is listed in Table 1 below.

Table 1: average carbon, nitrogen and the sulphur concentration of VTD are entered in existing method

Ingredient	Concentration, weight %
		Carbon	0.022
Nitrogen	0.0072
		Sulphur	0.016

As shown in table 1, in the conventional method, the concentration of carbon of steel compositions is, for example, less than within the scope of desired 0.035% carbon, directly from electric arc furnaces.As described above, this needs that steel will not be upset to be added to steel compositions in VTD The alloy and flux of low-carbon amount in composition are selected.

Table 2: the average VTD of existing method enters the composition (weight %) of clinker

CaO	SiO2	Al2O3	MgO	FeO+MnO
					57.8	5.6	28.4	7.7	0.5

In the embodiment of the method for the present invention, to steel compositions oxygen therein in the steel compositions of entrance in VTD It measures with temperature, and is measured again after VTD circulation.Clinker and steel are also sampled after degassing circulation Sample is to be used for chemical analysis.The aim carbon and sulfur content of steel compositions after degassing can be respectively about 0.015% peace treaty 0.0010%.Average carbon, nitrogen and the sulphur concentration for entering the steel compositions of VTD are as shown in table 3.

Table 3: average carbon, nitrogen and the sulphur concentration of VTD are entered in the method for the present invention

Ingredient	Concentration, weight %
		Carbon	0.035
Nitrogen	0.0069
		Sulphur	0.036

In the embodiment of the method for the present invention, once degassing circulation is completed to be shut off porous plug, VTD is put back into atmosphere It is opened under pressure and by bell.At this point, sampling steel compositions and slag composition, and the temperature and oxygen of steel compositions are surveyed It is fixed.Then as desired by overhead crane, by the steel compositions in ladle transport in ladle metallurgy furnace (LMF) with into One step carries out alloy and heat treatment to reach the casting temperature of requirement.

The technology can be used for preparation without brilliant gap steel.The carbon level that no brilliant gap steel has can be lower than 0.01%, and 0.005% can be lower than.

In order to determine the efficiency of the method for the present invention embodiment, more following two kinds of data: utilize existing method from 500 furnaces The previous data recorded in steel, and given birth to using the embodiment of published method of the present invention from experiments in two months of 500 furnace steel Produce the data obtained in equipment.The data include the amount of oxygen in the steel compositions measured in tapping step, carbon and sulphur, are being gone out The temperature of steel compositions in steel step, and the amount of the FeO in EAF slag composition.Fig. 3 show to existing method and The comparison of the oxygen content of steel compositions between published method of the present invention.As shown in figure 3, compared with the conventional method, the present invention is public The embodiment of the extraction of root provides lower oxygen content.Averagely tapping oxygen is reduced to the present invention from the 1398ppm of existing method The 962ppm of method.

Fig. 4 shows influence of the lower tapping oxygen content for the FeO content of stove slag composition.Slag composition FeO content from using the 38.6% of existing method be reduced to using published method of the present invention 27.7%.

Fig. 5 shows tapping temperature (existing method and the method for the present invention).As shown in figure 5, average tapping temperature slightly rises Height is increased to 1724 DEG C from 1708 DEG C.It is same to provide that other decarbonation process in VTD needs slightly higher tapping temperature VTD outlet temperature.

Fig. 6 shows lower influence of the tapping oxygen level for steel compositions carbon content, using after direct tapping from The sample of ladle sampling measures.As shown in fig. 6, the relevant carbon content of reduced tapping oxygen content to steel compositions from 0.022% increases to 0.035%.It follows following reactions:

[C]+[O]=(CO)_Gas (1)

Wherein [C], [O] and (CO)_GasRespectively indicate dissolution carbon, dissolved oxygen and CO gas.According to reaction (1) institute Show, under constant CO partial pressure, the lower dissolved oxygen content of steel compositions will lead to higher dissolution carbon content.

The sulphur that steel compositions of the existing method in the method for the present invention embodiment into VTD when are compared in Fig. 7 contains Amount.The sulphur level of steel compositions increases average from 0.016%~0.036% when Fig. 7 shows access into VTD.Due to after tapping, Not having sulfur transfer, therefore the distribution of sulphur becomes more regular into clinker.Present approach provides tapping opening steps, not into The deoxidation of row steel compositions until tapping until, and in VTD carry out steel compositions decarburization.In such a situa-tion, exist It is generally impossible to that desulfurization occurs in tapping process, this is because the removal of sulphur is driven by following reactions:

[S]+(O^2-)=(S^2-)+[O] (2)

Wherein [S] and [O] respectively indicates dissolution sulphur and oxygen content in steel compositions, and (O^2-) and (S^2-) indicate clinker In oxygen and sulphion.High oxygen ion concentration will drive instead in low dissolved oxygen content and slag composition in steel compositions Answer (2) to the right to carry out desulfurization to steel compositions.The deoxidation of steel compositions causes lower dissolved oxygen content de- to auxiliary Sulphur.But deoxidation does not occur in tapping process by steel compositions prepared by the method for the present invention, so desulfurization will not be started.Separately Outside, blast furnace basicity of slag makes the oxygen ion concentration in slag composition high, this will not appear in the embodiment party of the method for the present invention In formula, this is because fusing agent additive is not mixed into steel compositions by the method for the present invention.Therefore, the method for the present invention is utilized When embodiment, into VTD steel compositions sulphur level now higher than using pervious method preparation twice of steel compositions It is more.Table 4, which summarizes, utilizes average tapping carbon, sulphur, oxygen and the temperature in existing method and the steel compositions of the method for the present invention preparation Value.

Table 4: the summary of the tapping mean parameter of selection

Into in the vacuum tank degasification furnace of the method for the present invention embodiment slag composition and steel compositions and existing side Method is by relatively big difference.VTD process of the present invention produces low-carbon, low-sulfur steel product.Addition model of the invention is developed to be used to calculate Time needed for making the steel compositions decarburization to 0.015% carbon entered.Decarburization time is changed with the functional form for carbon of tapping；But it is de- The carbon time can be about 2~5 minutes.In addition, addition model is for calculating the aluminium and silicon that make steel compositions deoxidation to required amount The amount of manganese iron, such as after except carbon elimination, which is lower than 3ppm oxygen.The model also calculates will be with obtained deoxidation Steel and slag composition are mixed for the lime of desulfurization and the amount of calcium aluminate.Addition model utilizes the oxygen water measured in VTD It is flat.

Table 5 summarizes the average chemical composition of final VTD clinker (past and new method).

Table 5: average final VTD clinker composition

	CaO	SiO2	Al2O3	MgO	FeO+MnO
						Existing method	60.5	6.0	25.2	7.7	0.6
The method of the present invention	60.4	7.1	23.5	8.3	0.7

Table 5 shows that embodiment by the method for the invention and existing method obtain two kinds of final slag compositions very phase Seemingly.This shows that the steel sulphur level of the invention in the steel compositions manufactured by the method for the invention should pass through past side with those The product that method path obtains is consistent, sulphur content cloth (L_S) is defined as:

L_S=(weight %S)_Clinker/ [weight %S]_Steel (3)

It can calculate over the sulphur content cloth of method and the method for the present invention.The L of existing method_SIt is 2100, and the method for the present invention Embodiment L_SIt is 1975.This be for sulphur content cloth it is very high, illustrate final slag composition remove and protect Hold the effect in terms of the low levels in steel compositions.Such as Sosinsky, D.J. and Sommerville, the written The of I.D. Composition and Temperature Dependence of the Sulfide Capacity of Metallurgical Slags, Met.Trans.B, vol.17B, 1986, described in pp.331-337, when slag-metal system Oxygen position (oxygen potential) known to when, can be with calculated equilibrium sulphur content cloth, or can be calculated by deoxidation equilibrium flat Weigh sulphur content cloth.The balance sulphur breadth coefficient that equation (3) indicates temperature and optical basicity with clinker to indicate.

log L_S=(21920-54640 Λ)/T+43.6 Λ -23.9-log [a₀] (4)

Wherein Λ is the optical basicity of slag composition, and T is the temperature indicated with absolute temperature and a₀It is steel compositions In oxygen activity (activity of oxygen).Calculated balance sulphur breadth coefficient and measured value are carried out in table 6 Compare.

Table 6: measurement and calculated balance sulphur content cloth

	The L of measurements	Calculated balance Ls
			Existing method	2100	2476
The method of the present invention	1975	2569

Table 6 shows that the sulphur content cloth of the embodiment of existing method and the method for the present invention is closely similar, and they are close The balance of calculating.Ability close to calculated balance shows to make us full in the vacuum tank degasification furnace for being equipped with two porous plugs Clinker/steel compositions mixing of meaning.

Fig. 8 and 9 is respectively illustrated in the embodiment of existing method and the method for the present invention, degassing circulation after carbon and Sulphur content cloth.This it appears that carbon distribution is changed from Fig. 8, and the carbon that is averaged declines from 0.0245% (existing method) To 0.0195% (the method for the present invention).In published method of the present invention, carbon amounts slightly above utilizes the addition calculated carbon amounts of model. The present invention adds decarburization time needed for model calculates 0.015% carbon of preparation.As shown in figure 9, final sulphur content cloth becomes without obvious Change.

It should be the result shows that can routinely produce low-carbon and low-sulfur steel compositions using method disclosed by the invention.By Decarburization in VTD, the method for the present invention can prepare the steel grade of the low remnants of high quality, and significantly reduce oven refractory and alloy Cost.It is per ton to save about 20 U.S. dollar of cost.Using this method, which can continue about 8 months.

It should be considered illustrative although the present invention is illustrated and described in detail in attached drawing and description above Rather than the limitation to property of the present invention, it should be understood that preferred embodiment only has shown and described, and the invention is intended to protect Protect all changes and modification within the scope of spirit of that invention.

Claims (16)

1. manufacturing the method with the steel lower than 0.035 weight % low-carbon, the method does not include the low-carbon comprising low-carbon FeMn The use of ferroalloy, described method includes following steps:

(a) in converter, prepare the furnace melting steel compositions that temperature reaches tapping temperature, which is vacuum tank degassing Temperature needed for carrying out desulfurization in furnace,

(b) oxygen level of tapping is opened as the melting steel compositions of 600~1120ppm and corresponding higher tapping carbon level to Sheng Steel drum, wherein the temperature at 1660 DEG C~1771 DEG C is implemented to open tapping step,

(c) ladle is supplied to cover with slag making compound to form clinker on the melting steel compositions in ladle,

(d) the melting steel compositions and clinker transported in ladle are covered to vacuum tank degasification furnace, and the clinker is covered on transport To the heat loss and oxidation for reducing melting steel compositions during vacuum tank degasification furnace,

(e) before decarburization, desired carbon content in the oxygen level and steel compositions in association melting steel compositions,

(f) decarburization is carried out to melting steel compositions by being evacuated to 350-650 millibars in vacuum tank degasification furnace,

(g) after decarburization, one or more deoxidiers are added into melting steel compositions and deoxidation is carried out to melting steel compositions,

(h) after deoxidation, one or more flux compounds are added to carry out desulfurization to melting steel compositions, and

(i) casting melting steel compositions has the steel for being lower than 0.035 weight % low-carbon to be formed,

Wherein decarburization, deoxidation and desulfurization all carry out in vacuum tank degasification furnace.

2. the method that manufacture described in claim 1 has the steel lower than 0.035 weight % low-carbon, wherein in tapping step Carbon amounts in steel compositions is 0.02%~0.05 weight %.

3. the method that manufacture of any of claims 1 or 2 has the steel lower than 0.035 weight % low-carbon, wherein prepare furnace melting The step of steel compositions, carries out in electric arc furnaces.

4. the method that manufacture described in claim 1 has the steel lower than 0.035 weight % low-carbon, wherein decarbonation process is in 350~550 millibars of vacuum level.

5. the method that manufacture of any of claims 1 or 2 has the steel lower than 0.035 weight % low-carbon, wherein be added it is a kind of or The aluminium of requirement is added in the vacuum level that the step of a variety of deoxidiers is included in 530~1000 millibars.

6. the method that manufacture of any of claims 1 or 2 has the steel lower than 0.035 weight % low-carbon, further includes walking as follows It is rapid: after desulfurization, to be evacuated to 1~2.5 millibar except denitrification.

7. the method that manufacture of any of claims 1 or 2 has the steel lower than 0.035 weight % low-carbon, wherein be added it is a kind of or The step of a variety of flux compounds includes that the one or more compounds for being selected from lime, aluminium, calcium aluminate and fero-manganesesilicon are added.

8. the method that manufacture as claimed in claim 7 has the steel lower than 0.035 weight % low-carbon, wherein the lime includes Dolomite lime.

9. the method that manufacture of any of claims 1 or 2 has the steel lower than 0.035 weight % low-carbon, wherein in tapping step In, the sulfur content in steel compositions is 0.02%~0.06 weight %.

10. the method that manufacture of any of claims 1 or 2 has the steel lower than 0.035 weight % low-carbon, further includes in decarburization Following step before step:

(i) melting steel compositions of the stirring in the ladle of vacuum tank degasification furnace,

(ii) temperature of the carbon amounts in steel compositions, the oxygen amount in steel compositions and steel compositions is measured and recorded,

(iii) process model is provided, the oxygen and carbon amounts and steel compositions in process model association steel compositions reach needs Decarburization time needed for carbon amounts；And

(iv) amount based on the oxygen and carbon that measure in steel compositions, determines decarburization time using process model.

11. the method that manufacture of any of claims 1 or 2 has the steel lower than 0.035 weight % low-carbon, further includes in decarburization Following step before step:

(i) steel compositions of the stirring in the ladle of vacuum tank degasification furnace,

(ii) temperature of the carbon amounts in steel compositions, the oxygen amount in steel compositions and steel compositions is measured and recorded,

(iii) process model is provided, the amount of oxygen and carbon in process model association steel compositions takes off with to steel compositions The amount of deoxidation additive needed for oxygen, and

(iv) amount based on the oxygen and carbon that measure, the amount of deoxidation additive in steel compositions is determined using process model.

12. the method that manufacture of any of claims 1 or 2 has the steel lower than 0.035 weight % low-carbon, further includes in decarburization Following step before step:

(i) steel compositions of the stirring in the ladle of vacuum tank degasification furnace,

(ii) temperature of the carbon amounts in steel compositions, the oxygen amount in steel compositions and steel compositions is measured and recorded；

(iii) process model is provided, the oxygen and carbon amounts which is associated in steel compositions carry out desulfurization with to steel compositions The amount of required flux component and price based on flux component can select one or more flux components；And

(iv) amount based on the oxygen and carbon that measure determines the selection of flux component and their amount using process model.

13. the method that manufacture of any of claims 1 or 2 has the steel lower than 0.035 weight % low-carbon, wherein at 1660 DEG C ~1700 DEG C of temperature is implemented to open tapping step.

14. the method that manufacture of any of claims 1 or 2 has the steel lower than 0.035 weight % low-carbon, wherein at 1700 DEG C ~1750 DEG C of temperature is implemented to open tapping step.

15. the method that manufacture of any of claims 1 or 2 has the steel lower than 0.035 weight % low-carbon, wherein at 1693 DEG C ~1771 DEG C of temperature is implemented to open tapping step.

16. the method that manufacture of any of claims 1 or 2 has the steel lower than 0.035 weight % low-carbon comprising: in (g) step After rapid, free oxygen is added into melting steel compositions until level is that 20~70ppm and total oxygen content are at least 70ppm's Step.