UA66219A - A method for the dephosphorization and desulphurization of cast iron - Google Patents

Abstract

A method for the dephosphorization and desulphurization of cast iron involves the out-of furnace processing the cast iron with flux containing sodium salts - sodium sulfate and carbonate. At that the flux being incorporated into the liquid cast iron in the form of melt of these salts

Description

Description of the invention

The invention relates to the field of ferrous metallurgy, in particular to the out-of-furnace processing of cast iron and can be used mainly in the dephosphorization and desulfurization of pig iron.

When smelting cast iron from a charge containing sulfur and phosphorus, their content in the finished cast iron often exceeds permissible standards. One of the methods of bringing cast iron to the desired condition is post-bake treatment - desulfurization and dephosphorization, which allow reducing the content of unwanted impurities to the required values.

After-burning treatment of the liquid bath is carried out with special reagents - fluxes. 70 There is a known method of dephosphorization and desulfurization of cast iron, which consists in treating the melt with sodium-containing flux.

A mixture of sodium carbonate and oxygen-containing material (rolling slag, etc.) is used as a flux. (1.

Dephosphorization of molten iron. (Nippon Kokan k.k.). Application 57-98617, IPC I321С1/02, Japan, filed 11.12.80, R.zh. Metallurgy, 68140P, 1983).

A significant drawback of the method is the high cost of processing, due to the use of expensive pure materials (sodium carbonate), as well as the increased consumption of the reagent, due to the inclusion of the dusty fraction in the gas phase. In addition, when using the method, there is a significant (up to 1007) decrease in the temperature of cast iron during processing, due to the large amount of iron contained in the oxidizer, which further leads to an increase in the cost of cast iron for steel smelting and, therefore, to an increase in the cost of finished steel.

The method of dephosphorization and desulfurization of cast iron, which consists in treating the melt with a flux consisting of a mixture of equal parts of sodium carbonate and sodium sulfate, used in the form of powders, was adopted as a prototype. (2. Ipotse K., Zi!yo, N. "Serpozrpogigayop oi MoMep Igop Bu bodisht Sagropaie apa Bodiit Ziyirpagye" // "Kezeagsi Apisie" Tgapsasiopz IBI), 1981, Moi.21, Mov, p.545-553).

The use of this method allows processing of cast iron with a degree of dephosphorization equal to 9890 29 with a flux consumption of 995 from the weight of the processed metal. "

The main disadvantage of this method is the high cost of post-bake processing of cast iron, caused by the large consumption of an expensive reagent (flux). Within the framework of this method, it is impossible to reduce flux consumption, because significant losses of sodium carbonate and sulfate are due to their evaporation as a result of thermal dissociation during heating at the moment of impact on the surface of liquid cast iron and the removal of small particles of flux (used components of 30 flux are powders) by convection currents from the active zone. "-

In addition, the increased amount of flux components carried away by gas flows has a negative impact on the environment. with

The invention is based on the task: to reduce the cost of post-furnace processing (dephosphorization and desulfurization) of cast iron by using a cheaper material as a flux - and fused waste containing 30% sulfate and sodium carbonate. eh

The technical result achieved when using the invention is a reduction in reagent consumption due to limiting the evaporation of flux components and reducing flux removal into the atmosphere due to its use in the form of an alloy of sulfate and sodium carbonate, i.e. in the form of compact particles (for example, granules). "

In addition, environmental pollution by flux vapor products and particles that C 70 are carried out of the processing area by convection currents is reduced. c The solution to the given problem is achieved by the fact that in the proposed method, the liquid is processed after baking

From" cast iron is made with a flux containing sodium salts - sodium sulfate and sodium carbonate, which are introduced into the cast iron in the form of an alloy of these salts. Flux is obtained by burning caprolactam and adipic acid production waste in a hydrocarbon atmosphere. 45 To increase the effect achieved when using the invention, the flux is composed in such a way that the ratio of the content of sodium carbonate and sulfate in the flux is 1:4-4:1.

Gee! To increase the effect achieved when using the invention, part of the flux is introduced by blowing it into the mass of liquid cast iron with the help of an immersion nozzle. di To increase the effect achieved when using the invention, fusion of the flux is done -sh 20 immediately before the introduction of components into the liquid metal.

A comparison of the claimed method with the prototype shows the following differences: c - the flux is injected into the liquid metal in the form of an alloy of sodium salts, - the ratio of the content of sodium carbonate and sodium sulfate in the flux is 1:4-4:1, - part of the flux is injected by blowing into the mass of cast iron with the help of an immersion lance, - the flux is obtained by burning the waste products of the production of caprolactam and adipic acids in a hydrocarbon furnace. atmosphere, fusion of the flux is done immediately before the introduction of components into the liquid metal.

Therefore, the claimed method meets the "novelty" criterion.

A comparison with other technical solutions in this field of technology did not allow us to identify features that distinguish the claimed method from the prototype. Because, therefore, the claimed technical solution meets the "inventive level" criterion.

The essence of the claimed method is that, when burning raw materials (liquid waste from the production of caprolactam and adipic acids) in cyclone furnaces in a hydrocarbon atmosphere, ash with the following composition is produced: b5 sodium carbonate (Mag2СО3) 20-8096;

sodium sulfate (MazZOd) 80-2095; sodium chloride (mass) 5-69; caustic sodium (maOH) up to 1.595, the high content of sodium sulfate and carbonate in which determined its use as a reagent.

Ash is a solid crystalline substance in the form of flat particles with a thickness of 5 mm and dimensions of 30 x 5 mm, which before use are crushed to a fraction of 1 mm, for example, using granulation.

Sodium sulfate Ma»5O,4, contained in the ash, is an active oxidizing agent, 1.2 g is contained in 1 cm. of active 70 Koxygen, that is, as much as in liquid oxygen at minus 19572 |Z. OeiYivep MU, Epirpozrpogipd pa

Epivpuletaiipu Kopiepzioitgeiisneg Eivepesptei!lep ipieg Semzhippipd RIozrpogzatsgegispe, mazzegioviispeg zspiaspep

LEE Agsp. Eiseppiy, 1965, 36, Mo12, p.861-871.), and the absence of ballast iron (BeO, Re»Oz) in the oxidizer does not accompany the dephosphorization process with a significant decrease in temperature.

When the flux comes into contact with molten cast iron, it melts, partially dissociates and interacts with 75 components of the flux with cast iron impurities. Sodium sulfate effectively oxidizes phosphorus contained in cast iron to pentoxide P»Ov. This compound is unstable, and the phosphorus from it can be easily reduced by cast iron carbon. To prevent this phenomenon, sodium carbonate is included in the composition of the flux, which, as an active flux-forming material, binds ROB pentoxide into a stable complex - sodium phosphate MazR»Ov, which turns into slag.

In addition, sodium carbonate (Ma»CO3) binds sulfur present in cast iron into stable sodium sulfide.

When processing liquid cast iron, the material proposed in this application as flux (ash) behaves slightly differently than the mechanical mixture of powdered carbonate and sodium sulfate, which also turns into slag.

It is known that the rate of evaporation of the components or the combination of the mixture depends on the activity of the components. As the activity of the components decreases, the rate of their evaporation decreases. The components of the mechanical mixture have activities equal to one, and the components of the fused material have activity values less than one, therefore, in the Ma-containing salts, which are in the fused state, there is less evaporation loss, the degree of use of the reagent is higher, and therefore the specific consumption of the reagent is lower. "

The use of flux in the form of an alloy of sodium salts reduces the amount of substances released into the atmosphere during processing, which contributes to the reduction of environmental pollution.

The higher efficiency of the proposed method was established by comparing the results obtained during its use with those described in the prototype.

To do this, an experimental study of the refining ability of the flux was carried out on hot models using a laboratory resistance furnace according to the method described in the prototype (2). The weight of processed C metal is 300 g. The weight of the embedded flux is 28 g. The ratio of the content of sodium carbonate to the content of sodium sulfate in the flux was changed from 4.7:1 to 1:5.02. The change in the content of sulfur and phosphorus in cast iron as a result of processing was evaluated based on the data of chemical analysis of cast iron samples taken before and after processing. The efficiency of the use of the reagent (He) was estimated by the value of the specific mass flow rate of the reagent per impurity to be removed (indicator bkg/kg),

For comparison, the values of indicator 2 were calculated for the experiments described in the prototype. (Table 1) "

The values of d. and Br, obtained as a result of experimental processing, allow us to quantitatively assess the efficiency of the sulfur and phosphorus removal process by calculating the reagent costs for the removal of kg of impurity c (kg/kg) and are the basis for comparison with the efficiency indicators of the claimed technology. ;" is (o) Mop/p Refining flux o name) » -

Fo

The advantage of the proposed method (minimum specific consumption of the reagent for removing sulfur and phosphorus 5. and 59 Vr) is illustrated by the results given in Table 2. c" As a result of processing cast iron with fused sulfate and sodium carbonate with a ratio of components in the range of 1:4-4:1 (experiments Mo2-5), the maximum efficiency of the use of the reagent is achieved, i.e. its minimum consumption for sulfur removal (ve - 18.97 - Tanks and phosphorus (Br -43- compounds - When processing pig iron with a mixture of sulfate and sodium carbonate (Table 1), the consumption of the reagent for removing sulfur and phosphorus (8. and Br) is slightly higher and amounts to 21.63-23.85/k, respectively and 4.7-4.77 "7, which indicates a lower efficiency of using the reagent as a result of its higher degree of evaporation.

As a result of processing cast iron with fused carbonate and sodium sulfate with a ratio of 4.7:1.0 v5 (Experiment 1), the consumption of the reagent for removing phosphorus is higher (4.97/), which indicates the lack of sodium sulfate for the oxidation of phosphorus (the degree of desulfurization cast iron is quite high at the same time).

As a result of processing cast iron with fused carbonate and sodium sulfate with a ratio of components of 1:4.5 and 1:5.02, a fairly effective dephosphorization process is observed (Br - aa - alco l, however, the desulfurization process in this case is complicated, as evidenced by high indicators of r. - 26 -32kg 95 The fused material evaporates to a lesser extent when in contact with the liquid metal and is carried away from the processing zone by convection currents to a lesser extent. In this way, the effect is achieved that a large part of the flux is drawn into the processing process and the consumption of flux components is reduced.

The specified ratio of the components of the fused flux ensures the optimal ratio of the dephosphorization and desulfurization processes during the processing of cast iron due to the fact that the resulting refining slag has both a fairly high oxidizing capacity and a high sulfate and phosphate capacity.

Supplying part of the flux to the surface of the metal, and part of it to the mass of liquid metal with the help of a plunging nozzle, ensures effective metal processing by increasing the degree of use of the flux as a result of the assimilation of the particles carried out of the blowing reaction zone by the coating slag located on the surface.

The fusion of flux components directly in the process of its introduction into liquid cast iron ensures that the necessary material is obtained immediately before the interaction of the reagent components with cast iron impurities. In this situation, there is no need for an additional operation - crushing.

The proposed technical solution was implemented as follows:

Since dephosphorization and desulfurization of cast iron with Ma-containing fluxes is effective when the content of silicon in cast iron is at the level of 0.195 or less, cast iron before dephosphorization and desulfurization was subjected to preliminary desilication. For this purpose, in the process of filling the ladle with pig iron in the amount of 75 bt., containing 0.5955i, 0.195Mp, 0.050955 and 0.22090Р, lump fused sulfate and sodium carbonate with a specific mass flow rate of 15 kg/t were given "under the stream" cast iron In the process of filling the ladle, intensive melting of the mixture took place and effective interaction of the silicon of the cast iron with the oxygen of the flux, as a result of which the content of silicon in the cast iron was reduced to 0.1195. The slag formed in the desilication process was skimmed off the surface of the cast iron, after which the ladle with the cast iron was directed to dephosphorization and desulfurization. For this purpose, 340 kg (5095 of the required amount) of fused lump sulfate and sodium carbonate were released from the hopper-doser into the ladle on the surface of the cast iron to form a covering refining slag on the surface of the metal.

Another amount of flux (340Okg) in the form of near-spherical particles with a size of 1-3mm was injected during 16 minutes into the mass of cast iron with the help of an immersion nozzle by injection with an intensity of 22kg/min. As a result, F 30. - y and y such processing produced cast iron containing 0.0190Р and 0.005955. At the same time, indicators were achieved -

Ve - baki Her work - act. sch se;

From Mo p/p | Content of components in | Ratio Specific mass flow rate of flux Specific flow rate of reagent per ise)

ZAS sya ss znszNst ns st NI NS « - p

And a | for 100 loyav 00100111005800000 oo oo ayu soyu (oo oz og zy) for 440 sho. Thus, the use of the proposed method of dephosphorization and desulfurization of cast iron allows solving the problem of reducing the cost of post-furnace processing of cast iron and obtaining a technical result, which consists in (22) reducing flux costs and reducing harmful emissions. name) -oUu 70

Claims (5)

The formula of the invention iChe) and sho and . more 1. The method of dephosphorization and desulfurization of cast iron, which includes post-furnace treatment of cast iron with a flux containing sodium salts - sulfate and sodium carbonate, which differs in that the flux is introduced into liquid cast iron in the form of an alloy of these salts. 2. The method according to claim 1, which differs in that the ratio of the content of carbonate and sodium sulfate in the flux is is 1:4 - 4:1. C. The method according to claim 1, which differs in that part of the flux is introduced by blowing into the mass of cast iron with the help of an immersion nozzle. in 4. The method according to claim 1, which is characterized by the fact that the flux is obtained by burning caprolactam and adipic acid production waste in a hydrocarbon atmosphere. 5. The method according to claim 1, which differs in that the fusion of the flux is carried out immediately before the introduction of the components into the liquid metal. Official bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated 65 microcircuits", 2004, M 4, 15.04.2004. State Department of Intellectual Property of the Ministry of Education and