KR20140017193A - Desurfurization method for hot metal - Google Patents

Abstract

The present invention relates to a method of desulfurizing molten iron which removes a sulfur component in the molten iron during a steel manufacturing process by reusing waste, the method comprising: a step of injecting molten iron in a desulfurizing converter; a step of injecting a desulfurizing agent, which includes welding slag, into the injected molten iron; and a step of removing the sulfur component in the molten iron by stirring the injected desulfurizing agent and the molten iron. [Reference numerals] (AA) START; (BB) END; (S10) Inject molten iron in a desulfurizing converter; (S20) Inject a desulfurizing agent including welding slag into the injected molten iron; (S30) Remove the sulfur component in the molten iron by stirring the injected desulfurizing agent and the molten iron

Description

{DESURFURIZATION METHOD FOR HOT METAL}

The present invention relates to a desulfurization method for molten iron, and more particularly, to a molten iron desulfurization method for recycling waste to remove sulfur components in molten iron during a steelmaking process.

The steelmaking process that uses iron ore as a raw material to produce steel as final product starts with a steelmaking process that dissolves iron ore in the blast furnace. A molten steel is prepared by performing a pretreatment process such as desulfurization on a molten iron which is an iron ore-dissolved form. The molten steel thus produced is subjected to a primary refining process for removing impurities and a secondary refining process for finely adjusting the components in the primary refined molten steel to complete the component adjustment. After the secondary refining is completed, the molten steel is moved to a continuous casting process, and a semi-finished product such as slab, bloom, billet, etc. is formed through a continuous casting process. The semi-finished product thus formed is manufactured into a desired final product such as a rolling coil and a heavy plate through a final molding process such as rolling.

The molten iron is subjected to a preliminary treatment before the primary refining, that is, the decarburization and deoxidation treatment in the converter. The preliminary treatment of molten iron includes a desulfurization step in which the sulfur component of the molten iron is removed to the target value as necessary. Such a desulfurization process can be carried out in a mechanical stirrer called KR. At the time of desulfurization, the desulfurizing agent is injected into the molten iron and the molten iron is stirred by the impeller to promote the reaction between the desulfurizing agent and the molten iron. After the desulfurization process is completed and the sulfur content is removed to the pre-refining target value, the molten iron is transferred to the converter for the subsequent refining.

Related Prior Art Korean Patent Publication No. 2001-0010721 discloses a desulfurizing agent using deoxidized slag and a desulfurizing method using this desulfurizing agent.

The present invention is to provide a method of desulfurizing molten iron which can effectively introduce by-products generated in a welding process into a steelmaking process and effectively remove sulfur components in the molten iron using such by-products.

The technical objects to be achieved by the present invention are not limited to the above-mentioned technical problems.

According to an aspect of the present invention, there is provided a desulfurization method for molten iron, comprising the steps of: inputting molten iron into a desulfurization furnace; introducing a desulfurizing agent containing welding slag into the molten iron charged in the desulfurization furnace; And removing the sulfur component in the molten iron by stirring.

Specifically, the desulfurizing agent may be a mixed form of the welding slag and the calcium oxide (CaO), which are by-products generated when the metal plate is welded, at a predetermined ratio.

The weld slag may consist of 45 to 55% of Al ₂ O ₃ , 15 to 25% of MgO, 25 to 35% of CaO and the balance of other unavoidable impurities.

The mixing ratio of the welding slag and quicklime may be set to 1: 0.538 to 0.666.

INDUSTRIAL APPLICABILITY As described above, the present invention has the effect of realizing the effective utilization of waste resources by introducing the byproducts generated in the welding process into the steelmaking process by making them effective resources. In addition, since the use of a harmful desulfurizing agent used in the desulfurization step can be suppressed, environmental pollution is not generated. In addition, it is possible to improve the desulfurization efficiency while carrying out a process using an environmentally friendly desulfurizing material.

1 is a conceptual view briefly showing a mechanical stirring method among a desulfurization method of a molten iron associated with the present invention.
FIG. 2 is a conceptual view briefly showing a gas injection method of a molten iron desulfurization method according to the present invention.
3 is a flow chart showing a method of desulfurizing molten iron according to an embodiment of the present invention in order.
FIG. 4 is a schematic view of a desulfurization mechanism of a common molten iron according to the present invention.
FIG. 5 is a graph showing the difference in liquid phase ratio according to the kind of the desulfurizing agent related to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same components are denoted by the same reference symbols whenever possible. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

FIG. 1 is a conceptual view briefly showing a mechanical stirring method among molten iron desulfurization methods, and FIG. 2 is a conceptual view briefly showing a gas injection method during a molten iron desulfurization method. Referring to the drawings, a desulfurization process of a molten iron is carried out in the order of receiving molten iron (M) in a form in which iron ore is dissolved, and performing desulfurization and tapping. The molten iron desulfurization line M is moved to the decarburized converter to enter the main circulation.

The KR (Kanvara Reactor) method and the gas injection method are mainly used for the desulfurization process of the charcoal. In the mechanical stirring method, a molten iron to be desulfurized is charged into a desulfurization ladle, and mainly a massive desulfurizing agent (2) is charged through a hopper (1) into a molten iron at the top of the ladle, and an impeller (3) And the molten iron is stirred by rotating the molten iron, and the sulfur of the molten iron is reacted with the desulfurizing agent by the agitating force generated at this time.

In the gas injection system, the desulfurizing agent 20 is introduced into the converter from the hopper 10 separately installed at the upper part of the desulfurizing ladle, and the lance 30 capable of blowing gas from the upper part of the desulfurization converter is inserted into the tallin converter The gas is blown into the top of the charged charcoal. That is, the gas may be blown into the inside of the molten iron through the lance 20 at the top of the molten iron ladle to stir the molten iron to promote the desulfurization reaction.

When the molten iron is stirred by introducing the desulfurizing agent as described above, slag is formed on the molten iron M that has been desulfurized. After the desulfurization is completed, it is spouted and transferred for the next process.

FIG. 3 is a flowchart illustrating a method of desulfurizing molten iron according to an embodiment of the present invention. Referring to FIG. 3, a molten iron manufactured through a first step of a steelmaking process is charged into a converter (S10). At this time, the converter may be a desulfurization furnace which performs only desulfurization. As described above, the desulfurization furnace can be selectively used either KR which performs desulfurization by mechanical stirring or desulfurization furnace which performs desulfurization by gas agitation This is possible.

In this way, the charcoal charged into the converter may contain a large amount of sulfur component originating from iron ore, and desulfurizing agent is injected into the charcoal to remove it. The desulfurizing agent used in the present invention is a desulfurizing agent containing a welding slag, and the welding slag is a welding by-product generated when a metal plate used for shipbuilding or the like is welded, such as alumina (Al ₂ O ₃ ), magnesium oxide (MgO) (CaO), and the like. For example, the welding slag may be a slag generated when welding a board material for shipbuilding, and in this case, about 70 g of slag is generated per 1 m of the welding. Since the welding slag generated at this time is classified as waste, in the present invention, such a welding slag is introduced into the steelmaking furnace and used as a desulfurizing agent, so that the waste resources can be effectively used to make an environmentally friendly function.

Generally, in the steelmaking process, a pre-treatment process is performed to remove sulfur or phosphorous in the iron wire before the first refining of the hot metal made of iron ore. In the desulfurizing step of the preliminary treatment of the molten iron, a predetermined desulfurizing agent is injected into the molten iron to remove a large amount of the sulfur component contained in the molten iron to the target value set before the refining. To a desulfurization before to perform only desulfurization of the molten iron is used separately (for primary polishing) as before decarburization To this end, common desulfurizing agent used in a desulfurization before by the calcium oxide (CaO) to the base The calcium fluoride (CaF ₂₎ Are mixed and used. The fluorite used herein is used for the purpose of lowering the melting point of quicklime and improving the sulfur removal capacity, but it is classified as an environmentally harmful substance and its use is very limited. Therefore, in the present invention, a desulfurizing agent in which the welding slag is mixed with quicklime is used so that the melting point of the quicklime used as a desulfurizing agent can be reduced without using fluorspar, and the waste can be effectively used.

The welding slag of the present invention has the composition as shown in Table 1 below. The welding slag contains the same components as alumina (Al ₂ O ₃ )), magnesium oxide (MgO) and a certain amount of calcium oxide (CaO) have.

ingredient Al ₂ O ₃ MgO CaO Content (% by weight) 45-55 15-25 25`35

The composition of the welding slag shown in Table 1 may further include other inevitably added impurity components.

Thus, the alumina component included in the welding slag reduces the melting point of the quicklime used as the desulfurizing agent together with the welding slag, thereby promoting the reaction with the molten iron at the same temperature, thereby improving the desulfurization efficiency of the molten iron.

FIG. 4 is a schematic view of a desulfurization mechanism of a general charcoal line. Referring to FIG. 4, when burnt lime is introduced into a charcoal line, a desulfurization reaction occurs at a portion where the surface of the burnt lime is melted and comes into contact with charcoal. That is, since the melting point of the quicklime is high, the molten slag is desulfurized by the reaction shown in the following reaction formula 1 at the surface portion of the burnt lime to be melted first, rather than being completely melted and reacted in the molten iron.

Scheme 1

CaO + S = CaS + O

In this way, desulfurization is carried out through the reaction of quicklime with sulfur (S) in the charcoal, and fluorite plays a role in effectively reacting activated charcoal (CaO) with charcoal. In other words, fluorocarbons increase C _S (sulfur's capacity) by increasing the area of the slag / charcoal and stabilizing the desulfurization product in the slag.

In the present invention, in particular, the role of the lowering of the melting point of the quicklime carried out by the existing fluorite is defined as the liquid phase rate (%) meaning the liquid phase rate, that is, the efficiency of facilitating liquefaction due to the lowering of the melting point of calcium oxide (CaO) Were compared with each other. As shown in FIG. 5, the liquid phase ratio of the desulfurizing agent, that is, the melting point of the burnt lime injected into the desulfurizing agent, is reduced to increase the area of the reaction interface of the desulfurizing agent to improve the sulfur removal capacity It can be seen that the mixed lime and alumina (Al ₂ O ₃ ) are the highest.

Specifically, it can be seen that the desulfurization agent in the form of the quicklime and alumina mixed with the liquidity is about 12%, which is higher than the liquidus rate of the desulfurization agent in which the quicklime and fluorite (CaF ₂ ) are generally used. Therefore, in the present invention, the alumina component contained in the welding slag used as the desulfurizing agent promotes the lowering of the melting point of the calcium oxide (CaO) component contained in the burnt lime and the welding slag itself, so that the reaction surface area Thereby enabling effective desulfurization.

The desulfurizing agent used in the present invention is a mixed form of a by-product of welding slag and calcium oxide (CaO), which are byproducts generated when welding a metal plate, at a predetermined ratio. Specifically, 60 to 65% by weight of the welding slag and 35 to 40% . Therefore, the mixing ratio of the welding slag and the quicklime is preferably set to 1: 0.538 to 0.666.

Generally, about 10% of the weight of quicklime is used when desulfurizing lime and fluorite are used as desulfurizing agent. However, when the welding slag and the quicklime according to the present invention are used as a desulfurizing agent, calcium oxide (CaO), which is a quicklime component, is already contained in the welding slag as shown in Table 1, It is possible to contribute to cost reduction of the steelmaking process.

In the present invention, the reason why the mixing ratio of the weld slag and the quicklime is limited to the above ratio is that the desulfurization efficiency is improved in consideration of the amount of components such as alumina and calcium oxide in the weld slag, So that an appropriate component ratio that does not affect the composition can be maintained.

In addition, magnesium oxide (MgO) contained in the welding slag is also a component that can participate in desulfurization of the molten iron and is a component that does not affect the quality of the molten iron other than the desulfurization. Therefore, the welding slag is very suitable for the desulfurization Material.

Finally, desulfurization of the molten iron is performed by removing the sulfur component in the molten iron by stirring the molten iron with the desulfurization agent injected into the desulfurization converter (S30). In the present invention, when the KR is used after mixing the welding slag and the quicklime in accordance with the above-mentioned ratio, the impeller is rotated to stir the molten iron and the desulfurizing agent to accelerate desulfurization in the molten iron. When the desulfurization is carried out through the gas injection method, desulfurization is carried out by introducing the desulfurizing agent and then blowing the gas into the molten iron to promote the reaction between the molten iron and the desulfurizing agent.

The method of desulfurizing the molten iron as described above is not limited to the construction and operation of the embodiments described above. The above embodiments may be configured such that various modifications may be made by selectively combining all or part of the embodiments.

1, 10: hopper 2, 20: desulfurizing agent
3: impeller 30: lance

Claims (4)

Introducing a charcoal into the desulfurization furnace;
Introducing a desulfurizing agent including welding slag into the charged molten iron; And
And removing the sulfur component in the molten iron by stirring the desulfurization agent and the molten iron introduced in the molten iron.
The method according to claim 1,
The desulfurizing agent,
A method of desulfurizing a molten iron which is a by-product of welding slag and calcium oxide (CaO) mixed in a predetermined ratio.
The method according to claim 1,
The weld slag, in weight percent,
45 to 55% of Al ₂ O ₃ , 15 to 25% of MgO, 25 to 35% of CaO, and other unavoidable impurities.
The method according to claim 2,
Wherein a mixing ratio of the welding slag and the quick lime is set to 1: 0.538 to 0.666.

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